2014-11-27 20:39:05 +08:00
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Video Input with OpenCV and similarity measurement {#tutorial_video_input_psnr_ssim}
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==================================================
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2020-12-08 00:13:54 +08:00
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@tableofcontents
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2020-12-05 06:46:00 +08:00
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@prev_tutorial{tutorial_raster_io_gdal}
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2020-05-20 06:59:28 +08:00
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@next_tutorial{tutorial_video_write}
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2020-12-05 06:46:00 +08:00
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| Original author | Bernát Gábor |
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| Compatibility | OpenCV >= 3.0 |
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2014-11-27 20:39:05 +08:00
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Goal
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----
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Today it is common to have a digital video recording system at your disposal. Therefore, you will
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eventually come to the situation that you no longer process a batch of images, but video streams.
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These may be of two kinds: real-time image feed (in the case of a webcam) or prerecorded and hard
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2018-01-07 08:15:43 +08:00
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disk drive stored files. Luckily OpenCV treats these two in the same manner, with the same C++
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2014-11-27 20:39:05 +08:00
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class. So here's what you'll learn in this tutorial:
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- How to open and read video streams
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- Two ways for checking image similarity: PSNR and SSIM
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The source code
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---------------
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As a test case where to show off these using OpenCV I've created a small program that reads in two
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video files and performs a similarity check between them. This is something you could use to check
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just how well a new video compressing algorithms works. Let there be a reference (original) video
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like [this small Megamind clip
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2016-06-14 21:01:36 +08:00
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](https://github.com/opencv/opencv/tree/master/samples/data/Megamind.avi) and [a compressed
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version of it ](https://github.com/opencv/opencv/tree/master/samples/data/Megamind_bugy.avi).
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You may also find the source code and these video file in the
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2016-02-12 18:42:44 +08:00
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`samples/data` folder of the OpenCV source library.
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2020-02-22 19:42:26 +08:00
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@add_toggle_cpp
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@include cpp/tutorial_code/videoio/video-input-psnr-ssim/video-input-psnr-ssim.cpp
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@end_toggle
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@add_toggle_python
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@include samples/python/tutorial_code/videoio/video-input-psnr-ssim.py
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@end_toggle
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2014-11-27 20:39:05 +08:00
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How to read a video stream (online-camera or offline-file)?
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-----------------------------------------------------------
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2014-11-28 00:54:13 +08:00
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Essentially, all the functionalities required for video manipulation is integrated in the @ref cv::VideoCapture
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C++ class. This on itself builds on the FFmpeg open source library. This is a basic
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dependency of OpenCV so you shouldn't need to worry about this. A video is composed of a succession
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of images, we refer to these in the literature as frames. In case of a video file there is a *frame
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rate* specifying just how long is between two frames. While for the video cameras usually there is a
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limit of just how many frames they can digitize per second, this property is less important as at
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any time the camera sees the current snapshot of the world.
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The first task you need to do is to assign to a @ref cv::VideoCapture class its source. You can do
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this either via the @ref cv::VideoCapture::VideoCapture or its @ref cv::VideoCapture::open function. If this argument is an
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integer then you will bind the class to a camera, a device. The number passed here is the ID of the
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device, assigned by the operating system. If you have a single camera attached to your system its ID
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will probably be zero and further ones increasing from there. If the parameter passed to these is a
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string it will refer to a video file, and the string points to the location and name of the file.
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For example, to the upper source code a valid command line is:
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@code{.bash}
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video/Megamind.avi video/Megamind_bug.avi 35 10
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@endcode
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We do a similarity check. This requires a reference and a test case video file. The first two
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arguments refer to this. Here we use a relative address. This means that the application will look
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into its current working directory and open the video folder and try to find inside this the
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*Megamind.avi* and the *Megamind_bug.avi*.
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@code{.cpp}
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const string sourceReference = argv[1],sourceCompareWith = argv[2];
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VideoCapture captRefrnc(sourceReference);
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// or
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VideoCapture captUndTst;
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captUndTst.open(sourceCompareWith);
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@endcode
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To check if the binding of the class to a video source was successful or not use the @ref cv::VideoCapture::isOpened
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function:
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@code{.cpp}
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if ( !captRefrnc.isOpened())
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{
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cout << "Could not open reference " << sourceReference << endl;
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return -1;
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}
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@endcode
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Closing the video is automatic when the objects destructor is called. However, if you want to close
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it before this you need to call its @ref cv::VideoCapture::release function. The frames of the video are just
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simple images. Therefore, we just need to extract them from the @ref cv::VideoCapture object and put
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them inside a *Mat* one. The video streams are sequential. You may get the frames one after another
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by the @ref cv::VideoCapture::read or the overloaded \>\> operator:
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@code{.cpp}
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Mat frameReference, frameUnderTest;
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captRefrnc >> frameReference;
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2019-02-11 16:45:16 +08:00
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captUndTst.read(frameUnderTest);
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@endcode
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The upper read operations will leave empty the *Mat* objects if no frame could be acquired (either
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cause the video stream was closed or you got to the end of the video file). We can check this with a
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simple if:
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@code{.cpp}
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if( frameReference.empty() || frameUnderTest.empty())
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{
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// exit the program
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}
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@endcode
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A read method is made of a frame grab and a decoding applied on that. You may call explicitly these
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two by using the @ref cv::VideoCapture::grab and then the @ref cv::VideoCapture::retrieve functions.
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Videos have many-many information attached to them besides the content of the frames. These are
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usually numbers, however in some case it may be short character sequences (4 bytes or less). Due to
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this to acquire these information there is a general function named @ref cv::VideoCapture::get that returns double
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values containing these properties. Use bitwise operations to decode the characters from a double
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type and conversions where valid values are only integers. Its single argument is the ID of the
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queried property. For example, here we get the size of the frames in the reference and test case
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video file; plus the number of frames inside the reference.
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@code{.cpp}
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Size refS = Size((int) captRefrnc.get(CAP_PROP_FRAME_WIDTH),
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(int) captRefrnc.get(CAP_PROP_FRAME_HEIGHT)),
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cout << "Reference frame resolution: Width=" << refS.width << " Height=" << refS.height
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<< " of nr#: " << captRefrnc.get(CAP_PROP_FRAME_COUNT) << endl;
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@endcode
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When you are working with videos you may often want to control these values yourself. To do this
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there is a @ref cv::VideoCapture::set function. Its first argument remains the name of the property you want to
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change and there is a second of double type containing the value to be set. It will return true if
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it succeeds and false otherwise. Good examples for this is seeking in a video file to a given time
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or frame:
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@code{.cpp}
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captRefrnc.set(CAP_PROP_POS_MSEC, 1.2); // go to the 1.2 second in the video
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captRefrnc.set(CAP_PROP_POS_FRAMES, 10); // go to the 10th frame of the video
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// now a read operation would read the frame at the set position
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@endcode
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For properties you can read and change look into the documentation of the @ref cv::VideoCapture::get and
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@ref cv::VideoCapture::set functions.
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2014-11-27 20:39:05 +08:00
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2020-11-10 20:36:13 +08:00
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### Image similarity - PSNR and SSIM
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We want to check just how imperceptible our video converting operation went, therefore we need a
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system to check frame by frame the similarity or differences. The most common algorithm used for
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this is the PSNR (aka **Peak signal-to-noise ratio**). The simplest definition of this starts out
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2020-11-14 10:47:44 +08:00
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from the *mean squared error*. Let there be two images: I1 and I2; with a two dimensional size i and
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j, composed of c number of channels.
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\f[MSE = \frac{1}{c*i*j} \sum{(I_1-I_2)^2}\f]
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Then the PSNR is expressed as:
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\f[PSNR = 10 \cdot \log_{10} \left( \frac{MAX_I^2}{MSE} \right)\f]
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2017-08-14 22:16:04 +08:00
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Here the \f$MAX_I\f$ is the maximum valid value for a pixel. In case of the simple single byte image
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per pixel per channel this is 255. When two images are the same the MSE will give zero, resulting in
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an invalid divide by zero operation in the PSNR formula. In this case the PSNR is undefined and as
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we'll need to handle this case separately. The transition to a logarithmic scale is made because the
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pixel values have a very wide dynamic range. All this translated to OpenCV and a function looks
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like:
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2020-02-22 19:42:26 +08:00
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@add_toggle_cpp
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2020-11-10 20:36:13 +08:00
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@snippet cpp/tutorial_code/videoio/video-input-psnr-ssim/video-input-psnr-ssim.cpp get-psnr
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@end_toggle
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@add_toggle_python
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2020-11-10 20:36:13 +08:00
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@snippet samples/python/tutorial_code/videoio/video-input-psnr-ssim.py get-psnr
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2020-02-22 19:42:26 +08:00
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@end_toggle
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2014-11-27 20:39:05 +08:00
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Typically result values are anywhere between 30 and 50 for video compression, where higher is
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better. If the images significantly differ you'll get much lower ones like 15 and so. This
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similarity check is easy and fast to calculate, however in practice it may turn out somewhat
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inconsistent with human eye perception. The **structural similarity** algorithm aims to correct
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this.
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Describing the methods goes well beyond the purpose of this tutorial. For that I invite you to read
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the article introducing it. Nevertheless, you can get a good image of it by looking at the OpenCV
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implementation below.
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2020-03-21 08:25:49 +08:00
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@note
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SSIM is described more in-depth in the: "Z. Wang, A. C. Bovik, H. R. Sheikh and E. P.
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Simoncelli, "Image quality assessment: From error visibility to structural similarity," IEEE
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Transactions on Image Processing, vol. 13, no. 4, pp. 600-612, Apr. 2004." article.
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2020-02-22 19:42:26 +08:00
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@add_toggle_cpp
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2020-11-10 20:36:13 +08:00
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@snippet samples/cpp/tutorial_code/videoio/video-input-psnr-ssim/video-input-psnr-ssim.cpp get-mssim
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2020-02-22 19:42:26 +08:00
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@end_toggle
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2014-11-27 20:39:05 +08:00
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2020-02-22 19:42:26 +08:00
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@add_toggle_python
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2020-11-10 20:36:13 +08:00
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@snippet samples/python/tutorial_code/videoio/video-input-psnr-ssim.py get-mssim
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2020-02-22 19:42:26 +08:00
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@end_toggle
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2014-11-27 20:39:05 +08:00
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This will return a similarity index for each channel of the image. This value is between zero and
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one, where one corresponds to perfect fit. Unfortunately, the many Gaussian blurring is quite
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costly, so while the PSNR may work in a real time like environment (24 frame per second) this will
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take significantly more than to accomplish similar performance results.
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Therefore, the source code presented at the start of the tutorial will perform the PSNR measurement
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for each frame, and the SSIM only for the frames where the PSNR falls below an input value. For
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visualization purpose we show both images in an OpenCV window and print the PSNR and MSSIM values to
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the console. Expect to see something like:
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2014-11-28 21:21:28 +08:00
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![](images/outputVideoInput.png)
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2014-11-28 21:21:28 +08:00
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You may observe a runtime instance of this on the [YouTube here](https://www.youtube.com/watch?v=iOcNljutOgg).
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2017-10-17 18:40:16 +08:00
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@youtube{iOcNljutOgg}
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