arskrald/AR-3/Assets/homo_inv.cs

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2019-03-04 17:07:53 +00:00
using OpenCVForUnity.CoreModule;
using OpenCVForUnity.ImgprocModule;
using OpenCVForUnity.ObjdetectModule;
using OpenCVForUnity.UnityUtils;
using OpenCVForUnity.UtilsModule;
using UnityEngine;
using OpenCVForUnity.Calib3dModule;
using System.Linq;
using Vuforia;
public class homo_inv : MonoBehaviour
{
public Camera cam;
public GameObject corner1;
public GameObject corner2;
public GameObject corner3;
public GameObject corner4;
//Default values: guessed, not calibrated
public float fx = 650;
public float fy = 650;
public float cx = 320;
public float cy = 240;
private int width = 1024;
private int height = 1024;
private MatOfPoint2f dstPoints;
private Texture2D outputTexture;
private Mat camImageMat;
private GameObject pls;
private Renderer rend;
private bool manualComputation = false;
private Mat skullTextureMat;
void Start()
{
skullTextureMat = MatDisplay.LoadRGBATexture("Resources/flying_skull_tex.png");
dstPoints = new MatOfPoint2f();
dstPoints.alloc(4);
/*dstPoints.put(0, 0, 0, height);
dstPoints.put(1, 0, width, height);
dstPoints.put(3, 0, width, 0);
dstPoints.put(2, 0, 0, 0);*/
dstPoints.put(2, 0, 0, height);
dstPoints.put(3, 0, width, height);
dstPoints.put(0, 0, 0, 0);
dstPoints.put(1, 0, width, 0);
outputTexture = new Texture2D(width, height, TextureFormat.RGBA32, false);
// Debugging
pls = GameObject.Find("pls");
rend = pls.GetComponent<Renderer>();
}
void Update()
{
//Access camera image provided by Vuforia
Image camImg = CameraDevice.Instance.GetCameraImage(Image.PIXEL_FORMAT.RGBA8888);
if (camImg != null)
{
if (camImg != null)
{
if (camImageMat == null)
{
camImageMat = new Mat(camImg.Height, camImg.Width, CvType.CV_8UC4);
}
camImageMat.put(0, 0, camImg.Pixels);
}
//---- TRANSFORM/PROJECT CORNER WORLD COORDINATES TO IMAGE COORDINATES ----
Vector3 worldPnt1 = corner1.transform.position;
Vector3 worldPnt2 = corner2.transform.position;
Vector3 worldPnt3 = corner3.transform.position;
Vector3 worldPnt4 = corner4.transform.position;
//See lecture slides
Matrix4x4 Rt = cam.transform.worldToLocalMatrix;
Matrix4x4 A = Matrix4x4.identity;
A.m00 = fx;
A.m11 = fy;
A.m02 = cx;
A.m12 = cy;
//See equation for pinhole camera model
Matrix4x4 worldToImage = A * Rt;
//Apply transform to get homogeneous image coordinates
Vector3 hUV1 = worldToImage.MultiplyPoint3x4(worldPnt1);
Vector3 hUV2 = worldToImage.MultiplyPoint3x4(worldPnt2);
Vector3 hUV3 = worldToImage.MultiplyPoint3x4(worldPnt3);
Vector3 hUV4 = worldToImage.MultiplyPoint3x4(worldPnt4);
//hUV are the image coordinates in homogeneous coordinates, we need to normalize, i.e., divide by Z to get to Cartesian coordinates
Vector2 uv1 = new Vector2(hUV1.x, hUV1.y) / hUV1.z;
Vector2 uv2 = new Vector2(hUV2.x, hUV2.y) / hUV2.z;
Vector2 uv3 = new Vector2(hUV3.x, hUV3.y) / hUV3.z;
Vector2 uv4 = new Vector2(hUV4.x, hUV4.y) / hUV4.z;
//Do not forget to alloc before putting values into a MatOfPoint2f (see Start() above)
//We need to flip the v-coordinates, see coordinate system overview
float maxV = camImg.Height - 1;
MatOfPoint2f imagePoints = new MatOfPoint2f();
imagePoints.alloc(4);
imagePoints.put(0, 0, uv1.x, maxV - uv1.y);
imagePoints.put(1, 0, uv2.x, maxV - uv2.y);
imagePoints.put(2, 0, uv3.x, maxV - uv3.y);
imagePoints.put(3, 0, uv4.x, maxV - uv4.y);
//Debug draw points using OpenCV's drawing functions
Point imgPnt1 = new Point(imagePoints.get(0, 0));
Point imgPnt2 = new Point(imagePoints.get(1, 0));
Point imgPnt3 = new Point(imagePoints.get(2, 0));
Point imgPnt4 = new Point(imagePoints.get(3, 0));
Mat camImgCopy = camImageMat.clone();
Mat outputMat = camImgCopy.clone();
if (true)
{
Imgproc.circle(camImageMat, imgPnt1, 5, new Scalar(255, 0, 0, 255));
Imgproc.circle(camImageMat, imgPnt2, 5, new Scalar(0, 255, 0, 255));
Imgproc.circle(camImageMat, imgPnt3, 5, new Scalar(0, 0, 255, 255));
Imgproc.circle(camImageMat, imgPnt4, 5, new Scalar(255, 255, 0, 255));
}
Mat homo = new Mat();
if (manualComputation)
{
homo = ComputeHomo(imagePoints, dstPoints);
}
else
{
homo = Calib3d.findHomography(imagePoints, dstPoints);
}
Mat outputSkullMat = camImgCopy.clone();
//Mat outputSkullMat = skullTextureMat.clone();
Imgproc.warpPerspective(skullTextureMat, outputSkullMat, homo.inv(), outputSkullMat.size());
var rectOutputMat = new Mat(outputMat, new OpenCVForUnity.CoreModule.Rect(0, 0, width, height));
Mat dstCam = camImageMat.clone();
Core.addWeighted(rectOutputMat, 0.95f, outputSkullMat, 0.7f, 0.0f, dstCam);
//Display the Mat that includes video feed and debug points
MatDisplay.DisplayMat(dstCam, MatDisplaySettings.FULL_BACKGROUND);
//rend.sharedMaterial.mainTexture = outputTexture;
// Makes camera prettier
//cam.fieldOfView = 2 * Mathf.Atan(camImg.Height * 0.5f / fy) * Mathf.Rad2Deg;
imagePoints.Dispose();
}
}
Mat ComputeHomo(MatOfPoint2f imgPoints, MatOfPoint2f destPoints)
{
Mat H = new Mat(8, 1, CvType.CV_32FC1);
Mat A = new Mat(8, 8, CvType.CV_32FC1);
Mat b = new Mat(8, 1, CvType.CV_32FC1);
for (int i = 0; i < 4; i++)
{
var u = destPoints.get(i, 0)[0];
var v = destPoints.get(i, 0)[1];
b.put(i * 2, 0, u);
b.put((i * 2)+1, 0, v);
var x = imgPoints.get(i, 0)[0];
var y = imgPoints.get(i, 0)[1];
A.put(i*2, 0, x, y, 1, 0, 0, 0, -u*x, -u*y);
A.put((i * 2)+1, 0, 0, 0, 0, x, y, 1, -v*x, -v*y);
}
Core.solve(A, b, H);
Mat ShitsReal = new Mat(3, 3, CvType.CV_32FC1);
ShitsReal.put(0, 0, H.get(0,0)[0], H.get(1,0)[0], H.get(2,0)[0]);
ShitsReal.put(1, 0, H.get(3,0)[0], H.get(4,0)[0], H.get(5,0)[0]);
ShitsReal.put(2, 0, H.get(6,0)[0], H.get(7,0)[0], 1);
return ShitsReal;
}
}