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5. Let V and W be finite dimensional vector spaces. Let T: VW be a linear transformation. transformation T = Iv. Then there exists a linear U: W → V such that U o 6. Let V be a vector space and S be a non- empty subset of V. Then span(span(S)) = span(S).

7. Let V and W be vector spaces and T, U: V → W be linear transformations. Then Z:= {ve V: T(v) = U(v)} is a subspace of V. 8. Let S = {V1, V2, V3, V4, V5} C P₂ (R) such that span (S) = P₂(R). Then there exists a subset of S which is a basis for P₂ (R). 9. There exists a vector space V and a linear transformation T: V → V such that T is surjective but not injective. 10. Let V and W be finite dimensional vector spaces, B = {v₁, ..., Vn} be a basis for V, and T V W be an injective linear transformation. Then {T(v₁), ..., T(vn)} is a basis for W.