Alternant matrix

Last updated September 29, 2023

In linear algebra, an alternant matrix is a matrix formed by applying a finite list of functions pointwise to a fixed column of inputs. An alternant determinant is the determinant of a square alternant matrix.

M={\begin{bmatrix}f_{1}(\alpha _{1})&f_{2}(\alpha _{1})&\cdots &f_{n}(\alpha _{1})\\f_{1}(\alpha _{2})&f_{2}(\alpha _{2})&\cdots &f_{n}(\alpha _{2})\\f_{1}(\alpha _{3})&f_{2}(\alpha _{3})&\cdots &f_{n}(\alpha _{3})\\\vdots &\vdots &\ddots &\vdots \\f_{1}(\alpha _{m})&f_{2}(\alpha _{m})&\cdots &f_{n}(\alpha _{m})\\\end{bmatrix}}

or, more compactly, $M_{ij}=f_{j}(\alpha _{i})$ . (Some authors use the transpose of the above matrix.) Examples of alternant matrices include Vandermonde matrices, for which $f_{j}(\alpha )=\alpha ^{j-1}$ , and Moore matrices, for which $f_{j}(\alpha )=\alpha ^{q^{j-1}}$ .

Properties

The alternant can be used to check the linear independence of the functions $f_{1},f_{2},\dots ,f_{n}$ in function space. For example, let $f_{1}(x)=\sin(x)$ , $f_{2}(x)=\cos(x)$ and choose $\alpha _{1}=0,\alpha _{2}=\pi /2$ . Then the alternant is the matrix $\left[{\begin{smallmatrix}0&1\\1&0\end{smallmatrix}}\right]$ and the alternant determinant is $-1\neq 0$ . Therefore M is invertible and the vectors $\{\sin(x),\cos(x)\}$ form a basis for their spanning set: in particular, $\sin(x)$ and $\cos(x)$ are linearly independent.

Linear dependence of the columns of an alternant does not imply that the functions are linearly dependent in function space. For example, let $f_{1}(x)=\sin(x)$ , $f_{2}=\cos(x)$ and choose $\alpha _{1}=0,\alpha _{2}=\pi$ . Then the alternant is $\left[{\begin{smallmatrix}0&1\\0&-1\end{smallmatrix}}\right]$ and the alternant determinant is 0, but we have already seen that $\sin(x)$ and $\cos(x)$ are linearly independent.

Despite this, the alternant can be used to find a linear dependence if it is already known that one exists. For example, we know from the theory of partial fractions that there are real numbers A and B for which ${\frac {A}{x+1}}+{\frac {B}{x+2}}={\frac {1}{(x+1)(x+2)}}$ . Choosing $f_{1}(x)={\frac {1}{x+1}}$ , $f_{2}(x)={\frac {1}{x+2}}$ , $f_{3}(x)={\frac {1}{(x+1)(x+2)}}$ and $(\alpha _{1},\alpha _{2},\alpha _{3})=(1,2,3)$ , we obtain the alternant ${\begin{bmatrix}1/2&1/3&1/6\\1/3&1/4&1/12\\1/4&1/5&1/20\end{bmatrix}}\sim {\begin{bmatrix}1&0&1\\0&1&-1\\0&0&0\end{bmatrix}}$ . Therefore, $(1,-1,-1)$ is in the nullspace of the matrix: that is, $f_{1}-f_{2}-f_{3}=0$ . Moving $f_{3}$ to the other side of the equation gives the partial fraction decomposition $A=1,B=-1$ .

If $n=m$ and $\alpha _{i}=\alpha _{j}$ for any $i\neq j$ , then the alternant determinant is zero (as a row is repeated).

If $n=m$ and the functions $f_{j}(x)$ are all polynomials, then $(\alpha _{j}-\alpha _{i})$ divides the alternant determinant for all $1\leq i<j\leq n$ . In particular, if V is a Vandermonde matrix, then ${\textstyle \prod _{i<j}(\alpha _{j}-\alpha _{i})=\det V}$ divides such polynomial alternant determinants. The ratio ${\textstyle {\frac {\det M}{\det V}}}$ is therefore a polynomial in $\alpha _{1},\ldots ,\alpha _{m}$ called the bialternant. The Schur polynomial $s_{(\lambda _{1},\dots ,\lambda _{n})}$ is classically defined as the bialternant of the polynomials $f_{j}(x)=x^{\lambda _{j}}$ .

Applications

Alternant matrices are used in coding theory in the construction of alternant codes.

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References

Thomas Muir (1960). A treatise on the theory of determinants. Dover Publications. pp. 321–363.
A. C. Aitken (1956). Determinants and Matrices. Oliver and Boyd Ltd. pp. 111–123.
Richard P. Stanley (1999). Enumerative Combinatorics. Cambridge University Press. pp. 334–342.

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v t e Matrix classes
Explicitly constrained entries	Alternant Anti-diagonal Anti-Hermitian Anti-symmetric Arrowhead Band Bidiagonal Bisymmetric Block-diagonal Block Block tridiagonal Boolean Cauchy Centrosymmetric Conference Complex Hadamard Copositive Diagonally dominant Diagonal Discrete Fourier Transform Elementary Equivalent Frobenius Generalized permutation Hadamard Hankel Hermitian Hessenberg Hollow Integer Logical Matrix unit Metzler Moore Nonnegative Pentadiagonal Permutation Persymmetric Polynomial Quaternionic Signature Skew-Hermitian Skew-symmetric Skyline Sparse Sylvester Symmetric Toeplitz Triangular Tridiagonal Vandermonde Walsh Z
Constant	Exchange Hilbert Identity Lehmer Of ones Pascal Pauli Redheffer Shift Zero
Conditions on eigenvalues or eigenvectors	Companion Convergent Defective Definite Diagonalizable Hurwitz Positive-definite Stieltjes
Satisfying conditions on products or inverses	Congruent Idempotent or Projection Invertible Involutory Nilpotent Normal Orthogonal Unimodular Unipotent Unitary Totally unimodular Weighing
With specific applications	Adjugate Alternating sign Augmented Bézout Carleman Cartan Circulant Cofactor Commutation Confusion Coxeter Distance Duplication and elimination Euclidean distance Fundamental (linear differential equation) Generator Gram Hessian Householder Jacobian Moment Payoff Pick Random Rotation Seifert Shear Similarity Symplectic Totally positive Transformation
Used in statistics	Centering Correlation Covariance Design Doubly stochastic Fisher information Hat Precision Stochastic Transition
Used in graph theory	Adjacency Biadjacency Degree Edmonds Incidence Laplacian Seidel adjacency Tutte
Used in science and engineering	Cabibbo–Kobayashi–Maskawa Density Fundamental (computer vision) Fuzzy associative Gamma Gell-Mann Hamiltonian Irregular Overlap S State transition Substitution Z (chemistry)
Related terms	Jordan normal form Linear independence Matrix exponential Matrix representation of conic sections Perfect matrix Pseudoinverse Row echelon form Wronskian
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Alternant matrix

Contents

Properties

Applications

See also

Related Research Articles

References