Difference between revisions of "Example Rectification Calibrated"
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Stereo rectification is the process of distorting an image such that the epipoles of both images are at infinity. If the epipoles are at infinity along the x-axis, then corresponding features must lie along the same y-coordinates. Using knowledge that correspondence feature's have the same y-coordinate allows for quick searches. Many stereo vision algorithm rely on rectification. The example below demonstrates rectification for a calibrated stereo pair. Note that after calibration the new camera view has a different set of intrinsic parameters. | Stereo rectification is the process of distorting an image such that the epipoles of both images are at infinity. If the epipoles are at infinity along the x-axis, then corresponding features must lie along the same y-coordinates. Using knowledge that correspondence feature's have the same y-coordinate allows for quick searches. Many stereo vision algorithm rely on rectification. The example below demonstrates rectification for a calibrated stereo pair. Note that after calibration the new camera view has a different set of intrinsic parameters. | ||
Example File: [https://github.com/lessthanoptimal/BoofCV/blob/v0. | Example File: [https://github.com/lessthanoptimal/BoofCV/blob/v0.39/examples/src/main/java/boofcv/examples/stereo/ExampleRectifyCalibratedStereo.java ExampleRectifyCalibratedStereo.java] | ||
Concepts: | Concepts: | ||
Line 21: | Line 21: | ||
<syntaxhighlight lang="java"> | <syntaxhighlight lang="java"> | ||
/** | /** | ||
* Shows how to rectify a pair of stereo images with known intrinsic parameters and stereo baseline. When you | |||
* Shows how to rectify a pair of stereo images with known intrinsic parameters and stereo baseline. | * rectify a stereo pair you are applying a transform that removes lens distortion and "rotates" the views | ||
* | * such that they are parallel to each other, facilitating stereo processing. | ||
* | |||
* | * | ||
* < | * The example code does the following: | ||
* Note that the y-axis in left and right images align after rectification. The curved image | * <ol> | ||
* <li>Load stereo extrinsic and intrinsic parameters from a file along with a pair of images.</li> | |||
* <li>Undistort and rectify images. This provides one rectification matrix for each image along with a new | |||
* camera calibration matrix.</li> | |||
* <li>The original rectification does not try to maximize view area, however it can be adjusted.</li> | |||
* <li>After rectification is finished the results are displayed.</li> | |||
* </ol> | |||
* | |||
* Note that the y-axis in left and right images align after rectification. You can click in the images to draw a line | |||
* that makes this easy to see. The curved image birder is an artifact of lens distortion being removed. | |||
* | * | ||
* @author Peter Abeles | * @author Peter Abeles | ||
*/ | */ | ||
public class ExampleRectifyCalibratedStereo { | public class ExampleRectifyCalibratedStereo { | ||
public static void main( String[] args ) { | |||
public static void main( String | |||
String dir = UtilIO.pathExample("calibration/stereo/Bumblebee2_Chess/"); | String dir = UtilIO.pathExample("calibration/stereo/Bumblebee2_Chess/"); | ||
StereoParameters param = CalibrationIO.load(new File(dir , "stereo.yaml")); | StereoParameters param = CalibrationIO.load(new File(dir, "stereo.yaml")); | ||
// load images | // load images | ||
BufferedImage origLeft = UtilImageIO.loadImage(dir,"left05.jpg"); | BufferedImage origLeft = UtilImageIO.loadImage(dir, "left05.jpg"); | ||
BufferedImage origRight = UtilImageIO.loadImage(dir,"right05.jpg"); | BufferedImage origRight = UtilImageIO.loadImage(dir, "right05.jpg"); | ||
// distorted images | // distorted images | ||
Planar<GrayF32> distLeft = | Planar<GrayF32> distLeft = | ||
ConvertBufferedImage.convertFromPlanar(origLeft, null,true, GrayF32.class); | ConvertBufferedImage.convertFromPlanar(origLeft, null, true, GrayF32.class); | ||
Planar<GrayF32> distRight = | Planar<GrayF32> distRight = | ||
ConvertBufferedImage.convertFromPlanar(origRight, null,true, GrayF32.class); | ConvertBufferedImage.convertFromPlanar(origRight, null, true, GrayF32.class); | ||
// storage for undistorted + rectified images | // storage for undistorted + rectified images | ||
Line 67: | Line 67: | ||
DMatrixRMaj K2 = PerspectiveOps.pinholeToMatrix(param.getRight(), (DMatrixRMaj)null); | DMatrixRMaj K2 = PerspectiveOps.pinholeToMatrix(param.getRight(), (DMatrixRMaj)null); | ||
rectifyAlg.process(K1,new Se3_F64(),K2,leftToRight); | rectifyAlg.process(K1, new Se3_F64(), K2, leftToRight); | ||
// rectification matrix for each image | // rectification matrix for each image | ||
DMatrixRMaj rect1 = rectifyAlg. | DMatrixRMaj rect1 = rectifyAlg.getUndistToRectPixels1(); | ||
DMatrixRMaj rect2 = rectifyAlg. | DMatrixRMaj rect2 = rectifyAlg.getUndistToRectPixels2(); | ||
// New calibration matrix, | // New calibration matrix, | ||
// Both cameras have the same one after rectification. | // Both cameras have the same one after rectification. | ||
Line 81: | Line 81: | ||
// undistorted and rectify images | // undistorted and rectify images | ||
var rect1_F32 = new FMatrixRMaj(3, 3); // TODO simplify code some how | |||
var rect2_F32 = new FMatrixRMaj(3, 3); | |||
ConvertMatrixData.convert(rect1, rect1_F32); | ConvertMatrixData.convert(rect1, rect1_F32); | ||
ConvertMatrixData.convert(rect2, rect2_F32); | ConvertMatrixData.convert(rect2, rect2_F32); | ||
ImageDistort rectifyImageLeft = | ImageDistort<Planar<GrayF32>, Planar<GrayF32>> rectifyImageLeft = | ||
RectifyDistortImageOps.rectifyImage(param.getLeft(), rect1_F32, BorderType.SKIP, distLeft.getImageType()); | |||
ImageDistort rectifyImageRight = | ImageDistort<Planar<GrayF32>, Planar<GrayF32>> rectifyImageRight = | ||
RectifyDistortImageOps.rectifyImage(param.getRight(), rect2_F32, BorderType.SKIP, distRight.getImageType()); | |||
rectifyImageLeft.apply(distLeft,rectLeft); | rectifyImageLeft.apply(distLeft, rectLeft); | ||
rectifyImageRight.apply(distRight,rectRight); | rectifyImageRight.apply(distRight, rectRight); | ||
// convert for output | // convert for output | ||
BufferedImage outLeft = ConvertBufferedImage.convertTo(rectLeft,null,true); | BufferedImage outLeft = ConvertBufferedImage.convertTo(rectLeft, null, true); | ||
BufferedImage outRight = ConvertBufferedImage.convertTo(rectRight, null,true); | BufferedImage outRight = ConvertBufferedImage.convertTo(rectRight, null, true); | ||
// show results and draw a horizontal line where the user clicks to see rectification easier | // show results and draw a horizontal line where the user clicks to see rectification easier | ||
var panel = new ListDisplayPanel(); | |||
panel.addItem(new RectifiedPairPanel(true, origLeft, origRight), "Original"); | panel.addItem(new RectifiedPairPanel(true, origLeft, origRight), "Original"); | ||
panel.addItem(new RectifiedPairPanel(true, outLeft, outRight), "Rectified"); | panel.addItem(new RectifiedPairPanel(true, outLeft, outRight), "Rectified"); | ||
ShowImages.showWindow(panel,"Stereo Rectification Calibrated",true); | ShowImages.showWindow(panel, "Stereo Rectification Calibrated", true); | ||
} | } | ||
} | } | ||
</syntaxhighlight> | </syntaxhighlight> |
Latest revision as of 19:31, 8 October 2021
Stereo rectification is the process of distorting an image such that the epipoles of both images are at infinity. If the epipoles are at infinity along the x-axis, then corresponding features must lie along the same y-coordinates. Using knowledge that correspondence feature's have the same y-coordinate allows for quick searches. Many stereo vision algorithm rely on rectification. The example below demonstrates rectification for a calibrated stereo pair. Note that after calibration the new camera view has a different set of intrinsic parameters.
Example File: ExampleRectifyCalibratedStereo.java
Concepts:
- Stereo Rectification
- Stereo Vision
Related Examples:
Example Code
/**
* Shows how to rectify a pair of stereo images with known intrinsic parameters and stereo baseline. When you
* rectify a stereo pair you are applying a transform that removes lens distortion and "rotates" the views
* such that they are parallel to each other, facilitating stereo processing.
*
* The example code does the following:
* <ol>
* <li>Load stereo extrinsic and intrinsic parameters from a file along with a pair of images.</li>
* <li>Undistort and rectify images. This provides one rectification matrix for each image along with a new
* camera calibration matrix.</li>
* <li>The original rectification does not try to maximize view area, however it can be adjusted.</li>
* <li>After rectification is finished the results are displayed.</li>
* </ol>
*
* Note that the y-axis in left and right images align after rectification. You can click in the images to draw a line
* that makes this easy to see. The curved image birder is an artifact of lens distortion being removed.
*
* @author Peter Abeles
*/
public class ExampleRectifyCalibratedStereo {
public static void main( String[] args ) {
String dir = UtilIO.pathExample("calibration/stereo/Bumblebee2_Chess/");
StereoParameters param = CalibrationIO.load(new File(dir, "stereo.yaml"));
// load images
BufferedImage origLeft = UtilImageIO.loadImage(dir, "left05.jpg");
BufferedImage origRight = UtilImageIO.loadImage(dir, "right05.jpg");
// distorted images
Planar<GrayF32> distLeft =
ConvertBufferedImage.convertFromPlanar(origLeft, null, true, GrayF32.class);
Planar<GrayF32> distRight =
ConvertBufferedImage.convertFromPlanar(origRight, null, true, GrayF32.class);
// storage for undistorted + rectified images
Planar<GrayF32> rectLeft = distLeft.createSameShape();
Planar<GrayF32> rectRight = distRight.createSameShape();
// Compute rectification
RectifyCalibrated rectifyAlg = RectifyImageOps.createCalibrated();
Se3_F64 leftToRight = param.getRightToLeft().invert(null);
// original camera calibration matrices
DMatrixRMaj K1 = PerspectiveOps.pinholeToMatrix(param.getLeft(), (DMatrixRMaj)null);
DMatrixRMaj K2 = PerspectiveOps.pinholeToMatrix(param.getRight(), (DMatrixRMaj)null);
rectifyAlg.process(K1, new Se3_F64(), K2, leftToRight);
// rectification matrix for each image
DMatrixRMaj rect1 = rectifyAlg.getUndistToRectPixels1();
DMatrixRMaj rect2 = rectifyAlg.getUndistToRectPixels2();
// New calibration matrix,
// Both cameras have the same one after rectification.
DMatrixRMaj rectK = rectifyAlg.getCalibrationMatrix();
// Adjust the rectification to make the view area more useful
RectifyImageOps.fullViewLeft(param.left, rect1, rect2, rectK, null);
// RectifyImageOps.allInsideLeft(param.left, rect1, rect2, rectK, null);
// undistorted and rectify images
var rect1_F32 = new FMatrixRMaj(3, 3); // TODO simplify code some how
var rect2_F32 = new FMatrixRMaj(3, 3);
ConvertMatrixData.convert(rect1, rect1_F32);
ConvertMatrixData.convert(rect2, rect2_F32);
ImageDistort<Planar<GrayF32>, Planar<GrayF32>> rectifyImageLeft =
RectifyDistortImageOps.rectifyImage(param.getLeft(), rect1_F32, BorderType.SKIP, distLeft.getImageType());
ImageDistort<Planar<GrayF32>, Planar<GrayF32>> rectifyImageRight =
RectifyDistortImageOps.rectifyImage(param.getRight(), rect2_F32, BorderType.SKIP, distRight.getImageType());
rectifyImageLeft.apply(distLeft, rectLeft);
rectifyImageRight.apply(distRight, rectRight);
// convert for output
BufferedImage outLeft = ConvertBufferedImage.convertTo(rectLeft, null, true);
BufferedImage outRight = ConvertBufferedImage.convertTo(rectRight, null, true);
// show results and draw a horizontal line where the user clicks to see rectification easier
var panel = new ListDisplayPanel();
panel.addItem(new RectifiedPairPanel(true, origLeft, origRight), "Original");
panel.addItem(new RectifiedPairPanel(true, outLeft, outRight), "Rectified");
ShowImages.showWindow(panel, "Stereo Rectification Calibrated", true);
}
}