Revision as of 16:16, 12 June 2021

Euler Angles

Here we will follow quite closely the online class notes prepared by Professor Mona Berciu, Department of Physics & Astronomy, University of British Columbia.

Basic Relations

In terms of the unit vectors of the $(X, Y, Z)$ Cartesian coordinate system shown in the left panel of Figure 1, we can uniquely specify the (red) vector, $\vec{A}$ , by the expression,

$\vec{A} = {\vec{e}}_{X} (A_{X}) + {\vec{e}}_{Y} (A_{Y}) + {\vec{e}}_{Z} (A_{Z})$

where the coefficient triplet, $(A_{X}, A_{Y}, A_{Z})$ , give the length (and $\pm$ direction) of each vector component. Alternatively, in terms of the unit vectors of the $(x_{1}, x_{2}, x_{3})$ Cartesian coordinate system shown in the right panel of Figure 1, the same (red) vector is specified by the expression,

$\vec{A} = {\vec{e}}_{1} (A_{1}) + {\vec{e}}_{2} (A_{2}) + {\vec{e}}_{3} (A_{3}) .$

Figure 1

Rotation Matrix

From the last row of the column labeled "Proper Euler angles" in Wikipedia's discussion of the rotation matrix, we find,

$Z_{1} X_{2} Z_{3}$

$=$

$[\begin{matrix} (c_{1} c_{3} - c_{2} s_{1} s_{3}) & (- c_{1} s_{3} - c_{2} c_{3} s_{1}) & (s_{1} s_{2}) \\ (c_{3} s_{1} + c_{1} c_{2} s_{3}) & (c_{1} c_{2} c_{3} - s_{1} s_{3}) & (- c_{1} s_{2}) \\ (s_{2} s_{3}) & (c_{3} s_{2}) & (c_{2}) \end{matrix}]$

The equivalent expression can be found in Professor Berciu's online class notes; it reads,

$\hat{R} (ϕ, θ, ψ)$

$=$

$[\begin{matrix} (\cos ϕ \cos ψ - \cos θ \sin ϕ \sin ψ) & (- \cos ϕ \sin ψ - \cos θ \cos ψ \sin ϕ) & (\sin ϕ \sin θ) \\ (\cos ψ \sin ϕ + \cos ϕ \cos θ \sin ψ) & (\cos ϕ \cos θ \cos ψ - \sin ϕ \sin ψ) & (- \cos ϕ \sin θ) \\ (\sin θ \sin ψ) & (\cos ψ \sin θ) & (\cos θ) \end{matrix}]$

@@ Line 4: / Line 4: @@
 =Euler Angles</font>=
 Here we will follow quite closely the [https://phas.ubc.ca/~berciu/TEACHING/PHYS206/LECTURES/FILES/euler.pdf online class notes] prepared by [https://phas.ubc.ca/~berciu/ Professor Mona Berciu], Department of Physics &amp; Astronomy, University of British Columbia.
+==Basic Relations==
+In terms of the unit vectors of the <math>(X, Y, Z)</math> Cartesian coordinate system shown in the left panel of Figure 1, we can uniquely specify the (red) vector, <math>\vec{A}</math>, by the expression,
+<div align="center">
+<math>~\vec{A} = \vec{e}_X (A_X) + \vec{e}_Y (A_Y) + \vec{e}_Z (A_Z)</math>
+</div>
+where the coefficient triplet, <math>(A_X, A_Y, A_Z)</math>, give the length (and <math>\pm</math> direction) of each vector component.  Alternatively, in terms of the unit vectors of the <math>(x_1, x_2, x_3)</math> Cartesian coordinate system shown in the right panel of Figure 1, the same (red) vector is specified by the expression,
+<div align="center">
+<math>~\vec{A} = \vec{e}_1 (A_1) + \vec{e}_2 (A_2) + \vec{e}_3 (A_3) \, .</math>
+</div>
+<table border="1" align="center" cellpadding="8">
+<tr><td align="center" colspan="2">'''Figure 1'''</td></tr>
+<tr>
+  <td align="center">
+[[File:BerciuFig1a.png|300px|Berciu Figure 1a]]
+  </td>
+  <td align="center">
+[[File:BerciuFig1b.png|300px|Berciu Figure 1b]]
+  </td>
+</tr>
+</table>
 ==Rotation Matrix==

Appendix/Mathematics/EulerAngles: Difference between revisions

Revision as of 16:16, 12 June 2021

Contents

Euler Angles

Basic Relations

Rotation Matrix

See Also

Navigation menu

Appendix/Mathematics/EulerAngles: Difference between revisions

Revision as of 16:16, 12 June 2021

Euler Angles

Basic Relations

Rotation Matrix

See Also

Navigation menu

Search