Interconnection Networks Based on a Generalization of Cube-Connected Cycles
IEEE Transactions on Computers
IEEE Transactions on Computers
ISCA '91 Proceedings of the 18th annual international symposium on Computer architecture
Optimal Distance Networks of Low Degree for Parallel Computers
IEEE Transactions on Computers
Wavelength Division Multiple Access Channel Hypercube Processor Interconnection
IEEE Transactions on Computers
Flexible oblivious router architecture
IBM Journal of Research and Development
Analysis of a variant hypercube topology
ICS '90 Proceedings of the 4th international conference on Supercomputing
High speed routing in a parallel processing environment: a simulation study
ANSS '91 Proceedings of the 24th annual symposium on Simulation
Simulation of fast packet-switched photonic networks for interprocessor communication
ANSS '91 Proceedings of the 24th annual symposium on Simulation
n-Dimensional Processor Arrays with Optical dBuses
The Journal of Supercomputing
Hypercube Multiprocessors with Bus Connections for Improving Communication Performance
IEEE Transactions on Computers
Routing Algorithms on the Bus-Based Hypercube Network
IEEE Transactions on Parallel and Distributed Systems
Hamming hypermeshes: high performance interconnection networks for pin-out limited systems
Performance Evaluation
| Hi-index | 14.99 |
A distributed computer system based on a hypercube topology is proposed, where multiaccess channels spanning all dimensional axes provide processor interconnection. The multiprocessor system can be built at relatively low cost by combining the recent advances in high-capacity channels available through fiber optics, and demand-assignment multiple-access protocols, creating a highly fault-tolerant system with good average packet delay and average distance characteristics, at a significantly reduced cost. A totally distributed system has been achieved in which the packets are self-routing, able to take advantage of the multiple paths of equal length between two modes. The proposed structure gives a highly fault tolerant system, degrading gracefully in the presence of failures.