Abstract
A new mathematical model is proposed for the Ring Spur Assignment Problem (RSAP) that arises in the design of next-generation telecommunication networks. In this problem, every node of the network lies either on a ring among a set of bounded disjoint local rings or is spurred by a single arc to another node on a
local ring. A special ring, called a tertiary ring, interconnects the local rings. Our new integer programming model employs only O(n2) variables and has a stronger LP relaxation. Several classes of valid inequalities and corresponding separation procedures are presented giving rise to an efficient branch-and-cut solution algorithm. We report optimal solutions for all SNDLib instances including those that have not previously been solved to optimality.
local ring. A special ring, called a tertiary ring, interconnects the local rings. Our new integer programming model employs only O(n2) variables and has a stronger LP relaxation. Several classes of valid inequalities and corresponding separation procedures are presented giving rise to an efficient branch-and-cut solution algorithm. We report optimal solutions for all SNDLib instances including those that have not previously been solved to optimality.
| Original language | English |
|---|---|
| Pages (from-to) | 91-102 |
| Journal | Computers & Operations Research |
| Volume | 88 |
| Early online date | 22 Jun 2017 |
| DOIs | |
| Publication status | Published - Dec 2017 |
Keywords
- location-allocation
- branch-and-cut
- next-generation telecommunications networks