Abstract :
This paper establishes the state of the art in both deterministic and randomized online permutation routing in the POPS network. Indeed, we show that any permutation can be routed online on a POPS(d, g) network either with O(d/g log g) deterministic slots, or, with high probability, with 5clfloord/grfloor + o(d/g) + O(log log g) randomized slots, where constant c = exp(1 + e-1) ap 3.927. When d = Theta(g), which we claim to be the "interesting" case, the randomized algorithm is exponentially faster than any other algorithm in the literature, both deterministic and randomized ones. This is true in practice as well. Indeed, experiments show that it outperforms its rivals even starting from as small a network as a POPS(2, 2) and the gap grows exponentially with the size of the network. We can also show that, under proper hypothesis, no deterministic algorithm can asymptotically match its performance
Keywords :
computational complexity; deterministic algorithms; multiprocessor interconnection networks; network routing; optical computing; optical interconnections; probability; randomised algorithms; deterministic online permutation routing algorithm; optical interconnection; partitioned optical passive star network; probability; randomized online permutation routing algorithm; Bandwidth; Broadcasting; Couplers; Hypercubes; Intelligent networks; Optical fiber networks; Optical interconnections; Optical noise; Partitioning algorithms; Routing; Optical interconnections; partitioned optical passive star network; permutation routing.;
