Weakly chained diagonally dominant matrix

In mathematics, the weakly chained diagonally dominant matrices are a family of nonsingular matrices that include the strictly diagonally dominant matrices.

Venn Diagram showing the containment of weakly chained diagonally dominant (WCDD) matrices relative to weakly diagonally dominant (WDD) and strictly diagonally dominant (SDD) matrices.

Definition

Preliminaries

We say row of a complex matrix is strictly diagonally dominant (SDD) if . We say is SDD if all of its rows are SDD. Weakly diagonally dominant (WDD) is defined with instead.

The directed graph associated with an complex matrix is given by the vertices and edges defined as follows: there exists an edge from if and only if .

Definition

A complex square matrix is said to be weakly chained diagonally dominant (WCDD) if

  • is WDD and
  • for each row that is not SDD, there exists a walk in the directed graph of ending at an SDD row .

Example

The directed graph associated with the WCDD matrix in the example. The first row, which is SDD, is highlighted. Note that regardless of which node we start at, we can find a walk .

The matrix

is WCDD.

Properties

Nonsingularity

A WCDD matrix is nonsingular.[1]

Proof:[2] Let be a WCDD matrix. Suppose there exists a nonzero in the null space of . Without loss of generality, let be such that for all . Since is WCDD, we may pick a walk ending at an SDD row .

Taking moduli on both sides of

and applying the triangle inequality yields

and hence row is not SDD. Moreover, since is WDD, the above chain of inequalities holds with equality so that whenever . Therefore, . Repeating this argument with , , etc., we find that is not SDD, a contradiction.

Recalling that an irreducible matrix is one whose associated directed graph is strongly connected, a trivial corollary of the above is that an irreducibly diagonally dominant matrix (i.e., an irreducible WDD matrix with at least one SDD row) is nonsingular.[3]

Relationship with nonsingular M-matrices

The following are equivalent:[4]

  • is a nonsingular WDD M-matrix.
  • is a nonsingular WDD L-matrix;
  • is a WCDD L-matrix;

In fact, WCDD L-matrices were studied (by James H. Bramble and B. E. Hubbard) as early as 1964 in a journal article[5] in which they appear under the alternate name of matrices of positive type.

Moreover, if is an WCDD L-matrix, we can bound its inverse as follows:[6]

  where  

Note that is always zero and that the right-hand side of the bound above is whenever one or more of the constants is one.

Tighter bounds for the inverse of a WCDD L-matrix are known.[7][8][9][10]

Applications

Due to their relationship with M-matrices (see above), WCDD matrices appear often in practical applications. An example is given below.

Monotone numerical schemes

WCDD L-matrices arise naturally from monotone approximation schemes for partial differential equations.

For example, consider the one-dimensional Poisson problem

  for  

with Dirichlet boundary conditions . Letting be a numerical grid (for some positive that divides unity), a monotone finite difference scheme for the Poisson problem takes the form of

  where  

and

Note that is a WCDD L-matrix.

References

  1. Shivakumar, P. N.; Chew, Kim Ho (1974). "A Sufficient Condition for Nonvanishing of Determinants" (PDF). Proceedings of the American Mathematical Society. 43 (1): 63. doi:10.1090/S0002-9939-1974-0332820-0. ISSN 0002-9939.
  2. Azimzadeh, Parsiad; Forsyth, Peter A. (2016). "Weakly Chained Matrices, Policy Iteration, and Impulse Control". SIAM Journal on Numerical Analysis. 54 (3): 1341–1364. arXiv:1510.03928. doi:10.1137/15M1043431. ISSN 0036-1429.
  3. Horn, Roger A.; Johnson, Charles R. (1990). "Matrix analysis". Cambridge University Press, Cambridge. Cite journal requires |journal= (help)
  4. Azimzadeh, Parsiad (2019). "A fast and stable test to check if a weakly diagonally dominant matrix is a nonsingular M-Matrix". Mathematics of Computation. 88 (316): 783–800. arXiv:1701.06951. Bibcode:2017arXiv170106951A. doi:10.1090/mcom/3347.
  5. Bramble, James H.; Hubbard, B. E. (1964). "On a finite difference analogue of an elliptic problem which is neither diagonally dominant nor of non-negative type". Journal of Mathematical Physics. 43: 117–132. doi:10.1002/sapm1964431117.
  6. Shivakumar, P. N.; Williams, Joseph J.; Ye, Qiang; Marinov, Corneliu A. (1996). "On Two-Sided Bounds Related to Weakly Diagonally Dominant M-Matrices with Application to Digital Circuit Dynamics". SIAM Journal on Matrix Analysis and Applications. 17 (2): 298–312. doi:10.1137/S0895479894276370. ISSN 0895-4798.
  7. Cheng, Guang-Hui; Huang, Ting-Zhu (2007). "An upper bound for of strictly diagonally dominant M-matrices". Linear Algebra and Its Applications. 426 (2–3): 667–673. doi:10.1016/j.laa.2007.06.001. ISSN 0024-3795.
  8. Li, Wen (2008). "The infinity norm bound for the inverse of nonsingular diagonal dominant matrices". Applied Mathematics Letters. 21 (3): 258–263. doi:10.1016/j.aml.2007.03.018. ISSN 0893-9659.
  9. Wang, Ping (2009). "An upper bound for of strictly diagonally dominant M-matrices". Linear Algebra and Its Applications. 431 (5–7): 511–517. doi:10.1016/j.laa.2009.02.037. ISSN 0024-3795.
  10. Huang, Ting-Zhu; Zhu, Yan (2010). "Estimation of for weakly chained diagonally dominant M-matrices". Linear Algebra and Its Applications. 432 (2–3): 670–677. doi:10.1016/j.laa.2009.09.012. ISSN 0024-3795.
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