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| import numpy as np | |
| import pycolmap | |
| def to_homogeneous(p): | |
| return np.pad(p, ((0, 0),) * (p.ndim - 1) + ((0, 1),), constant_values=1) | |
| def vector_to_cross_product_matrix(v): | |
| return np.array([[0, -v[2], v[1]], [v[2], 0, -v[0]], [-v[1], v[0], 0]]) | |
| def compute_epipolar_errors(qvec_r2t, tvec_r2t, p2d_r, p2d_t): | |
| T_r2t = pose_matrix_from_qvec_tvec(qvec_r2t, tvec_r2t) | |
| # Compute errors in normalized plane to avoid distortion. | |
| E = vector_to_cross_product_matrix(T_r2t[:3, -1]) @ T_r2t[:3, :3] | |
| l2d_r2t = (E @ to_homogeneous(p2d_r).T).T | |
| l2d_t2r = (E.T @ to_homogeneous(p2d_t).T).T | |
| errors_r = np.abs( | |
| np.sum(to_homogeneous(p2d_r) * l2d_t2r, axis=1) | |
| ) / np.linalg.norm(l2d_t2r[:, :2], axis=1) | |
| errors_t = np.abs( | |
| np.sum(to_homogeneous(p2d_t) * l2d_r2t, axis=1) | |
| ) / np.linalg.norm(l2d_r2t[:, :2], axis=1) | |
| return E, errors_r, errors_t | |
| def pose_matrix_from_qvec_tvec(qvec, tvec): | |
| pose = np.zeros((4, 4)) | |
| pose[:3, :3] = pycolmap.qvec_to_rotmat(qvec) | |
| pose[:3, -1] = tvec | |
| pose[-1, -1] = 1 | |
| return pose | |