Please do Part (i). Feel free to do Part (ii). The last time I posted this question, it wasn't answered properly, and got it wrong.
2. Consider the inner product space V = P2(R) with (5,9) = L5(0956 f(t)g(t) dt, and let T:V → V be the linear operator define
Please do Part (i). Feel free to do Part (ii). The last time I posted this...
Please do Part (ii). Feel free to do Part (i). Be careful, because the last time I submitted this question, the answers were wrong. 2. Consider the inner product space V = P2(R) with (5,9) = L5(0956 f(t)g(t) dt, and let T:V → V be the linear operator defined by T(f) = xf'(x) +2f(x). (i) Compute T*(1++r). (ii) Determine whether or not there is an orthonormal basis of eigenvectors B for which [T]3 is diagonal. If such a basis exists,...
Please do Part (ii). Feel free to do Part (i). 2. Consider the inner product space V = P2(R) with (5,9) = L5(0956 f(t)g(t) dt, and let T:V → V be the linear operator defined by T(f) = xf'(x) +2f(x). (i) Compute T*(1++r). (ii) Determine whether or not there is an orthonormal basis of eigenvectors B for which [T]3 is diagonal. If such a basis exists, find one.
Please do Part (i). Feel free to do Part (ii). 2. Consider the inner product space V = P2(R) with (5,9) = L5(0956 f(t)g(t) dt, and let T:V → V be the linear operator defined by T(f) = xf'(x) +2f(x). (i) Compute T*(1++r). (ii) Determine whether or not there is an orthonormal basis of eigenvectors B for which [T]3 is diagonal. If such a basis exists, find one.
2. Consider the inner product space V = P2(R) with (5,9) = . - f(t)g(t) dt, and let T:V + V be the linear operator defined by T(F) = xf'(x) + 2f (x). (i) Compute T*(1 + x + x2). (ii) Determine whether or not there is an orthonormal basis of eigenvectors ß for which [T]2 is diagonal. If such a basis exists, find one.
Please do Part (ii). If you'd like to do the first part as well, feel free to. 3. Consider the inner product space V = M2x2(C) with the Frobenius inner product, and let T:V + V be the linear operator defined by T(A) =) A. (i) Compute 1 T* ((1+1 :)) (ii) Determine whether or not there is an orthonormal basis of eigenvectors B for which [T], is diagonal. If such a basis exists, find one.
2. Consider the inner product space V = P2(R) with (5.9) = £ 5(0)9(e) dt, and let T:V V be the linear operator defined by T(f) = xf'(2) +2f(x). (i) Compute T*(1+2+x²). (ii) Determine whether or not there is an orthonormal basis of eigenvectors 8 for which [T], is diagonal. If such a basis exists, find one.
Please do Part (i). If you'd like to do the second part as well, feel free to. 3. Consider the inner product space V = M2x2(C) with the Frobenius inner product, and let T:V + V be the linear operator defined by T(A) =) A. (i) Compute 1 T* ((1+1 :)) (ii) Determine whether or not there is an orthonormal basis of eigenvectors B for which [T], is diagonal. If such a basis exists, find one.
Consider the inner product space V = P2(R) with (5,9) = { $(0)g(t) dt, and let T:VV be the linear operator defined by T(f) = x f'(x) +2f (x) +1. (i) Compute T*(1 + x + x2). (ii) Determine whether or not there is an orthonormal basis of eigenvectors ß for which [T]k is diagonal. If such a basis exists, find one.
this is all information was given, what do you need more? 2. Consider the inner product space V = P,(R) with (5.91 = 5(0)g(t) dt, and let T: VV be the linear operator defined by T(f) = xf'(x) +2f(x). (1) Compute T*(1+2+x2). (ii) Determine whether or not there is an orthonormal basis of eigenvectors 8 for which [T], is diagonal. If such a basis exists, find one.
Can I get some help please? Thanks in advance 2. Consider the inner product space V = P2(R) with 0.9) = (()() dt, and let T:V V be the linear operator defined by T(S) = rf'(:r) + 2(r). (i) Compute T*(1 + 1 + x²). (ii) Determine whether or not there is an orthonormal basis of eigenvectors B for which T]s is diagonal. If such a basis exists, find one.