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876 lines
38 KiB
/*M/////////////////////////////////////////////////////////////////////////////////////// |
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// |
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// IMPORTANT: READ BEFORE DOWNLOADING, COPYING, INSTALLING OR USING. |
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// By downloading, copying, installing or using the software you agree to this license. |
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// If you do not agree to this license, do not download, install, |
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// copy or use the software. |
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// |
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// License Agreement |
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// For Open Source Computer Vision Library |
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// |
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// Copyright (C) 2000-2008, Intel Corporation, all rights reserved. |
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// Copyright (C) 2008-2012, Willow Garage Inc., all rights reserved. |
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// Third party copyrights are property of their respective owners. |
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// Redistribution and use in source and binary forms, with or without modification, |
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// are permitted provided that the following conditions are met: |
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// * Redistribution's of source code must retain the above copyright notice, |
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// * Redistribution's in binary form must reproduce the above copyright notice, |
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// this list of conditions and the following disclaimer in the documentation |
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// * The name of the copyright holders may not be used to endorse or promote products |
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// derived from this software without specific prior written permission. |
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// This software is provided by the copyright holders and contributors "as is" and |
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// any express or implied warranties, including, but not limited to, the implied |
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//M*/ |
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#ifndef OPENCV_PHOTO_HPP |
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#define OPENCV_PHOTO_HPP |
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#include "opencv2/core.hpp" |
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#include "opencv2/imgproc.hpp" |
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/** |
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@defgroup photo Computational Photography |
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@{ |
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@defgroup photo_denoise Denoising |
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@defgroup photo_hdr HDR imaging |
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This section describes high dynamic range imaging algorithms namely tonemapping, exposure alignment, |
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camera calibration with multiple exposures and exposure fusion. |
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@defgroup photo_clone Seamless Cloning |
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@defgroup photo_render Non-Photorealistic Rendering |
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@defgroup photo_c C API |
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@} |
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*/ |
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namespace cv |
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{ |
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//! @addtogroup photo |
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//! @{ |
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//! the inpainting algorithm |
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enum |
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{ |
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INPAINT_NS = 0, // Navier-Stokes algorithm |
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INPAINT_TELEA = 1 // A. Telea algorithm |
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}; |
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enum |
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{ |
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NORMAL_CLONE = 1, |
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MIXED_CLONE = 2, |
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MONOCHROME_TRANSFER = 3 |
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}; |
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enum |
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{ |
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RECURS_FILTER = 1, |
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NORMCONV_FILTER = 2 |
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}; |
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/** @brief Restores the selected region in an image using the region neighborhood. |
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@param src Input 8-bit, 16-bit unsigned or 32-bit float 1-channel or 8-bit 3-channel image. |
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@param inpaintMask Inpainting mask, 8-bit 1-channel image. Non-zero pixels indicate the area that |
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needs to be inpainted. |
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@param dst Output image with the same size and type as src . |
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@param inpaintRadius Radius of a circular neighborhood of each point inpainted that is considered |
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by the algorithm. |
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@param flags Inpainting method that could be one of the following: |
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- **INPAINT_NS** Navier-Stokes based method [Navier01] |
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- **INPAINT_TELEA** Method by Alexandru Telea @cite Telea04 . |
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The function reconstructs the selected image area from the pixel near the area boundary. The |
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function may be used to remove dust and scratches from a scanned photo, or to remove undesirable |
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objects from still images or video. See <http://en.wikipedia.org/wiki/Inpainting> for more details. |
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@note |
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- An example using the inpainting technique can be found at |
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opencv_source_code/samples/cpp/inpaint.cpp |
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- (Python) An example using the inpainting technique can be found at |
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opencv_source_code/samples/python/inpaint.py |
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*/ |
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CV_EXPORTS_W void inpaint( InputArray src, InputArray inpaintMask, |
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OutputArray dst, double inpaintRadius, int flags ); |
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//! @addtogroup photo_denoise |
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//! @{ |
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/** @brief Perform image denoising using Non-local Means Denoising algorithm |
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<http://www.ipol.im/pub/algo/bcm_non_local_means_denoising/> with several computational |
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optimizations. Noise expected to be a gaussian white noise |
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@param src Input 8-bit 1-channel, 2-channel, 3-channel or 4-channel image. |
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@param dst Output image with the same size and type as src . |
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@param templateWindowSize Size in pixels of the template patch that is used to compute weights. |
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Should be odd. Recommended value 7 pixels |
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@param searchWindowSize Size in pixels of the window that is used to compute weighted average for |
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given pixel. Should be odd. Affect performance linearly: greater searchWindowsSize - greater |
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denoising time. Recommended value 21 pixels |
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@param h Parameter regulating filter strength. Big h value perfectly removes noise but also |
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removes image details, smaller h value preserves details but also preserves some noise |
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This function expected to be applied to grayscale images. For colored images look at |
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fastNlMeansDenoisingColored. Advanced usage of this functions can be manual denoising of colored |
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image in different colorspaces. Such approach is used in fastNlMeansDenoisingColored by converting |
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image to CIELAB colorspace and then separately denoise L and AB components with different h |
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parameter. |
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*/ |
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CV_EXPORTS_W void fastNlMeansDenoising( InputArray src, OutputArray dst, float h = 3, |
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int templateWindowSize = 7, int searchWindowSize = 21); |
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|
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/** @brief Perform image denoising using Non-local Means Denoising algorithm |
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<http://www.ipol.im/pub/algo/bcm_non_local_means_denoising/> with several computational |
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optimizations. Noise expected to be a gaussian white noise |
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@param src Input 8-bit or 16-bit (only with NORM_L1) 1-channel, |
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2-channel, 3-channel or 4-channel image. |
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@param dst Output image with the same size and type as src . |
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@param templateWindowSize Size in pixels of the template patch that is used to compute weights. |
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Should be odd. Recommended value 7 pixels |
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@param searchWindowSize Size in pixels of the window that is used to compute weighted average for |
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given pixel. Should be odd. Affect performance linearly: greater searchWindowsSize - greater |
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denoising time. Recommended value 21 pixels |
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@param h Array of parameters regulating filter strength, either one |
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parameter applied to all channels or one per channel in dst. Big h value |
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perfectly removes noise but also removes image details, smaller h |
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value preserves details but also preserves some noise |
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@param normType Type of norm used for weight calculation. Can be either NORM_L2 or NORM_L1 |
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This function expected to be applied to grayscale images. For colored images look at |
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fastNlMeansDenoisingColored. Advanced usage of this functions can be manual denoising of colored |
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image in different colorspaces. Such approach is used in fastNlMeansDenoisingColored by converting |
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image to CIELAB colorspace and then separately denoise L and AB components with different h |
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parameter. |
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*/ |
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CV_EXPORTS_W void fastNlMeansDenoising( InputArray src, OutputArray dst, |
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const std::vector<float>& h, |
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int templateWindowSize = 7, int searchWindowSize = 21, |
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int normType = NORM_L2); |
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/** @brief Modification of fastNlMeansDenoising function for colored images |
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@param src Input 8-bit 3-channel image. |
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@param dst Output image with the same size and type as src . |
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@param templateWindowSize Size in pixels of the template patch that is used to compute weights. |
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Should be odd. Recommended value 7 pixels |
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@param searchWindowSize Size in pixels of the window that is used to compute weighted average for |
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given pixel. Should be odd. Affect performance linearly: greater searchWindowsSize - greater |
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denoising time. Recommended value 21 pixels |
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@param h Parameter regulating filter strength for luminance component. Bigger h value perfectly |
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removes noise but also removes image details, smaller h value preserves details but also preserves |
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some noise |
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@param hColor The same as h but for color components. For most images value equals 10 |
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will be enough to remove colored noise and do not distort colors |
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The function converts image to CIELAB colorspace and then separately denoise L and AB components |
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with given h parameters using fastNlMeansDenoising function. |
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*/ |
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CV_EXPORTS_W void fastNlMeansDenoisingColored( InputArray src, OutputArray dst, |
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float h = 3, float hColor = 3, |
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int templateWindowSize = 7, int searchWindowSize = 21); |
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/** @brief Modification of fastNlMeansDenoising function for images sequence where consecutive images have been |
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captured in small period of time. For example video. This version of the function is for grayscale |
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images or for manual manipulation with colorspaces. For more details see |
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<http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.131.6394> |
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@param srcImgs Input 8-bit 1-channel, 2-channel, 3-channel or |
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4-channel images sequence. All images should have the same type and |
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size. |
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@param imgToDenoiseIndex Target image to denoise index in srcImgs sequence |
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@param temporalWindowSize Number of surrounding images to use for target image denoising. Should |
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be odd. Images from imgToDenoiseIndex - temporalWindowSize / 2 to |
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imgToDenoiseIndex - temporalWindowSize / 2 from srcImgs will be used to denoise |
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srcImgs[imgToDenoiseIndex] image. |
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@param dst Output image with the same size and type as srcImgs images. |
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@param templateWindowSize Size in pixels of the template patch that is used to compute weights. |
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Should be odd. Recommended value 7 pixels |
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@param searchWindowSize Size in pixels of the window that is used to compute weighted average for |
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given pixel. Should be odd. Affect performance linearly: greater searchWindowsSize - greater |
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denoising time. Recommended value 21 pixels |
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@param h Parameter regulating filter strength. Bigger h value |
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perfectly removes noise but also removes image details, smaller h |
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value preserves details but also preserves some noise |
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*/ |
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CV_EXPORTS_W void fastNlMeansDenoisingMulti( InputArrayOfArrays srcImgs, OutputArray dst, |
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int imgToDenoiseIndex, int temporalWindowSize, |
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float h = 3, int templateWindowSize = 7, int searchWindowSize = 21); |
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|
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/** @brief Modification of fastNlMeansDenoising function for images sequence where consecutive images have been |
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captured in small period of time. For example video. This version of the function is for grayscale |
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images or for manual manipulation with colorspaces. For more details see |
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<http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.131.6394> |
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@param srcImgs Input 8-bit or 16-bit (only with NORM_L1) 1-channel, |
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2-channel, 3-channel or 4-channel images sequence. All images should |
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have the same type and size. |
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@param imgToDenoiseIndex Target image to denoise index in srcImgs sequence |
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@param temporalWindowSize Number of surrounding images to use for target image denoising. Should |
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be odd. Images from imgToDenoiseIndex - temporalWindowSize / 2 to |
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imgToDenoiseIndex - temporalWindowSize / 2 from srcImgs will be used to denoise |
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srcImgs[imgToDenoiseIndex] image. |
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@param dst Output image with the same size and type as srcImgs images. |
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@param templateWindowSize Size in pixels of the template patch that is used to compute weights. |
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Should be odd. Recommended value 7 pixels |
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@param searchWindowSize Size in pixels of the window that is used to compute weighted average for |
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given pixel. Should be odd. Affect performance linearly: greater searchWindowsSize - greater |
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denoising time. Recommended value 21 pixels |
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@param h Array of parameters regulating filter strength, either one |
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parameter applied to all channels or one per channel in dst. Big h value |
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perfectly removes noise but also removes image details, smaller h |
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value preserves details but also preserves some noise |
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@param normType Type of norm used for weight calculation. Can be either NORM_L2 or NORM_L1 |
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*/ |
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CV_EXPORTS_W void fastNlMeansDenoisingMulti( InputArrayOfArrays srcImgs, OutputArray dst, |
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int imgToDenoiseIndex, int temporalWindowSize, |
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const std::vector<float>& h, |
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int templateWindowSize = 7, int searchWindowSize = 21, |
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int normType = NORM_L2); |
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|
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/** @brief Modification of fastNlMeansDenoisingMulti function for colored images sequences |
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@param srcImgs Input 8-bit 3-channel images sequence. All images should have the same type and |
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size. |
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@param imgToDenoiseIndex Target image to denoise index in srcImgs sequence |
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@param temporalWindowSize Number of surrounding images to use for target image denoising. Should |
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be odd. Images from imgToDenoiseIndex - temporalWindowSize / 2 to |
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imgToDenoiseIndex - temporalWindowSize / 2 from srcImgs will be used to denoise |
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srcImgs[imgToDenoiseIndex] image. |
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@param dst Output image with the same size and type as srcImgs images. |
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@param templateWindowSize Size in pixels of the template patch that is used to compute weights. |
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Should be odd. Recommended value 7 pixels |
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@param searchWindowSize Size in pixels of the window that is used to compute weighted average for |
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given pixel. Should be odd. Affect performance linearly: greater searchWindowsSize - greater |
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denoising time. Recommended value 21 pixels |
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@param h Parameter regulating filter strength for luminance component. Bigger h value perfectly |
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removes noise but also removes image details, smaller h value preserves details but also preserves |
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some noise. |
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@param hColor The same as h but for color components. |
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The function converts images to CIELAB colorspace and then separately denoise L and AB components |
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with given h parameters using fastNlMeansDenoisingMulti function. |
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*/ |
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CV_EXPORTS_W void fastNlMeansDenoisingColoredMulti( InputArrayOfArrays srcImgs, OutputArray dst, |
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int imgToDenoiseIndex, int temporalWindowSize, |
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float h = 3, float hColor = 3, |
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int templateWindowSize = 7, int searchWindowSize = 21); |
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/** @brief Primal-dual algorithm is an algorithm for solving special types of variational problems (that is, |
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finding a function to minimize some functional). As the image denoising, in particular, may be seen |
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as the variational problem, primal-dual algorithm then can be used to perform denoising and this is |
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exactly what is implemented. |
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It should be noted, that this implementation was taken from the July 2013 blog entry |
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@cite MA13 , which also contained (slightly more general) ready-to-use source code on Python. |
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Subsequently, that code was rewritten on C++ with the usage of openCV by Vadim Pisarevsky at the end |
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of July 2013 and finally it was slightly adapted by later authors. |
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Although the thorough discussion and justification of the algorithm involved may be found in |
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@cite ChambolleEtAl, it might make sense to skim over it here, following @cite MA13 . To begin |
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with, we consider the 1-byte gray-level images as the functions from the rectangular domain of |
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pixels (it may be seen as set |
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\f$\left\{(x,y)\in\mathbb{N}\times\mathbb{N}\mid 1\leq x\leq n,\;1\leq y\leq m\right\}\f$ for some |
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\f$m,\;n\in\mathbb{N}\f$) into \f$\{0,1,\dots,255\}\f$. We shall denote the noised images as \f$f_i\f$ and with |
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this view, given some image \f$x\f$ of the same size, we may measure how bad it is by the formula |
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\f[\left\|\left\|\nabla x\right\|\right\| + \lambda\sum_i\left\|\left\|x-f_i\right\|\right\|\f] |
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\f$\|\|\cdot\|\|\f$ here denotes \f$L_2\f$-norm and as you see, the first addend states that we want our |
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image to be smooth (ideally, having zero gradient, thus being constant) and the second states that |
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we want our result to be close to the observations we've got. If we treat \f$x\f$ as a function, this is |
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exactly the functional what we seek to minimize and here the Primal-Dual algorithm comes into play. |
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@param observations This array should contain one or more noised versions of the image that is to |
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be restored. |
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@param result Here the denoised image will be stored. There is no need to do pre-allocation of |
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storage space, as it will be automatically allocated, if necessary. |
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@param lambda Corresponds to \f$\lambda\f$ in the formulas above. As it is enlarged, the smooth |
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(blurred) images are treated more favorably than detailed (but maybe more noised) ones. Roughly |
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speaking, as it becomes smaller, the result will be more blur but more sever outliers will be |
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removed. |
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@param niters Number of iterations that the algorithm will run. Of course, as more iterations as |
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better, but it is hard to quantitatively refine this statement, so just use the default and |
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increase it if the results are poor. |
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*/ |
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CV_EXPORTS_W void denoise_TVL1(const std::vector<Mat>& observations,Mat& result, double lambda=1.0, int niters=30); |
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//! @} photo_denoise |
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//! @addtogroup photo_hdr |
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//! @{ |
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enum { LDR_SIZE = 256 }; |
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/** @brief Base class for tonemapping algorithms - tools that are used to map HDR image to 8-bit range. |
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*/ |
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class CV_EXPORTS_W Tonemap : public Algorithm |
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{ |
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public: |
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/** @brief Tonemaps image |
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@param src source image - 32-bit 3-channel Mat |
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@param dst destination image - 32-bit 3-channel Mat with values in [0, 1] range |
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*/ |
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CV_WRAP virtual void process(InputArray src, OutputArray dst) = 0; |
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CV_WRAP virtual float getGamma() const = 0; |
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CV_WRAP virtual void setGamma(float gamma) = 0; |
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}; |
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/** @brief Creates simple linear mapper with gamma correction |
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@param gamma positive value for gamma correction. Gamma value of 1.0 implies no correction, gamma |
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equal to 2.2f is suitable for most displays. |
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Generally gamma \> 1 brightens the image and gamma \< 1 darkens it. |
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*/ |
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CV_EXPORTS_W Ptr<Tonemap> createTonemap(float gamma = 1.0f); |
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/** @brief Adaptive logarithmic mapping is a fast global tonemapping algorithm that scales the image in |
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logarithmic domain. |
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Since it's a global operator the same function is applied to all the pixels, it is controlled by the |
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bias parameter. |
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Optional saturation enhancement is possible as described in @cite FL02 . |
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For more information see @cite DM03 . |
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*/ |
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class CV_EXPORTS_W TonemapDrago : public Tonemap |
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{ |
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public: |
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CV_WRAP virtual float getSaturation() const = 0; |
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CV_WRAP virtual void setSaturation(float saturation) = 0; |
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CV_WRAP virtual float getBias() const = 0; |
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CV_WRAP virtual void setBias(float bias) = 0; |
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}; |
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/** @brief Creates TonemapDrago object |
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@param gamma gamma value for gamma correction. See createTonemap |
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@param saturation positive saturation enhancement value. 1.0 preserves saturation, values greater |
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than 1 increase saturation and values less than 1 decrease it. |
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@param bias value for bias function in [0, 1] range. Values from 0.7 to 0.9 usually give best |
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results, default value is 0.85. |
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*/ |
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CV_EXPORTS_W Ptr<TonemapDrago> createTonemapDrago(float gamma = 1.0f, float saturation = 1.0f, float bias = 0.85f); |
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/** @brief This algorithm decomposes image into two layers: base layer and detail layer using bilateral filter |
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and compresses contrast of the base layer thus preserving all the details. |
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This implementation uses regular bilateral filter from opencv. |
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Saturation enhancement is possible as in ocvTonemapDrago. |
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For more information see @cite DD02 . |
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*/ |
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class CV_EXPORTS_W TonemapDurand : public Tonemap |
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{ |
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public: |
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CV_WRAP virtual float getSaturation() const = 0; |
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CV_WRAP virtual void setSaturation(float saturation) = 0; |
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CV_WRAP virtual float getContrast() const = 0; |
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CV_WRAP virtual void setContrast(float contrast) = 0; |
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CV_WRAP virtual float getSigmaSpace() const = 0; |
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CV_WRAP virtual void setSigmaSpace(float sigma_space) = 0; |
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CV_WRAP virtual float getSigmaColor() const = 0; |
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CV_WRAP virtual void setSigmaColor(float sigma_color) = 0; |
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}; |
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/** @brief Creates TonemapDurand object |
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@param gamma gamma value for gamma correction. See createTonemap |
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@param contrast resulting contrast on logarithmic scale, i. e. log(max / min), where max and min |
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are maximum and minimum luminance values of the resulting image. |
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@param saturation saturation enhancement value. See createTonemapDrago |
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@param sigma_space bilateral filter sigma in color space |
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@param sigma_color bilateral filter sigma in coordinate space |
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*/ |
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CV_EXPORTS_W Ptr<TonemapDurand> |
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createTonemapDurand(float gamma = 1.0f, float contrast = 4.0f, float saturation = 1.0f, float sigma_space = 2.0f, float sigma_color = 2.0f); |
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/** @brief This is a global tonemapping operator that models human visual system. |
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Mapping function is controlled by adaptation parameter, that is computed using light adaptation and |
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color adaptation. |
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For more information see @cite RD05 . |
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*/ |
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class CV_EXPORTS_W TonemapReinhard : public Tonemap |
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{ |
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public: |
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CV_WRAP virtual float getIntensity() const = 0; |
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CV_WRAP virtual void setIntensity(float intensity) = 0; |
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CV_WRAP virtual float getLightAdaptation() const = 0; |
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CV_WRAP virtual void setLightAdaptation(float light_adapt) = 0; |
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CV_WRAP virtual float getColorAdaptation() const = 0; |
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CV_WRAP virtual void setColorAdaptation(float color_adapt) = 0; |
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}; |
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/** @brief Creates TonemapReinhard object |
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@param gamma gamma value for gamma correction. See createTonemap |
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@param intensity result intensity in [-8, 8] range. Greater intensity produces brighter results. |
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@param light_adapt light adaptation in [0, 1] range. If 1 adaptation is based only on pixel |
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value, if 0 it's global, otherwise it's a weighted mean of this two cases. |
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@param color_adapt chromatic adaptation in [0, 1] range. If 1 channels are treated independently, |
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if 0 adaptation level is the same for each channel. |
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*/ |
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CV_EXPORTS_W Ptr<TonemapReinhard> |
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createTonemapReinhard(float gamma = 1.0f, float intensity = 0.0f, float light_adapt = 1.0f, float color_adapt = 0.0f); |
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/** @brief This algorithm transforms image to contrast using gradients on all levels of gaussian pyramid, |
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transforms contrast values to HVS response and scales the response. After this the image is |
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reconstructed from new contrast values. |
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For more information see @cite MM06 . |
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*/ |
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class CV_EXPORTS_W TonemapMantiuk : public Tonemap |
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{ |
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public: |
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CV_WRAP virtual float getScale() const = 0; |
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CV_WRAP virtual void setScale(float scale) = 0; |
|
|
|
CV_WRAP virtual float getSaturation() const = 0; |
|
CV_WRAP virtual void setSaturation(float saturation) = 0; |
|
}; |
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|
|
/** @brief Creates TonemapMantiuk object |
|
|
|
@param gamma gamma value for gamma correction. See createTonemap |
|
@param scale contrast scale factor. HVS response is multiplied by this parameter, thus compressing |
|
dynamic range. Values from 0.6 to 0.9 produce best results. |
|
@param saturation saturation enhancement value. See createTonemapDrago |
|
*/ |
|
CV_EXPORTS_W Ptr<TonemapMantiuk> |
|
createTonemapMantiuk(float gamma = 1.0f, float scale = 0.7f, float saturation = 1.0f); |
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|
|
/** @brief The base class for algorithms that align images of the same scene with different exposures |
|
*/ |
|
class CV_EXPORTS_W AlignExposures : public Algorithm |
|
{ |
|
public: |
|
/** @brief Aligns images |
|
|
|
@param src vector of input images |
|
@param dst vector of aligned images |
|
@param times vector of exposure time values for each image |
|
@param response 256x1 matrix with inverse camera response function for each pixel value, it should |
|
have the same number of channels as images. |
|
*/ |
|
CV_WRAP virtual void process(InputArrayOfArrays src, std::vector<Mat>& dst, |
|
InputArray times, InputArray response) = 0; |
|
}; |
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|
|
/** @brief This algorithm converts images to median threshold bitmaps (1 for pixels brighter than median |
|
luminance and 0 otherwise) and than aligns the resulting bitmaps using bit operations. |
|
|
|
It is invariant to exposure, so exposure values and camera response are not necessary. |
|
|
|
In this implementation new image regions are filled with zeros. |
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|
|
For more information see @cite GW03 . |
|
*/ |
|
class CV_EXPORTS_W AlignMTB : public AlignExposures |
|
{ |
|
public: |
|
CV_WRAP virtual void process(InputArrayOfArrays src, std::vector<Mat>& dst, |
|
InputArray times, InputArray response) = 0; |
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|
|
/** @brief Short version of process, that doesn't take extra arguments. |
|
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|
@param src vector of input images |
|
@param dst vector of aligned images |
|
*/ |
|
CV_WRAP virtual void process(InputArrayOfArrays src, std::vector<Mat>& dst) = 0; |
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|
|
/** @brief Calculates shift between two images, i. e. how to shift the second image to correspond it with the |
|
first. |
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|
@param img0 first image |
|
@param img1 second image |
|
*/ |
|
CV_WRAP virtual Point calculateShift(InputArray img0, InputArray img1) = 0; |
|
/** @brief Helper function, that shift Mat filling new regions with zeros. |
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|
@param src input image |
|
@param dst result image |
|
@param shift shift value |
|
*/ |
|
CV_WRAP virtual void shiftMat(InputArray src, OutputArray dst, const Point shift) = 0; |
|
/** @brief Computes median threshold and exclude bitmaps of given image. |
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|
@param img input image |
|
@param tb median threshold bitmap |
|
@param eb exclude bitmap |
|
*/ |
|
CV_WRAP virtual void computeBitmaps(InputArray img, OutputArray tb, OutputArray eb) = 0; |
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|
CV_WRAP virtual int getMaxBits() const = 0; |
|
CV_WRAP virtual void setMaxBits(int max_bits) = 0; |
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|
CV_WRAP virtual int getExcludeRange() const = 0; |
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CV_WRAP virtual void setExcludeRange(int exclude_range) = 0; |
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|
CV_WRAP virtual bool getCut() const = 0; |
|
CV_WRAP virtual void setCut(bool value) = 0; |
|
}; |
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|
|
/** @brief Creates AlignMTB object |
|
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|
@param max_bits logarithm to the base 2 of maximal shift in each dimension. Values of 5 and 6 are |
|
usually good enough (31 and 63 pixels shift respectively). |
|
@param exclude_range range for exclusion bitmap that is constructed to suppress noise around the |
|
median value. |
|
@param cut if true cuts images, otherwise fills the new regions with zeros. |
|
*/ |
|
CV_EXPORTS_W Ptr<AlignMTB> createAlignMTB(int max_bits = 6, int exclude_range = 4, bool cut = true); |
|
|
|
/** @brief The base class for camera response calibration algorithms. |
|
*/ |
|
class CV_EXPORTS_W CalibrateCRF : public Algorithm |
|
{ |
|
public: |
|
/** @brief Recovers inverse camera response. |
|
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|
@param src vector of input images |
|
@param dst 256x1 matrix with inverse camera response function |
|
@param times vector of exposure time values for each image |
|
*/ |
|
CV_WRAP virtual void process(InputArrayOfArrays src, OutputArray dst, InputArray times) = 0; |
|
}; |
|
|
|
/** @brief Inverse camera response function is extracted for each brightness value by minimizing an objective |
|
function as linear system. Objective function is constructed using pixel values on the same position |
|
in all images, extra term is added to make the result smoother. |
|
|
|
For more information see @cite DM97 . |
|
*/ |
|
class CV_EXPORTS_W CalibrateDebevec : public CalibrateCRF |
|
{ |
|
public: |
|
CV_WRAP virtual float getLambda() const = 0; |
|
CV_WRAP virtual void setLambda(float lambda) = 0; |
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|
|
CV_WRAP virtual int getSamples() const = 0; |
|
CV_WRAP virtual void setSamples(int samples) = 0; |
|
|
|
CV_WRAP virtual bool getRandom() const = 0; |
|
CV_WRAP virtual void setRandom(bool random) = 0; |
|
}; |
|
|
|
/** @brief Creates CalibrateDebevec object |
|
|
|
@param samples number of pixel locations to use |
|
@param lambda smoothness term weight. Greater values produce smoother results, but can alter the |
|
response. |
|
@param random if true sample pixel locations are chosen at random, otherwise they form a |
|
rectangular grid. |
|
*/ |
|
CV_EXPORTS_W Ptr<CalibrateDebevec> createCalibrateDebevec(int samples = 70, float lambda = 10.0f, bool random = false); |
|
|
|
/** @brief Inverse camera response function is extracted for each brightness value by minimizing an objective |
|
function as linear system. This algorithm uses all image pixels. |
|
|
|
For more information see @cite RB99 . |
|
*/ |
|
class CV_EXPORTS_W CalibrateRobertson : public CalibrateCRF |
|
{ |
|
public: |
|
CV_WRAP virtual int getMaxIter() const = 0; |
|
CV_WRAP virtual void setMaxIter(int max_iter) = 0; |
|
|
|
CV_WRAP virtual float getThreshold() const = 0; |
|
CV_WRAP virtual void setThreshold(float threshold) = 0; |
|
|
|
CV_WRAP virtual Mat getRadiance() const = 0; |
|
}; |
|
|
|
/** @brief Creates CalibrateRobertson object |
|
|
|
@param max_iter maximal number of Gauss-Seidel solver iterations. |
|
@param threshold target difference between results of two successive steps of the minimization. |
|
*/ |
|
CV_EXPORTS_W Ptr<CalibrateRobertson> createCalibrateRobertson(int max_iter = 30, float threshold = 0.01f); |
|
|
|
/** @brief The base class algorithms that can merge exposure sequence to a single image. |
|
*/ |
|
class CV_EXPORTS_W MergeExposures : public Algorithm |
|
{ |
|
public: |
|
/** @brief Merges images. |
|
|
|
@param src vector of input images |
|
@param dst result image |
|
@param times vector of exposure time values for each image |
|
@param response 256x1 matrix with inverse camera response function for each pixel value, it should |
|
have the same number of channels as images. |
|
*/ |
|
CV_WRAP virtual void process(InputArrayOfArrays src, OutputArray dst, |
|
InputArray times, InputArray response) = 0; |
|
}; |
|
|
|
/** @brief The resulting HDR image is calculated as weighted average of the exposures considering exposure |
|
values and camera response. |
|
|
|
For more information see @cite DM97 . |
|
*/ |
|
class CV_EXPORTS_W MergeDebevec : public MergeExposures |
|
{ |
|
public: |
|
CV_WRAP virtual void process(InputArrayOfArrays src, OutputArray dst, |
|
InputArray times, InputArray response) = 0; |
|
CV_WRAP virtual void process(InputArrayOfArrays src, OutputArray dst, InputArray times) = 0; |
|
}; |
|
|
|
/** @brief Creates MergeDebevec object |
|
*/ |
|
CV_EXPORTS_W Ptr<MergeDebevec> createMergeDebevec(); |
|
|
|
/** @brief Pixels are weighted using contrast, saturation and well-exposedness measures, than images are |
|
combined using laplacian pyramids. |
|
|
|
The resulting image weight is constructed as weighted average of contrast, saturation and |
|
well-exposedness measures. |
|
|
|
The resulting image doesn't require tonemapping and can be converted to 8-bit image by multiplying |
|
by 255, but it's recommended to apply gamma correction and/or linear tonemapping. |
|
|
|
For more information see @cite MK07 . |
|
*/ |
|
class CV_EXPORTS_W MergeMertens : public MergeExposures |
|
{ |
|
public: |
|
CV_WRAP virtual void process(InputArrayOfArrays src, OutputArray dst, |
|
InputArray times, InputArray response) = 0; |
|
/** @brief Short version of process, that doesn't take extra arguments. |
|
|
|
@param src vector of input images |
|
@param dst result image |
|
*/ |
|
CV_WRAP virtual void process(InputArrayOfArrays src, OutputArray dst) = 0; |
|
|
|
CV_WRAP virtual float getContrastWeight() const = 0; |
|
CV_WRAP virtual void setContrastWeight(float contrast_weiht) = 0; |
|
|
|
CV_WRAP virtual float getSaturationWeight() const = 0; |
|
CV_WRAP virtual void setSaturationWeight(float saturation_weight) = 0; |
|
|
|
CV_WRAP virtual float getExposureWeight() const = 0; |
|
CV_WRAP virtual void setExposureWeight(float exposure_weight) = 0; |
|
}; |
|
|
|
/** @brief Creates MergeMertens object |
|
|
|
@param contrast_weight contrast measure weight. See MergeMertens. |
|
@param saturation_weight saturation measure weight |
|
@param exposure_weight well-exposedness measure weight |
|
*/ |
|
CV_EXPORTS_W Ptr<MergeMertens> |
|
createMergeMertens(float contrast_weight = 1.0f, float saturation_weight = 1.0f, float exposure_weight = 0.0f); |
|
|
|
/** @brief The resulting HDR image is calculated as weighted average of the exposures considering exposure |
|
values and camera response. |
|
|
|
For more information see @cite RB99 . |
|
*/ |
|
class CV_EXPORTS_W MergeRobertson : public MergeExposures |
|
{ |
|
public: |
|
CV_WRAP virtual void process(InputArrayOfArrays src, OutputArray dst, |
|
InputArray times, InputArray response) = 0; |
|
CV_WRAP virtual void process(InputArrayOfArrays src, OutputArray dst, InputArray times) = 0; |
|
}; |
|
|
|
/** @brief Creates MergeRobertson object |
|
*/ |
|
CV_EXPORTS_W Ptr<MergeRobertson> createMergeRobertson(); |
|
|
|
//! @} photo_hdr |
|
|
|
/** @brief Transforms a color image to a grayscale image. It is a basic tool in digital printing, stylized |
|
black-and-white photograph rendering, and in many single channel image processing applications |
|
@cite CL12 . |
|
|
|
@param src Input 8-bit 3-channel image. |
|
@param grayscale Output 8-bit 1-channel image. |
|
@param color_boost Output 8-bit 3-channel image. |
|
|
|
This function is to be applied on color images. |
|
*/ |
|
CV_EXPORTS_W void decolor( InputArray src, OutputArray grayscale, OutputArray color_boost); |
|
|
|
//! @addtogroup photo_clone |
|
//! @{ |
|
|
|
/** @example cloning_demo.cpp |
|
An example using seamlessClone function |
|
*/ |
|
/** @brief Image editing tasks concern either global changes (color/intensity corrections, filters, |
|
deformations) or local changes concerned to a selection. Here we are interested in achieving local |
|
changes, ones that are restricted to a region manually selected (ROI), in a seamless and effortless |
|
manner. The extent of the changes ranges from slight distortions to complete replacement by novel |
|
content @cite PM03 . |
|
|
|
@param src Input 8-bit 3-channel image. |
|
@param dst Input 8-bit 3-channel image. |
|
@param mask Input 8-bit 1 or 3-channel image. |
|
@param p Point in dst image where object is placed. |
|
@param blend Output image with the same size and type as dst. |
|
@param flags Cloning method that could be one of the following: |
|
- **NORMAL_CLONE** The power of the method is fully expressed when inserting objects with |
|
complex outlines into a new background |
|
- **MIXED_CLONE** The classic method, color-based selection and alpha masking might be time |
|
consuming and often leaves an undesirable halo. Seamless cloning, even averaged with the |
|
original image, is not effective. Mixed seamless cloning based on a loose selection proves |
|
effective. |
|
- **MONOCHROME_TRANSFER** Monochrome transfer allows the user to easily replace certain features of |
|
one object by alternative features. |
|
*/ |
|
CV_EXPORTS_W void seamlessClone( InputArray src, InputArray dst, InputArray mask, Point p, |
|
OutputArray blend, int flags); |
|
|
|
/** @brief Given an original color image, two differently colored versions of this image can be mixed |
|
seamlessly. |
|
|
|
@param src Input 8-bit 3-channel image. |
|
@param mask Input 8-bit 1 or 3-channel image. |
|
@param dst Output image with the same size and type as src . |
|
@param red_mul R-channel multiply factor. |
|
@param green_mul G-channel multiply factor. |
|
@param blue_mul B-channel multiply factor. |
|
|
|
Multiplication factor is between .5 to 2.5. |
|
*/ |
|
CV_EXPORTS_W void colorChange(InputArray src, InputArray mask, OutputArray dst, float red_mul = 1.0f, |
|
float green_mul = 1.0f, float blue_mul = 1.0f); |
|
|
|
/** @brief Applying an appropriate non-linear transformation to the gradient field inside the selection and |
|
then integrating back with a Poisson solver, modifies locally the apparent illumination of an image. |
|
|
|
@param src Input 8-bit 3-channel image. |
|
@param mask Input 8-bit 1 or 3-channel image. |
|
@param dst Output image with the same size and type as src. |
|
@param alpha Value ranges between 0-2. |
|
@param beta Value ranges between 0-2. |
|
|
|
This is useful to highlight under-exposed foreground objects or to reduce specular reflections. |
|
*/ |
|
CV_EXPORTS_W void illuminationChange(InputArray src, InputArray mask, OutputArray dst, |
|
float alpha = 0.2f, float beta = 0.4f); |
|
|
|
/** @brief By retaining only the gradients at edge locations, before integrating with the Poisson solver, one |
|
washes out the texture of the selected region, giving its contents a flat aspect. Here Canny Edge |
|
Detector is used. |
|
|
|
@param src Input 8-bit 3-channel image. |
|
@param mask Input 8-bit 1 or 3-channel image. |
|
@param dst Output image with the same size and type as src. |
|
@param low_threshold Range from 0 to 100. |
|
@param high_threshold Value \> 100. |
|
@param kernel_size The size of the Sobel kernel to be used. |
|
|
|
**NOTE:** |
|
|
|
The algorithm assumes that the color of the source image is close to that of the destination. This |
|
assumption means that when the colors don't match, the source image color gets tinted toward the |
|
color of the destination image. |
|
*/ |
|
CV_EXPORTS_W void textureFlattening(InputArray src, InputArray mask, OutputArray dst, |
|
float low_threshold = 30, float high_threshold = 45, |
|
int kernel_size = 3); |
|
|
|
//! @} photo_clone |
|
|
|
//! @addtogroup photo_render |
|
//! @{ |
|
|
|
/** @brief Filtering is the fundamental operation in image and video processing. Edge-preserving smoothing |
|
filters are used in many different applications @cite EM11 . |
|
|
|
@param src Input 8-bit 3-channel image. |
|
@param dst Output 8-bit 3-channel image. |
|
@param flags Edge preserving filters: |
|
- **RECURS_FILTER** = 1 |
|
- **NORMCONV_FILTER** = 2 |
|
@param sigma_s Range between 0 to 200. |
|
@param sigma_r Range between 0 to 1. |
|
*/ |
|
CV_EXPORTS_W void edgePreservingFilter(InputArray src, OutputArray dst, int flags = 1, |
|
float sigma_s = 60, float sigma_r = 0.4f); |
|
|
|
/** @brief This filter enhances the details of a particular image. |
|
|
|
@param src Input 8-bit 3-channel image. |
|
@param dst Output image with the same size and type as src. |
|
@param sigma_s Range between 0 to 200. |
|
@param sigma_r Range between 0 to 1. |
|
*/ |
|
CV_EXPORTS_W void detailEnhance(InputArray src, OutputArray dst, float sigma_s = 10, |
|
float sigma_r = 0.15f); |
|
|
|
/** @example npr_demo.cpp |
|
An example using non-photorealistic line drawing functions |
|
*/ |
|
/** @brief Pencil-like non-photorealistic line drawing |
|
|
|
@param src Input 8-bit 3-channel image. |
|
@param dst1 Output 8-bit 1-channel image. |
|
@param dst2 Output image with the same size and type as src. |
|
@param sigma_s Range between 0 to 200. |
|
@param sigma_r Range between 0 to 1. |
|
@param shade_factor Range between 0 to 0.1. |
|
*/ |
|
CV_EXPORTS_W void pencilSketch(InputArray src, OutputArray dst1, OutputArray dst2, |
|
float sigma_s = 60, float sigma_r = 0.07f, float shade_factor = 0.02f); |
|
|
|
/** @brief Stylization aims to produce digital imagery with a wide variety of effects not focused on |
|
photorealism. Edge-aware filters are ideal for stylization, as they can abstract regions of low |
|
contrast while preserving, or enhancing, high-contrast features. |
|
|
|
@param src Input 8-bit 3-channel image. |
|
@param dst Output image with the same size and type as src. |
|
@param sigma_s Range between 0 to 200. |
|
@param sigma_r Range between 0 to 1. |
|
*/ |
|
CV_EXPORTS_W void stylization(InputArray src, OutputArray dst, float sigma_s = 60, |
|
float sigma_r = 0.45f); |
|
|
|
//! @} photo_render |
|
|
|
//! @} photo |
|
|
|
} // cv |
|
|
|
#ifndef DISABLE_OPENCV_24_COMPATIBILITY |
|
#include "opencv2/photo/photo_c.h" |
|
#endif |
|
|
|
#endif
|
|
|