RollPitchYawMatrix
RollPitchYawMatrix[{α,β,γ}]
gives the 3D rotation matrix formed by rotating by α around the initial axis, then by β around the initial axis, and then by γ around the initial axis.
RollPitchYawMatrix[{α,β,γ},{a,b,c}]
gives the 3D rotation matrix formed by rotating by α around the fixed a axis, then by β around the fixed b axis, and then by γ around the fixed c axis.
Details and Options
- RollPitchYawMatrix is also known as bank-elevation-heading matrix or Cardan matrix. The angles {α,β,γ} are often referred to as Cardan angles, Tait–Bryan angles, nautical angles, bank-elevation-heading, or roll-pitch-yaw.
- RollPitchYawMatrix is typically used to specify a rotation as a sequence of basic rotations around coordinate axes where each rotation is referring to the initial or extrinsic coordinate frame.
- RollPitchYawMatrix[{α,β,γ}] is equivalent to RollPitchYawMatrix[{α,β,γ},{3,2,1}].
- RollPitchYawMatrix[{α,β,γ},{a,b,c}] is equivalent to where Rα,a=RotationMatrix[α,UnitVector[3,a]] etc.
- The default z-y-x rotation RollPitchYawMatrix[{α,β,γ},{3,2,1}]:
- The rotation axes a, b, and c can be any integer 1, 2, or 3, but there are only twelve combinations that are general enough to be able to specify any 3D rotation.
- Rotations with the first and last axis repeated:
-
{3,2,3} z-y-z rotation {3,1,3} z-x-z rotation {2,3,2} y-z-y rotation {2,1,2} y-x-y rotation {1,3,1} x-z-x rotation {1,2,1} x-y-x rotation - Rotations with all three axes different:
-
{1,2,3} x-y-z rotation {1,3,2} x-z-y rotation {2,1,3} y-x-z rotation {2,3,1} y-z-x rotation {3,1,2} z-x-y rotation {3,2,1} z-y-x rotation (default) - Rotations with subsequent axes repeated still produce a rotation matrix, but cannot be inverted uniquely using RollPitchYawAngles.
- RollPitchYawMatrix supports the option TargetStructure, which specifies the structure of the returned matrix. Possible settings for TargetStructure include:
-
Automatic automatically choose the representation returned "Dense" represent the matrix as a dense matrix "Orthogonal" represent the matrix as an orthogonal matrix "Unitary" represent the matrix as a unitary matrix - RollPitchYawMatrix[…,TargetStructureAutomatic] is equivalent to RollPitchYawMatrix[…,TargetStructure"Dense"].
Examples
open allclose allScope (5)
Give the standard z-y-x roll-pitch-yaw rotation matrix with , , and :
Visualize the rotated vector (red):
Give an x-y-z roll-pitch-yaw rotation matrix by specifying the second argument:
Rotate and visualize the vector {1,0,0}:
Rotate primitives in 3D graphics using GeometricTransformation:
Rotate a region using TransformedRegion:
Rotate a 3D image using ImageTransformation:
Options (1)
Applications (6)
Illustrations (1)
Build a function that illustrates Euler rotations, showing the axis that is being rotated around:
Here are all six of the a-b-c axes rotations. First is the standard z-y-x roll-pitch-yaw rotation:
The x-y-z roll-pitch-yaw rotation:
The x-z-y roll-pitch-yaw rotation:
The y-x-z roll-pitch-yaw rotation:
The y-z-x roll-pitch-yaw rotation:
The z-x-y roll-pitch-yaw rotation:
Then there are the six a-b-a axes rotations. First is the x-y-x roll-pitch-yaw rotation:
The x-z-x roll-pitch-yaw rotation:
The y-x-y roll-pitch-yaw rotation:
The y-z-y roll-pitch-yaw rotation:
Gimbal (5)
A gimbal is a system of pivoted rings that allows an object to orient itself in an arbitrary direction. These are used in various navigations and imaging applications:
The orientation of the object within a gimbal can be modeled using RollPitchYawMatrix with the angles of the rings' rotations, from the outermost to the innermost rings. Note that an a-b-a axis system is used:
A gimbal with a-b-c axis rotations models a gimbal system with an initial state where all rings' axes are perpendicular to each other:
This uses the x-y-z roll-pitch-yaw rotation:
A rotation system may enter gimbal lock, a situation where a certain angle value reduces the system's degrees of freedom. The normal, non-locked case produces the following:
The vector {1,1,0} can be rotated to an arbitrary point on a surface:
In the locked case, only the difference can affect the rotation:
Now the vector {1,1,0} can only be rotated to a point on a curve:
When axes , gimbal lock will occur when . Here is an example x-y-x rotation:
The non-locked m1 and locked m2 cases:
Unlocked m1 and locked m2 cases for z-y-z rotation:
And when axes are all different , gimbal lock will occur when . Here, when doing an x-y-z rotation:
Properties & Relations (11)
RollPitchYawMatrix corresponds to three rotations:
With general ordering of rotation axes:
Use RollPitchYawAngles to return angles that produce the same rotation matrix:
The angles need not be the same:
However, both sets of angles produce the same rotation matrix:
RollPitchYawMatrix rotates wrt the global axes (fixed frame) in each step:
EulerMatrix rotates wrt the local axes (moving frame) in each step:
If two subsequent rotation axes are identical, i.e. or , the system has two degrees of freedom, such as here when performing an x-y-y rotation:
If all rotation axes are identical, i.e. , the system has only one degree of freedom, such as here when performing an x-x-x rotation:
RollPitchYawMatrix[{α,β,γ},{a,b,c}] is the same as EulerMatrix[{γ,β,α},{c,b,a}]:
RollPitchYawMatrix parametrizes any rotation in terms of three axis-oriented rotations:
For rotations around a general axis, use RotationMatrix:
RollPitchYawMatrix only applies in :
For general dimension, use RotationMatrix:
RollPitchYawMatrix is an orthogonal matrix with determinant 1:
The inverse of a RollPitchYawMatrix is its transpose:
The inverse of RollPitchYawMatrix[{α,β,γ},{a,b,c}] is RollPitchYawMatrix[{-γ,-β,-α},{c,b,a}]:
Possible Issues (1)
RollPitchYawMatrix allows equal consecutive axes, and this generates a rotation matrix:
However, RollPitchYawAngles requires consecutive axes to be distinct:
This is because with consecutive axes equal, some rotation matrices cannot be represented:
Neat Examples (2)
Use GeometricTransformation to visualize the rotation of a sphere by a range of angles:
Text
Wolfram Research (2015), RollPitchYawMatrix, Wolfram Language function, https://reference.wolfram.com/language/ref/RollPitchYawMatrix.html (updated 2024).
CMS
Wolfram Language. 2015. "RollPitchYawMatrix." Wolfram Language & System Documentation Center. Wolfram Research. Last Modified 2024. https://reference.wolfram.com/language/ref/RollPitchYawMatrix.html.
APA
Wolfram Language. (2015). RollPitchYawMatrix. Wolfram Language & System Documentation Center. Retrieved from https://reference.wolfram.com/language/ref/RollPitchYawMatrix.html