Notes on \a,b,c\-Modular Matrices
Abstract
Let A ∈ Zm × n be an integral matrix and a, b, c ∈ Z satisfy a ≥ b ≥ c ≥ 0. The question is to recognize whether A is \a,b,c\-modular, i.e., whether the set of n × n subdeterminants of A in absolute value is \a,b,c\. We will succeed in solving this problem in polynomial time unless A possesses a duplicative relation, that is, A has nonzero n × n subdeterminants k1 and k2 satisfying 2 · |k1| = |k2|. This is an extension of the well-known recognition algorithm for totally unimodular matrices. As a consequence of our analysis, we present a polynomial time algorithm to solve integer programs in standard form over \a,b,c\-modular constraint matrices for any constants a, b and c.
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