A Transition Matrix for Rotation in R² Find the coordinates of a point (x, y) in R² relative to the basis B′ = {(cos θ, sin θ), (-sin θ, cos θ)}.

Question

A Transition Matrix for Rotation in [latex]R²[/latex]

Find the coordinates of a point [latex](x, y)[/latex]in [latex]R²[/latex] relative to the basis

[latex]B´[/latex] = {(cos [latex]θ,[/latex] sin [latex]θ[/latex]), (-sin [latex]θ,[/latex] cos [latex]θ[/latex])}.

Accepted Answer

By Theorem 4.21 you have

[latex][B´ B] = \left [ \begin{matrix} cos θ& -sin θ& 1 & 0 \ sin θ& cos θ& 0 & 1 \end{matrix} ight ] .[/latex]
Because [latex]B[/latex] is the standard basis for [latex]R², P^{-1}[/latex] is represented by [latex](B´)^{-1}.[/latex] You can use the formula given in Section 2.3 (page 66) for the inverse of a 2 × 2 matrix to find [latex](B´)^{-1}.[/latex]

This results in

[latex][I P^{-1}] = \left [ \begin{matrix} 1& 0& cos θ & sin θ \ 0& 1& -sin θ & cos θ \end{matrix} ight ] .[/latex]
By letting [latex](x´, y´)[/latex] be the coordinates of [latex](x, y)[/latex] relative to [latex]B´,[/latex] you can use the transition matrix [latex]P^{-1}[/latex] as follows.

[latex]\left [ \begin{matrix} cos θ& sin θ \ -sin θ& cos θ \end{matrix} ight ]\left [ \begin{matrix} x \ y \end{matrix} ight ] = \left [ \begin{matrix} x´ \ y´ \end{matrix} ight ] [/latex]
The [latex]x´ -[/latex] and [latex]y´ -[/latex] coordinates are [latex]x´ =x[/latex] cos [latex]θ[/latex] + [latex]y[/latex] sin [latex]θ[/latex] and [latex]y´ = -x[/latex] sin [latex]θ + y[/latex] cos [latex]θ.[/latex]

Question 4.8.6: A Transition Matrix for Rotation in R² Find the coordinates ...

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