Span

4 Activities

Select all of the vectors that are in Span(u⃗,v⃗)\text{Span}(\vec u, \vec v)Span(u,v) where u⃗=(−1,1,2),v⃗=(2,1,−3)\vec u=(-1,1,2), \vec v=(2,1,-3)u=(−1,1,2),v=(2,1,−3)

Practice: Span

Show that for all w⃗,x⃗,y⃗,z⃗∈Rn\vec w,\vec x,\vec y, \vec z\in\mathbb{R}^nw,x,y​,z∈Rn , if w⃗∈Span{x⃗,y⃗,z⃗}\vec w\in Span\{\vec x, \vec y, \vec z\}w∈Span{x,y​,z} then w⃗∈Span{x⃗−y⃗,y⃗−z⃗,z⃗}\vec w\in Span\{\vec x-\vec y, \vec y-\vec z,\vec z\}w∈Span{x−y​,y​−z,z} .

When is a Vector in the Span of Others

Determine if x⃗=(16,−15,8)∈Span{u⃗,v⃗,w⃗}\vec x=(16,-15, 8) \in \text{Span}\{\vec u, \vec v, \vec w\}x=(16,−15,8)∈Span{u,v,w} if:
u⃗=(1,1,1),v⃗=(1,1,0),w⃗=(1,0,−1)\vec u = (1,1,1), \vec v = (1,1,0), \vec w =(1,0,-1)u=(1,1,1),v=(1,1,0),w=(1,0,−1)

Span

Practice: Span
Let u⃗=⟨1,0,1⟩, v⃗=⟨1,1,1⟩, w⃗=⟨1,−1,1⟩\vec u = \lang 1,0,1\rang,\ 
\vec v = \lang 1,1,1\rang,\ 
\vec w = \lang 1,-1,1 \rangu=⟨1,0,1⟩, v=⟨1,1,1⟩, w=⟨1,−1,1⟩ be vectors in R3\reals^3R3, and suppose b⃗=⟨3,y,z⟩∈span({u⃗,v⃗,w⃗})\vec b = \lang 3,y,z \rang \in \text{span}(\{\vec u, \vec v, \vec w\})b=⟨3,y,z⟩∈span({u,v,w}).
Find the value of zzz.

Practice: Span

Let u⃗=(2,2,1),v⃗=(2,1,2),w⃗=(2,5,−2),x⃗=(x,y,z)\vec u = (2,2,1), \vec v = (2,1,2), \vec w = (2,5,-2), \vec x = (x,y,z)u=(2,2,1),v=(2,1,2),w=(2,5,−2),x=(x,y,z) be vectors in R3\mathbb{R}^3R3
Find the conditions that the values x,y,zx,y,zx,y,z must satisfy in order for x⃗\vec xx to be in Span({u⃗,v⃗,w⃗})\text{Span}(\{\vec u, \vec v, \vec w\})Span({u,v,w})

Span

Practice: Span
Let u⃗=⟨1,0,1⟩, v⃗=⟨1,1,1⟩, w⃗=⟨1,−1,1⟩\vec u = \lang 1,0,1\rang,\ 
\vec v = \lang 1,1,1\rang,\ 
\vec w = \lang 1,-1,1 \rangu=⟨1,0,1⟩, v=⟨1,1,1⟩, w=⟨1,−1,1⟩ be vectors in R3\reals^3R3, and suppose b⃗=⟨3,y,z⟩∈span({u⃗,v⃗,w⃗})\vec b = \lang 3,y,z \rang \in \text{span}(\{\vec u, \vec v, \vec w\})b=⟨3,y,z⟩∈span({u,v,w}).
Find the value of zzz.

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)}?

133 - FML 3 - 18.1W - e.g. 31

Knowing that 
				[06330−7151−113]→RREF[100010001000]\bcb{\begin{bmatrix}%[c]
					 0 & 6 & 3 \\
					 3 & 0 & -7 \\
					 1 & 5 & 1 \\
					 -1 & 1 & 3
				 \end{bmatrix}
				 %
				 	\xrightarrow{\text{{\tiny RREF}}}
				 %
				 \begin{bmatrix}
				 	1 & 0 & 0 \\
				 	0 & 1 & 0 \\
				 	0 & 0 & 1 \\
				 	0 & 0 & 0
				 \end{bmatrix}}​031−1​6051​3−713​​RREF​​1000​0100​0010​​,
determine whether the vector v⃗1=<0,3,1,−1>\bcb{\vec{v}_1 = \big< 0,3,1,-1\big>}v1​=⟨0,3,1,−1⟩ is in the span of the vectors v⃗2=<6,0,5,1>\bcb{\vec{v}_2 = \big< 6,0,5,1\big>}v2​=⟨6,0,5,1⟩ and v⃗3=<3,−7,1,3>\bcb{\vec{v}_3 = \big< 3,-7,1,3\big>}v3​=⟨3,−7,1,3⟩.

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​ .

19.4F_Final_Builder_Ch_4.6_Span_Line_From_FAQ_$\tkco{eg}$_$\key{Final}$_Builder_$\tkcth{4.6.}\tkcf{6}$_$\key{|Strc>5.2}$

Describe the set of all linear combinations (sums of constant multiples of) the vectors:
   v⃗=[111]\vv = \colvecth{1}{1}{1}v=​111​​  and  w⃗=[−121]\vw = \colvecth{-1}{2}{1}w=​−121​​. 

133 - FML 3 - 18.1W - e.g. 30

Given the standard basis vectors for R2\bcb{\mathbb{R}^{2}}R2, viz. ı^\bcb{\ihat}^ and ȷ^\bcb{\jhat}^​ and the vector u⃗=[02]\bcb{\vec{u} = \begin{bmatrix} 0 \\ 2 \end{bmatrix}}u=[02​], determine whether ı^\bcb{\ihat}^ is in the span ⁣{u⃗,ȷ^}\bcb{
\vspan{\vec{u}, \jhat} }span{u,^​}.
Briefly justify your answer. 

Let (V,+,⋅)(V, +, \cdot)(V,+,⋅) be a real vector space. If v1,…,vnv_1, \dots, v_nv1​,…,vn​ is a set of vectors that spans the entirety of VVV , prove that the following set of vectors also spans VVV .
v1−v2,v2−v3,…,vn−1−vn,vnv_1 - v_2, v_2 - v_3, \dots, v_{n - 1} - v_n, v_nv1​−v2​,v2​−v3​,…,vn−1​−vn​,vn​

19.4F_Final_Builder_Ch_4.6_Span_Line_From_FAQ_$\tkco{eg}$_$\key{Final}$_Builder_$\tkcth{4.6.}\tkcf{4}$_$\key{|Strc>5.2}$

Describe the set of all constant multiples of the vector:
  v⃗=[−121]\vv = \colvecth{-1}{2}{1}v=​−121​​. 

19.4F_Final_Builder_Ch_4.6_Span_Line_From_FAQ_$\tkco{eg}$_$\key{Final}$_Builder_$\tkcth{4.6.}\tkcf{2}$_$\key{|Strc>5.2}$

Describe the set of all constant multiples of the vector v⃗=[11]\vv = \colvec{1}{1}v=[11​]. 

Practice Question: Arbitrary Vector as Linear Combination

Show that every vector in R2\mathbb{R}^2R2 is a linear combination of (1,−1)(1,-1)(1,−1) and (2,1)(2,1)(2,1) .

Arbitrary Vector as Linear Combination

Show every vector in R3\mathbb{R}^3R3 is a combination of (8,0,0),(0,1,1),(0,2,3)(8,0,0),(0,1,1),(0,2,3)(8,0,0),(0,1,1),(0,2,3).

Suppose that S=span([1−12],[−33−6],[121],[547])S=span\left(\begin{bmatrix}1\\-1\\2\end{bmatrix},\begin{bmatrix}-3\\3\\-6\end{bmatrix},\begin{bmatrix}1\\2\\1\end{bmatrix},\begin{bmatrix}5\\4\\7\end{bmatrix}\right)S=span​​1−12​​,​−33−6​​,​121​​,​547​​​   , which of the following statements is true?

Span

Related Topics

Span

More Span Questions:

Practice: Span

When is a Vector in the Span of Others

Span

Practice: Span

Span

Linear Independence and Span concepts

133 - FML 3 - 18.1W - e.g. 31

19.4F_Final_Builder_Ch_4.6_Span_Line_From_FAQ_$\tkco{eg}$_$\key{Final}$_Builder_$\tkcth{4.6.}\tkcf{6}$_$\key{|Strc>5.2}$

133 - FML 3 - 18.1W - e.g. 30

19.4F_Final_Builder_Ch_4.6_Span_Line_From_FAQ_$\tkco{eg}$_$\key{Final}$_Builder_$\tkcth{4.6.}\tkcf{4}$_$\key{|Strc>5.2}$

19.4F_Final_Builder_Ch_4.6_Span_Line_From_FAQ_$\tkco{eg}$_$\key{Final}$_Builder_$\tkcth{4.6.}\tkcf{2}$_$\key{|Strc>5.2}$

Practice Question: Arbitrary Vector as Linear Combination

Arbitrary Vector as Linear Combination