het T:V W be an isomorphism. Prove That ir & w, wg... ... on} is Set in wel, then the premages of dwe, log... an} a linearly Independent set knearly Independent 19
Let T :V → W be an isomorphism. Prove that if {ū1, ū2, ..., ūn} is a linearly independent set in W, then the preimages of {ū1, ū2, ... , ūn} is a linearly independent set in V.
Let T:V→WT:V→W be an isomorphism. Prove that if {w⃗ 1,w⃗ 2,…,w⃗ n}{w→1,w→2,…,w→n} is a linearly independent set in WW, then the preimages of {w⃗ 1,w⃗ 2,…,w⃗ n}{w→1,w→2,…,w→n} is a linearly independent set in VV.
suppose that s=(v1,v2,......vm) is a finite set of linearly independent vectors in V, and w ∈ V some other vector. Let T= S ∪ (W). Prove that T is not linearly independent if and only if w∈ span(s).
5. Let ui, . . . ,Um, w V. Prove that vi, . . . , tầm, w s linearly independent if and only if vi . . .tầm is linearly independent and w f span(vi,...Vm).
Let V and W be vector spaces over F, and let f: V W be a linear transformation. (a) Prove that f is one-to-one if and only if f carries linearly independent (b) Suppose that f is one-to-one and that S is a subset of V. Prove that subsets of V to linearlv independent subsets of W S is linearly independent if and only if (S) is linearly independent.
Let T: V + W be a linear transformation. Assume that T is one-to-one. Prove that if {V1, V2, V3} C V is a linearly independent subset of V, then {T(01), T(v2), T(13)} C W is a linearly independent subset of W.
Please give answer with the details. Thanks a lot! Let T: V-W be a linear transformation between vector spaces V and W (1) Prove that if T is injective (one-to-one) and {vi,.. ., vm) is a linearly independent subset of V the n {T(6),…,T(ền)} is a linearly independent subset of W (2) Prove that if the image of any linearly independent subset of V is linearly independent then Tis injective. (3) Suppose that {b1,... bkbk+1,. . . ,b,) is a...
Problem 6. Let V be a vector space (a) Let (--) : V x V --> R be an inner product. Prove that (-, -) is a bilinear form on V. (b) Let B = (1, ... ,T,) be a basis of V. Prove that there exists a unique inner product on V making Borthonormal. (c) Let (V) be the set of all inner products on V. By part (a), J(V) C B(V). Is J(V) a vector subspace of B(V)?...