Spaces:
Running
on
Zero
Running
on
Zero
| import torch | |
| def quaternion_raw_multiply(a: torch.Tensor, b: torch.Tensor) -> torch.Tensor: | |
| """ | |
| From Pytorch3d | |
| Multiply two quaternions. | |
| Usual torch rules for broadcasting apply. | |
| Args: | |
| a: Quaternions as tensor of shape (..., 4), real part first. | |
| b: Quaternions as tensor of shape (..., 4), real part first. | |
| Returns: | |
| The product of a and b, a tensor of quaternions shape (..., 4). | |
| """ | |
| aw, ax, ay, az = torch.unbind(a, -1) | |
| bw, bx, by, bz = torch.unbind(b, -1) | |
| ow = aw * bw - ax * bx - ay * by - az * bz | |
| ox = aw * bx + ax * bw + ay * bz - az * by | |
| oy = aw * by - ax * bz + ay * bw + az * bx | |
| oz = aw * bz + ax * by - ay * bx + az * bw | |
| return torch.stack((ow, ox, oy, oz), -1) | |
| # Written by Stan Szymanowicz 2023 | |
| def matrix_to_quaternion(M: torch.Tensor) -> torch.Tensor: | |
| """ | |
| Matrix-to-quaternion conversion method. Equation taken from | |
| https://www.euclideanspace.com/maths/geometry/rotations/conversions/matrixToQuaternion/index.htm | |
| Args: | |
| M: rotation matrices, (3 x 3) | |
| Returns: | |
| q: quaternion of shape (4) | |
| """ | |
| tr = 1 + M[ 0, 0] + M[ 1, 1] + M[ 2, 2] | |
| if tr > 0: | |
| r = torch.sqrt(tr) / 2.0 | |
| x = ( M[ 2, 1] - M[ 1, 2] ) / ( 4 * r ) | |
| y = ( M[ 0, 2] - M[ 2, 0] ) / ( 4 * r ) | |
| z = ( M[ 1, 0] - M[ 0, 1] ) / ( 4 * r ) | |
| elif ( M[ 0, 0] > M[ 1, 1]) and (M[ 0, 0] > M[ 2, 2]): | |
| S = torch.sqrt(1.0 + M[ 0, 0] - M[ 1, 1] - M[ 2, 2]) * 2 # S=4*qx | |
| r = (M[ 2, 1] - M[ 1, 2]) / S | |
| x = 0.25 * S | |
| y = (M[ 0, 1] + M[ 1, 0]) / S | |
| z = (M[ 0, 2] + M[ 2, 0]) / S | |
| elif M[ 1, 1] > M[ 2, 2]: | |
| S = torch.sqrt(1.0 + M[ 1, 1] - M[ 0, 0] - M[ 2, 2]) * 2 # S=4*qy | |
| r = (M[ 0, 2] - M[ 2, 0]) / S | |
| x = (M[ 0, 1] + M[ 1, 0]) / S | |
| y = 0.25 * S | |
| z = (M[ 1, 2] + M[ 2, 1]) / S | |
| else: | |
| S = torch.sqrt(1.0 + M[ 2, 2] - M[ 0, 0] - M[ 1, 1]) * 2 # S=4*qz | |
| r = (M[ 1, 0] - M[ 0, 1]) / S | |
| x = (M[ 0, 2] + M[ 2, 0]) / S | |
| y = (M[ 1, 2] + M[ 2, 1]) / S | |
| z = 0.25 * S | |
| return torch.stack([r, x, y, z], dim=-1) |