As part of my master thesis I am exploring Structure From Motion. After reading parts of the H&Z book, following online tutorials and reading through many SO posts I have some useful results, but I have also some problems. I'm using OpenCVSharp wrapper. All images are taken with the same camera.

What I have now:

First I calculate initial 3d points coordinates. I do this with these steps:

- Calculate Farneback's dense optical flow.
- Find the Fundamental matrix using Cv2.FindFundamentalMat with RANSAC
Get Essential matrix using camera intrinsics (at this point I use pre-determined intrinsics) and decompose it:

`Mat essential = camera_matrix.T() * fundamentalMatrix * camera_matrix; SVD decomp = new SVD(essential, OpenCvSharp.SVDFlag.ModifyA); Mat diag = new Mat(3, 3, MatType.CV_64FC1, new double[] { 1.0D, 0.0D, 0.0D, 0.0D, 1.0D, 0.0D, 0.0D, 0.0D, 0.0D }); Mat Er = decomp.U * diag * decomp.Vt; SVD svd = new SVD(Er, OpenCvSharp.SVDFlag.ModifyA); Mat W = new Mat(3, 3, MatType.CV_64FC1, new double[] { 0.0D, -1.0D, 0.0D, 1.0D, 0.0D, 0.0D, 0.0D, 0.0D, 1.0D }); Mat Winv = new Mat(3, 3, MatType.CV_64FC1, new double[] { 0.0D, 1.0D, 0.0D, -1.0D, 0.0D, 0.0D, 0.0D, 0.0D, 1.0D }); Mat R1 = svd.U * W * svd.Vt; Mat T1 = svd.U.Col[2]; Mat R2 = svd.U * Winv * svd.Vt; Mat T2 = -svd.U.Col[2]; Mat[] Ps = new Mat[4]; for (int i = 0; i < 4; i++) Ps[i] = new Mat(3, 4, MatType.CV_64FC1); Cv2.HConcat(R1, T1, Ps[0]); Cv2.HConcat(R1, T2, Ps[1]); Cv2.HConcat(R2, T1, Ps[2]); Cv2.HConcat(R2, T2, Ps[3]);`

Then I check which projection matrix has the most points in front of both cameras by triangulating the points and then multiplying them by projection matrices (I tried both Cv2.TriangulatePoints and H&Z version with similar results) and checking for positive Z values (after converting from homogenous values):

`P * point3D`

- At this point I should have more or less correct 3D points. The 3D visualization looks quite correct.

Then I calculate SolvePNP for every new frame by using again the dense optical flow and with the previous projection matrix known I calculate next 3D points and add them to the model. Again 3D visualization looks more or less correct (no bundle adjustment at this point).

Since I need to use SolvePNP for every new frame I started by checking it with the one calculated for the first 2 images with the fundamental matrix. Theoretically the projection matrix should be the same or almost the same as the one calculated with the initial algorithm - I use the initial 3D points and the corresponding 2D points in the second image. But it's not the same.

Here is the one calculated by decomposing the fundamental matrix:

```
0,955678480016302 -0,0278536127242155 0,293091827064387 -0,148461857222772
-0,0710609269521247 0,944258717203142 0,321443338158658 -0,166586733489084
0,285707870900394 0,328023857736121 -0,900428432059693 0,974786098164824
```

And here is the one I got from the SolvePnPRansac:

```
0,998124823499476 -0,0269266503551759 -0,0549708305812315 -0,0483615883381834
0,0522887223187244 0,8419572918112 0,537004476968512 -2,0699592377647
0,0318233598542908 -0,538871853288516 0,841786433426546 28,7686946357429
```

Both of them look like correct projection matrices, but they are different.

For those patient people who read the whole post I have 3 questions:

```
1. Why are these matrices different? I know the reconstruction is up to scale, but since I have an arbitrary scale assigned in the first place the SolvePNP should keep that scale.
2. I noticed one strange thing - the translation in the first matrix seems to be exactly the same no matter what images I use.
3. Is the overal algorithm correct, or am I doing something wrong? Do I miss some important step?
```

If more code is required let me know and I will edit the question.

Thank You!