Multiprocessor architectures and physical law

Proceedings Workshop on Physics and Computation. PhysComp '94 Pub Date : 1994-11-17 DOI:10.1109/PHYCMP.1994.363703
P. Vitányi
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引用次数: 9

Abstract

We show that all highly symmetrical interconnection topologies for multiprocessors with low diameter require very long interconnect lengths. Therefore, such multicomputers do not scale well in the physical world with 3 dimensions. On the other hand, highly irregular (random) interconnection topologies have a very large subgraph of diameter two and therefore also require very long interconnect lengths. Hence the only scaling topologies for future massively parallel computers are high diameter regular ones, like mesh networks. The techniques used are symmetry properties in terms of orbits of automorphism groups of graphs, and a modern notion of randomness of individual objects, Kolmogorov complexity.<>
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多处理器体系结构和物理定律
我们证明了所有高度对称的低直径多处理器互连拓扑都需要非常长的互连长度。因此,这种多计算机在三维物理世界中不能很好地扩展。另一方面,高度不规则(随机)互连拓扑具有非常大的直径为2的子图,因此也需要非常长的互连长度。因此,未来大规模并行计算机的唯一可伸缩拓扑是大直径的规则拓扑,如网状网络。使用的技术是图的自同构群的轨道的对称性,以及单个对象的随机性的现代概念,Kolmogorov复杂度
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Proceedings Workshop on Physics and Computation. PhysComp '94
Proceedings Workshop on Physics and Computation. PhysComp '94
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