Determine which ones are linearly independent:

Linear Independence

4 Activities

Determine which ones are linearly independent:

1. {[100],[101],[111]}\left\{\begin{bmatrix}
1\\0\\0
\end{bmatrix},\begin{bmatrix}
1\\0\\1
\end{bmatrix},\begin{bmatrix}
1\\1\\1
\end{bmatrix}\right\}⎩⎨⎧​​100​​,​101​​,​111​​⎭⎬⎫​

2. {[−230],[5−15]}\left\{\begin{bmatrix}
-2\\3\\0
\end{bmatrix},\begin{bmatrix}
5\\-1\\5
\end{bmatrix}\right\}⎩⎨⎧​​−230​​,​5−15​​⎭⎬⎫​

3. {[52],[27],[14],[−17]}\left\{\begin{bmatrix}
5\\2\\
\end{bmatrix},\begin{bmatrix}
2\\7\\
\end{bmatrix},\begin{bmatrix}
1\\4\\
\end{bmatrix},\begin{bmatrix}
-1\\7\\
\end{bmatrix}\right\}{[52​],[27​],[14​],[−17​]}

I don't know

Linearly independent vectors

Determine variable x such that 𝒖 = (1,1,1) ,𝒗 = (3,2,1) and 𝒘 = (𝑥, 0,1) are linearly dependent.

Linearly independent vectors

Determine variable x such that 𝒖 = (1,1,1) ,𝒗 = (3,2,1) and 𝒘 = (𝑥, 0,1) are linearly dependent.

Determine r and s such that (1,-1,4,1), (-1,1,0,0) and (2,r,s,3) are linearly dependent.

Linearly independent vectors

Is this set of vectors {[1 3], [2,-2]} linearly independent?   Write [4,-2] as  a linear combination of this set.

Linear Independence

Example: Linear Independence
Let u⃗=[40−2]\vec u =
\begin{bmatrix}
  4\\ 0\\ -2\\
\end{bmatrix}
u=​40−2​​, v⃗=[137]\vec v=
\begin{bmatrix}
  1\\ 3\\ 7\\
\end{bmatrix}v=​137​​, and w⃗=[335]\vec w = 
\begin{bmatrix}
  3\\ 3\\ 5\\
\end{bmatrix}w=​335​​.
Determine if the set {u⃗,v⃗,w⃗}\{\vec u, \vec v, \vec w\}{u,v,w} is linearly independent.

Practice Question: Linear Independence

Use the definition of linear independence to show that the vectors (1,0,3),(0,−1,0),(2,2,2)∈R3(1,0,3),(0,-1,0),(2,2,2) \in\mathbb{R}^3(1,0,3),(0,−1,0),(2,2,2)∈R3 are linearly independent.

Practice: Linear Independence

Show that if x⃗+z⃗,x⃗+3⃗z,y⃗+z⃗\vec x+\vec z, \vec x+\vec 3z, \vec y+\vec zx+z,x+3z,y​+z are linearly independent vectors in Rn\mathbb{R}^nRn then x⃗,y⃗,z⃗\vec x,\vec y,\vec zx,y​,z  are also linearly independent vectors in Rn\mathbb{R}^nRn  .

Practice Question: Linear Independence

Use the definition of linear independence to show that the vectors (1,0,3),(0,−1,0),(2,2,2)∈R3(1,0,3),(0,-1,0),(2,2,2) \in\mathbb{R}^3(1,0,3),(0,−1,0),(2,2,2)∈R3 are linearly independent

Linear Independence

Practice: Linear Independence
Let {v⃗1,v⃗2,v⃗3}\{\vec v_1,\vec v_2,\vec v_3\}{v1​,v2​,v3​} be a linearly independent set of vectors in a vector space VVV.
Define the following vectors in VVV, where k∈Rk \in \realsk∈R:

Practice: Linear Independence

Let u⃗=(−1,1,0,1)\vec u = (-1,1,0,1)u=(−1,1,0,1), v⃗=(1,0,−1,1)\vec v = (1,0,-1,1)v=(1,0,−1,1), and w⃗=(0,−1,1,−2)\vec w=(0,-1,1,-2)w=(0,−1,1,−2)
Determine if the set {u⃗,v⃗,w⃗}\{\vec u, \vec v, \vec w\}{u,v,w} is linearly independent

Practice: Linear Independence

Let {v⃗1,v⃗2,v⃗3}\{\vec v_1,\vec v_2,\vec v_3\}{v1​,v2​,v3​} be a linearly independent set of vectors in a vector space VVV
Now define the following vectors in VVV:
w⃗1=2v⃗2+kv⃗3w⃗2=v⃗1+kv⃗2w⃗3=kv⃗1−4v⃗3\vec w_1=2\vec v_2+k\vec v_3\qquad \vec w_2=\vec v_1+k\vec v_2 \qquad \vec w_3=k\vec v_1-4\vec v_3w1​=2v2​+kv3​w2​=v1​+kv2​w3​=kv1​−4v3​

Linear Independence

Practice: Linear Independence
Let {v⃗1,v⃗2,v⃗3}\{\vec v_1,\vec v_2,\vec v_3\}{v1​,v2​,v3​} be a linearly independent set of vectors in a vector space VVV.
Define the following vectors in VVV, where k∈Rk \in \realsk∈R:

Linear Independence and Span concepts

Which of the following statements are true about the set of vectors {(1,1,−1,0),(−1,3,−1,1),(2,0,−3,4)}\{(1,1,-1,0),(-1,3,-1,1),(2,0,-3,4)\}{(1,1,−1,0),(−1,3,−1,1),(2,0,−3,4)}?

Linear Independence

Example: Linear Independence
Let u⃗=(1,2,1)\vec u = (1,2,1)u=(1,2,1), v⃗=(1,3,2)\vec v=(1,3,2)v=(1,3,2), and w⃗=(7,17,a2+1)\vec w = (7,17,a^2+1)w=(7,17,a2+1).
Determine the value(s) of aaa that will make the set {u⃗,v⃗,w⃗}\{\vec u, \vec v, \vec w\}{u,v,w} linearly independent.

Linear Independence

Let u⃗=[40−2]\vec u =
\begin{bmatrix}
  4\\ 0\\ -2\\
\end{bmatrix}
u=​40−2​​, v⃗=[137]\vec v=
\begin{bmatrix}
  1\\ 3\\ 7\\
\end{bmatrix}v=​137​​, and w⃗=[335]\vec w = 
\begin{bmatrix}
  3\\ 3\\ 5\\
\end{bmatrix}w=​335​​.
Determine if the set {u⃗,v⃗,w⃗}\{\vec u, \vec v, \vec w\}{u,v,w} is linearly independent.

Consider the space of polynomials of degree 3 or lower, P3\mathcal{P}_3P3​ . Give an example of a linearly independent set of vectors whose span is the entirety of P3\mathcal{P}_3P3​ .

133 - FML 3 - 18.1W - e.g. 32

Show that the vectors v⃗1=(1,2,3,4)\bcb{\vec{v}_1 = (1,2,3,4)}v1​=(1,2,3,4), v⃗2=(0,1,0,−1)\bcb{\vec{v}_2 = (0,1,0,-1)}v2​=(0,1,0,−1), and v⃗3=(1,3,3,3)\bcb{\vec{v}_3 = (1,3,3,3)}v3​=(1,3,3,3) form a linearly dependent set, then express each vector as a linear combination of the other two.
v⃗1=\vv_1 = v1​= -1
 v⃗2\vv_2v2​ + 1 
v⃗3\vv_3v3​

v⃗2=\vv_2 = v2​= -1
 v⃗1\vv_1v1​ + 1 
v⃗3\vv_3v3​

Let our real vector space be (R3,+,⋅)(\mathbb{R}^3, +, \cdot)(R3,+,⋅) . Are the following set of vectors linearly independent? If not, write one of the vectors as as linear combination of the others.
(−134),(31−2),(1375),(121)\left ( \begin{array}{c}
-1\\3\\4
\end{array} \right ), \left ( \begin{array}{c}
3\\1\\-2
\end{array} \right ), \left ( \begin{array}{c}
13\\7\\5
\end{array} \right ), \left ( \begin{array}{c}
1\\2\\1
\end{array} \right )​−134​​,​31−2​​,​1375​​,​121​​

Let our real vector space be (R3,+,⋅)(\mathbb{R}^3, +, \cdot)(R3,+,⋅) . Are the following set of vectors linearly independent? If not, write one of the vectors as a linear combination of the others.
(123),(011),(−111)\left ( \begin{array}{c}
1\\2\\3
\end{array} \right ), \left ( \begin{array}{c}
0\\1\\1
\end{array} \right ), \left ( \begin{array}{c}
-1\\1\\1
\end{array} \right )​123​​,​011​​,​−111​​

133- 05.4F - Final - PartI Question#7

 For what values of α are the vectors (α,1,1)\bcb{(\alpha, 1, 1)}(α,1,1), (1,α,α)\bcb{(1, \alpha, \alpha)}(1,α,α) and (8,7,α)\bcb{(8, 7, \alpha) }(8,7,α)linearly dependent ? 

133- 05.4F - Final - PartII Question#3b

Suppose that the vectors {v1,v2,v3}\bcb{ \{v1, v2, v3\} }{v1,v2,v3} are linearly independent. 
If a1=4v1+2v2−2v3\bcb{a1 = 4v1 + 2v2 − 2v3}a1=4v1+2v2−2v3, a2=v1+3v2−v3\bcb{a2 = v1 + 3v2 − v3}a2=v1+3v2−v3, and a3=3v1−6v2\bcb{a3 = 3v1 − 6v2}a3=3v1−6v2, show that the vectors {a1, a2, a3} are not linearly independent. 

133- 05.4F - Final - PartII Question#3a

Suppose that the vectors {v1,v2,v3}\bcb{ \{v1, v2, v3\} }{v1,v2,v3} are linearly independent. 
If w1=v1−v2+v3\bcb{w1 = v1 − v2 + v3}w1=v1−v2+v3, w2=v1−v3\bcb{w2 = v1 − v3}w2=v1−v3, and w3=v1+v2+v3\bcb{w3 = v1 + v2 + v3}w3=v1+v2+v3, show that the vectors {w1,w2,w3}\bcb{ \{w1, w2, w3\}}{w1,w2,w3} are linearly independent. 

Determine r and s such that (1,-1,4,1), (-1,1,0,0) and (2,r,s,3) are linearly dependent.

Given that u⃗\vec{u}uand v⃗\vec{v}vare linearly independent, which of the following sets is also linearly independent?

Determine which ones are linearly independent:

Related Topics

Linear Independence

More Linear Independence Questions:

Linearly independent vectors

Linearly independent vectors

Linearly independent vectors

Linear Independence

Practice Question: Linear Independence

Practice: Linear Independence

Practice Question: Linear Independence

Linear Independence

Practice: Linear Independence

Practice: Linear Independence

Linear Independence

Linear Independence and Span concepts

Linear Independence

Linear Independence

133 - FML 3 - 18.1W - e.g. 32

133- 05.4F - Final - PartI Question#7

133- 05.4F - Final - PartII Question#3b

133- 05.4F - Final - PartII Question#3a