Let V be a finite dimensional space over R, with a positive definite scalar product. Let...

Let V be a finite dimensional vector space over R with an inner product 〈x, y〉...

Let V be a finite dimensional vector space over R with an inner product 〈x, y〉 ∈ R for x, y ∈ V . (a) (3points) Let λ∈R with λ>0. Show that 〈x,y〉′ = λ〈x,y〉, for x,y ∈ V, (b) (2 points) Let T : V → V be a linear operator, such that 〈T(x),T(y)〉 = 〈x,y〉, for all x,y ∈ V. Show that T is one-to-one. (c) (2 points) Recall that the norm of a vector x ∈ V...

Suppose that V is a finite dimensional inner product space over C and dim V =...

Suppose that V is a finite dimensional inner product space over C and dim V = n, let T be a normal linear transformation of V If S is a linear transformation of V and T has n distinc eigenvalues such that ST=TS. Prove S is normal.

Let V be a finite-dimensional vector space and let T be a linear map in L(V,...

Let V be a finite-dimensional vector space and let T be a linear map in L(V, V ). Suppose that dim(range(T 2 )) = dim(range(T)). Prove that the range and null space of T have only the zero vector in common

(3) Let V be a finite dimensional vector space, and let T: V® V be a...

(3) Let V be a finite dimensional vector space, and let T: V® V be a linear transformation such that rk(T) = rk(T2). a) Show that ker(T) = ker(T2). b) Show that 0 is the only vector that lies in both the null space of T, and the range space of T

Let V be a finite-dimensional vector space over C and T in L(V) be an invertible...

Let V be a finite-dimensional vector space over C and T in L(V) be an invertible operator in V. Suppose also that T=SR is the polar decomposition of T where S is the correspondIng isometry and R=(T*T)^1/2 is the unique positive square root of T*T. Prove that R is an invertible operator that committees with T, that is TR-RT.

Let T:V→V be an endomorphism of a finite dimensional vector space over the field Z/pZ with...

Let T:V→V be an endomorphism of a finite dimensional vector space over the field Z/pZ with p elements, satisfying the equation Tp=T. Show that T is diagonalisable.

Let (V, C) be a finite-dimensional complex inner product space. We recall that a map T...

Let (V, C) be a finite-dimensional complex inner product space. We recall that a map T : V → V is said to be normal if T∗ ◦ T = T ◦ T∗ . 1. Show that if T is normal, then |T∗(v)| = |T(v)| for all vectors v ∈ V. 2. Let T be normal. Show that if v is an eigenvector of T relative to the eigenvalue λ, then it is also an eigenvector of T∗ relative to...

Let V be a vector space: d) Suppose that V is finite-dimensional, and let S be...

Let V be a vector space: d) Suppose that V is finite-dimensional, and let S be a set of inner products on V that is (when viewed as a subset of B(V)) linearly independent. Prove that S must be finite e) Exhibit an infinite linearly independent set of inner products on R(x), the vector space of all polynomials with real coefficients.

Suppose that V is finite-dimensional, U ⊂ V is a subspace, and S : U →...

Suppose that V is finite-dimensional, U ⊂ V is a subspace, and S : U → W is a linear map. Show that there exists a linear map T : V → W such that T u = Su for every u ∈ U.

Let f be a non-degenerate form on a finite-dimensional space V. Show that each linear operator...

Let f be a non-degenerate form on a finite-dimensional space V. Show that each linear operator S has an adjoint relative to f.