Q₁/(a) Let S and T be subsets of a vector space X over a field F such that SCT,showthat whether (1) if S generate X then T generate X or not. (2) if T generate Xthen S generate X or not.(b) Let X be a vector space over a field F and A,B are subsets of X such that A isconvex set and B is affine set, show that whether AnB is convex set or not,and if f be a function from X into a space Y then f(B) is an affine set or not./(a) Let M and N be two hyperspaces of a space X write a condition to proveMUN is a hyperspace of X and condition to get that MUN is not hyperspace of X.Write with proveapplicationn Panach theorem

Q1/(b) Convex and Affine Sets(1) A ∩ B is a convex set.Yes, A ∩ B is a convex set.Proof: * Let…

Answered: Q₁/(a) Let S and T be subsets of a…

Elementary Linear Algebra (MindTap Course List)

8th Edition

ISBN:9781305658004

Author:Ron Larson

Publisher:Ron Larson

Chapter5: Inner Product Spaces

Section5.CR: Review Exercises

Problem 47CR: Find an orthonormal basis for the subspace of Euclidean 3 space below. W={(x1,x2,x3):x1+x2+x3=0}

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Similar questions

Find an orthonormal basis for the subspace of Euclidean 3 space below. W={(x1,x2,x3):x1+x2+x3=0}
Let V be the set of all positive real numbers. Determine whether V is a vector space with the operations shown below. x+y=xyAddition cx=xcScalar multiplication If it is, verify each vector space axiom; if it is not, state all vector space axioms that fail.
Determine whether the set R2 with the operations (x1,y1)+(x2,y2)=(x1x2,y1y2) and c(x1,y1)=(cx1,cy1) is a vector space. If it is, verify each vector space axiom; if it is not, state all vector space axioms that fail.
Find a basis for R2 that includes the vector (2,2).
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Let (x, y, z) be Scalar Pield and F a vector field.. $ Derive expression for D. (OF) and * (OF) in terms of operations applied to $(x,y, Z_) and F
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(1) Let M and N be non-empty subsets of a linear space X, show that whether = U or not, and show that there whether exsits a liear function from P₂(x) into R' which onto but not one-to-one or not. ام (2) Let R be a field of real numbers and P,(x)=(a+bx+cx? / a,b,ce R} be a vector space over R, show that whether there exsit two hyperspaces A and B such that AUB is a hyperspace or not. (3) Let A be an affine set in a linear space X over afield F and tEA, show that A-t is a subspace of Xand show that if M and N are balanced sets then M+N is balanced set. (4) Write the definition of bounded set in a normed space, and write with prove an equivalent statement to definition. (5) Let d be a metric on a linear space X over a field F, write conditions on d in order to get that there is a norm on X induced dy d and prove that. (6) Let M be a non-empty subset of a normed space X, show that xEcl(M) iff for any r>o there exsits yEM such that llx-yll
1) Let V be the set of all ordered pairs (x, y) of real numbers and F be the field of real numbers. Define (x, y) + (X1, y2) = (3y + 3 yı, -x - x1) and c[x, y) = (3cy, -cx). Verify that V, with these operations, is not a vector space over the field of real numbers.
For all differentiable vector fields v(r) and w(r), use index notation to show that v × (▼ × w) + w × (▼ × v) = ▼ (v · w) — (v · ▼ )w – (w · V)v. x
2. Let V be the set R regarded as a vector space over the field Q with the usual operations. Show that the set {², k = 0, 1, 2, ...} CV is linearly independent. You may use without proof that is a transcendental number.
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