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Rotation Representations

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true of all parameterizations other than trivial SO(3) Rotation ... Yaw-Pitch-Roll ... For Yaw-Pitch-Roll Convention. Rotation Axis Angle. Euler's ... – PowerPoint PPT presentation

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Title: Rotation Representations


1
Rotation Representations
2
Rotations Differ from Translations
  • Rotations are non-Euclidean
  • like travelling on a globe vs. a grid
  • Rotations are not commutative
  • x-rotate, y-rotate is not equal y-rotate,
    x-rotate etc.
  • Rotations are non-linear
  • true of all parameterizations other than trivial
    SO(3)

3
Rotation Parameterization
  • Represent rotation space in Euclidean R3
  • e.g. Euler angles, exponential map
  • Pros
  • three parameters for three DOFs
  • Cons
  • singularities, potentially poor interpolation

4
Rotation Parameterization
  • non-Euclidean space
  • e.g. unit quaternions (S3)
  • Pros
  • singularity free
  • Cons
  • must take extra measures to stay in legal
    sub-space
  • four parameters required for three DOFs

5
Euler angles (f,?,?)
  • An Euler angle is a rotation about a single
    Cartesian axis
  • Create multi-DOF rotations by concatenating
    Eulers
  • R R? R? Rf
  • 3 DOFs can be obtained by
    concatenating

Euler-X
Euler-Y
Euler-Z
6
X-Convention
  • Most commonly used
  • The rotation given by Euler angles (f,?,?), where
    the first rotation is by an angle f about the
    z-axis, the second is by an angle ? about the
    x-axis, and the third is by an angle ? about the
    z-axis (again).
  • R R? R? Rf

7
Yaw-Pitch-Roll Convention
8
Singularities
  • More than one sets of parameters can create the
    same rotation matrix.
  • Gimbal lock - two or more axes align, results in
    loss of rotational DOFs
  • For Yaw-Pitch-Roll Convention

9
Rotation Axis Angle
  • Eulers Rotation Theorem
  • all rotations can be expressed as axis/angle

10
Quaternions
  • Traditional solution Use unit quaternions to
    represent rotations
  • S3 has same topology as rotation space (a
    sphere), so no singularities
  • A member of unit sphere in R4
  • q(qx,qy,qz,qw)
  • a rotation about unit axis v
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