True or false: the matrix of Rot_ is indeed cos-sinsincos

Special Linear Transformations in $\reals^2$

4 Activities

True or false: the matrix of RotθRot_{\theta}Rotθ​ is indeed [cos⁡θ−sin⁡θsin⁡θcos⁡θ]\begin{bmatrix}\cos\theta&-\sin\theta\\\sin\theta&\cos\theta\end{bmatrix}[cosθsinθ​−sinθcosθ​]

True

False

I don't know

More Special Linear Transformations in $\reals^2$ Questions:

Composition of linear transformations

Suppose that A=[2011]A=\left[\begin{array}{rr}2&0\\1&1\end{array}\right]A=[21​01​]
TTT is the linear transformation induced by the matrix AAA , and
SSSis the linear transformation with matrix BBB that rotates a vector by 60 degrees ( π/3\pi/3π/3 rad) counterclockwise around the point (0,0)(0,0)(0,0)

Composition of linear transformations

Suppose that A=[2011]A=\left[\begin{array}{rr}2&0\\1&1\end{array}\right]A=[21​01​]
TTT is the linear transformation induced by the matrix AAA , and
SSSis the linear transformation with matrix BBB that rotates a vector by 60 degrees ( π/3\pi/3π/3 rad) counterclockwise around the point (0,0)(0,0)(0,0)

Composition of linear transformations

Suppose that A=[2011]A=\left[\begin{array}{rr}2&0\\1&1\end{array}\right]A=[21​01​]
TTT is the linear transformation induced by the matrix AAA , and
SSSis the linear transformation with matrix BBB that rotates a vector by 60 degrees ( π/3\pi/3π/3 rad) counterclockwise around the point (0,0)(0,0)(0,0)

Composition of linear transformations

Suppose that A=[2011]A=\left[\begin{array}{rr}2&0\\1&1\end{array}\right]A=[21​01​]
TTT is the linear transformation induced by the matrix AAA , and
SSSis the linear transformation with matrix BBB that rotates a vector by 60 degrees ( π/3\pi/3π/3 rad) counterclockwise around the point (0,0)(0,0)(0,0)

Composition of linear transformations

Suppose that A=[2011]A=\left[\begin{array}{rr}2&0\\1&1\end{array}\right]A=[21​01​]
TTT is the linear transformation induced by the matrix AAA , and
SSSis the linear transformation with matrix BBB that rotates a vector by 60 degrees ( π/3\pi/3π/3 rad) counterclockwise around the point (0,0)(0,0)(0,0)

Consider the matrix transformation T:R2→R2T:\mathbb{R}^2\to\mathbb{R}^2T:R2→R2 induced by the matrix [0110]\begin{bmatrix}0&1\\1&0\end{bmatrix}[01​10​] . Then TTT is:  

Consider the matrix transformation T:R2→R2T:\mathbb{R}^2 \rightarrow \mathbb{R}^2T:R2→R2 induced by the matrix  [100−1]\left[ \begin{array}{cc} 1&0\\0&-1 \end{array} \right][10​0−1​]
Then TTT is:

Rotation, Projection and Reflection Transformations

 Write down matrix of the rotation which transforms 
T([01])=[−10]T\left(\begin{bmatrix}
0\\1
\end{bmatrix}\right)=\begin{bmatrix}
-1\\0
\end{bmatrix}T([01​])=[−10​]

Special Linear Transformations

Example: Special Linear Transformations
Suppose T:R2→R2T:\mathbb{R}^2\to\mathbb{R}^2T:R2→R2is a linear transformation that reflects a vector across the line y=2xy = 2xy=2x, then rotates the resulting vector through an angle of 60°60\degree60°counter-clockwise.
Find the matrix that induces TTT.

Consider the matrix transformation T:R2→R2T:\mathbb{R}^2\to\mathbb{R}^2T:R2→R2 induced by the matrix [−1001]\begin{bmatrix}-1&0\\0&1\end{bmatrix}[−10​01​] . Then TTT is:

Consider line L passing through the origin with direction [2,−4]. Find the matrix that represents
 reflection across the line L

Let A be the matrix that rotates a 2D vector counterclockwise by 60, B be the matrix that reflects 2D vectors across the line 𝑦=3𝑥,𝑦=\sqrt{3}𝑥,y=3​x, and C be the projection to the line y=x.   Which three of the following statements are true?

 Consider line L passing through the origin with direction [2,−4]. Find the matrix that  
 represents reflection across the line L

 a) If A is a rotation matrix for 30 degree CCW, find 𝑛 such that: 𝑨n = 𝑨-1
 b) Find two different rotation matrices B such that 𝑩2=[01−10]\text{
b) Find two different rotation matrices B such that }𝑩^2 =\begin{bmatrix}
0&1\\
-1&0
\end{bmatrix} b) Find two different rotation matrices B such that B2=[0−1​10​] 

Consider the linear transformation T which takes vectors in R2, first rotates them by 30 degree counter-clockwise and then projects the result onto the direction
[12]. Find T([10]).\begin{bmatrix}
1\\
2
\end{bmatrix}.\ Find\ T\left(\begin{bmatrix}
1\\
0
\end{bmatrix}\right).[12​]. Find T([10​]).

Prove the matrix of RotθRot_{\theta}Rotθ​ is indeed [cos⁡θ−sin⁡θsin⁡θcos⁡θ]\begin{bmatrix}\cos\theta&-\sin\theta\\\sin\theta&\cos\theta\end{bmatrix}[cosθsinθ​−sinθcosθ​]

True or false. Suppose TTT is a linear transformation with induced by [0−110]\begin{bmatrix} 0 & -1\\ 1 & 0 \end{bmatrix}[01​−10​] , then TTT is a rotation through the angle 90°90\degree90°counter-clockwise.

Special Linear Transformations

Example: Special Linear Transformations
Suppose T:R2→R2T:\mathbb{R}^2\to\mathbb{R}^2T:R2→R2 is a linear transformation that reflects a vector across the line y=2xy = 2xy=2x, then rotates the resulting vector through an angle of 60°60\degree60°counter-clockwise.
Find the matrix that induces TTT.

Composition of linear transformations

Suppose that A=[2011]A=\left[\begin{array}{rr}2&0\\1&1\end{array}\right]A=[21​01​]
TTT is the linear transformation induced by the matrix AAA , and
SSSis the linear transformation with matrix BBB that rotates a vector by 60 degrees ( π/3\pi/3π/3 rad) counterclockwise around the point (0,0)(0,0)(0,0)

19.4F_Mid_Builder_$\tkcth{8.6.}$$\tkco{14}$_(8.6.1 without the general line)

Consider the transformation T:R2→R2T: \mathbb{R}^2 \to \mathbb{R}^2T:R2→R2 that reflects a vector x⃗\vxx across the line y=15xy = \frac{1}{5}xy=51​x. 
Find a vector parallel to the line. We call any vector that is a scalar multiple of the (parallel) direction of the line the direction vector of the line d⃗\vdd. 


Find a unit vector d^\dhatd^ pointing in the same direction as d⃗\vdd. 

19.4F_Final_Builder_Ch_6.7_Curve_Fitting_$\tkco{eg1}(\tkco{a+b})$_$\key{Final}$_Builder_$\tkcth{6.7.}\tkcf{1}$_

Consider the transformation T:R2→R2T: \mathbb{R}^2 \to \mathbb{R}^2T:R2→R2 that projects a vector x⃗\vxx onto the line y=5xy = 5xy=5x. 
Find a vector parallel to the line. We call any vector that is a scalar multiple of the (parallel) direction of the line the direction vector of the line d⃗\vdd. 

Find T(d⃗)T(\vd)T(d) by geometric reasoning (i.e. think about the effect of the transformation: no computation is required). 

Prove that for rotation matrix A in 2D, AT=A-1

Prove that for rotation matrix A in 2D, AT=A-1

There are two linear transformations of R2\mathbb{R}^2R2 that map the square with vertices at (0,0); (1,0); (0,1);
 and (1,1) to the square with vertices at (0,0); (1,1);(-1,1); and (0,2). Call them T1 and T2.
 Determine the matrices of T1 and T2.

Special Linear Transformations

Practice: Special Linear Transformations
A linear transformation T:R2→R2T: \reals^2 \to \reals^2T:R2→R2 is the result of the following transformations (in order):
first reflects across the line at an angle π4 rad\dfrac{\pi}{4} \text{ rad}4π​ rad below the positive xxx-axis, then

Special Linear Transformations

Practice: Special Linear Transformations
Find the matrix inducing the linear transformation S:R2→R2S: \reals^2 \to \reals^2S:R2→R2 that does the following:
first, rotates vectors counter-clockwise by π2 rad\dfrac{\pi}{2} \text{ rad}2π​ rad, then

Rotation, Projection and Reflection Transformations

Suppose that P is a projection, R is a rotation and Q is a reflection in 2D. Choose the statement below that is not true:

True or false: the matrix of Rot_ is indeed cos-sinsincos

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Special Linear Transformations in $\reals^2$

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19.4F_Mid_Builder_$\tkcth{8.6.}$$\tkco{14}$_(8.6.1 without the general line)

19.4F_Final_Builder_Ch_6.7_Curve_Fitting_$\tkco{eg1}(\tkco{a+b})$_$\key{Final}$_Builder_$\tkcth{6.7.}\tkcf{1}$_

Special Linear Transformations

Special Linear Transformations

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Common Transformations

True or false: the matrix of Rot_ is indeed cos-sinsincos

Related Topics

Special Linear Transformations in R2\reals^2R2

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Composition of linear transformations

19.4F_Mid_Builder_$\tkcth{8.6.}$$\tkco{14}$_(8.6.1 without the general line)

19.4F_Final_Builder_Ch_6.7_Curve_Fitting_$\tkco{eg1}(\tkco{a+b})$_$\key{Final}$_Builder_$\tkcth{6.7.}\tkcf{1}$_

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Special Linear Transformations

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Common Transformations

Special Linear Transformations in $\reals^2$

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