Differential algebraic systems anew
Applied Numerical Mathematics
Discrete Applied Mathematics
Differential-Algebraic Systems: Analytical Aspects and Circuit Applications
Differential-Algebraic Systems: Analytical Aspects and Circuit Applications
A note on fundamental, non-fundamental, and robust cycle bases
Discrete Applied Mathematics
Augmented nodal matrices and normal trees
Discrete Applied Mathematics
Minimum cut bases in undirected networks
Discrete Applied Mathematics
Circuit synthesis of passive descriptor systems—a modified nodal approach
International Journal of Circuit Theory and Applications
Nondegeneracy conditions for active memristive circuits
IEEE Transactions on Circuits and Systems II: Express Briefs
Semistate models of electrical circuits including memristors
International Journal of Circuit Theory and Applications
Integral cycle bases for cyclic timetabling
Discrete Optimization
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In this paper, we address several properties of the so-called augmented cyclic matrices of weighted digraphs. These matrices arise in different applications of digraph theory to electrical circuit analysis, and can be seen as an enlargement of basic cyclic matrices of the form BWB^T, where B is a cycle matrix and W is a diagonal matrix of weights. By using certain matrix factorizations and some properties of cycle bases, we characterize the determinant of augmented cyclic matrices, via Cauchy-Binet expansions, in terms of the so-called proper cotrees. In the simpler context defined by basic cyclic matrices, we obtain the dual result of Maxwell's determinantal expansion for weighted Laplacian (nodal) matrices. Additional relations with nodal matrices are also discussed. We apply this framework to the characterization of the differential-algebraic circuit models arising from loop analysis, and also to the analysis of branch-oriented models of circuits including charge-controlled memristors.