Given the following matrix, what can you conclude? A = 1 0 -2 1 5 1

Linear Transformations

5 Activities

Given the following matrix, what can you conclude?
A=[10−2151]A = \begin{bmatrix}
1 & 0 \\
-2 & 1\\
5 & 1
\end{bmatrix}A=​1−25​011​​

Determine if a transformation is linear

Let W={(x,y,z)  ∣  x,y,z∈R+}W=\{(x,y,z)\;|\;x,y,z\in\mathbb{R}^+\}W={(x,y,z)∣x,y,z∈R+} be the vector with defined operations:
(x1,y1,z2)+(x2,y2,z2)=(x1x2,  y1y2,  z1z2)(x_1,y_1,z_2)+(x_2,y_2,z_2)=(x_1x_2,\;y_1y_2,\;z_1z_2)(x1​,y1​,z2​)+(x2​,y2​,z2​)=(x1​x2​,y1​y2​,z1​z2​)
k⋅(x,y,z)=(xk,  yk,  zk)k\cdot(x,y,z)=(x^k,\;y^k,\;z^k)k⋅(x,y,z)=(xk,yk,zk)

Matrix of a Linear Transformation

Consider the map T:R3→R3x⃗→proj(1,1,0)x⃗+2proj(1,0,−1)x⃗−proj(0,0,1)x⃗\begin{array}{l}T:\mathbb{R}^3\rightarrow\mathbb{R}^3\\\vec x\rightarrow proj_{(1,1,0)}\vec x+2proj_{(1,0,-1)}\vec x-proj_{(0,0,1)}\vec x\end{array}T:R3→R3x→proj(1,1,0)​x+2proj(1,0,−1)​x−proj(0,0,1)​x​
a) Show that T is a linear transformation
b) Compute the matrix of T, and its inverse matrix.

Find the matrix of a given transformation

(a) Let L:R3⟶R4L:\mathbb{R}^3\longrightarrow\mathbb{R}^4L:R3⟶R4 be defined by:
L((x,y,z))=(2x−y,2y+3z,−3x+5z,x−y+z)L\big((x,y,z)\big)=(2x-y,2y+3z,-3x+5z,x-y+z)L((x,y,z))=(2x−y,2y+3z,−3x+5z,x−y+z)
Find the matrix AAA that represents LLL

Supposse T[01]=[112],  T[11]=[21−1],  B=[010],  and  C=[001]T\begin{bmatrix} 0\\1 \end{bmatrix}=\begin{bmatrix} 1\\1\\2 \end{bmatrix},\; T\begin{bmatrix} 1\\1 \end{bmatrix}=\begin{bmatrix} 2\\1\\-1 \end{bmatrix},\; B=\begin{bmatrix} 0\\1\\0 \end{bmatrix},\; and\; C=\begin{bmatrix} 0\\0\\1 \end{bmatrix}T[01​]=​112​​,T[11​]=​21−1​​,B=​010​​,andC=​001​​
Then:

Finding Non-linear Transformation

Which of the following transformations are linear?
a)[xy]→[x−y2x+y+60]a)\begin{bmatrix}
x\\y
\end{bmatrix}→\begin{bmatrix}
x-y\\
2x+y+6\\
0
\end{bmatrix}a)[xy​]→​x−y2x+y+60​​

Let T be a linear transformation. Suppose that
T([101])=[−20−1],T([011])=[032],T([010])=[0−40]T\left(\begin{bmatrix}
1\\0\\1
\end{bmatrix}\right)=\begin{bmatrix}
-2\\0\\-1
\end{bmatrix},T\left(\begin{bmatrix}
0\\1\\1
\end{bmatrix}\right)=\begin{bmatrix}
0\\3\\2
\end{bmatrix},T\left(\begin{bmatrix}
0\\1\\0
\end{bmatrix}\right)=\begin{bmatrix}
0\\-4\\0
\end{bmatrix}T​​101​​​=​−20−1​​,T​​011​​​=​032​​,T​​010​​​=​0−40​​
a) Find T([100])a)\ Find\ T\left(\begin{bmatrix}
1\\0\\0
\end{bmatrix}\right)a) Find T​​100​​​

Find a linear transformation T from R2 to R2, if
T([1−4])=[−36]T\left(\begin{bmatrix}
1\\-4
\end{bmatrix}\right)=\begin{bmatrix}
-3\\6
\end{bmatrix}T([1−4​])=[−36​]
and it transforms points on liney=0 y=0 y=0 to new line y=2xy=2xy=2x and vice versa:

Let u⃗=[−314]\vec{u} = \begin{bmatrix} -3 \\ 1 \\ 4 \end{bmatrix}u=​−314​​ and let T:R3→R3T : \mathbb{R}^3 \rightarrow \mathbb{R}^3T:R3→R3 be the linear transformation defined by T(v⃗)=proj⁡u⃗(v⃗)T(\vec{v}) = \operatorname{proj}_{_{\vec{u}}} (\vec{v})T(v)=proju​​(v). Find the matrix of TTT.

Let T:R2→R2T:\mathbb{R}^2\to\mathbb{R}^2T:R2→R2 be a linear transformation with T[3−2]=[62]T\begin{bmatrix}3\\-2\end{bmatrix}=\begin{bmatrix}6\\2\end{bmatrix}T[3−2​]=[62​] and T[−54]=[−40]T\begin{bmatrix}-5\\4\end{bmatrix}=\begin{bmatrix}-4\\0\end{bmatrix}T[−54​]=[−40​]
(a) Find the matrix of TTT, that is, find a matrix AAA such that Tv⃗=Av⃗T\vec{v}=A\vec{v}Tv=Av for all v⃗∈R2\vec{v}\in\mathbb{R}^2v∈R2.
(b) Is TTT invertible? If so, find the matrix of T−1T^{-1}T−1. If not, prove why not.

The unit square in R2 is the set of all points (x; y) with 0 ≤ 𝑥 ≤ 2 and 0 ≤ 𝑦 ≤ 2. Suppose each point in
  the unit square undergoes a linear transformation that has the given matrix representation
A=[1221].Draw a labelled sketch of the transformed points.A=\begin{bmatrix}
1&2\\2&1
\end{bmatrix}\text{.Draw a labelled sketch of the transformed points.}A=[12​21​].Draw a labelled sketch of the transformed points.

Find the matrix A representing the linear transformation T: R3 to R3 such that it satisfies:
𝑻(𝑒1) = 𝑒1 + 2𝑒2 + 3𝑒3, 𝑻(𝑒1 + 𝑒2) = 𝑒1 + 2𝑒2, 𝑻(𝑒1 + 𝑒2 + 𝑒3) = −2𝑒2 + 𝑒3.

Suppose T is a linear transformation such that
T[113]=[2−1],T[202]=[32],T[424]=[−14]T\begin{bmatrix}
1\\1\\3
\end{bmatrix}=\begin{bmatrix}
2\\-1\\
\end{bmatrix},T\begin{bmatrix}
2\\0\\2
\end{bmatrix}=\begin{bmatrix}
3\\2
\end{bmatrix},T\begin{bmatrix}
4\\2\\4
\end{bmatrix}=\begin{bmatrix}
-1\\4
\end{bmatrix}T​113​​=[2−1​],T​202​​=[32​],T​424​​=[−14​]
Find the matrix of T.

Let u⃗=[−311]\vec{u} = \begin{bmatrix} -3 \\ 1 \\ 1 \end{bmatrix}u=​−311​​ and let T:R3→R3T : \mathbb{R}^3\rightarrow\mathbb{R}^3T:R3→R3 be the linear transformation defined by T(v⃗)=proj⁡u⃗(v⃗)T(\vec{v})=\operatorname{proj}_{_{\vec{u}}}(\vec{v})T(v)=proju​​(v). Find the matrix of TTT.

Find the matrix for the linear transformation S :R3 to R3 given by
S([xyz])=([−y+zx+y+z−x+2y])S\left(\begin{bmatrix}
x\\y\\z
\end{bmatrix}\right)=\left(\begin{bmatrix}
-y+z\\
x+y+z\\
-x+2y
\end{bmatrix}\right)S​​xyz​​​=​​−y+zx+y+z−x+2y​​​

Suppose a⃗\vec{a}ais a fixed vector in ℝ3 and consider the transformation 𝑇:ℝ3 → ℝ3 defined by 𝑇((x)⃗=a⃗ ×x.⃗𝑇(\vec{\left(x\right)}=\vec{a}\ \times\vec{x.}T((x)​=a ×x. Prove that T is a linear transformation and find the matrix of T.

If T is a linear transformation such that T[−12]=[31]T\begin{bmatrix}-1\\2\end{bmatrix}=\begin{bmatrix}3\\1\end{bmatrix}T[−12​]=[31​] and T[13]=[−12]T\begin{bmatrix}1\\3\end{bmatrix}=\begin{bmatrix}-1\\2\end{bmatrix}T[13​]=[−12​] , find T[4−3]T\begin{bmatrix}4\\-3\end{bmatrix}T[4−3​]

Suppose T is a linear transformation and
T[25]=[123],T[38]=[−101]T\begin{bmatrix}
2\\5
\end{bmatrix}=\begin{bmatrix}
1\\2\\3
\end{bmatrix},T\begin{bmatrix}
3\\8
\end{bmatrix}=\begin{bmatrix}
-1\\0\\1
\end{bmatrix}T[25​]=​123​​,T[38​]=​−101​​
Find the matrix of this linear transformation.

Consider the transformation T defined by 𝑇(𝑥1,𝑥2,𝑥3,x4)=(x1+2x2,𝑥3−𝑥4)𝑇(𝑥_1,𝑥_2,𝑥_3,x_4)=(x_1+2x_2,𝑥_3−𝑥_4)T(x1​,x2​,x3​,x4​)=(x1​+2x2​,x3​−x4​). Prove T is a linear transformation and find the matrix of T.

Suppose a⃗\vec{a}a is a fixed vector in ℝn and consider the transformation 𝑇:ℝn → ℝ defined by  𝑇 (x⃗)=a.⃗  x.⃗  𝑇\ \left(\vec{x}\right)=\vec{a.}\ \ \vec{x.}\ \ T (x)=a.  x.   Prove that T is a linear transformation and find the matrix of T.

Suppose T is a linear transformation and
T[25]=[123],T[38]=[−101]T\begin{bmatrix}
2\\5
\end{bmatrix}=\begin{bmatrix}
1\\2\\3
\end{bmatrix},T\begin{bmatrix}
3\\8
\end{bmatrix}=\begin{bmatrix}
-1\\0\\1
\end{bmatrix}T[25​]=​123​​,T[38​]=​−101​​
Find the matrix of this linear transformation.

For a linear transformation W from R2 to R2, if 𝑊
W([20])=[32],W([12])=[−14],find W([−44]).W \left(\begin{bmatrix}
2\\0
\end{bmatrix}\right)=\begin{bmatrix}
3\\2
\end{bmatrix},W\left(\begin{bmatrix}
1\\2
\end{bmatrix}\right)=\begin{bmatrix}
-1\\4
\end{bmatrix},find\ W\left(\begin{bmatrix}
-4\\4
\end{bmatrix}\right).W([20​])=[32​],W([12​])=[−14​],find W([−44​]).

True or False: Suppose a ⃗\vec{a\ }a  is a fixed vector in Rn\mathbb{R}^nRn and T:Rn→RT:\mathbb{R}^n\to\mathbb{R}T:Rn→R defined by T(x⃗)=a⃗⋅x⃗T(\vec{x})=\vec{a}\cdot\vec{x}T(x)=a⋅x then TTT is a linear transformation and its matrix is [a1⋯an]\begin{bmatrix}a_1&\cdots&a_n\end{bmatrix}[a1​​⋯​an​​]

Suppose T:R2→R3T:\mathbb{R}^2\to\mathbb{R}^3T:R2→R3 is a linear transformation and
T[25]=[123],T[38]=[−101]T\begin{bmatrix}2\\5\end{bmatrix}=\begin{bmatrix}1\\2\\3\end{bmatrix},\quad T\begin{bmatrix}3\\8\end{bmatrix}=\begin{bmatrix}-1\\0\\1\end{bmatrix}T[25​]=​123​​,T[38​]=​−101​​
Find the matrix of this linear transformation.

Example: Finding the Linear Transformation Matrix

Find the corresponding matrix M of the linear transformation 𝑓(𝑥, 𝑦, 𝑧) = (𝑥 − 𝑦, 3𝑦, 3𝑥 + 2𝑧).

Finding Non-linear Transformation

Which of the following transformations are linear?

Is the given transformation linear?

Let VVV be the vector space {(x,y)  ∣  x,y∈R+}\{(x,y)\;|\;x,y\in\mathbb{R}^+\}{(x,y)∣x,y∈R+} with the operations:
(x1,y1)+(x2,y2)=(x1x2,y1y2)(x_1,y_1)+(x_2,y_2)=(x_1x_2,y_1y_2)(x1​,y1​)+(x2​,y2​)=(x1​x2​,y1​y2​)
k⋅(x,y)=(xk,yk)k\cdot(x,y)=(x^k,y^k)k⋅(x,y)=(xk,yk)

Practice Question: Linear and Non-Linear Maps

Determine whether the following maps are linear or not.
1. L:R→RL: \mathbb{R} \rightarrow \mathbb{R}L:R→R , defined by L(x)=cos⁡(x)L(x) = \cos(x)L(x)=cos(x) .
2. L:R→RL : \mathbb{R} \rightarrow \mathbb{R} L:R→R , defined by L(x)=3x−2L(x) = 3x -2 L(x)=3x−2

19.4F_Mid_Builder_$\tkcth{8.4.}\tkcf{15}$_$\tkco{Mock 3}$.

The following is known about the system of linear equations given by   ⁣M ⁣‾   x⃗=y⃗\M \, \vx = \vec{y}M​x=y​: 
There is a unique solution for any y⃗ ∈ R5\vec{y} \, \in \,  \mathbb{R}^{5}y​∈R5. 

If one interchanges the 3rd and 4th rows and then adds twice the third row to the first before finally multiplying the 2nd and 4th rows by 3,   ⁣M ⁣‾  \MM​ will be in its RREF.

Find the matrix of a given transformation

(a) Let L:R3⟶R4L:\mathbb{R}^3\longrightarrow\mathbb{R}^4L:R3⟶R4 be defined by:
L((x,y,z))=(2x−y,2y+3z,−3x+5z,x−y+z)L\big((x,y,z)\big)=(2x-y,2y+3z,-3x+5z,x-y+z)L((x,y,z))=(2x−y,2y+3z,−3x+5z,x−y+z)
Find the matrix AAA that represents LLL

19.4F_Mid_Builder_$\tkcth{8.4.}\tkcf{14}$_

Given the transformation T:R2 → R2T: \mathbb{R}^2 \, \to \, \mathbb{R}^2T:R2→R2 where T(v⃗)=x⃗T(\vv) = \vxT(v)=x and T(w⃗)=y⃗T(\vw) = \vec{y}T(w)=y​, where 
v⃗=[14]\vv = \colvec{1}{4}v=[14​], w⃗=[311]\vw = \colvec{3}{11}w=[311​], x⃗=[02]\vx = \colvec{0}{2}x=[02​] and y⃗=[−30]\vec{y} = \colvec{-3}{0}y​=[−30​], 
find the matrix representation   ⁣M ⁣‾  TB\M_{T_B}M​TB​​ of the transformation TTT in the basis B={[28], [−3−11]}B = \left\{  \colvec{2}{8},\, \colvec{-3}{-11} \right\}B={[28​],[−3−11​]} . 

Let L:R2→R3L : \mathbb{R}^2 \rightarrow \mathbb{R}^{3}L:R2→R3  be the map defined by
L(x,y)=(2x,3y,x+y)L(x, y) = (2x, 3y, x + y)L(x,y)=(2x,3y,x+y)
Is this map a linear transformation? If so, what is the kernel and image of this function? 

133 - FML 3 - 18.1W - e.g. 34

If T[10]=[4−4]\bcb{T\begin{bmatrix} 1 \\ 0 \end{bmatrix} = \begin{bmatrix} 4 \\ -4 \end{bmatrix}}T[10​]=[4−4​] and T[01]=[3−1]\bcb{T\begin{bmatrix} 0 \\ 1 \end{bmatrix} = \begin{bmatrix} 3 \\ -1 \end{bmatrix}}T[01​]=[3−1​], find the matrix representation of the transformation in the space spanned by the basis vectors u⃗1=(1,1)\bcb{\vec{u}_1 = (1,1)}u1​=(1,1) and u⃗2=(1,−1)\bcb{\vec{u}_2 = (1,-1)}u2​=(1,−1).
            ⁣M ⁣‾  T{u⃗1,u⃗2}=\M_{T_{\{\vu_1, \vu_2\}}} = M​T{u1​,u2​}​​=  7  
 1  
                                 -5 
 -3 

19.4F_Mid_Builder_$\tkcth{8.5.}\tkco{5}$__$\tkco{Mock 3}$

Given the basis for R2\mathbb{R}^2R2
 v⃗=[1−1]\vv = \colvec{1}{-1}v=[1−1​]    and    w⃗=[2−3]\vw = \colvec{2}{-3}w=[2−3​]. 
If T(v⃗)=2v⃗+3w⃗T(\vv) = 2\vv + 3\vwT(v)=2v+3w and T(w⃗)=v⃗+3w⃗T(\vw) = \vv + 3\vwT(w)=v+3w, determine the matrix representation of the transformation TTT. 

Let L:R3⟶RL:\mathbb{R}^3\longrightarrow\mathbb{R}L:R3⟶R be defined by:
L((x,y,z))=3x−y+2zL\big((x,y,z)\big)=3x-y+2zL((x,y,z))=3x−y+2z
(a) Show that v→=(2,−10,−8)\overrightarrow{v}=(2,-10,-8)v=(2,−10,−8) is in ker(L)ker(L)ker(L)

What is the matrix for the linear map 
L(x,y,z)=(x+y+z,2x−3z)L(x, y, z) = (x + y + z, 2x - 3z)L(x,y,z)=(x+y+z,2x−3z)
with respect to the standard basis?

Let LLL be a linear transformation defined by:
L(x→)=Ax→L(\overrightarrow{x})=A\overrightarrow{x}L(x)=Ax
where A=[2−31−14−3]A=\left[\begin{array}{rrr}
2&-3&1\\
-1&4&-3
\end{array}\right]A=[2−1​−34​1−3​]

Properties

Practice: Similar Matrices
Consider the matrix A=[−1421]A=
\left[
\begin{array}{rrr}
-1 & 4\\
2 & 1
\end{array}
\right]A=[−12​41​].

Concept Clarifier

If TTT and SSS are linear transformations induced by the matrices
[−2024],[1−201]\begin{bmatrix}-2&0\\2&4\end{bmatrix},\quad \begin{bmatrix}1&-2\\0&1\end{bmatrix}[−22​04​],[10​−21​]
respectively, then find (S∘T)(x⃗)(S \circ T)(\vec{x})(S∘T)(x) where x⃗=[15]\vec{x}=\begin{bmatrix}1\\5\end{bmatrix}x=[15​]

133 - FML 3 - 18.1W e.g. 2.3

Determine whether the following transformation is linear:{y1= 3(x1+x2)y2=−x1\boldsymbol{ \begin{cases} y_1 &=~ 3(x_1 + x_2) \\ y_2 & = -x_1 \end{cases} }{y1​y2​​= 3(x1​+x2​)=−x1​​

133 - FML 3 - 18.1W e.g. 2.3

Determine whether the following transformation is linear:{y1= 1y2=1y3= 1\boldsymbol{ \begin{cases} y_1 &=~ 1 \\ y_2 & = 1 \\ y_3 &=~ 1 \end{cases} }⎩⎨⎧​y1​y2​y3​​= 1=1= 1​

133 - FML 3 - 18.1W e.g. 2.2

Determine whether the following transformation is linear:{y1= x1y2=x1x2\boldsymbol{ \begin{cases} y_1 &=~ x_1 \\ y_2 & = x_1x_2 \end{cases} }{y1​y2​​= x1​=x1​x2​​

133 - FML 3 - 18.1W e.g. 2.1

Determine whether the following transformation is linear:{y1= x3y2= x3y3= x3\boldsymbol{ \begin{cases} y_1 &=~ x_3 \\ y_2 & = ~x_3 \\ y_3 &=~ x_3 \end{cases} }⎩⎨⎧​y1​y2​y3​​= x3​= x3​= x3​​

Linear Transformations

Practice: Identifying Non-Linear Transformations
Select all of the following transformations that are non-linear.

Linear Transformations

Practice: Linear Transformations
Suppose T:R2→R3T:\mathbb{R}^2\to\mathbb{R}^3T:R2→R3 is a linear transformation where
T[25]=[123],T[38]=[−101]T\begin{bmatrix}2\\5\end{bmatrix}=\begin{bmatrix}1\\2\\3\end{bmatrix},\quad T\begin{bmatrix}3\\8\end{bmatrix}=\begin{bmatrix}-1\\0\\1\end{bmatrix}T[25​]=​123​​,T[38​]=​−101​​.

Let L:R3⟶R2L:\mathbb{R}^3\longrightarrow\mathbb{R}^2L:R3⟶R2 be defined by:
L((x,y,z))=(x+2y+3z,−x+2y+5z)L\big((x,y,z)\big)=(x+2y+3z,-x+2y+5z)L((x,y,z))=(x+2y+3z,−x+2y+5z)
(a) Prove that LLL is a linear transformation

Define the vector space V={(x,y,z)  ∣  x,y,z>0}V=\{(x,y,z)\;|\;x,y,z>0\}V={(x,y,z)∣x,y,z>0} with the operations:
(x1,y1,z1)+(x2,y2,z2)=(x1x2,y1y2,z1+z2)(x_1,y_1,z_1)+(x_2,y_2,z_2)=(x_1x_2,y_1y_2,\textcolor{red}{z_1+z_2})(x1​,y1​,z1​)+(x2​,y2​,z2​)=(x1​x2​,y1​y2​,z1​+z2​)
k⋅(x,y,z)=(xk,yk,kz)k\cdot(x,y,z)=(x^k,y^k,\textcolor{red}{kz})k⋅(x,y,z)=(xk,yk,kz)

Let LLL be the linear transformation such that L(v→)=Av→L(\overrightarrow{v})=A\overrightarrow{v}L(v)=Av where:
A=[111−10201021−1]A=\left[\begin{array}{rrr}
1&1&1\\[0.5em]
-1&0&2\\[0.5em]
0&1&0\\[0.5em]
2&1&-1\\
\end{array}\right]A=​1−102​1011​120−1​​
Find the rule that defines LLL including the domain and co-domain vector spaces

Introduction to Transformations

Practice: Linear Transformations

Suppose T:R2→R3T:\mathbb{R}^2\to\mathbb{R}^3T:R2→R3 is a linear transformation and
T[25]=[123],T[38]=[−101]T\begin{bmatrix}2\\5\end{bmatrix}=\begin{bmatrix}1\\2\\3\end{bmatrix},\quad T\begin{bmatrix}3\\8\end{bmatrix}=\begin{bmatrix}-1\\0\\1\end{bmatrix}T[25​]=​123​​,T[38​]=​−101​​
Find the matrix of this linear transformation.

Linear Transformations

Given that S:R2→R2S:\mathbb{R}^2 \to \mathbb{R}^2S:R2→R2and T:R2→R2T:\mathbb{R}^2 \to \mathbb{R}^2T:R2→R2such that 
S[35]=[1−1],S[3−1]=[25]S\begin{bmatrix}3\\5\end{bmatrix}=\begin{bmatrix}1\\-1\end{bmatrix}, \quad S\begin{bmatrix}3\\-1\end{bmatrix}=\begin{bmatrix}2\\5\end{bmatrix}S[35​]=[1−1​],S[3−1​]=[25​]and T[2−2]=[10],T[11]=[25]T\begin{bmatrix}2\\-2\end{bmatrix}=\begin{bmatrix}1\\0\end{bmatrix}, \quad T\begin{bmatrix}1\\1\end{bmatrix}=\begin{bmatrix}2\\5\end{bmatrix}T[2−2​]=[10​],T[11​]=[25​]
Find S∘T[3−1]S \circ T\begin{bmatrix}3\\-1\end{bmatrix}S∘T[3−1​]

Matrix Multiplication

Find a 3 × 3 matrix M such that 
  ⁣M ⁣‾  [   0−2   0]=[−1   1−1] ⁣,  ⁣M ⁣‾  [0018]=[   0−2   3] ⁣,and  ⁣M ⁣‾  [1300]=[−2   2−1]\bcb{
\M\begin{bmatrix}
\ \ \ 0\\-2\\\ \ \ 0
\end{bmatrix}=
\begin{bmatrix}
-1\\\ \ \ 1\\-1
\end{bmatrix}\!, \hspace{0.7cm}

\M\begin{bmatrix}
0\\0\\\tfrac{1}{8}
\end{bmatrix}=
\begin{bmatrix}
\ \ \ 0\\-2\\\ \ \ 3
\end{bmatrix}\!, \hspace{0.5cm} \text{\small{and}}\hspace{0.5cm} 

\M\begin{bmatrix}
\tfrac{1}{3}\\0\\0
\end{bmatrix}=
\begin{bmatrix}
-2\\\ \ \ 2\\-1
\end{bmatrix}
}M​​   0−2   0​​=​−1   1−1​​,M​​0081​​​=​   0−2   3​​,andM​​31​00​​=​−2   2−1​​

Matrix of a Projection

a) Find the matrix AAA so that for x⃗∈R3\vec x \in \mathbb{R}^3x∈R3 the transformation mapping x⃗→proj(−13,1,12)x⃗\vec x\rightarrow proj_{(\frac{-1}{3},1,\frac{1}{2})}\vec xx→proj(3−1​,1,21​)​x is the same as the transformation mapping  x⃗→Ax⃗\vec x\rightarrow A\vec xx→Ax 
b) What is rank(A)rank(A)rank(A) ?

Matrix Multiplication

e.g. Find a 3 × 3 matrix M such that 
 ⁣M[   0−2   0]=[−1   1−1] ⁣, ⁣M[000]=[   0−2   3] ⁣,and M[1300]=[−2   2−1]\!M\begin{bmatrix}
\ \ \ 0\\-2\\\ \ \ 0
\end{bmatrix}=
\begin{bmatrix}
-1\\\ \ \ 1\\-1
\end{bmatrix}\!, \hspace{0.7cm}

\!M\begin{bmatrix}
0\\0\\0
\end{bmatrix}=
\begin{bmatrix}
\ \ \ 0\\-2\\\ \ \ 3
\end{bmatrix}\!, \hspace{0.7cm} \text{\small{and}}\ 

M\begin{bmatrix}
\frac{1}{3}\\0\\0
\end{bmatrix}=
\begin{bmatrix}
-2\\\ \ \ 2\\-1
\end{bmatrix}M​   0−2   0​​=​−1   1−1​​,M​000​​=​   0−2   3​​,and M​31​00​​=​−2   2−1​​

Projection onto a subspace

Suppose u⃗,v⃗∈Rn\vec u,\vec v\in\mathbb{R}^nu,v∈Rn satisfy u⃗⋅v⃗=0,∣∣u⃗∣∣=∣∣v⃗∣∣=1\vec u\cdot\vec v=0, ||\vec u||=||\vec v||=1u⋅v=0,∣∣u∣∣=∣∣v∣∣=1, and define U:=span{u⃗,v⃗}U := span\{\vec u,\vec v\}U:=span{u,v} .  
Using the definition that projUx⃗=A(ATA)−1ATx⃗proj_U\vec x=A(A^TA)^{-1}A^T\vec xprojU​x=A(ATA)−1ATx , where A=[u⃗v⃗]A=\left[\begin{array}{rr}\vec u&\vec v\end{array}\right]A=[u​v​] , show that for all x⃗∈Rn\vec x\in\mathbb{R}^nx∈Rn we have that projUx⃗=proju⃗x⃗+projv⃗x⃗proj_U\vec x=proj_{\vec u}\vec x+proj_{\vec v}\vec xprojU​x=proju​x+projv​x .

Given the following matrix, what can you conclude? A = 1 0 -2 1 5 1

Related Topics

Linear Transformations

More Linear Transformations Questions:

Determine if a transformation is linear

Matrix of a Linear Transformation

Find the matrix of a given transformation

Finding Non-linear Transformation

Example: Finding the Linear Transformation Matrix

Finding Non-linear Transformation

Is the given transformation linear?

Practice Question: Linear and Non-Linear Maps

19.4F_Mid_Builder_$\tkcth{8.4.}\tkcf{15}$_$\tkco{Mock 3}$.

Find the matrix of a given transformation

19.4F_Mid_Builder_$\tkcth{8.4.}\tkcf{14}$_

133 - FML 3 - 18.1W - e.g. 34

19.4F_Mid_Builder_$\tkcth{8.5.}\tkco{5}$__$\tkco{Mock 3}$

Properties

Concept Clarifier

133 - FML 3 - 18.1W e.g. 2.3

133 - FML 3 - 18.1W e.g. 2.3

133 - FML 3 - 18.1W e.g. 2.2

133 - FML 3 - 18.1W e.g. 2.1

Linear Transformations

Linear Transformations

Introduction to Transformations

Practice: Linear Transformations

Linear Transformations

Matrix Multiplication

Matrix of a Projection

Matrix Multiplication

Projection onto a subspace