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dist

Angular distance in radians

Since R2020b

Description

distance = dist(quatA,quatB) returns the angular distance in radians between two quaternions, quatA and quatB.

example

Examples

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Calculate the quaternion distance between a single quaternion and each element of a vector of quaternions. Define the quaternions using Euler angles.

q = quaternion([0,0,0],"eulerd","ZYX","frame")
q = quaternion
     1 + 0i + 0j + 0k

qArray = quaternion([0,45,0;0,90,0;0,180,0;0,-90,0;0,-45,0],"eulerd","ZYX","frame")
qArray = 5x1 quaternion array
       0.92388 +         0i +   0.38268j +         0k
       0.70711 +         0i +   0.70711j +         0k
    6.1232e-17 +         0i +         1j +         0k
       0.70711 +         0i -   0.70711j +         0k
       0.92388 +         0i -   0.38268j +         0k

quaternionDistance = rad2deg(dist(q,qArray))
quaternionDistance = 5×1

   45.0000
   90.0000
  180.0000
   90.0000
   45.0000

If both arguments to dist are vectors, the quaternion distance is calculated between corresponding elements. Calculate the quaternion distance between two quaternion vectors.

angles1 = [30,0,15; ...
           30,5,15; ...
           30,10,15; ...
           30,15,15];
angles2 = [30,6,15; ...
           31,11,15; ...
           30,16,14; ...
           30.5,21,15.5];

qVector1 = quaternion(angles1,"eulerd","ZYX","frame");
qVector2 = quaternion(angles2,"eulerd","ZYX","frame");

rad2deg(dist(qVector1,qVector2))
ans = 4×1

    6.0000
    6.0827
    6.0827
    6.0287

Note that a quaternion represents the same rotation as its negative. Calculate a quaternion and its negative.

qPositive = quaternion([30,45,-60],"eulerd","ZYX","frame")
qPositive = quaternion
     0.72332 - 0.53198i + 0.20056j +  0.3919k

qNegative = -qPositive
qNegative = quaternion
    -0.72332 + 0.53198i - 0.20056j -  0.3919k

Find the distance between the quaternion and its negative.

dist(qPositive,qNegative)
ans = 
0

The components of a quaternion may look different from the components of its negative, but both expressions represent the same rotation.

Input Arguments

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Quaternions to calculate distance between, specified as comma-separated quaternion objects or arrays of quaternion objects of any dimensionality. quatA and quatB must have compatible sizes:

  • size(quatA) == size(quatB), or

  • numel(quatA) == 1, or

  • numel(quatB) == 1, or

  • if [Adim1,…,AdimN] = size(quatA) and [Bdim1,…,BdimN] = size(quatB), then for i = 1:N, either Adimi==Bdimi or Adim==1 or Bdim==1.

    If one of the quaternion arguments contains only one quaternion, then this function returns the distances between that quaternion and every quaternion in the other argument.

Output Arguments

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Angular distance in radians, returned as a numeric scalar or numeric array. The dimensions are the maximum of the union of size(quatA) and size(quatB).

Data Types: single | double

Algorithms

The dist function returns the angular distance between two quaternions.

A quaternion may be defined by an axis (ub,uc,ud) and angle of rotation θq: q=cos(θq2)+sin(θq2)(ubi+ucj+udk).

Angle Rotation

Given a quaternion in the form, q=a+bi+cj+dk, where a is the real part, you can solve for the angle of q as θq=2cos1(a).

Consider two quaternions, p and q, and the product z=p*conjugate(q). As p approaches q, the angle of z goes to 0, and z approaches the unit quaternion.

The angular distance between two quaternions can be expressed as θz=2cos1(real(z)).

Using the quaternion data type syntax, the angular distance is calculated as:

angularDistance = 2*acos(abs(parts(p*conj(q))));

Extended Capabilities

C/C++ Code Generation
Generate C and C++ code using MATLAB® Coder™.

Version History

Introduced in R2020b

See Also

Functions

Objects