quaternion2rotation: Convert Quaternion into a Rotation Matrix
In neuroconductor-releases/oro.nifti: Rigorous - 'NIfTI' + 'ANALYZE' + 'AFNI' : Input / Output
Description
Usage
Arguments
Details
Value
Author(s)
References
Examples
Description
The affine/rotation matrix R is calculated from the quaternion
parameters.
Usage
1
2
3
quaternion2rotation(b, c, d, tol = 1e-07)
quaternion2mat44(nim, tol = 1e-07)
Arguments
b
is the quaternion b parameter.
c
is the quaternion c parameter.
d
is the quaternion d parameter.
tol
is a very small value used to judge if a number is essentially
zero.
nim
is an object of class nifti.
Details
The quaternion representation is chosen for its compactness in representing
rotations. The orientation of the (x,y,z) axes relative to the
(i,j,k) axes in 3D space is specified using a unit quaternion
[a,b,c,d], where a*a+b*b+c*c+d*d=1. The
(b,c,d) values are all that is needed, since we require that
a=sqrt(1.0-(b*b+c*c+d*d)) be non-negative.
The (b,c,d) values are stored in the (quatern_b,
quatern_c, quatern_d) fields.
Value
The (proper) 3x3 rotation matrix or
4x4 affine matrix.
Author(s)
Brandon Whitcher bwhitcher@gmail.com
References
NIfTI-1
http://nifti.nimh.nih.gov/
Examples
1
2
3
## This R matrix is represented by quaternion [a,b,c,d] = [0,1,0,0]
## (which encodes a 180 degree rotation about the x-axis).
(R <- quaternion2rotation(1, 0, 0))
neuroconductor-releases/oro.nifti documentation built on Jan. 1, 2021, 11:40 a.m.
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Description Usage Arguments Details Value Author(s) References Examples
Description
The affine/rotation matrix R is calculated from the quaternion parameters.
Usage
1 2 3 | quaternion2rotation(b, c, d, tol = 1e-07)
quaternion2mat44(nim, tol = 1e-07)
|
Arguments
b |
is the quaternion b parameter. |
c |
is the quaternion c parameter. |
d |
is the quaternion d parameter. |
tol |
is a very small value used to judge if a number is essentially zero. |
nim |
is an object of class |
Details
The quaternion representation is chosen for its compactness in representing
rotations. The orientation of the (x,y,z) axes relative to the
(i,j,k) axes in 3D space is specified using a unit quaternion
[a,b,c,d], where a*a+b*b+c*c+d*d=1. The
(b,c,d) values are all that is needed, since we require that
a=sqrt(1.0-(b*b+c*c+d*d)) be non-negative.
The (b,c,d) values are stored in the (quatern_b,
quatern_c, quatern_d) fields.
Value
The (proper) 3x3 rotation matrix or 4x4 affine matrix.
Author(s)
Brandon Whitcher bwhitcher@gmail.com
References
NIfTI-1
http://nifti.nimh.nih.gov/
Examples
1 2 3 | ## This R matrix is represented by quaternion [a,b,c,d] = [0,1,0,0]
## (which encodes a 180 degree rotation about the x-axis).
(R <- quaternion2rotation(1, 0, 0))
|
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