Designing low‐diameter interconnection networks with multi‐ported host‐switch graphs

Abstract: A host-switch graph was originally proposed as a graph that represents a network topology of a computer systems with 1-port host computers and Δ-port switches. It has been studied from both theoretical and practical aspects in terms of the diameter, the average shortest path length, and the performance of real applications. In recent high-performance computing systems, however, a host computer is connected to multiple switches by using InfiniBand, NVSwitch, or Omni-Path, and consequently they provide high band… Show more

“…Another related line of topology research stems from the famous small-world phenomenon, first proposed by [15], that demonstrates that people living in a country constitute societies of a network with only short path lengths. Later, Wattz and Strogatz characterized the small-world phenomenon into the Wattz-Strogatz (WS) model [16], which allows networks to be generated with short average distance and large clustering coefficient [17,18]. The model uses a few additional long edges to reduce the diameter in random graphs for social networks and Internet topologies [3,18].…”

“…Later, Wattz and Strogatz characterized the small-world phenomenon into the Wattz-Strogatz (WS) model [16], which allows networks to be generated with short average distance and large clustering coefficient [17,18]. The model uses a few additional long edges to reduce the diameter in random graphs for social networks and Internet topologies [3,18]. Since then, researchers have been exploring the small-world phenomenon in computer networks [19][20][21].…”

Edge-Based Heuristics for Optimizing Shortcut-Augmented Topologies for HPC Interconnects

“…Another related line of topology research stems from the famous small-world phenomenon, first proposed by [15], that demonstrates that people living in a country constitute societies of a network with only short path lengths. Later, Wattz and Strogatz characterized the small-world phenomenon into the Wattz-Strogatz (WS) model [16], which allows networks to be generated with short average distance and large clustering coefficient [17,18]. The model uses a few additional long edges to reduce the diameter in random graphs for social networks and Internet topologies [3,18].…”

“…Later, Wattz and Strogatz characterized the small-world phenomenon into the Wattz-Strogatz (WS) model [16], which allows networks to be generated with short average distance and large clustering coefficient [17,18]. The model uses a few additional long edges to reduce the diameter in random graphs for social networks and Internet topologies [3,18]. Since then, researchers have been exploring the small-world phenomenon in computer networks [19][20][21].…”

Edge-Based Heuristics for Optimizing Shortcut-Augmented Topologies for HPC Interconnects

“…The diameter is the maximum value of the shortest path between any two nodes in the network and is the lower limit of the delay time required to transmit information to the entire network. A network having a relatively small diameter compared to the number of nodes, despite the short distance between nodes, has a disadvantage that it is difficult to design the network in terms of hardware as the number of nodes increases [16][17][18]. The interconnection networks that have been proposed until now can be classified into the following three types according to the number of nodes: mesh class with k × n nodes, hypercube class with 2 n nodes, and star graph class with n!…”

A Novel Interconnection Network with Improved Network Cost Through Shuffle-Exchange Permutation Graph

The Case for Disjoint Job Mapping on High-Radix Networked Parallel Computers