Title :
Multi-frame isochronous service for ATM networks: stop-and go revisited
Author :
Ibaraki, T. ; Kameda, T.
Author_Institution :
Dept. of Appl. Math. & Phys., Kyoto Univ., Japan
Abstract :
The ATM switching scheme we propose is similar to the multi-frame stop-and-go, except that we use EDF (earliest-deadline-first) scheduling, instead of rate-monotonic, static-priority scheduling. Unlike the multi-frame stop-and-go, our scheme can fully utilize the link bandwidth, and does not require that the input or output frames of the same size be synchronized. EDF scheduling is, in general, more complex than static-priority scheduling. However, we show that the next earliest deadline needs to be computed only when an output frame reaches its end, i.e., not whenever a cell is output, resulting in significant saving in computation time. We derive bounds on end-to-end delay and delay-jitter, and discuss implementation issues
Keywords :
asynchronous transfer mode; buffer storage; computational complexity; jitter; queueing theory; scheduling; telecommunication links; telecommunication networks; ATM networks; ATM switching; FIFO queues; bounds; computation time saving; delay-jitter; earliest-deadline-first scheduling; end-to-end delay; input frames; link bandwidth utilization; multi-frame isochronous service; multi-frame stop-and-go; next earliest deadline; output frames; output-buffered switches; static-priority scheduling; Asynchronous transfer mode; Belts; Clocks; Delay; Fabrics; Physics; Process control; Processor scheduling; Scheduling algorithm; Switches;
Conference_Titel :
Computer Communications and Networks, 1997. Proceedings., Sixth International Conference on
Conference_Location :
Las Vegas, NV
Print_ISBN :
0-8186-8186-1
DOI :
10.1109/ICCCN.1997.623284
