Title :
Omega network-based ATM switch with neural network-controlled bypass queueing and multiplexing
Author :
Park, Young-Keun ; Cherkassky, Vladimir ; Lee, Gyungho
Author_Institution :
Dept. of Electr. Eng., Minnesota Univ., Minneapolis, MN, USA
fDate :
12/1/1994 12:00:00 AM
Abstract :
Multistage interconnection networks (MINs) have long been studied for use in switching networks. Since they have a unique path between source and destination and the intermediate nodes of the paths are shared, internal blocking can cause very poor throughput. This paper proposes a high throughput ATM switch consisting of an Omega network with a new form of input queues called bypass queues. We also improve the switch throughput by partitioning the Input buffers into disjoint buffer sets and multiplexing several sets of nonblocking cells within a time slot, assuming that the routing switch operates only a couple of times faster than the transmission rate. A neural network model is presented as a controller for cell scheduling and multiplexing in the switch. Our simulation results under uniform traffic show that the proposed approach achieves almost 100% of potential switch throughput
Keywords :
B-ISDN; asynchronous transfer mode; multistage interconnection networks; neural nets; queueing theory; telecommunication control; telecommunication network routing; telecommunication traffic; time division multiplexing; ATM switch; B-ISDN; Omega network; TDM; bypass queueing; cell scheduling; controller; input buffers; input queues; multistage interconnection networks; neural network control; neural network model; nonblocking cells; routing switch; simulation result; switching networks; throughput; transmission rate; uniform traffic; Asynchronous transfer mode; B-ISDN; Communication switching; Multiprocessor interconnection networks; Neural networks; Packet switching; Quality of service; Routing; Switches; Throughput;
Journal_Title :
Selected Areas in Communications, IEEE Journal on
