FPT Algorithms for a Special Block-structured Integer Program with Applications in Scheduling

TL;DR

This paper develops fixed parameter tractable algorithms for a special class of block-structured integer programs, enabling efficient solutions for complex scheduling problems with specific matrix structures and rank conditions.

Contribution

It introduces FPT algorithms for combinatorial 4-block n-fold integer programs, extending the understanding of structural properties and bounds of Graver basis elements in this context.

Findings

Bounded the $ ext{l}_{ ext{infinity}}$-norm of Graver basis elements by $O_{FPT}(n)$.

Developed algorithms with runtime $O_{FPT}(n^4 ext{log}^2 ext{largest input number})$.

Applied results to classical scheduling problems like rejection and bicriteria scheduling.

Abstract

We consider integer programs whose constraint matrix has a special block structure: $\min\{f(x):H_{com}x=b, l\le x\le u,x\in\mathbb{Z}^{t_B+nt_A}\}$, where the objective function $f$ is separable convex and the constraint matrix $H_ {com}$ is composed of small submatrices $A_i,B,C,D_i$ such that the first row is $(C,D_1,D_2,\ldots,D_n)$, the first column is $(C,B,B,\ldots,B)^{\top}$, the main diagonal is $(C,A_1,A_2,\ldots,A_n)$, and the rest entries are 0. Furthermore, $\text{rank}(B)$=1. We study fixed parameter tractable (FPT) algorithms by taking as parameters the number of rows and columns of small submatrices, together with the largest absolute value over their entries. We call the IP (almost) combinatorial 4-block n-fold IP. It generalizes the generalized n-fold IP and is a special case of the generalized 4-block n-fold IP. The existence of FPT algorithms for the generalized 4-block n-fold IP is a major open problem, which motivates us to study special cases of the generalized 4-block n-fold IP to find structural insights. We show the $\ell_{\infty}$-norm of Graver basis elements of combinatorial 4-block n-fold IP is $\Omega(n)$. There is some FPT-value $\lambda$ such that for any nonzero element $g\in\{x: H_{com} x= 0\}$, $\lambda g$ can always be decomposed into Graver basis elements in the same orthant whose $\ell_{\infty}$-norm is FPT-bounded (while g might not admit such a decomposition). Then we can bound the $\ell_{\infty}$-norm of Graver basis elements by $O_{FPT}(n)$ and develop $O_{FPT}({n^4\hat{L}^2})$-time algorithms ($O_{FPT}$ hides a multiplicative FPT-term, and $\hat{L}$ denotes the logarithm of the largest number occurring in the input). As applications, combinatorial 4-block n-fold IP can be used to model some classical problems, including scheduling with rejection and bicriteria scheduling.