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I.1 Statement of the theorem

According to the Cayley-Hamilton theorem, every square matrix A satisfies its own characteristic equation (Volume 1, section 9.3.1). Let the characteristic polynomial of A be

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET                     (I.1)

When the determinant is fully expanded and terms in the same power of λ are collected, one obtains

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET                    (I.2)

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

For example, let

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET                              (I.3)

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET                             (I.4)

and

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET                               (I.5)

It will become clear at the end of Section I.3 why a matrix of integers provides an especially appropriate example.

The Cayley-Hamilton theorem asserts that

χ(A)= 0,                                 (I.6)

where 0 is the zero matrix and
Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET                                  (I.7)

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

For the example in Eqs. (I.3–I.5),

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET                      (I.8)

Exercise I.1.2 verifies that χ(A)= 0 for this example.

Exercises for Section I.1

I.1.1 Verify Eq. (I.5).

I.1.2 Verify that χ(A)= 0, where A is defined in Eq. (I.3).

I.2 Elementary proof

Since the Cayley-Hamilton theorem is a fundamental result in linear algebra, it is useful to give two proofs, an elementary one and a more general one. The elementary proof is valid when the eigenvectors of A span the vector space on which A acts. The eigenvalue-eigenvector equation can be written in the form

AV = VΛ                                 (I.9)

where V is the matrix of eigenvectors,

V =[v1 ,..., vn]                               (I.10)

and Λ is a diagonal matrix, the elements of which are the eigenvalues of A (Volume 1, Eq. (9.217)). Because this proof requires that the eigenvalues of A must belong to the same number field F to which the matrix elements of A belong, F must be algebraically closed, meaning that the roots of every polynomial equation with coefficients in F must belong to F. For the purposes of this proof, it is convenient to assume that F = C, the field of complex numbers.

Because we have assumed that the eigenvectors span the entire vector space Cn , the matrix V is non-singular. Therefore the inverse matrix V−1 exists. Multiplying both sides of Eq. (I.9) from the right with V−1 results in the equation

A = VΛV−1.                          (I.11)

Now

Ak = VΛk V−1,                              (I.12)

from which it follows that

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET                        (I.13)

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

since each eigenvalue λk is a root of the characteristic equation χ(λ) = 0. This establishes Eq. (I.6) for the case in which A is diagonalizable.

General proof

The general proof assumes only scalars that belong to a number field F, and n × n square matrices. A matrix of scalars is one in which every element is a scalar that belongs to F.A λ-matrix B(λ) is a matrix, the elements of which are polynomials over F in an unknown λ.A λ-matrix is equal to the zero matrix, 0, if and only if every matrix element is equal to the zero polynomial.

If, in each matrix element of a λ-matrix, one collects terms in powers of λ, the resulting λ-matrix is equal to a sum of matrices of scalars, Bj , each one multiplied by a power of λ:

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET                           (I.14)

where Bl ≠ 0 unless B(λ)= 0.

For example, let

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

Then

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

IatnhdatphpaetnBs that B(λ) is the matrix of cofactors of the matrix A − λ1 in Eq. (I.4), 0 is the matrix of cofactors of A; more of this later.

To prepare for the proof of the Cayley-Hamilton theorem, it is useful to show that, if a λ-matrix of the form

C(λ)= B(λ)(A − λ1)                      (I.17)

is equal to a matrix of scalars, then C(λ)= 0. To see this, expand the right-hand side using Eq. (I.14):

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET                               (I.18)

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

Because C(λ) is equal to a matrix of scalars, the matrix coefficient of the leading term, Bl, must vanish, along with each of the matrix coefficients in the terms j = l, l − 1,..., 1. But Bl = 0 and Bl A − Bl−1 = 0 imply that Bl−1 = 0.
Continuing the chain of equalities downward in j , one sees that Bj = 0 for j = l, l − 1,..., 0. It follows that C(λ)= 0.

Let B(λ) be the matrix of cofactors of the n x n matrix A − λ1. Each element of the cofactor matrix B(λ) is obtained from the matrix elements of A − λ1 by evaluating the determinant of a sub-matrix of A − λ1, and is therefore a polynomial of degree n − 1 or lower. Therefore B(λ) is a A-matrix as defined above:

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET                       (I.19)

By the Laplace expansion of a determinant (Volume 1, Eq. (6.347)),

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET                   (I.20)

where χ is the characteristic polynomial of the matrix A.

We now evaluate χ(A) and show that it is equal to the zero matrix. For every j ∈ (2 : n),

A− λj 1 = (Aj−1 + λAj−2 + ··· + λj−2A + λj−1) (A − λ1).                           (I.21)

Then

Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences | Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

where G(λ)isa λ-matrix. Then

χ(A)= χ(λ)1 − G(λ)(A − λ1).                                               (I.23)

Eq. (I.20) provides another expression for χ(λ)1. Substituting in Eq. (I.23), one obtains

χ(A) = B(λ) − G(λ) (A − λ1).                          (I.24)

But χ(A) is a matrix of scalars, and this equation is of the form of Eq. (I.17).

Therefore

χ(A)= 0.                                  (I.25)

After a little study, one realizes that this proof makes no use of division by a scalar. In fact, the Cayley-Hamilton remains true if the number field F is replaced by a commutative ring R, such as the ring of integers, Z. In this case, the underlying vector space is replaced by an R-module (Volume 1, p. 207).

For example, if R = Z, then an underlying space of n × 1 column vectors with elements in a field F is replaced by a space whose elements are vectors of integers. The only allowable matrices that act on an R-module are matrices whose elements belong to R, as in Eq. (I.3), or are polynomials over R,as in Eq. (I.4). Determinants can still be defined. Each element of the matrix of cofactors is a determinant of a matrix of integers, and therefore is an integer, as in Eq. (I.15). The Laplace expansion of a determinant, Eq. (I.20), is still valid. Since every step of the proof remains valid for R-modules, the conclusion, Eq. (I.25), is also valid when the elements of A belong to a commutative ring R. The goal of Exercise I.3.2 is to verify the Cayley-Hamilton theorem for the matrix of integers defined in Eq. (I.3).

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FAQs on Cayley Hamilton Theorem - Matrix Algebra, CSIR-NET Mathematical Sciences - Mathematics for IIT JAM, GATE, CSIR NET, UGC NET

1. What is Cayley Hamilton theorem in matrix algebra?
Ans. The Cayley Hamilton theorem states that every square matrix satisfies its own characteristic equation. In other words, if A is a square matrix of order n, then the characteristic equation of A is given by det(A-λI) = 0, where det denotes the determinant, λ is an eigenvalue of A, and I is the identity matrix of order n. The Cayley Hamilton theorem states that if p(λ) is the characteristic polynomial of A, then p(A) = 0, where p(A) is obtained by substituting A for λ in p(λ).
2. How is the Cayley Hamilton theorem used in matrix algebra?
Ans. The Cayley Hamilton theorem is used to find powers of a matrix. Once we have the characteristic polynomial of a matrix, we can use the Cayley Hamilton theorem to express higher powers of the matrix in terms of its lower powers. This is useful in many applications, such as solving systems of linear equations, finding inverses of matrices, and determining the behavior of dynamical systems.
3. What is the significance of the Cayley Hamilton theorem in CSIR-NET Mathematical Sciences exam?
Ans. The Cayley Hamilton theorem is an important topic in CSIR-NET Mathematical Sciences exam. It is often tested in questions related to matrix algebra, eigenvalues, and eigenvectors. Understanding and applying the Cayley Hamilton theorem is crucial for solving problems in linear algebra and related areas. Familiarity with this theorem can greatly enhance one's ability to solve complex mathematical problems in the exam.
4. Can the Cayley Hamilton theorem be applied to non-square matrices?
Ans. No, the Cayley Hamilton theorem only applies to square matrices. It states that every square matrix satisfies its own characteristic equation. For non-square matrices, the concept of eigenvalues and characteristic polynomials is not defined, and therefore the Cayley Hamilton theorem does not hold.
5. Are there any limitations or exceptions to the Cayley Hamilton theorem?
Ans. Yes, there are some limitations to the Cayley Hamilton theorem. One limitation is that it only holds for matrices over fields, which are algebraic structures with addition, subtraction, multiplication, and division operations defined. Another limitation is that the Cayley Hamilton theorem may not hold for matrices over non-commutative rings. Additionally, if a matrix has repeated eigenvalues, the Cayley Hamilton theorem may not provide a unique solution for higher powers of the matrix.
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