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Lawrence Lee 2025-04-21 22:37:26 -07:00
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8
rtdata/languages/Catala
View File

@ -3445,17 +3445,17 @@ ZOOMPANEL_ZOOMOUT;Allunya\nDrecera: <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -3843,7 +3843,7 @@ ZOOMPANEL_ZOOMOUT;Allunya\nDrecera: <b>-</b>
!TP_LOCALLAB_SETTINGS;Settings !TP_LOCALLAB_SETTINGS;Settings
!TP_LOCALLAB_SH1;Shadows Highlights !TP_LOCALLAB_SH1;Shadows Highlights
!TP_LOCALLAB_SH2;Equalizer !TP_LOCALLAB_SH2;Equalizer
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SHADEX;Shadows !TP_LOCALLAB_SHADEX;Shadows
!TP_LOCALLAB_SHADEXCOMP;Shadow compression !TP_LOCALLAB_SHADEXCOMP;Shadow compression
!TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS !TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS

8
rtdata/languages/Czech
View File

@ -3914,17 +3914,17 @@ ZOOMPANEL_ZOOMOUT;Oddálit\nZkratka: <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -4312,7 +4312,7 @@ ZOOMPANEL_ZOOMOUT;Oddálit\nZkratka: <b>-</b>
!TP_LOCALLAB_SETTINGS;Settings !TP_LOCALLAB_SETTINGS;Settings
!TP_LOCALLAB_SH1;Shadows Highlights !TP_LOCALLAB_SH1;Shadows Highlights
!TP_LOCALLAB_SH2;Equalizer !TP_LOCALLAB_SH2;Equalizer
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SHADEX;Shadows !TP_LOCALLAB_SHADEX;Shadows
!TP_LOCALLAB_SHADEXCOMP;Shadow compression !TP_LOCALLAB_SHADEXCOMP;Shadow compression
!TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS !TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS

8
rtdata/languages/Dansk
View File

@ -3813,17 +3813,17 @@ ZOOMPANEL_ZOOMOUT;Zoom Ud\nGenvej: <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -4211,7 +4211,7 @@ ZOOMPANEL_ZOOMOUT;Zoom Ud\nGenvej: <b>-</b>
!TP_LOCALLAB_SETTINGS;Settings !TP_LOCALLAB_SETTINGS;Settings
!TP_LOCALLAB_SH1;Shadows Highlights !TP_LOCALLAB_SH1;Shadows Highlights
!TP_LOCALLAB_SH2;Equalizer !TP_LOCALLAB_SH2;Equalizer
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SHADEX;Shadows !TP_LOCALLAB_SHADEX;Shadows
!TP_LOCALLAB_SHADEXCOMP;Shadow compression !TP_LOCALLAB_SHADEXCOMP;Shadow compression
!TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS !TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS

90
rtdata/languages/Deutsch
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@ -89,6 +89,7 @@
#87 29.03.2025 Erweiterung (marter) RT 5.12 #87 29.03.2025 Erweiterung (marter) RT 5.12
#100 #100
#101 @LANGUAGE_DISPLAY_NAME=Deutsch #101 @LANGUAGE_DISPLAY_NAME=Deutsch
ABOUT_TAB_BUILD;Version ABOUT_TAB_BUILD;Version
ABOUT_TAB_CREDITS;Danksagungen ABOUT_TAB_CREDITS;Danksagungen
ABOUT_TAB_LICENSE;Lizenz ABOUT_TAB_LICENSE;Lizenz
@ -1654,28 +1655,28 @@ HISTORY_MSG_LOCAL_FEATHERSH;(sel. Editieren - Schatten/Lichter)\nVerlaufsfilter\
HISTORY_MSG_LOCAL_FEATHERVIB;(sel. Editieren - Farbtemperatur)\nVerlaufsfilter\nVerlaufsbreite HISTORY_MSG_LOCAL_FEATHERVIB;(sel. Editieren - Farbtemperatur)\nVerlaufsfilter\nVerlaufsbreite
HISTORY_MSG_LOCAL_FEATHERWAV;(sel. Editieren - Wavelet)\nVerlaufsfilter\nVerlaufsbreite HISTORY_MSG_LOCAL_FEATHERWAV;(sel. Editieren - Wavelet)\nVerlaufsfilter\nVerlaufsbreite
HISTORY_MSG_LOCAL_GAMUTMUNSEL;(sel. Editieren - Spot)\nSpeziell\nFarbverschiebung vermeiden HISTORY_MSG_LOCAL_GAMUTMUNSEL;(sel. Editieren - Spot)\nSpeziell\nFarbverschiebung vermeiden
HISTORY_MSG_LOCAL_LOGCIE12;(sel. Editieren -CIECAM)\nQuellen-Daten\nLog-Kodierung
HISTORY_MSG_LOCAL_GHSMETHOD;(sel. Editieren - Schatten/Lichter - GHS)\nMethodenauswahl HISTORY_MSG_LOCAL_GHSMETHOD;(sel. Editieren - Schatten/Lichter - GHS)\nMethodenauswahl
HISTORY_MSG_LOCAL_GHS_D;(sel. Editieren - Schatten/Lichter - GHS)\nDehnungsfaktor
HISTORY_MSG_LOCAL_GHS_SLOPE;(sel. Editieren - Schatten/Lichter - GHS)\nSteigungsfaktor Lab
HISTORY_MSG_LOCAL_GHS_CHRO;(sel. Editieren - Schatten/Lichter - GHS)\nBuntheitsfaktor Lab
HISTORY_MSG_LOCAL_GHS_B;(sel. Editieren - Schatten/Lichter - GHS)\nLokale Intensität HISTORY_MSG_LOCAL_GHS_B;(sel. Editieren - Schatten/Lichter - GHS)\nLokale Intensität
HISTORY_MSG_LOCAL_GHS_SP;(sel. Editieren - Schatten/Lichter - GHS)\nSymmetriepunkt
HISTORY_MSG_LOCAL_GHS_LP;(sel. Editieren - Schatten/Lichter - GHS)\nSchatten schützen
HISTORY_MSG_LOCAL_GHS_HP;(sel. Editieren - Schatten/Lichter - GHS)\nLichter schützen
HISTORY_MSG_LOCAL_GHS_LC;(sel. Editieren - Schatten/Lichter - GHS)\nLokaler Kontrast
HISTORY_MSG_LOCAL_GHS_MID;(sel. Editieren - Schatten/Lichter - GHS)\nMitteltöne
HISTORY_MSG_LOCAL_GHS_BLP;(sel. Editieren - Schatten/Lichter - GHS)\nSchwarzpunkt HISTORY_MSG_LOCAL_GHS_BLP;(sel. Editieren - Schatten/Lichter - GHS)\nSchwarzpunkt
HISTORY_MSG_LOCAL_GHS_CHRO;(sel. Editieren - Schatten/Lichter - GHS)\nBuntheitsfaktor Lab
HISTORY_MSG_LOCAL_GHS_D;(sel. Editieren - Schatten/Lichter - GHS)\nDehnungsfaktor
HISTORY_MSG_LOCAL_GHS_HLP;(sel. Editieren - Schatten/Lichter - GHS)\nWeißpunkt HISTORY_MSG_LOCAL_GHS_HLP;(sel. Editieren - Schatten/Lichter - GHS)\nWeißpunkt
HISTORY_MSG_LOCAL_GHS_HP;(sel. Editieren - Schatten/Lichter - GHS)\nLichter schützen
HISTORY_MSG_LOCAL_GHS_INV;(sel. Editieren - Schatten/Lichter - GHS)\nGHS Invertieren HISTORY_MSG_LOCAL_GHS_INV;(sel. Editieren - Schatten/Lichter - GHS)\nGHS Invertieren
HISTORY_MSG_LOCAL_GHS_LC;(sel. Editieren - Schatten/Lichter - GHS)\nLokaler Kontrast
HISTORY_MSG_LOCAL_GHS_LP;(sel. Editieren - Schatten/Lichter - GHS)\nSchatten schützen
HISTORY_MSG_LOCAL_GHS_MID;(sel. Editieren - Schatten/Lichter - GHS)\nMitteltöne
HISTORY_MSG_LOCAL_GHS_SLOPE;(sel. Editieren - Schatten/Lichter - GHS)\nSteigungsfaktor Lab
HISTORY_MSG_LOCAL_GHS_SMOOTH;(sel. Editieren - Schatten/Lichter - GHS)\nGlanzlichtdämpfung HISTORY_MSG_LOCAL_GHS_SMOOTH;(sel. Editieren - Schatten/Lichter - GHS)\nGlanzlichtdämpfung
HISTORY_MSG_LOCAL_GHS_SP;(sel. Editieren - Schatten/Lichter - GHS)\nSymmetriepunkt
HISTORY_MSG_LOCAL_LOGCIE12;(sel. Editieren -CIECAM)\nQuellen-Daten\nLog-Kodierung
HISTORY_MSG_LOCAL_LOG_BLACKS;(sel. Editieren - LOG-Kodierung)\nSchwarz-Verteilung HISTORY_MSG_LOCAL_LOG_BLACKS;(sel. Editieren - LOG-Kodierung)\nSchwarz-Verteilung
HISTORY_MSG_LOCAL_LOG_COMPR;(sel. Editieren - LOG-Kodierung)\nHelligkeitskompression HISTORY_MSG_LOCAL_LOG_COMPR;(sel. Editieren - LOG-Kodierung)\nHelligkeitskompression
HISTORY_MSG_LOCAL_LOG_SAT;(sel. Editieren - LOG-Kodierung)\nSättigungskontrolle HISTORY_MSG_LOCAL_LOG_SAT;(sel. Editieren - LOG-Kodierung)\nSättigungskontrolle
HISTORY_MSG_LOCAL_LOG_WHITES;(sel. Editieren - LOG-Kodierung)\nWeißverteilung HISTORY_MSG_LOCAL_LOG_WHITES;(sel. Editieren - LOG-Kodierung)\nWeißverteilung
HISTORY_MSG_LOCAL_NLITER;(sel. Editieren - Rauschminderung)\nNicht-lokales Mittel\nIterationen
HISTORY_MSG_LOCAL_OFFSETWAV;(sel. Editieren - lokaler Kontrast)\nWavelets\nVersatz HISTORY_MSG_LOCAL_OFFSETWAV;(sel. Editieren - lokaler Kontrast)\nWavelets\nVersatz
HISTORY_MSG_LOCAL_PROCESSWAV;(sel. Editieren - lokaler Kontrast)\nWavelets\nAnzeige der modifizierten Bereiche HISTORY_MSG_LOCAL_PROCESSWAV;(sel. Editieren - lokaler Kontrast)\nWavelets\nAnzeige der modifizierten Bereiche
HISTORY_MSG_LOCAL_NLITER;(sel. Editieren - Rauschminderung)\nNicht-lokales Mittel\nIterationen
HISTORY_MSG_LOCAL_QJMETHOD;(sel. Editieren - CIECAM)\nTonemapping Operator Q & J HISTORY_MSG_LOCAL_QJMETHOD;(sel. Editieren - CIECAM)\nTonemapping Operator Q & J
HISTORY_MSG_LOCAL_SIGBLCIE;(sel. Editieren - CIECAM)\nCAM16 - Sigmoid Q\nÜberlagern 5.11 HISTORY_MSG_LOCAL_SIGBLCIE;(sel. Editieren - CIECAM)\nCAM16 - Sigmoid Q\nÜberlagern 5.11
HISTORY_MSG_LOCAL_SIGDACIE;(sel. Editieren - CIECAM)\nCAM16 - Sigmoid Q\nKontrast 5.11 HISTORY_MSG_LOCAL_SIGDACIE;(sel. Editieren - CIECAM)\nCAM16 - Sigmoid Q\nKontrast 5.11
@ -2292,7 +2293,6 @@ PREFERENCES_WBACORR_TOOLTIP;Diese Einstellungen ermöglichen, abhängig von den
PREFERENCES_WBAENA;Zeige Einstellungen der Temperaturkorrelation bei automatischem Weißabgleich PREFERENCES_WBAENA;Zeige Einstellungen der Temperaturkorrelation bei automatischem Weißabgleich
PREFERENCES_WBAENACUSTOM;Benutzerdefinierte Temperatur und Tönung PREFERENCES_WBAENACUSTOM;Benutzerdefinierte Temperatur und Tönung
PREFERENCES_WBAFORC;Erzwingt extra Algorithmus PREFERENCES_WBAFORC;Erzwingt extra Algorithmus
!PREFERENCES_WBAGREENDELTA;Delta temperature in green iterate loop (if Force Extra enabled)
PREFERENCES_WBANOPURP;Keine lila Farben verwendet PREFERENCES_WBANOPURP;Keine lila Farben verwendet
PREFERENCES_WBAPATCH;maximale Anzahl der im bild verwendeten Farben PREFERENCES_WBAPATCH;maximale Anzahl der im bild verwendeten Farben
PREFERENCES_WBAPRECIS;Präzision Algorithmus - skaliert PREFERENCES_WBAPRECIS;Präzision Algorithmus - skaliert
@ -3363,49 +3363,49 @@ TP_LOCALLAB_GAMUTXYZRELA;XYZ Relativ
TP_LOCALLAB_GAMW;Gamma (Wavelet Pyramiden) TP_LOCALLAB_GAMW;Gamma (Wavelet Pyramiden)
TP_LOCALLAB_GHSBPWP; Anzahl ungültiger Pixel - Schatten:%1 Lichter:%2 TP_LOCALLAB_GHSBPWP; Anzahl ungültiger Pixel - Schatten:%1 Lichter:%2
TP_LOCALLAB_GHSBPWPVALUE;Pixelwerte - Dunkelste:%1 Hellste:%2 TP_LOCALLAB_GHSBPWPVALUE;Pixelwerte - Dunkelste:%1 Hellste:%2
TP_LOCALLAB_GHS_GHSDIAG; Visualisierung der GHS-Kurve TP_LOCALLAB_GHSFRA;Dehnungseinstellungen
TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Zeigt eine repräsentative Kurve der GHS-Funktion. TP_LOCALLAB_GHSHUE;Farbton (HSL)
TP_LOCALLAB_GHSLAB;Helligkeit & Buntheit (Lab)
TP_LOCALLAB_GHSLABFRA;Lab Einstellungen
TP_LOCALLAB_GHSLUM;Helligkeit (HSL)
TP_LOCALLAB_GHSRGBLUM;RGB Luminanz TP_LOCALLAB_GHSRGBLUM;RGB Luminanz
TP_LOCALLAB_GHSRGBSTD;RGB Standard TP_LOCALLAB_GHSRGBSTD;RGB Standard
TP_LOCALLAB_GHSLAB;Helligkeit & Buntheit (Lab)
TP_LOCALLAB_GHSHUE;Farbton (HSL)
TP_LOCALLAB_GHSLUM;Helligkeit (HSL)
TP_LOCALLAB_GHSSAT;Sättigung (HSL) TP_LOCALLAB_GHSSAT;Sättigung (HSL)
TP_LOCALLAB_GHSFRA;Dehnungseinstellungen
TP_LOCALLAB_GHS_D;Dehnungsfaktor (D)
TP_LOCALLAB_GHS_B;Lokale Intensität (b) TP_LOCALLAB_GHS_B;Lokale Intensität (b)
TP_LOCALLAB_GHS_SP;Symmetriepunkt (SP)
TP_LOCALLAB_GHS_LP;Schatten schützen (LP)
TP_LOCALLAB_GHS_HP;Lichter schützen (HP)
TP_LOCALLAB_GHS_LC;lokaler Kontrast (LC)
TP_LOCALLAB_GHS_LC_FRAME;Dehnungsregelung & Mitteltöne
TP_LOCALLAB_GHS_LC_TOOLTIP;Erhöht leicht den lokalen Kontrast, der durch die Dehnung abgeschwächt wurde.\nKann durch andere, auf lokalen Kontrast spezialisierte Tools wie Wavelets ergänzt werden.\n\nWenn der Dehnungsfaktor 0,002 oder weniger beträgt, sind Dehnungsregulierung und Mitteltöne deaktiviert.
TP_LOCALLAB_GHS_MID;Mitteltöne
TP_LOCALLAB_GHS_MID_TOOLTIP;Passt die Mitteltonbalance nach der GHS-Transformation an.\n Kann verwendet werden, um die Mitteltöne des Bildes nach der Dehnung neu auszugleichen.\n\nWenn der Dehnungsfaktor 0,002 oder weniger beträgt, sind Dehnungsregulierung und Mitteltöne deaktiviert.
TP_LOCALLAB_GHS_BPFRAME_TOOLTIP;Legt den Schwarzpunkt (BP linear), den Weißpunkt (WP linear) und die Lichter für eine lineare Dehnung des Bildes fest.\n\n * Die Einstellungen für Schwarzpunkt (BP linear) und Weißpunkt (WP linear) sind nur verfügbar, wenn der Dehnungsfaktor (D) zwischen 0,001 und 0,002 liegt, um das Histogramm nicht zu beeinflussen.\n\n * Wenn der Dehnungsfaktor 0,002 oder weniger beträgt, haben, außer Schwarzpunkt und Weißpunkt; keinerlei Dehnungseinstellungen eine Wirkung.\n\n * Die Einstellungen für Schwarzpunkt (BP linear) und Weißpunkt (WP linear) reagieren empfindlich auf die allgemeinen Einstellungen vor GHS: Lichterrekonstruktion, Weißabgleich und RAW-Prozesse.\n\n * Um relevante Einstellungen für Schwarzpunkt (BP linear) und Weißpunkt (WP linear) zu erhalten, muss das gesamte Bild analysiert werden. Es wird empfohlen, „Gesamtes Bild an Bildschirm anpassen Tastenkombination Alt-f“ zu verwenden.
TP_LOCALLAB_GHS_BLACKPOINT_FRAME;Schwarzpunkt/Weißpunkt/Glanzlichter TP_LOCALLAB_GHS_BLACKPOINT_FRAME;Schwarzpunkt/Weißpunkt/Glanzlichter
TP_LOCALLAB_GHS_BLP;Schwarzpunkt (BP linear) TP_LOCALLAB_GHS_BLP;Schwarzpunkt (BP linear)
TP_LOCALLAB_GHS_BLP_TOOLTIP;Legt den Schwarzpunkt für eine lineare Dehnung des Bildes fest.\n * Bei negativen Schiebereglerwerten werden in GHS „normal“ die Schatten linear angehoben, um übermäßiges Rauschen zu vermeiden und die Arbeit mit GHS zu erleichtern.\n * Bei positiven Schiebereglerwerten wird das Histogramm nach links verschoben. Für RAW-Bilder können Sie auch „Raw-Tab > RAW-Schwarzpunkte Dunst entfernen“ verwenden, was präziser ist.\n * Der durch die lineare Dehnung gewonnene Kontrast wird gleichmäßig über das Bild verteilt.\n\n * Sie können einen linearen Schwarzpunkt-Offset anpassen, um entweder:\n - Rauschen in den tiefen Schatten auszugleichen.\n - das Histogramm anzupassen.\n\n * Es wird empfohlen, diese Schieberegler vor den Haupt-GHS-Schiebereglern anzupassen, um ein Übersteuern der Daten zu vermeiden. Für diese Anpassung wird ein sehr niedriger Dehnungsfaktor (D) empfohlen (standardmäßig 0,001). \n * Die Beschriftung „Anzahl ungültiger Pixel Schatten:x Lichter=y“ zeigt die Anzahl der Pixel an, die abgeschnitten würden, wenn die beiden Schieberegler nicht angepasst würden. \n * Die Beschriftung „Pixelwerte Dunkelste:w Hellste:z“ zeigt die minimalen und maximalen Werte im Bereich [0, 1] an. \n * Im Modus „GHS Invertieren“ ist das Verhalten umgekehrt und es gibt mögliche Interaktionen mit dem Weißpunkt. TP_LOCALLAB_GHS_BLP_TOOLTIP;Legt den Schwarzpunkt für eine lineare Dehnung des Bildes fest.\n * Bei negativen Schiebereglerwerten werden in GHS „normal“ die Schatten linear angehoben, um übermäßiges Rauschen zu vermeiden und die Arbeit mit GHS zu erleichtern.\n * Bei positiven Schiebereglerwerten wird das Histogramm nach links verschoben. Für RAW-Bilder können Sie auch „Raw-Tab > RAW-Schwarzpunkte Dunst entfernen“ verwenden, was präziser ist.\n * Der durch die lineare Dehnung gewonnene Kontrast wird gleichmäßig über das Bild verteilt.\n\n * Sie können einen linearen Schwarzpunkt-Offset anpassen, um entweder:\n - Rauschen in den tiefen Schatten auszugleichen.\n - das Histogramm anzupassen.\n\n * Es wird empfohlen, diese Schieberegler vor den Haupt-GHS-Schiebereglern anzupassen, um ein Übersteuern der Daten zu vermeiden. Für diese Anpassung wird ein sehr niedriger Dehnungsfaktor (D) empfohlen (standardmäßig 0,001). \n * Die Beschriftung „Anzahl ungültiger Pixel Schatten:x Lichter=y“ zeigt die Anzahl der Pixel an, die abgeschnitten würden, wenn die beiden Schieberegler nicht angepasst würden. \n * Die Beschriftung „Pixelwerte Dunkelste:w Hellste:z“ zeigt die minimalen und maximalen Werte im Bereich [0, 1] an. \n * Im Modus „GHS Invertieren“ ist das Verhalten umgekehrt und es gibt mögliche Interaktionen mit dem Weißpunkt.
TP_LOCALLAB_GHS_HLP;Weißpunkt (WP linear) TP_LOCALLAB_GHS_BPFRAME_TOOLTIP;Legt den Schwarzpunkt (BP linear), den Weißpunkt (WP linear) und die Lichter für eine lineare Dehnung des Bildes fest.\n\n * Die Einstellungen für Schwarzpunkt (BP linear) und Weißpunkt (WP linear) sind nur verfügbar, wenn der Dehnungsfaktor (D) zwischen 0,001 und 0,002 liegt, um das Histogramm nicht zu beeinflussen.\n\n * Wenn der Dehnungsfaktor 0,002 oder weniger beträgt, haben, außer Schwarzpunkt und Weißpunkt; keinerlei Dehnungseinstellungen eine Wirkung.\n\n * Die Einstellungen für Schwarzpunkt (BP linear) und Weißpunkt (WP linear) reagieren empfindlich auf die allgemeinen Einstellungen vor GHS: Lichterrekonstruktion, Weißabgleich und RAW-Prozesse.\n\n * Um relevante Einstellungen für Schwarzpunkt (BP linear) und Weißpunkt (WP linear) zu erhalten, muss das gesamte Bild analysiert werden. Es wird empfohlen, „Gesamtes Bild an Bildschirm anpassen Tastenkombination Alt-f“ zu verwenden.
TP_LOCALLAB_GHS_METHOD_TOOLTIP;Mit dem GHS-Verfahren (Generalized Hyperbolic Stretch, oder auch die verallgemeinerte hyperbolische Dehnung) können Sie die Pixelwerte in Ihrem Bild transformieren, um die Darstellung der zugrunde liegenden Daten für die menschliche Visualisierung zu verbessern.\nDie im GHS-Verfahren verwendeten verallgemeinerten hyperbolischen Gleichungen haben fünf Hauptparameter. Dies ermöglicht erhebliche Flexibilität bei der Gestaltung der Transformationsform.\n\nTypische Anwendungen von Pixelintensitätstransformationen sind:\n * Anfängliche Dehnung der Pixeldaten aus dem linearen Zustand.\n * Hinzufügen von Kontrast zu wichtigen Bildbereichen.\n * Allgemeine Aufhellung oder Abdunkelung des Bildes.\n * Anpassung des Bilddynamikbereichs.\n * Anpassung der Pixeldaten in den Kanälen RGB-Luminanz, RGB-Standard, Luminanz - Buntheit (Lab/Lch), Helligkeit (HSL), Sättigung (HSL) oder Farbton (HSL).\n * Für bessere Ergebnisse können Sie in mehreren Schritten vorgehen und zwei oder mehr RT-Spots erstellen, die jeweils mit dem GHS-Werkzeug überlagert werden. Für jeden RT-Spot ist der Basiswert des Symmetriepunkts (SP) unterschiedlich. Verwenden Sie die Histogrammspitze, um den SP-Wert zu positionieren.\n * Sie können das System beispielsweise im RGB-Modus (1. Spot) starten, dann den 2. Spot im RGB-Modus mit einem anderen SP und den 3. Spot im Sättigungs- oder Farbtonmodus.\n * Sie können RT-Spots im „Normal“-Modus und im „Invers“-Modus mischen, um den Kontrast auszugleichen.\n * Im Vollbildmodus können Sie den Effekt basierend auf dem DeltaE auf bestimmte Farben beschränken.
TP_LOCALLAB_GHS_HLP_TOOLTIP;Legt den Weißpunkt für eine lineare Dehnung des Bildes fest. Pixel mit einem Wert größer als der eingegebene Weißpunkt werden abgeschnitten und die Daten gehen verloren.\n * Der durch die lineare Dehnung gewonnene Kontrast wird gleichmäßig über das Bild verteilt, das dadurch aufgehellt wird. Pixel mit Werten größer als der Weißpunkt erscheinen weiß und haben den Wert 1,0.\n * Wenn Sie diesen Parameter auf einen Wert größer als 1 setzen, wird der Dynamikumfang im oberen Bereich erweitert.\n * Die Methode „Lichter rekonstruieren“ hat einen sehr starken Einfluss auf den Weißpunktwert.\n\n * Es wird empfohlen, diesen Schieberegler vor den Haupt-GHS-Schiebereglern einzustellen, um Datenverluste zu vermeiden. Für diese Anpassung wird ein sehr niedriger Dehnungsfaktor (D) empfohlen (standardmäßig 0,001). \n * Die Beschriftung „Anzahl ungültiger Pixel Schatten: x, Lichter = y“ zeigt die Anzahl der Pixel an, die abgeschnitten würden, wenn die beiden Schieberegler nicht angepasst würden. \n * Die Beschriftung „Pixelwerte Dunkelste: w, Hellste: z“ zeigt die minimalen und maximalen Werte im Bereich [0, 1] an. \n * Im Modus „GHS Invertieren“ ist das Verhalten umgekehrt und es gibt mögliche Interaktionen mit dem Schwarzpunkt.
TP_LOCALLAB_GHS_MODELIN;Linear
TP_LOCALLAB_GHS_MODECUR;GHS
TP_LOCALLAB_GHS_D_TOOLTIP;Dieser Parameter steuert den Grad der Dehnung. Ist der Dehnungsfaktor auf Null gesetzt, erfolgt keine Dehnung. Anders ausgedrückt handelt es sich um die Identitätstransformation.\n\n * Die Einstellungen für Schwarzpunkt (BP linear) und Weißpunkt (WP linear) sind nur verfügbar, wenn der Dehnungsfaktor (D) zwischen 0,001 und 0,002 liegt.
TP_LOCALLAB_GHS_B_TOOLTIP;Dieser Parameter steuert, wie eng die Dehnung um den Symmetriepunkt (SP) fokussiert ist, indem er die Form der Transformation selbst ändert:\n * Für konzentrierte Dehnungen (wie z. B. anfängliche Dehnungen bei linearen Bildern) sollte ein großer 'b'-Faktor verwendet werden, um eine Dehnung innerhalb einer Histogrammspitze zu fokussieren und gleichzeitig die Dehnung von der Histogrammspitze weg zu defokussieren.\n * Zur Anpassung nichtlinearer Bilder sollten niedrigere 'b'-Parameter verwendet werden, um Kontrast und Helligkeit gleichmäßiger zu verteilen.\n * Große positive 'b'-Werte können als Histogrammverbreiterung betrachtet werden, d. h. sie breiten das Histogramm breiter um den Fokuspunkt SP aus.\n * Im Gegensatz dazu verschieben niedrigere 'b'-Werte das Histogramm tendenziell in eine hellere oder dunklere Position, ohne seine Breite zu stark zu beeinflussen.\n * Als allgemeine Regel gilt, dass der verwendete 'b'-Faktor abnimmt, wenn sich eine Dehnungssequenz dem Ende nähert, obwohl höhere 'b'-Werte immer noch zur präzisen Platzierung von zusätzlichem Kontrast verwendet werden können. TP_LOCALLAB_GHS_B_TOOLTIP;Dieser Parameter steuert, wie eng die Dehnung um den Symmetriepunkt (SP) fokussiert ist, indem er die Form der Transformation selbst ändert:\n * Für konzentrierte Dehnungen (wie z. B. anfängliche Dehnungen bei linearen Bildern) sollte ein großer 'b'-Faktor verwendet werden, um eine Dehnung innerhalb einer Histogrammspitze zu fokussieren und gleichzeitig die Dehnung von der Histogrammspitze weg zu defokussieren.\n * Zur Anpassung nichtlinearer Bilder sollten niedrigere 'b'-Parameter verwendet werden, um Kontrast und Helligkeit gleichmäßiger zu verteilen.\n * Große positive 'b'-Werte können als Histogrammverbreiterung betrachtet werden, d. h. sie breiten das Histogramm breiter um den Fokuspunkt SP aus.\n * Im Gegensatz dazu verschieben niedrigere 'b'-Werte das Histogramm tendenziell in eine hellere oder dunklere Position, ohne seine Breite zu stark zu beeinflussen.\n * Als allgemeine Regel gilt, dass der verwendete 'b'-Faktor abnimmt, wenn sich eine Dehnungssequenz dem Ende nähert, obwohl höhere 'b'-Werte immer noch zur präzisen Platzierung von zusätzlichem Kontrast verwendet werden können.
TP_LOCALLAB_GHS_SLOPE;Steigungsfaktor (S) Lab
TP_LOCALLAB_GHS_SLOPE_TOOLTIP;Ändert die Steigung der Lab-Transformation, um die Schattenwiedergabe zu verbessern.
TP_LOCALLAB_GHS_CHRO;Buntheitsfaktor (C) Lab TP_LOCALLAB_GHS_CHRO;Buntheitsfaktor (C) Lab
TP_LOCALLAB_GHS_CHRO_TOOLTIP;GHS Buntheit - große Dehnungen kompensieren TP_LOCALLAB_GHS_CHRO_TOOLTIP;GHS Buntheit - große Dehnungen kompensieren
TP_LOCALLAB_GHSLABFRA;Lab Einstellungen
TP_LOCALLAB_GHS_SP_TOOLTIP;Der Standardwert von 0,015 ist für die meisten Bilder geeignet.\n * Dies ist der Schlüsselbalancewert des GHS-Systems.\n * Legt den Fokuspunkt fest, um den die Dehnung angewendet wird der Kontrast wird symmetrisch um SP verteilt.\n * Während „b“ den Fokusgrad der Dehnung angibt, bestimmt SP, wo der Fokus angewendet wird.\n * SP sollte generell innerhalb einer Histogrammspitze platziert werden, damit die Dehnung die Spitze verbreitert und absenkt, indem an diesem Punkt der größte Kontrast in die Dehnung eingefügt wird. Die Pixelwerte verschieben sich vom SP-Standort weg.
TP_LOCALLAB_GHS_LP_TOOLTIP;Legt einen Wert fest, unterhalb dessen die Dehnung angepasst wird, um den Kontrast in den Schatten zu erhalten. Dies geschieht durch eine lineare Dehnung der Daten unterhalb des LP-Pegels, wobei Kontrast vom Rest des Bildes reserviert wird. Durch Verschieben des LP-Pegels in Richtung der aktuellen SP-Einstellung ändern sich sowohl Umfang als auch Stärke dieser Kontrastreservierung. Der Nettoeffekt besteht darin, die Gesamtdehnung zu höheren Helligkeitsstufen zu verschieben, während Kontrast und Definition im Hintergrund erhalten bleiben. Die für die Schatten reservierte Kontraststärke ist so gewählt, dass die Kontinuität der Dehnung erhalten bleibt.\n * Dieser Parameter muss mindestens 0 und darf nicht größer als der Symmetriepunkt sein.\n * Der Einsteller begrenzt den Maximalwert automatisch auf den Symmetriepunkt (SP).\n\n * Durch die Verwendung des Schwarzpunkts (negative Werte) können, sofern möglich, sowohl der Wert des Symmetriepunkts (SP) als auch die Aktion „Schatten schützen (LP)“ geändert werden.
TP_LOCALLAB_GHS_HP_TOOLTIP;Legt einen Wert fest, ab dem die Dehnung angepasst wird, um den Kontrast in den Lichtern zu erhalten. Dies geschieht durch eine lineare Dehnung der Daten oberhalb des „HP“-Werts, wobei Kontrast vom restlichen Bild reserviert wird. Durch Verschieben des HP-Werts in Richtung der aktuellen SP-Einstellung werden sowohl Umfang als auch Stärke dieser Kontrastreservierung erhöht. Der Nettoeffekt besteht darin, die Gesamtdehnung zu niedrigeren Helligkeitsstufen zu verschieben, während Kontrast und Schärfe in den Lichtern erhalten bleiben. Die für die Lichter reservierte Kontraststärke ist so gewählt, dass die Kontinuität der Dehnung erhalten bleibt.\n * Dieser Parameter darf höchstens 1 und nicht kleiner als der Symmetriepunkt sein.\n * Der Einsteller begrenzt den Maximalwert automatisch auf den Symmetriepunkt (SP)..\n\n * Die Verwendung der Glanzlichterdämpfung verstärkt die Wirkung von „Lichter schützen (HP)“.
TP_LOCALLAB_GHS_SMOOTH_TOOLTIP;Glätten und mildern Sie hervorgehobene Bereiche. Verstärkt die Aktion „Lichter schützen (HP)“.
TP_LOCALLAB_GHS_SMOOTH;Glanzlichtdämpfung
TP_LOCALLAB_GHS_CURVE_TOOLTIP;Zeigt die durch GHS-Berechnungen generierte S-Kurve, hauptsächlich zur Veranschaulichung.\n\n * Die Kurve reagiert nur auf die Einsteller und kann nicht direkt geändert werden. TP_LOCALLAB_GHS_CURVE_TOOLTIP;Zeigt die durch GHS-Berechnungen generierte S-Kurve, hauptsächlich zur Veranschaulichung.\n\n * Die Kurve reagiert nur auf die Einsteller und kann nicht direkt geändert werden.
TP_LOCALLAB_GHS_D;Dehnungsfaktor (D)
TP_LOCALLAB_GHS_D_TOOLTIP;Dieser Parameter steuert den Grad der Dehnung. Ist der Dehnungsfaktor auf Null gesetzt, erfolgt keine Dehnung. Anders ausgedrückt handelt es sich um die Identitätstransformation.\n\n * Die Einstellungen für Schwarzpunkt (BP linear) und Weißpunkt (WP linear) sind nur verfügbar, wenn der Dehnungsfaktor (D) zwischen 0,001 und 0,002 liegt.
TP_LOCALLAB_GHS_GHSDIAG; Visualisierung der GHS-Kurve
TP_LOCALLAB_GHS_HLP;Weißpunkt (WP linear)
TP_LOCALLAB_GHS_HLP_TOOLTIP;Legt den Weißpunkt für eine lineare Dehnung des Bildes fest. Pixel mit einem Wert größer als der eingegebene Weißpunkt werden abgeschnitten und die Daten gehen verloren.\n * Der durch die lineare Dehnung gewonnene Kontrast wird gleichmäßig über das Bild verteilt, das dadurch aufgehellt wird. Pixel mit Werten größer als der Weißpunkt erscheinen weiß und haben den Wert 1,0.\n * Wenn Sie diesen Parameter auf einen Wert größer als 1 setzen, wird der Dynamikumfang im oberen Bereich erweitert.\n * Die Methode „Lichter rekonstruieren“ hat einen sehr starken Einfluss auf den Weißpunktwert.\n\n * Es wird empfohlen, diesen Schieberegler vor den Haupt-GHS-Schiebereglern einzustellen, um Datenverluste zu vermeiden. Für diese Anpassung wird ein sehr niedriger Dehnungsfaktor (D) empfohlen (standardmäßig 0,001). \n * Die Beschriftung „Anzahl ungültiger Pixel Schatten: x, Lichter = y“ zeigt die Anzahl der Pixel an, die abgeschnitten würden, wenn die beiden Schieberegler nicht angepasst würden. \n * Die Beschriftung „Pixelwerte Dunkelste: w, Hellste: z“ zeigt die minimalen und maximalen Werte im Bereich [0, 1] an. \n * Im Modus „GHS Invertieren“ ist das Verhalten umgekehrt und es gibt mögliche Interaktionen mit dem Schwarzpunkt.
TP_LOCALLAB_GHS_HP;Lichter schützen (HP)
TP_LOCALLAB_GHS_HP_TOOLTIP;Legt einen Wert fest, ab dem die Dehnung angepasst wird, um den Kontrast in den Lichtern zu erhalten. Dies geschieht durch eine lineare Dehnung der Daten oberhalb des „HP“-Werts, wobei Kontrast vom restlichen Bild reserviert wird. Durch Verschieben des HP-Werts in Richtung der aktuellen SP-Einstellung werden sowohl Umfang als auch Stärke dieser Kontrastreservierung erhöht. Der Nettoeffekt besteht darin, die Gesamtdehnung zu niedrigeren Helligkeitsstufen zu verschieben, während Kontrast und Schärfe in den Lichtern erhalten bleiben. Die für die Lichter reservierte Kontraststärke ist so gewählt, dass die Kontinuität der Dehnung erhalten bleibt.\n * Dieser Parameter darf höchstens 1 und nicht kleiner als der Symmetriepunkt sein.\n * Der Einsteller begrenzt den Maximalwert automatisch auf den Symmetriepunkt (SP)..\n\n * Die Verwendung der Glanzlichterdämpfung verstärkt die Wirkung von „Lichter schützen (HP)“.
TP_LOCALLAB_GHS_INV;GHS Invertieren TP_LOCALLAB_GHS_INV;GHS Invertieren
TP_LOCALLAB_GHS_INV_TOOLTIP;Die invertierte GHS-Transformation eignet sich für die Arbeit im Negativraum. Sie erhöht den Kontrast rechts und links im Histogramm, hellt tiefe Schatten auf, verdunkelt helle Lichter und verdichtet das Histogramm zur Bildmitte hin.\n\n * Die verallgemeinerte hyperbolische inverse Transformation ermöglicht die Wiederherstellung des Originalbildes unter Einhaltung mathematischer Genauigkeit, kann aber auch für andere Zwecke eingesetzt werden.\n\n * Wurden Weißpunkt und Schwarzpunkt im Normalmodus geändert, müssen sie wahrscheinlich neu angepasst werden. Der Weißpunkt muss oft nach unten korrigiert werden. Es besteht eine Wechselwirkung zwischen den beiden Einstellungen. TP_LOCALLAB_GHS_INV_TOOLTIP;Die invertierte GHS-Transformation eignet sich für die Arbeit im Negativraum. Sie erhöht den Kontrast rechts und links im Histogramm, hellt tiefe Schatten auf, verdunkelt helle Lichter und verdichtet das Histogramm zur Bildmitte hin.\n\n * Die verallgemeinerte hyperbolische inverse Transformation ermöglicht die Wiederherstellung des Originalbildes unter Einhaltung mathematischer Genauigkeit, kann aber auch für andere Zwecke eingesetzt werden.\n\n * Wurden Weißpunkt und Schwarzpunkt im Normalmodus geändert, müssen sie wahrscheinlich neu angepasst werden. Der Weißpunkt muss oft nach unten korrigiert werden. Es besteht eine Wechselwirkung zwischen den beiden Einstellungen.
TP_LOCALLAB_GHS_LC;lokaler Kontrast (LC)
TP_LOCALLAB_GHS_LC_FRAME;Dehnungsregelung & Mitteltöne
TP_LOCALLAB_GHS_LC_TOOLTIP;Erhöht leicht den lokalen Kontrast, der durch die Dehnung abgeschwächt wurde.\nKann durch andere, auf lokalen Kontrast spezialisierte Tools wie Wavelets ergänzt werden.\n\nWenn der Dehnungsfaktor 0,002 oder weniger beträgt, sind Dehnungsregulierung und Mitteltöne deaktiviert.
TP_LOCALLAB_GHS_LP;Schatten schützen (LP)
TP_LOCALLAB_GHS_LP_TOOLTIP;Legt einen Wert fest, unterhalb dessen die Dehnung angepasst wird, um den Kontrast in den Schatten zu erhalten. Dies geschieht durch eine lineare Dehnung der Daten unterhalb des LP-Pegels, wobei Kontrast vom Rest des Bildes reserviert wird. Durch Verschieben des LP-Pegels in Richtung der aktuellen SP-Einstellung ändern sich sowohl Umfang als auch Stärke dieser Kontrastreservierung. Der Nettoeffekt besteht darin, die Gesamtdehnung zu höheren Helligkeitsstufen zu verschieben, während Kontrast und Definition im Hintergrund erhalten bleiben. Die für die Schatten reservierte Kontraststärke ist so gewählt, dass die Kontinuität der Dehnung erhalten bleibt.\n * Dieser Parameter muss mindestens 0 und darf nicht größer als der Symmetriepunkt sein.\n * Der Einsteller begrenzt den Maximalwert automatisch auf den Symmetriepunkt (SP).\n\n * Durch die Verwendung des Schwarzpunkts (negative Werte) können, sofern möglich, sowohl der Wert des Symmetriepunkts (SP) als auch die Aktion „Schatten schützen (LP)“ geändert werden.
TP_LOCALLAB_GHS_METHOD_TOOLTIP;Mit dem GHS-Verfahren (Generalized Hyperbolic Stretch, oder auch die verallgemeinerte hyperbolische Dehnung) können Sie die Pixelwerte in Ihrem Bild transformieren, um die Darstellung der zugrunde liegenden Daten für die menschliche Visualisierung zu verbessern.\nDie im GHS-Verfahren verwendeten verallgemeinerten hyperbolischen Gleichungen haben fünf Hauptparameter. Dies ermöglicht erhebliche Flexibilität bei der Gestaltung der Transformationsform.\n\nTypische Anwendungen von Pixelintensitätstransformationen sind:\n * Anfängliche Dehnung der Pixeldaten aus dem linearen Zustand.\n * Hinzufügen von Kontrast zu wichtigen Bildbereichen.\n * Allgemeine Aufhellung oder Abdunkelung des Bildes.\n * Anpassung des Bilddynamikbereichs.\n * Anpassung der Pixeldaten in den Kanälen RGB-Luminanz, RGB-Standard, Luminanz - Buntheit (Lab/Lch), Helligkeit (HSL), Sättigung (HSL) oder Farbton (HSL).\n * Für bessere Ergebnisse können Sie in mehreren Schritten vorgehen und zwei oder mehr RT-Spots erstellen, die jeweils mit dem GHS-Werkzeug überlagert werden. Für jeden RT-Spot ist der Basiswert des Symmetriepunkts (SP) unterschiedlich. Verwenden Sie die Histogrammspitze, um den SP-Wert zu positionieren.\n * Sie können das System beispielsweise im RGB-Modus (1. Spot) starten, dann den 2. Spot im RGB-Modus mit einem anderen SP und den 3. Spot im Sättigungs- oder Farbtonmodus.\n * Sie können RT-Spots im „Normal“-Modus und im „Invers“-Modus mischen, um den Kontrast auszugleichen.\n * Im Vollbildmodus können Sie den Effekt basierend auf dem DeltaE auf bestimmte Farben beschränken.
TP_LOCALLAB_GHS_MID;Mitteltöne
TP_LOCALLAB_GHS_MID_TOOLTIP;Passt die Mitteltonbalance nach der GHS-Transformation an.\n Kann verwendet werden, um die Mitteltöne des Bildes nach der Dehnung neu auszugleichen.\n\nWenn der Dehnungsfaktor 0,002 oder weniger beträgt, sind Dehnungsregulierung und Mitteltöne deaktiviert.
TP_LOCALLAB_GHS_MODECUR;GHS
TP_LOCALLAB_GHS_MODELIN;Linear
TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Zeigt eine repräsentative Kurve der GHS-Funktion.
TP_LOCALLAB_GHS_SLOPE;Steigungsfaktor (S) Lab
TP_LOCALLAB_GHS_SLOPE_TOOLTIP;Ändert die Steigung der Lab-Transformation, um die Schattenwiedergabe zu verbessern.
TP_LOCALLAB_GHS_SMOOTH;Glanzlichtdämpfung
TP_LOCALLAB_GHS_SMOOTH_TOOLTIP;Glätten und mildern Sie hervorgehobene Bereiche. Verstärkt die Aktion „Lichter schützen (HP)“.
TP_LOCALLAB_GHS_SP;Symmetriepunkt (SP)
TP_LOCALLAB_GHS_SP_TOOLTIP;Der Standardwert von 0,015 ist für die meisten Bilder geeignet.\n * Dies ist der Schlüsselbalancewert des GHS-Systems.\n * Legt den Fokuspunkt fest, um den die Dehnung angewendet wird der Kontrast wird symmetrisch um SP verteilt.\n * Während „b“ den Fokusgrad der Dehnung angibt, bestimmt SP, wo der Fokus angewendet wird.\n * SP sollte generell innerhalb einer Histogrammspitze platziert werden, damit die Dehnung die Spitze verbreitert und absenkt, indem an diesem Punkt der größte Kontrast in die Dehnung eingefügt wird. Die Pixelwerte verschieben sich vom SP-Standort weg.
TP_LOCALLAB_GRADANG;Rotationswinkel TP_LOCALLAB_GRADANG;Rotationswinkel
TP_LOCALLAB_GRADANG_TOOLTIP;Rotationswinkel in Grad: -180° 0° +180° TP_LOCALLAB_GRADANG_TOOLTIP;Rotationswinkel in Grad: -180° 0° +180°
TP_LOCALLAB_GRADFRA;Verlaufsfiltermaske TP_LOCALLAB_GRADFRA;Verlaufsfiltermaske
@ -3667,8 +3667,8 @@ TP_LOCALLAB_MRONE;Keine
TP_LOCALLAB_MRTHR;Original Bild TP_LOCALLAB_MRTHR;Original Bild
TP_LOCALLAB_MULTIPL_TOOLTIP;Weitbereichs-Toneinstellung: -18 EV bis + 4 EV. Der erste Regler wirkt auf sehr dunkle Töne zwischen -18 EV und -6 EV. Der letzte Regler wirkt auf helle Töne bis zu 4 EV. TP_LOCALLAB_MULTIPL_TOOLTIP;Weitbereichs-Toneinstellung: -18 EV bis + 4 EV. Der erste Regler wirkt auf sehr dunkle Töne zwischen -18 EV und -6 EV. Der letzte Regler wirkt auf helle Töne bis zu 4 EV.
TP_LOCALLAB_NEIGH;Radius TP_LOCALLAB_NEIGH;Radius
TP_LOCALLAB_NLDENOISENLITER_TOOLTIP;Führen Sie mehrere Iterationen von Nicht-lokalen-Mitteln aus. Die Ergebnisse sind oft besser bei mehreren Iterationen mit geringer Stärke.
TP_LOCALLAB_NLDENOISENLGAM_TOOLTIP;Niedrigere Werte bewahren Details und Textur, höhere Werte erhöhen die Rauschunterdrückung.\nIst Gamma = 3, wird Luminanz 'linear' angewendet. TP_LOCALLAB_NLDENOISENLGAM_TOOLTIP;Niedrigere Werte bewahren Details und Textur, höhere Werte erhöhen die Rauschunterdrückung.\nIst Gamma = 3, wird Luminanz 'linear' angewendet.
TP_LOCALLAB_NLDENOISENLITER_TOOLTIP;Führen Sie mehrere Iterationen von Nicht-lokalen-Mitteln aus. Die Ergebnisse sind oft besser bei mehreren Iterationen mit geringer Stärke.
TP_LOCALLAB_NLDENOISENLPAT_TOOLTIP;Passt die Intensität der Rauschreduzierung an die Größe der zu verarbeitenden Objekte an. TP_LOCALLAB_NLDENOISENLPAT_TOOLTIP;Passt die Intensität der Rauschreduzierung an die Größe der zu verarbeitenden Objekte an.
TP_LOCALLAB_NLDENOISENLRAD_TOOLTIP;Höhere Werte erhöhen die Rauschreduzierung auf Kosten der Verarbeitungszeit. TP_LOCALLAB_NLDENOISENLRAD_TOOLTIP;Höhere Werte erhöhen die Rauschreduzierung auf Kosten der Verarbeitungszeit.
TP_LOCALLAB_NLDENOISE_TOOLTIP;'Detailwiederherstellung' basiert auf einer Laplace-Transformation, um einheitliche Bereiche und keine Bereiche mit Details zu erfassen. TP_LOCALLAB_NLDENOISE_TOOLTIP;'Detailwiederherstellung' basiert auf einer Laplace-Transformation, um einheitliche Bereiche und keine Bereiche mit Details zu erfassen.
@ -4727,3 +4727,9 @@ ZOOMPANEL_ZOOMIN;Hineinzoomen\nTaste: <b>+</b>
ZOOMPANEL_ZOOMOUT;Herauszoomen\nTaste: <b>-</b> ZOOMPANEL_ZOOMOUT;Herauszoomen\nTaste: <b>-</b>
//TP_WBALANCE_ITCWBNOPURPLE_TOOLTIP;By default when "Inpaint opposed" is activated, purple colors are not taken into account. However, if the image does not need highlight reconstruction, or if this image naturally contains purple tints (flowers, etc.), it may be necessary to deactivate, to take into account all the colors. //TP_WBALANCE_ITCWBNOPURPLE_TOOLTIP;By default when "Inpaint opposed" is activated, purple colors are not taken into account. However, if the image does not need highlight reconstruction, or if this image naturally contains purple tints (flowers, etc.), it may be necessary to deactivate, to take into account all the colors.
//TP_WBALANCE_ITCWB_FORCED;Forces use of the entire CIE diagram //TP_WBALANCE_ITCWB_FORCED;Forces use of the entire CIE diagram
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!PREFERENCES_WBAGREENDELTA;Delta temperature in green iterate loop (if Force Extra enabled)

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@ -3392,16 +3392,16 @@ TP_WBALANCE_PATCHLABEL_TOOLTIP;Display number of read colours (max=237).\nDispla
!TP_LOCALLAB_GHS_GHSDIAG;GHS Curve Visualization !TP_LOCALLAB_GHS_GHSDIAG;GHS Curve Visualization
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -3736,7 +3736,7 @@ TP_WBALANCE_PATCHLABEL_TOOLTIP;Display number of read colours (max=237).\nDispla
!TP_LOCALLAB_SETTINGS;Settings !TP_LOCALLAB_SETTINGS;Settings
!TP_LOCALLAB_SH1;Shadows Highlights !TP_LOCALLAB_SH1;Shadows Highlights
!TP_LOCALLAB_SH2;Equalizer !TP_LOCALLAB_SH2;Equalizer
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SHADEX;Shadows !TP_LOCALLAB_SHADEX;Shadows
!TP_LOCALLAB_SHADEXCOMP;Shadow compression !TP_LOCALLAB_SHADEXCOMP;Shadow compression
!TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS !TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS

8
rtdata/languages/English (US)
View File

@ -3301,17 +3301,17 @@
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -3699,7 +3699,7 @@
!TP_LOCALLAB_SETTINGS;Settings !TP_LOCALLAB_SETTINGS;Settings
!TP_LOCALLAB_SH1;Shadows Highlights !TP_LOCALLAB_SH1;Shadows Highlights
!TP_LOCALLAB_SH2;Equalizer !TP_LOCALLAB_SH2;Equalizer
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SHADEX;Shadows !TP_LOCALLAB_SHADEX;Shadows
!TP_LOCALLAB_SHADEXCOMP;Shadow compression !TP_LOCALLAB_SHADEXCOMP;Shadow compression
!TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS !TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS

8
rtdata/languages/Espanol (Castellano)
View File

@ -4487,17 +4487,17 @@ ZOOMPANEL_ZOOMOUT;Alejar\nAtajo de teclado: <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -4529,7 +4529,7 @@ ZOOMPANEL_ZOOMOUT;Alejar\nAtajo de teclado: <b>-</b>
!TP_LOCALLAB_QJMODE_512;5.12 !TP_LOCALLAB_QJMODE_512;5.12
!TP_LOCALLAB_QJMODE_TOOLTIP;The tone-mapping operators that use brightness data (Q for CAM16 and J for Jz) have been modified in RawTherapee version 5.12. This allows you to select either the current or the deprecated version. !TP_LOCALLAB_QJMODE_TOOLTIP;The tone-mapping operators that use brightness data (Q for CAM16 and J for Jz) have been modified in RawTherapee version 5.12. This allows you to select either the current or the deprecated version.
!TP_LOCALLAB_SATCIE;Saturation control !TP_LOCALLAB_SATCIE;Saturation control
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SIGBLACKSSCIE;Blacks distribution !TP_LOCALLAB_SIGBLACKSSCIE;Blacks distribution
!TP_LOCALLAB_SIGCIE;Sigmoid !TP_LOCALLAB_SIGCIE;Sigmoid
!TP_LOCALLAB_SIGFRA11;Sigmoid Q (deprecated) !TP_LOCALLAB_SIGFRA11;Sigmoid Q (deprecated)

8
rtdata/languages/Espanol (Latin America)
View File

@ -3868,17 +3868,17 @@ ZOOMPANEL_ZOOMOUT;Reducir Zoom\nTecla de Atajo: <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -4266,7 +4266,7 @@ ZOOMPANEL_ZOOMOUT;Reducir Zoom\nTecla de Atajo: <b>-</b>
!TP_LOCALLAB_SETTINGS;Settings !TP_LOCALLAB_SETTINGS;Settings
!TP_LOCALLAB_SH1;Shadows Highlights !TP_LOCALLAB_SH1;Shadows Highlights
!TP_LOCALLAB_SH2;Equalizer !TP_LOCALLAB_SH2;Equalizer
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SHADEX;Shadows !TP_LOCALLAB_SHADEX;Shadows
!TP_LOCALLAB_SHADEXCOMP;Shadow compression !TP_LOCALLAB_SHADEXCOMP;Shadow compression
!TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS !TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS

8
rtdata/languages/Francais
View File

@ -4353,17 +4353,17 @@ ZOOMPANEL_ZOOMOUT;Zoom Arrière\nRaccourci: <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -4412,7 +4412,7 @@ ZOOMPANEL_ZOOMOUT;Zoom Arrière\nRaccourci: <b>-</b>
!TP_LOCALLAB_RGBCURVE_TOOLTIP;In RGB mode you have 4 choices : Standard, Weighted standard, Luminance &amp; Film-like. !TP_LOCALLAB_RGBCURVE_TOOLTIP;In RGB mode you have 4 choices : Standard, Weighted standard, Luminance &amp; Film-like.
!TP_LOCALLAB_SATCIE;Saturation control !TP_LOCALLAB_SATCIE;Saturation control
!TP_LOCALLAB_SATURV;Saturation (s) !TP_LOCALLAB_SATURV;Saturation (s)
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SIGBLACKSSCIE;Blacks distribution !TP_LOCALLAB_SIGBLACKSSCIE;Blacks distribution
!TP_LOCALLAB_SIGCIE;Sigmoid !TP_LOCALLAB_SIGCIE;Sigmoid
!TP_LOCALLAB_SIGFRA11;Sigmoid Q (deprecated) !TP_LOCALLAB_SIGFRA11;Sigmoid Q (deprecated)

8
rtdata/languages/Italiano
View File

@ -4557,17 +4557,17 @@ ZOOMPANEL_ZOOMOUT;Rimpicciolisci.\nScorciatoia: <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -4595,7 +4595,7 @@ ZOOMPANEL_ZOOMOUT;Rimpicciolisci.\nScorciatoia: <b>-</b>
!TP_LOCALLAB_QJMODE_512;5.12 !TP_LOCALLAB_QJMODE_512;5.12
!TP_LOCALLAB_QJMODE_TOOLTIP;The tone-mapping operators that use brightness data (Q for CAM16 and J for Jz) have been modified in RawTherapee version 5.12. This allows you to select either the current or the deprecated version. !TP_LOCALLAB_QJMODE_TOOLTIP;The tone-mapping operators that use brightness data (Q for CAM16 and J for Jz) have been modified in RawTherapee version 5.12. This allows you to select either the current or the deprecated version.
!TP_LOCALLAB_SATCIE;Saturation control !TP_LOCALLAB_SATCIE;Saturation control
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SIGBLACKSSCIE;Blacks distribution !TP_LOCALLAB_SIGBLACKSSCIE;Blacks distribution
!TP_LOCALLAB_SIGCIE;Sigmoid !TP_LOCALLAB_SIGCIE;Sigmoid
!TP_LOCALLAB_SIGFRA11;Sigmoid Q (deprecated) !TP_LOCALLAB_SIGFRA11;Sigmoid Q (deprecated)

8
rtdata/languages/Japanese
View File

@ -4586,17 +4586,17 @@ ZOOMPANEL_ZOOMOUT;ズームアウト\nショートカット: <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -4614,7 +4614,7 @@ ZOOMPANEL_ZOOMOUT;ズームアウト\nショートカット: <b>-</b>
!TP_LOCALLAB_QJMODE_511;5.11 deprecated !TP_LOCALLAB_QJMODE_511;5.11 deprecated
!TP_LOCALLAB_QJMODE_512;5.12 !TP_LOCALLAB_QJMODE_512;5.12
!TP_LOCALLAB_QJMODE_TOOLTIP;The tone-mapping operators that use brightness data (Q for CAM16 and J for Jz) have been modified in RawTherapee version 5.12. This allows you to select either the current or the deprecated version. !TP_LOCALLAB_QJMODE_TOOLTIP;The tone-mapping operators that use brightness data (Q for CAM16 and J for Jz) have been modified in RawTherapee version 5.12. This allows you to select either the current or the deprecated version.
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SIGFRA11;Sigmoid Q (deprecated) !TP_LOCALLAB_SIGFRA11;Sigmoid Q (deprecated)
!TP_LOCALLAB_SIGJZFRA11;Sigmoid Jz (deprecated) !TP_LOCALLAB_SIGJZFRA11;Sigmoid Jz (deprecated)
!TP_LOCALLAB_SIGMOIDBL11;Blend !TP_LOCALLAB_SIGMOIDBL11;Blend

8
rtdata/languages/Magyar
View File

@ -3497,17 +3497,17 @@ ZOOMPANEL_ZOOMOUT;Kicsinyítés <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -3895,7 +3895,7 @@ ZOOMPANEL_ZOOMOUT;Kicsinyítés <b>-</b>
!TP_LOCALLAB_SETTINGS;Settings !TP_LOCALLAB_SETTINGS;Settings
!TP_LOCALLAB_SH1;Shadows Highlights !TP_LOCALLAB_SH1;Shadows Highlights
!TP_LOCALLAB_SH2;Equalizer !TP_LOCALLAB_SH2;Equalizer
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SHADEX;Shadows !TP_LOCALLAB_SHADEX;Shadows
!TP_LOCALLAB_SHADEXCOMP;Shadow compression !TP_LOCALLAB_SHADEXCOMP;Shadow compression
!TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS !TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS

8
rtdata/languages/Nederlands
View File

@ -4605,17 +4605,17 @@ ZOOMPANEL_ZOOMOUT;Zoom uit\nSneltoets: <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -4633,7 +4633,7 @@ ZOOMPANEL_ZOOMOUT;Zoom uit\nSneltoets: <b>-</b>
!TP_LOCALLAB_QJMODE_511;5.11 deprecated !TP_LOCALLAB_QJMODE_511;5.11 deprecated
!TP_LOCALLAB_QJMODE_512;5.12 !TP_LOCALLAB_QJMODE_512;5.12
!TP_LOCALLAB_QJMODE_TOOLTIP;The tone-mapping operators that use brightness data (Q for CAM16 and J for Jz) have been modified in RawTherapee version 5.12. This allows you to select either the current or the deprecated version. !TP_LOCALLAB_QJMODE_TOOLTIP;The tone-mapping operators that use brightness data (Q for CAM16 and J for Jz) have been modified in RawTherapee version 5.12. This allows you to select either the current or the deprecated version.
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SIGFRA11;Sigmoid Q (deprecated) !TP_LOCALLAB_SIGFRA11;Sigmoid Q (deprecated)
!TP_LOCALLAB_SIGJZFRA11;Sigmoid Jz (deprecated) !TP_LOCALLAB_SIGJZFRA11;Sigmoid Jz (deprecated)
!TP_LOCALLAB_SIGMOIDBL11;Blend !TP_LOCALLAB_SIGMOIDBL11;Blend

8
rtdata/languages/Polish
View File

@ -3696,17 +3696,17 @@ ZOOMPANEL_ZOOMOUT;Oddal\nSkrót: <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -4094,7 +4094,7 @@ ZOOMPANEL_ZOOMOUT;Oddal\nSkrót: <b>-</b>
!TP_LOCALLAB_SETTINGS;Settings !TP_LOCALLAB_SETTINGS;Settings
!TP_LOCALLAB_SH1;Shadows Highlights !TP_LOCALLAB_SH1;Shadows Highlights
!TP_LOCALLAB_SH2;Equalizer !TP_LOCALLAB_SH2;Equalizer
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SHADEX;Shadows !TP_LOCALLAB_SHADEX;Shadows
!TP_LOCALLAB_SHADEXCOMP;Shadow compression !TP_LOCALLAB_SHADEXCOMP;Shadow compression
!TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS !TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS

8
rtdata/languages/Portugues
View File

@ -3809,17 +3809,17 @@ ZOOMPANEL_ZOOMOUT;Afastar\nAtalho: <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -4207,7 +4207,7 @@ ZOOMPANEL_ZOOMOUT;Afastar\nAtalho: <b>-</b>
!TP_LOCALLAB_SETTINGS;Settings !TP_LOCALLAB_SETTINGS;Settings
!TP_LOCALLAB_SH1;Shadows Highlights !TP_LOCALLAB_SH1;Shadows Highlights
!TP_LOCALLAB_SH2;Equalizer !TP_LOCALLAB_SH2;Equalizer
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SHADEX;Shadows !TP_LOCALLAB_SHADEX;Shadows
!TP_LOCALLAB_SHADEXCOMP;Shadow compression !TP_LOCALLAB_SHADEXCOMP;Shadow compression
!TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS !TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS

8
rtdata/languages/Portugues (Brasil)
View File

@ -3806,17 +3806,17 @@ ZOOMPANEL_ZOOMOUT;Menos Zoom\nAtalho: <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -4204,7 +4204,7 @@ ZOOMPANEL_ZOOMOUT;Menos Zoom\nAtalho: <b>-</b>
!TP_LOCALLAB_SETTINGS;Settings !TP_LOCALLAB_SETTINGS;Settings
!TP_LOCALLAB_SH1;Shadows Highlights !TP_LOCALLAB_SH1;Shadows Highlights
!TP_LOCALLAB_SH2;Equalizer !TP_LOCALLAB_SH2;Equalizer
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SHADEX;Shadows !TP_LOCALLAB_SHADEX;Shadows
!TP_LOCALLAB_SHADEXCOMP;Shadow compression !TP_LOCALLAB_SHADEXCOMP;Shadow compression
!TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS !TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS

8
rtdata/languages/Russian
View File

@ -3530,17 +3530,17 @@ ZOOMPANEL_ZOOMOUT;Отдалить\nГорячая клавиша: <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -3928,7 +3928,7 @@ ZOOMPANEL_ZOOMOUT;Отдалить\nГорячая клавиша: <b>-</b>
!TP_LOCALLAB_SETTINGS;Settings !TP_LOCALLAB_SETTINGS;Settings
!TP_LOCALLAB_SH1;Shadows Highlights !TP_LOCALLAB_SH1;Shadows Highlights
!TP_LOCALLAB_SH2;Equalizer !TP_LOCALLAB_SH2;Equalizer
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SHADEX;Shadows !TP_LOCALLAB_SHADEX;Shadows
!TP_LOCALLAB_SHADEXCOMP;Shadow compression !TP_LOCALLAB_SHADEXCOMP;Shadow compression
!TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS !TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS

8
rtdata/languages/Serbian (Cyrilic Characters)
View File

@ -3468,17 +3468,17 @@ ZOOMPANEL_ZOOMOUT;Умањује приказ слике <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -3866,7 +3866,7 @@ ZOOMPANEL_ZOOMOUT;Умањује приказ слике <b>-</b>
!TP_LOCALLAB_SETTINGS;Settings !TP_LOCALLAB_SETTINGS;Settings
!TP_LOCALLAB_SH1;Shadows Highlights !TP_LOCALLAB_SH1;Shadows Highlights
!TP_LOCALLAB_SH2;Equalizer !TP_LOCALLAB_SH2;Equalizer
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SHADEX;Shadows !TP_LOCALLAB_SHADEX;Shadows
!TP_LOCALLAB_SHADEXCOMP;Shadow compression !TP_LOCALLAB_SHADEXCOMP;Shadow compression
!TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS !TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS

8
rtdata/languages/Slovenian
View File

@ -3812,17 +3812,17 @@ ZOOMPANEL_ZOOMOUT;Zoom Out\nBližnjica: <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -4210,7 +4210,7 @@ ZOOMPANEL_ZOOMOUT;Zoom Out\nBližnjica: <b>-</b>
!TP_LOCALLAB_SETTINGS;Settings !TP_LOCALLAB_SETTINGS;Settings
!TP_LOCALLAB_SH1;Shadows Highlights !TP_LOCALLAB_SH1;Shadows Highlights
!TP_LOCALLAB_SH2;Equalizer !TP_LOCALLAB_SH2;Equalizer
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SHADEX;Shadows !TP_LOCALLAB_SHADEX;Shadows
!TP_LOCALLAB_SHADEXCOMP;Shadow compression !TP_LOCALLAB_SHADEXCOMP;Shadow compression
!TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS !TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS

8
rtdata/languages/Swedish
View File

@ -3672,17 +3672,17 @@ ZOOMPANEL_ZOOMOUT;Förminska.\nKortkommando: <b>-</b>
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -4070,7 +4070,7 @@ ZOOMPANEL_ZOOMOUT;Förminska.\nKortkommando: <b>-</b>
!TP_LOCALLAB_SETTINGS;Settings !TP_LOCALLAB_SETTINGS;Settings
!TP_LOCALLAB_SH1;Shadows Highlights !TP_LOCALLAB_SH1;Shadows Highlights
!TP_LOCALLAB_SH2;Equalizer !TP_LOCALLAB_SH2;Equalizer
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SHADEX;Shadows !TP_LOCALLAB_SHADEX;Shadows
!TP_LOCALLAB_SHADEXCOMP;Shadow compression !TP_LOCALLAB_SHADEXCOMP;Shadow compression
!TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS !TP_LOCALLAB_SHADHIGH;Shadows/Highlights, Equalizer & GHS

8
rtdata/languages/Ukrainian
View File

@ -4572,17 +4572,17 @@ ZOOMPANEL_ZOOMOUT;Зменшити масштаб\nШвидка клавіша:
!TP_LOCALLAB_GHS_HLP;White point (WP linear) !TP_LOCALLAB_GHS_HLP;White point (WP linear)
!TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point. !TP_LOCALLAB_GHS_HLP_TOOLTIP;Sets the White point for a linear stretch of the image. Any pixel with value greater than the White point input will be clipped and the data lost.\n * Contrast gained by performing the linear stretch will be evenly distributed over the image, which will be brightened. Pixels with values greater than the White point will appear white and have a value of 1.0.\n * Setting this parameter to a value greater than 1 will extend the dynamic range at the high end.\n * The 'Highlight reconstruction' method has a very strong impact on the White-point value.\n\n * It is recommended to adjust this slider before the main GHS sliders to avoid clipping data. A very low Stretch factor (D) value (0.001 by default) is recommended for performing this adjustment.\n * The label 'Clipped pixel count - Shadows:x Highlights=y' shows you the number of pixels that would be clipped without adjusting the two sliders.\n * The label Pixel values - Darkest:w Lightest:z shows you the minimum and maximum values in the range [0, 1].\n\n * In Inverse GHS mode the behavior is reversed and there are possible interactions with the Black point.
!TP_LOCALLAB_GHS_HP;Protect highlights (HP) !TP_LOCALLAB_GHS_HP;Protect highlights (HP)
!TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limits the maximum value to the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP). !TP_LOCALLAB_GHS_HP_TOOLTIP;Sets a value above which the stretch is modified to preserve contrast in the highlights. This is done by performing a linear stretch of the data above the 'HP' level by reserving contrast from the rest of the image. Moving the HP level towards the current setting of SP increases both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to lower brightness levels while keeping the contrast and definition in the highlights. The amount of contrast reserved for the highlights is such that the continuity of the stretch is preserved.\n * This parameter must be at most 1 and no less than the Symmetry point.\n * The adjuster will automatically limit the minimum value based on the Symmetry Point (SP).\n\n * Using Highlight attenuation helps to reinforce the action of Protect highlights (HP).
!TP_LOCALLAB_GHS_INV;Inverse GHS !TP_LOCALLAB_GHS_INV;Inverse GHS
!TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings. !TP_LOCALLAB_GHS_INV_TOOLTIP;The inverse GHS is useful for working in negative space. It adds contrast on the far right and left of the histogram, brightening the deep shadows, darkening the bright highlights, and squeezing the histogram to the middle.\n\n * The Generalized Hyperbolic inverse transformation allows you to recover your original image, subject to mathematical precision, but you can use it for other purposes.\n\n * If the White point and Black point were changed in normal mode, they will likely need to be readjusted. The White point often needs to be readjusted lower. There is interaction between the two settings.
!TP_LOCALLAB_GHS_LC;Value (LC) !TP_LOCALLAB_GHS_LC;Value (LC)
!TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones !TP_LOCALLAB_GHS_LC_FRAME;Stretch Regularization & Midtones
!TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled. !TP_LOCALLAB_GHS_LC_TOOLTIP;Slightly increases local contrast that was weakened by stretching.\nCan be completed by other tools specific to local contrast such as wavelets.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_LP;Protect shadows (LP) !TP_LOCALLAB_GHS_LP;Protect shadows (LP)
!TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value to the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP). !TP_LOCALLAB_GHS_LP_TOOLTIP;Sets a value below which the stretch is modified to preserve contrast in the shadows/lowlights. This is done by performing a linear stretch of the data below the 'LP' level by reserving contrast from the rest of the image. Moving the LP level towards the current setting of SP changes both the scope (range) and the amount of this contrast reservation. The net effect is to push the overall stretch to higher brightness levels while keeping the contrast and definition in the background. The amount of contrast reserved for the lowlights is such that the continuity of the stretch is preserved.\n * This parameter must be at least 0 and no greater than the Symmetry point.\n * The adjuster will automatically limit the maximum value based on the Symmetry Point (SP).\n\n * Using Black point - negative values - when possible, allows to change both the value of Symmetry point (SP) and the action of Protect shadows (LP).
!TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE. !TP_LOCALLAB_GHS_METHOD_TOOLTIP;The Generalized Hyperbolic Stretch (GHS) process allows you to transform the values of pixels in your image to improve the representation of the underlying data for human visualisation.\nThe generalized hyperbolic equations used in the GHS process have five main parameters. This allows significant flexibility in designing the "shape" of the transformation.\n\nTypical uses of pixel intensity transformations include:\n * Initial stretch of pixel data from linear state.\n * Addition of contrast to key areas of the image.\n * Overall brightening or darkening of the image.\n * Adjustment of the image dynamic range.\n * Adjustment of pixel data in RGB Luminance, RGB standard, Luminance - chromaticity (Lab/Lch), Luminance (HSL), Saturation (HSL), or Hue (HSL) channels.\n\n * For a better results, you can proceed in several steps, creating 2 or more RT-spots each superimposed with the GHS tool. For each of the RT-Spots, the Symmetry point (SP) base value will be different. Use the histogram peak to position the SP value.\n * For example, you can start the system in RGB mode (1st Spot), then the 2nd Spot in RGB mode with a different SP, and the 3rd in Saturation or Hue mode.\n * You can mix RT-spots in 'Normal' mode and 'Inverse' mode to restore contrast balance.\n * Full Image allows you to limit the effect to specific colors based on the deltaE.
!TP_LOCALLAB_GHS_MID;Midtones !TP_LOCALLAB_GHS_MID;Midtones
!TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\n Can be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled !TP_LOCALLAB_GHS_MID_TOOLTIP;Adjusts midtone balance after GHS transformation.\nCan be used to rebalance the midtones of the image after stretching.\n\nWhen Stretch factor is 0.002 or less, Stretch Regularization & Midtones is disabled.
!TP_LOCALLAB_GHS_MODECUR;GHS !TP_LOCALLAB_GHS_MODECUR;GHS
!TP_LOCALLAB_GHS_MODELIN;Linear !TP_LOCALLAB_GHS_MODELIN;Linear
!TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function. !TP_LOCALLAB_GHS_SIMUL_TOOLTIP;Gives a representation of the GHS function.
@ -4614,7 +4614,7 @@ ZOOMPANEL_ZOOMOUT;Зменшити масштаб\nШвидка клавіша:
!TP_LOCALLAB_QJMODE_511;5.11 deprecated !TP_LOCALLAB_QJMODE_511;5.11 deprecated
!TP_LOCALLAB_QJMODE_512;5.12 !TP_LOCALLAB_QJMODE_512;5.12
!TP_LOCALLAB_QJMODE_TOOLTIP;The tone-mapping operators that use brightness data (Q for CAM16 and J for Jz) have been modified in RawTherapee version 5.12. This allows you to select either the current or the deprecated version. !TP_LOCALLAB_QJMODE_TOOLTIP;The tone-mapping operators that use brightness data (Q for CAM16 and J for Jz) have been modified in RawTherapee version 5.12. This allows you to select either the current or the deprecated version.
!TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch !TP_LOCALLAB_SH3;Generalized Hyperbolic Stretch (GHS)
!TP_LOCALLAB_SIGFRA11;Sigmoid Q (deprecated) !TP_LOCALLAB_SIGFRA11;Sigmoid Q (deprecated)
!TP_LOCALLAB_SIGJZFRA11;Sigmoid Jz (deprecated) !TP_LOCALLAB_SIGJZFRA11;Sigmoid Jz (deprecated)
!TP_LOCALLAB_SIGMOIDBL11;Blend !TP_LOCALLAB_SIGMOIDBL11;Blend