Homework for MATH 4330 in Fall 2024

Read your lecture notes and do
Sec 2.3: 1 and
watch the 61-minute video on companion matrices and rational canonical form (use the link provided or access it in the Modules section of our Canvas portal) and then do
H4. (a) Compute the companion matrix for the polynomial found in Question 2.3.1.
       (b) Compute the companion matrix of the characteristic polynomial of the matrix given in Question 2.1.11.
H5. (a) Suppose A and B are similar matrices. Show that A^k = 0 iff B^k = 0, where k ∊ ℕ.
       (b) Find the characteristic polynomial of the matrix A₄ given in H1.
       (c) Compute the companion matrix C of the polynomial found in (b).
       (d) Compute A₄² and C².
       (e) Use (a) and (d) to show that A₄ and C are NOT similar matrices.
       (H5(e) motivates using rational canonical form instead of C.)
H6. Find the rational canonical form of each of the following matrices:
       (a) the matrix A₄ given in H1 
       (b)
       (c)
       (d) the second matrix and the third matrix in Question 2.4.1.

See the information sheet in Canvas for Canvas Quiz 1.
Canvas Quiz 1 opens Sept 9; it is due Sept 22.

H9. Let A be the matrix
       (a) Find the Jordan canonical (normal) form J of A.
       (b) Find an invertible matrix P such that P^-1 A P = J.
       (c) Find the minimal polynomial of A and factor it.
H10. Let A be the matrix
       (a) Find the Jordan canonical (normal) form J of A.
       (b) Find an invertible matrix P such that P^-1 A P = J.
       (c) Find the minimal polynomial of A and factor it.
H11. Let A be the matrix
       (a) Find the Jordan canonical (normal) form J of A.
       (b) Find an invertible matrix P such that P^-1 A P = J.
       (c) Find the minimal polynomial of A and factor it.

If any of the mathematics does not display properly (e.g., an error message received), compare with this file.
Recall that a scan of the instructor’s lecture notes from Fall 2021 can be accessed via the Modules section of our Canvas portal.

Canvas Quiz 1 is due Sept 22.

H21. Suppose 𝔽 = ℂ and let T : ℂ³ → ℂ² be defined by
          .
        (a) Using the euclidean inner product on ℂ³ and ℂ², find a formula for T*: ℂ² → ℂ³.
        (b) Find the matrix of T and the matrix of T* with respect to the standard bases of ℂ² and ℂ³.
        (c) Compare your matrices in (b) with the first remark in the lecture on Section 3.2.
H22. Suppose 𝔽 = ℝ and let V denote the vector space of polynomials in the variable x of degree at most 1 with
         coefficients in ℝ and let T = d/dx : V→V. Using the IP        for all f, g ∊ V, find
         a formula for T*.
H23. Let V denote a finite-dimensional IPS. Suppose u₁, u₂ ∊ V. Let T : V → V be the linear map defined by
          T(v) = (v, u₁) u₂   for all v ∊ V. Find a formula for T*.
H24. Let V denote a finite-dimensional IPS. Let I denote the identity operator on V; that is I(v) = v for all v ∊ V.
          Justify that I* = I.
H25. Let T : ℝ² → ℝ be the linear map     Using the dot product for the
          IP on ℝ², find a vector u ∊ ℝ² such that (v, u) = T(v) for all v ∊ ℝ².
H26. Suppose 𝔽 = ℝ and let V denote the space of all polynomials in the variable x of degree at most 2 with
          coefficients in ℝ. View V as an IPS via        for all f, g ∊ V. Let T : V → ℝ be defined
          by     for all f ∊ V (where denotes the derivative of f with respect to x).
          Find u ∊ V such that   ( f , u ) = T( f )   for all f ∊ V.
          (Hint: find an orthonormal basis of V (e.g., see the lecture notes on Section 3.1) and see the proof of the
           claim in the lecture on Section 3.2.)
H27. (Optional) Let V denote the vector space of all infinite sequences v = (v₁, v₂, .…) where v_i ∊ 𝔽 for
          all i and v_i = 0 for all but finitely many i. Let e_i = (0,…, 0, 1, 0, ….) where the 1 occurs in the i’th position.
          View V as an IPS by using for all v, y ∊ V, where v = (v₁, v₂, .…), y = (y₁, y₂, .…).
          Let T : V → V denote the linear map for all
          v = (v₁, v₂, .…) ∊ V. (Optional: prove that T is a linear map.)
          (a) Verify that for all n ∊ ℕ.
          (b) Justify that the adjoint of T does not exist. (Hint: suppose T* does exist and show that
          T*(e_n) = (z₁, z₂, ….) where z_i ∊ 𝔽 for all i, but z_i is nonzero for infinitely many i (so T*(e_n) ∉ V).)

If any of the mathematics does not display properly (e.g., an error message received), compare with this file.
Recall that a scan of the instructor’s lecture notes from Fall 2021 can be accessed via the Modules section of our Canvas portal.

Canvas Quiz 1 is due Sept 22.
Test 1  will be 1 week from today; check Canvas for an information sheet.

          (a) 𝔽 = ℝ, V = ℝ², for all x, y ∊ ℝ.

          (b) 𝔽 = ℝ, V = ℝ³, for all x, y , z ∊ ℝ.

          (c) 𝔽 = ℂ, V = ℂ² , for all x, y ∊ ℂ,  where i² = –1.

          (d) 𝔽 = ℂ, V = ℂ² , for all x, y, z ∊ ℂ, where i² = –1.

If any of the mathematics does not display properly (e.g., an error message received), compare with this file.
Recall that a scan of the instructor’s lecture notes from Fall 2021 can be accessed via the Modules section of our Canvas portal.

If any of the mathematics does not display properly (e.g., an error message received), compare with this file.
Recall that a scan of the instructor’s lecture notes from Fall 2021 can be accessed via the Modules section of our Canvas portal.

         (a) Q : ℝ² → ℝ where for all x, y ∊ ℝ.

         (b) Q : ℝ³ → ℝ where   for all x, y, z ∊ ℝ.
H37. Suppose 𝔽 = ℝ. 
         (a)  Determine the quadratic form corresponding to the matrix .
         (a) Find the symmetric matrix corresponding to the quadratic form
              for all x₁,…, x₄ ∊ ℝ.

If any of the mathematics does not display properly (e.g., an error message received), compare with this file.
Recall that a scan of the instructor’s lecture notes from Fall 2021 can be accessed via the Modules section of our Canvas portal.

         (a) Verify that A is orthogonal with respect to the euclidean inner product on ℝ³.
         (b) Verify that the characteristic polynomial of A is   (x+1)(x²+1) = (x+1)(x+i)(x–i), where i² = –1.
         (c) Find the eigenspaces of A and verify that they are orthogonal with respect to the euclidean IP on ℂ³.
         (d) Find the new matrix that represents the linear map given by A with respect to the (reordered) standard
              basis B = {e₂, e₁, e₃} of ℝ³.
         (e) Compare the matrix in (d) with the last theorem of the lecture on Section 3.4.
         (f) Compare the basis vectors in B with the eigenvectors found in (c) (consider real and imaginary parts
              of the entries).

If any of the mathematics does not display properly (e.g., an error message received), compare with this file.
Recall that a scan of the instructor’s lecture notes from Fall 2021 can be accessed via the Modules section of our Canvas portal.

         (a) V = ℝ², for all x, y ∊ ℝ.
         (b) V = ℝ³, for all x, y, z ∊ ℝ.
         (c) V = the space of all 2×2 matrices with entries in ℝ, T(M) = the sum of the diagonal entries of M, for all
              M ∊ V.
         (d) V = the space of all 2×2 matrices with entries in ℝ, T(M) = the 22-entry of M, for all M ∊ V.
         (e) V = the space of all 2×2 matrices with entries in ℝ, T(M) = the determinant of M, for all M ∊ V.
H52. Let B denote the basis of ℝ³. Find the dual basis of relative to B.
H53. Suppose n ∊ ℕ and let B denote the basis {1, x, …, xⁿ} of the linear (vector) space V of all polynomials in x,
         with coefficients in ℝ, of degree at most n. Let for all p ∊ V, where p⁽⁰⁾ = p ,
          etc, and 0! = 1. Show that { } is the dual basis of relative to B.
H54. Suppose n ∊ ℕ and let V denote the vector space of all polynomials in a variable x, with coefficients in ℝ, of degree at most n.
         (a) If n = 2, show that {1, x-7, (x-7)²} is a basis of V.
         (b) If n = 2, find the dual basis of  relative to the basis in (a). (Hint: consider H53, but tweak it.)

If any of the mathematics does not display properly (e.g., an error message received), compare with this file.
Recall that a scan of the instructor’s lecture notes from Fall 2021 can be accessed via the Modules section of our Canvas portal.

Canvas Quiz 2 is due Nov 3.

H55. Let V denote a linear (vector) space (possibly of infinite dimension).
         (a) Show that T₁ + T₂ is a linear functional for all linear functionals T₁, T₂.
         (b) Show that kT is a linear functional for all linear functionals T, and for all k ∊ 𝔽.
H56. Let T : ℝ³ → ℝ² denote the linear map given by for all x, y, z ∊ ℝ.
         Let {φ₁, φ₂, φ₃} denote the dual basis of the standard basis of ℝ³ and let denote the dual basis of
         the standard basis of ℝ². Find   and   as linear combinations of φ₁, φ₂ and φ₃.
H57. Let V denote the linear (vector) space of all polynomials in x, with coefficients in ℝ, and let T : V → V
         denote the linear map given by   for all x ∊ ℝ, where denotes the
         2^nd derivative of p with respect to x.
         (a) Let φ ∊ be defined by   where denotes the derivative of p with respect to x.
               Find the linear functional    on V. 
         (b) Let φ ∊ be defined by  φ(p) =  for all p ∊ V. Find 
H58. Let V denote a linear (vector) space (possibly of infinite dimension).
         (a) Show that the dual map of the zero map on V is the zero map on .
         (b) Show that the dual map of the identity map on V is the identity map on
H59. Let V denote a linear (vector) space (possibly of infinite dimension). Suppose that T : V→ 𝔽 is a linear map.
         If T is not the zero map, explain why T(V) = 𝔽.

If any of the mathematics does not display properly (e.g., an error message received), compare with this file.
Recall that a scan of the instructor’s lecture notes from Fall 2021 can be accessed via the Modules section of our Canvas portal.

Canvas Quiz 2 is due Nov 3.
Test 2 will be 1 week from today; check Canvas for an information sheet.

=

         (a) Verify that U is a subspace of V and find a basis of U.
         (b) Find a basis B of V that contains the basis you found in (a).
         (c) Write explicitly with respect to the basis B from (b).
         (d) Find dim(V/U ).
         (e) Find a basis of V/U and justify it is indeed a basis.
H65. Refer to question H60.
         (a) Find dim(V).
         (b) Find dim(U).
         (c) Find dim(V/U).
         (d) Given your answer in (c), find a basis of V/U.
H66. Suppose 𝔽 = ℝ and let V = ℝ³, U = and T : V→V be given by A =
         with respect to the standard basis of V.
         (a) Verify that T(U) is contained in U.
         (b) Find a basis of V/U and find dim(V/U).
         (c) Find the matrix B of    with respect to the basis you found in (b).
         (d) Compare B with A; what do you notice?
H67. Suppose 𝔽 = ℝ and let V denote the linear space of all polynomials of degree at most three in the variable x
         with coefficients in ℝ. Let U denote the subspace of V consisting of all the constant polynomials in V, and let
         T = d/dx : V→V.
         (a) Verify that T(U) is contained in U.
         (b) Find the matrix A of T with respect to the basis  {1, x, x², x³}  of V.
         (c) Find the matrix B of the induced map    with respect to the basis
              {x + U,  x² + U,  x³ + U}  of  V/U.
         (d) Compare B with A; what do you notice?

If any of the mathematics does not display properly (e.g., an error message received), compare with this file.
Recall that a scan of the instructor’s lecture notes from Fall 2021 can be accessed via the Modules section of our Canvas portal.

Read your lecture notes and do
H68. Suppose that T : ℝ x ℝ² x ℝ³ → ℝ is a multilinear function (trilinear function) and that
         T (1, e₁, E₁) = 2, T (1, e₁, E₂) = 4, T (1, e₁, E₃) = –1,
         T (1, e₂, E₁) = –3, T (1, e₂, E₂) = 0, T (1, e₂, E₃) = 0,
         where e₁ = , e₂ = , E₁ = , E₂ = , E₃ = .
         (a) Find .          (b) Find .
H69. (a) Suppose that T : 𝔽 x 𝔽 x 𝔽 → 𝔽 is defined by T(a, b, c) = abc for all a, b, c ∊ 𝔽.
              Show that T is a trilinear function.
         (b) Let V₁ , …, V_k , W be linear (vector) spaces, and suppose V₁ = ··· = V_k . To say that a multilinear function
              T : V₁ x ··· x V_k → W is symmetric means that swapping any two distinct entries of the input preserves
              the output; that is, T(v₁, …, v_i ,….v_j ,…., v_k) = T(v₁, …, v_j ,…. v_i ,…., v_k) for all v_r ∊ V₁ for all r,
              where i < j. Show that the function T in (a) is symmetric.
H70. Let V₁ , …, V_k be linear (vector) spaces and let T_i : V_i → 𝔽 denote linear maps for i = 1, …, k. Let
         T : V₁ x ··· x V_k → 𝔽 be defined by  T(v₁, …, v_k) = T₁(v₁)T₂(v₂) ···T_k(v_k)  for all v_r ∊ V_r for all r.
         Show that T is a multilinear function.
H71. Let T : ℝ² x ℝ² → ℝ² be defined by for all x₁, x₂, y₁, y₂ ∊ ℝ.
         Verify that T is NOT a bilinear function.
H72. Let V₁ denote the linear (vector) space of all polynomials in x with coefficients in ℝ and
         let V₂ denote the linear (vector) space of all polynomials in y with coefficients in ℝ and
         let W denote the the linear (vector) space of all polynomials in the two variables x and y with coefficients
         in ℝ.
         (a) Show that the function T : V₁ x V₂ → W given by T(p, q) = pq , for all p ∊ V₁, q ∊ V₂, is a bilinear
               function.
         (b) For the function T in (a), show that x and y belong to the image of T, but x+y does not belong to the
               image of T.
         (c) Use (b) to show that the image of a multilinear function T : V₁ x ··· x V_k → W need not be a subspace
               of W if k ≥ 2.
H73. Let V₁ , …, V_k , W be linear (vector) spaces, and suppose V₁ = ··· = V_k . To say that a multilinear function
         T : V₁ x ··· x V_k → W is skew-symmetric means that swapping two distinct entries of the input multiplies the
         output by –1; that is,
         T(v₁, …, v_i ,….v_j ,…., v_k) = –T(v₁, …, v_j ,…. v_i ,…., v_k) for all v_r ∊ V₁ for all r, where i < j.
         (Note that some authors call such a function alternating, but, strictly speaking, the definitions of
         “skew-symmetric’’ and “alternating’’ can differ if  .)
         (a) Verify that if v_i = v_j in , then T(v₁, …, v_k) = 0 for all v₁, …, v_i-1 , v_i+1 ,…, v_j-1 , v_j+1 ,…., v_k ∊ V₁.
         (b) Show that, if W = 𝔽 and V₁ = ··· = V_k = 𝔽^k and if T is given by T(v₁, …, v_k) = det [v₁ ··· v_k] for all
               v₁, …, v_k ∊ 𝔽^k, then T is a skew-symmetric multilinear function.
         (c) Let T : 𝔽² x 𝔽² →𝔽 be a skew-symmetric multilinear function (so k = 2, V₁ = V₂ = 𝔽², W = 𝔽). Verify that
                  and .
         (d) Continuing (c), write , and find .
         (e) Continuing (c) and (d), show that for all a, b, c, d ∊ 𝔽.
Part (e) of the last question can be generalized as follows: if W = 𝔽 and V₁ = ··· = V_k = 𝔽^k and
T : V₁ x ··· x V_k → 𝔽 is a skew-symmetric multilinear function, then there exists s ∊ 𝔽 such that
T(v₁, …, v_k) = s det [v₁ ··· v_k] for all v₁, …, v_k ∊ 𝔽^k.

If any of the mathematics does not display properly (e.g., an error message received), compare with this file.
Recall that a scan of the instructor’s lecture notes from Fall 2021 can be accessed via the Modules section of our Canvas portal.