Euler–Rodrigues formula

In mathematics and mechanics, the Euler–Rodrigues formula describes the rotation of a vector in three dimensions. It is based on Rodrigues' rotation formula, but uses a different parametrization.

The rotation is described by four Euler parameters due to Leonhard Euler. The Rodrigues' rotation formula (named after Olinde Rodrigues), a method of calculating the position of a rotated point, is used in some software applications, such as flight simulators and computer games.

Definition

A rotation about the origin is represented by four real numbers, a, b, c, d such that

${\displaystyle a^{2}+b^{2}+c^{2}+d^{2}=1.}$

When the rotation is applied, a point at position x→ rotates to its new position,^[1]

${\displaystyle {\vec {x}}'={\begin{pmatrix}a^{2}+b^{2}-c^{2}-d^{2}&2(bc-ad)&2(bd+ac)\\2(bc+ad)&a^{2}+c^{2}-b^{2}-d^{2}&2(cd-ab)\\2(bd-ac)&2(cd+ab)&a^{2}+d^{2}-b^{2}-c^{2}\end{pmatrix}}{\vec {x}}.}$

Vector formulation

The parameter a may be called the scalar parameter and ω→ = (b, c, d) the vector parameter. In standard vector notation, the Rodrigues rotation formula takes the compact form^{[citation needed]}

${\displaystyle {\vec {x}}'={\vec {x}}+2a({\vec {\omega }}\times {\vec {x}})+2\left({\vec {\omega }}\times ({\vec {\omega }}\times {\vec {x}})\right)}$

Symmetry

The parameters (a, b, c, d) and (−a, −b, −c, −d) describe the same rotation. Apart from this symmetry, every set of four parameters describes a unique rotation in three-dimensional space.

Composition of rotations

The composition of two rotations is itself a rotation. Let (a₁, b₁, c₁, d₁) and (a₂, b₂, c₂, d₂) be the Euler parameters of two rotations. The parameters for the compound rotation (rotation 2 after rotation 1) are as follows:

${\displaystyle {\begin{aligned}a&=a_{1}a_{2}-b_{1}b_{2}-c_{1}c_{2}-d_{1}d_{2};\\b&=a_{1}b_{2}+b_{1}a_{2}-c_{1}d_{2}+d_{1}c_{2};\\c&=a_{1}c_{2}+c_{1}a_{2}-d_{1}b_{2}+b_{1}d_{2};\\d&=a_{1}d_{2}+d_{1}a_{2}-b_{1}c_{2}+c_{1}b_{2}.\end{aligned}}}$

It is straightforward, though tedious, to check that a² + b² + c² + d² = 1. (This is essentially Euler's four-square identity.)

Rotation angle and rotation axis

Any central rotation in three dimensions is uniquely determined by its axis of rotation (represented by a unit vector k→ = (k_x, k_y, k_z)) and the rotation angle φ. The Euler parameters for this rotation are calculated as follows:

${\displaystyle {\begin{aligned}a&=\cos {\frac {\varphi }{2}};\\b&=k_{x}\sin {\frac {\varphi }{2}};\\c&=k_{y}\sin {\frac {\varphi }{2}};\\d&=k_{z}\sin {\frac {\varphi }{2}}.\end{aligned}}}$

Note that if φ is increased by a full rotation of 360 degrees, the arguments of sine and cosine only increase by 180 degrees. The resulting parameters are the opposite of the original values, (−a, −b, −c, −d); they represent the same rotation.

In particular, the identity transformation (null rotation, φ = 0) corresponds to parameter values (a, b, c, d) = (±1, 0, 0, 0). Rotations of 180 degrees about any axis result in a = 0.

Connection with quaternions

The Euler parameters can be viewed as the coefficients of a quaternion; the scalar parameter a is the real part, the vector parameters b, c, d are the imaginary parts. Thus we have the quaternion

${\displaystyle q=a+bi+cj+dk,}$

which is a quaternion of unit length (or versor) since

${\displaystyle \left\|q\right\|^{2}=a^{2}+b^{2}+c^{2}+d^{2}=1.}$

Most importantly, the above equations for composition of rotations are precisely the equations for multiplication of quaternions ${\displaystyle q=q_{2}\,q_{1}}$. In other words, the group of unit quaternions with multiplication, modulo the negative sign, is isomorphic to the group of rotations with composition.

Connection with SU(2) spin matrices

The Lie group SU(2) can be used to represent three-dimensional rotations in complex 2 × 2 matrices. The SU(2)-matrix corresponding to a rotation, in terms of its Euler parameters, is

${\displaystyle U={\begin{pmatrix}\ a-di&-c-bi\\c-bi&a+di\end{pmatrix}}.}$

which can be written as the sum

${\displaystyle {\begin{aligned}U&=a\ {\begin{pmatrix}1&0\\0&1\end{pmatrix}}-ib\ {\begin{pmatrix}0&1\\1&0\end{pmatrix}}-ic\ {\begin{pmatrix}0&-i\\i&0\end{pmatrix}}-id\ {\begin{pmatrix}1&0\\0&-1\end{pmatrix}}\\&=a\,I-ib\,\sigma _{x}-ic\,\sigma _{y}-id\,\sigma _{z},\end{aligned}}}$

where the σ_i are the Pauli spin matrices.

Rotation is given by ${\displaystyle X^{\prime }\equiv (x_{1}^{\prime }\sigma _{x}+x_{2}^{\prime }\sigma _{y}+x_{3}^{\prime }\sigma _{z})=U\;X\;U^{\dagger }=(a\,I-ib\,\sigma _{x}-ic\,\sigma _{y}-id\,\sigma _{z})(x_{1}\sigma _{x}+x_{2}\sigma _{y}+x_{3}\sigma _{z})(a\,I+ib\,\sigma _{x}+ic\,\sigma _{y}+id\,\sigma _{z})}$, which it can be confirmed by multiplying out gives the Euler–Rodrigues formula as stated above.

Thus, the Euler parameters are the real and imaginary coordinates in an SU(2) matrix corresponding to an element of the spin group Spin(3), which maps by a double cover mapping to a rotation in the orthogonal group SO(3). This realizes ${\displaystyle \mathbb {R} ^{3}}$ as the unique three-dimensional irreducible representation of the Lie group SU(2) ≈ Spin(3).

Cayley–Klein parameters

The elements of the matrix ${\displaystyle U}$ are known as the Cayley–Klein parameters, after the mathematicians Arthur Cayley and Felix Klein,^[a]

${\displaystyle {\begin{aligned}\alpha &=a-di&\beta &=-c-bi\\\gamma &=c-bi&\delta &=\ a+di\end{aligned}}}$

In terms of these parameters the Euler–Rodrigues formula can then also be written ^[2][6][a]

${\displaystyle {\vec {x}}'={\begin{pmatrix}{\frac {1}{2}}(\alpha ^{2}-\gamma ^{2}+\delta ^{2}-\beta ^{2})&{\frac {1}{2}}i(\gamma ^{2}-\alpha ^{2}+\delta ^{2}-\beta ^{2})&\gamma \delta -\alpha \beta \\{\frac {1}{2}}i(\alpha ^{2}+\gamma ^{2}-\beta ^{2}-\delta ^{2})&{\frac {1}{2}}(\alpha ^{2}+\gamma ^{2}+\beta ^{2}+\delta ^{2})&-i(\alpha \beta +\gamma \delta )\\\beta \delta -\alpha \gamma &i(\alpha \gamma +\beta \delta )&\alpha \delta +\beta \gamma \end{pmatrix}}{\vec {x}}.}$

Klein and Sommerfeld used the parameters extensively in connection with Möbius transformations and cross-ratios in their discussion of gyroscope dynamics.^[3][7]

See also

• Rotation formalisms in three dimensions
• Quaternions and spatial rotation
• Versor
• Spinors in three dimensions
• SO(4)
• 3D rotation group
• Beltrami–Klein model (Cayley–Klein model)
• Cayley–Klein metric

Notes

1. Goldstein (1980)^[2] considers a passive (contravariant, or "alias") transformation, rather than the active (covariant, or "alibi") transformation here.
   His matrix ${\displaystyle A}$ therefore corresponds to the transpose of the Euler–Rodrigues matrix given at the head of this article, or, equivalently, to the Euler–Rodrigues matrix for an active rotation of ${\displaystyle -\varphi }$ rather than ${\displaystyle \varphi }$. Taking this into account, it is apparent that his ${\displaystyle e_{1}}$, ${\displaystyle e_{2}}$, and ${\displaystyle e_{3}}$ in eqn 4-67 (p.153) are equal to ${\displaystyle b}$, ${\displaystyle c}$, and ${\displaystyle d}$ here. However his ${\displaystyle \alpha }$, ${\displaystyle \beta }$, ${\displaystyle \gamma }$, and ${\displaystyle \delta }$, the elements of his matrix ${\displaystyle Q}$, correspond to the elements of matrix ${\displaystyle U^{\dagger }}$ here, rather than the matrix ${\displaystyle U}$. This then gives his parametrization

   ${\displaystyle {\begin{aligned}\alpha &=\;\;a+di&\beta &=c+bi\\\gamma &=-c+bi&\delta &=a-di\end{aligned}}}$

   In consequence, while his formula (4-64) is identical symbol-by-symbol to the transformation matrix given here, using his definitions for ${\displaystyle \alpha }$, ${\displaystyle \beta }$, ${\displaystyle \gamma }$, and ${\displaystyle \delta }$ it gives his matrix ${\displaystyle A}$, whereas the definitions based on the matrix ${\displaystyle U}$ above lead to the (active) Euler–Rodrigues matrix presented here.
   Pennestrì et al (2016)^[3] similarly define their ${\displaystyle \alpha }$, ${\displaystyle \beta }$, ${\displaystyle \gamma }$, and ${\displaystyle \delta }$ in terms of the passive matrix ${\displaystyle Q}$ rather than the active matrix ${\displaystyle U}$.
   The parametrization here accords with that used in eg Sakurai and Napolitano (2020),^[4] p. 165, and Altmann (1986),^[5] eqn. 5 p. 113 / eqn. 9 p. 117.

Further reading

• Cartan, Élie (1981). The Theory of Spinors. Dover. ISBN 0-486-64070-1.
• Hamilton, W. R. (1899). Elements of Quaternions. Cambridge University Press.
• Haug, E.J. (1984). Computer-Aided Analysis and Optimization of Mechanical Systems Dynamics. Springer-Verlag.
• Garza, Eduardo; Pacheco Quintanilla, M. E. (June 2011). "Benjamin Olinde Rodrigues, matemático y filántropo, y su influencia en la Física Mexicana" (PDF). Revista Mexicana de Física (in Spanish): 109–113. Archived from the original (pdf) on 2012-04-23.
• Shuster, Malcolm D. (1993). "A Survey of Attitude Representations" (PDF). Journal of the Astronautical Sciences. 41 (4): 439–517.
• Dai, Jian S. (October 2015). "Euler–Rodrigues formula variations, quaternion conjugation and intrinsic connections". Mechanism and Machine Theory. 92: 144–152. doi:10.1016/j.mechmachtheory.2015.03.004.

References

1. e.g. Felix Klein (1897), The mathematical theory of the top, New York: Scribner. p.4
2. Goldstein, H. (1980), "The Cayley-Klein Parameters and Related Quantities". §4-5 in Classical Mechanics, 2nd ed. Reading, MA: Addison-Wesley. p. 153
3. E. Pennestrì, P.P. Valentini, G. Figliolini, J. Angeles (2016), "Dual Cayley–Klein parameters and Möbius transform: Theory and applications", Mechanism and Machine Theory 106(January):50-67. doi:10.1016/j.mechmachtheory.2016.08.008. pdf available via ResearchGate
4. Sakurai, J. J.; Napolitano, Jim (2020). Modern Quantum Mechanics (3rd ed.). Cambridge. ISBN 978-1-108-47322-4. OCLC 1202949320.{{cite book}}: CS1 maint: location missing publisher (link)
5. Altmann, S. (1986), Rotations, Quaternions and Double Groups. Oxford:Clarendon Press. ISBN 0-19-855372-2
6. Weisstein, Eric W., Cayley-Klein Parameters, MathWorld. Accessed 2024-05-10
7. Felix Klein and Arnold Sommerfeld, Über die Theorie des Kreisels, vol 1. (Teubner, 1897). Translated (2008) as: The Theory of the Top, vol 1. Boston: Birkhauser. ISBN 0817647201