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 26: | Line 26: | ||
* | * | ||
* The example code does the following: | * 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>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 | * <li>Undistort and rectify images. This provides one rectification matrix for each image along with a new | ||
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* <li>The original rectification does not try to maximize view area, however it can be adjusted.</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> | * <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 | * Note that the y-axis in left and right images align after rectification. You can click in the images to draw a line | ||
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// 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()); | 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()); | RectifyDistortImageOps.rectifyImage(param.getRight(), rect2_F32, BorderType.SKIP, distRight.getImageType()); | ||
| Line 99: | Line 99: | ||
// 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"); | ||
Latest revision as of 19:31, 8 October 2021
Before rectification features are not aligned along the y-axis.
After rectification feature are aligned, as can easily be seen with the red line.
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);
}
}
