TY - JOUR
T1 - A wavelength reusing/sharing access protocol for multichannel photonic dual bus networks
AU - Huang, Nen Fu
AU - Sheu, Shiann Tsong
N1 - Funding Information:
Manuscript received January 6, 1995, revised October 23, 1995 This work was supported by the National Science Council, R 0 C , under Contract NSC83-0408-E007-011 N -F Huang is with the Department of Computer Science, Nahonal Tsing Hua University, Taiwan 300, R 0 C S -T Sheu is with the Department of Electrical Engineering, Tam Kang University, Tamsui, Taiwan 25 1, R 0 C Publisher Item Identifier S 0733-8724(96)03891-1
PY - 1996/5
Y1 - 1996/5
N2 - In a multichannel photonic dual bus network, each of the unidirectional bus contains a number of channels (wave-lengths) and the bus headend periodically generates fixed length slots on each of the channels. Generally, one channel called control channel is used to carry signals and the others are data channels. Each station is equipped with one fixed-transmitter and one fixed-receiver which are permanently tuned to the dedicated control channel, and n tunable-transmitters and m tunable-receivers are tunable over the entire wavelength range. For nonoverlapping traffic in network, the maximum network throughput will be achieved by applying the wavelength reusing concept. Given a set of serving traffic, a set of new traffic requests, and c data channels (wavelengths), the wavelength/receiver assignment problem [(n, m, c)-WRAP] is to assign a transmission wavelength and a receiver for each of the request such that the network throughput is maximized and the number of assigned wavelengths is minimized. In this paper, we prove that the (n, m, C)-WRAP is N P-hard. An efficient Distributed Wavelength Reusing/Sharing Access Protocol (DWRAP) is proposed for the (1, m, c)-WRAP. Based on the DWRAP, three different schemes are proposed for assigning the wavelength/receiver. The throughput of the DWRAP is analyzed and the performance of the three proposed schemes on the DWARP are evaluated and compared by simulation. Simulation results demonstrate that for a limited number of wavelengths and receivers, the proposed schemes substantially improve the network thrughput and access delay uader general treffic demands.
AB - In a multichannel photonic dual bus network, each of the unidirectional bus contains a number of channels (wave-lengths) and the bus headend periodically generates fixed length slots on each of the channels. Generally, one channel called control channel is used to carry signals and the others are data channels. Each station is equipped with one fixed-transmitter and one fixed-receiver which are permanently tuned to the dedicated control channel, and n tunable-transmitters and m tunable-receivers are tunable over the entire wavelength range. For nonoverlapping traffic in network, the maximum network throughput will be achieved by applying the wavelength reusing concept. Given a set of serving traffic, a set of new traffic requests, and c data channels (wavelengths), the wavelength/receiver assignment problem [(n, m, c)-WRAP] is to assign a transmission wavelength and a receiver for each of the request such that the network throughput is maximized and the number of assigned wavelengths is minimized. In this paper, we prove that the (n, m, C)-WRAP is N P-hard. An efficient Distributed Wavelength Reusing/Sharing Access Protocol (DWRAP) is proposed for the (1, m, c)-WRAP. Based on the DWRAP, three different schemes are proposed for assigning the wavelength/receiver. The throughput of the DWRAP is analyzed and the performance of the three proposed schemes on the DWARP are evaluated and compared by simulation. Simulation results demonstrate that for a limited number of wavelengths and receivers, the proposed schemes substantially improve the network thrughput and access delay uader general treffic demands.
UR - http://www.scopus.com/inward/record.url?scp=0030145846&partnerID=8YFLogxK
U2 - 10.1109/50.495146
DO - 10.1109/50.495146
M3 - 期刊論文
AN - SCOPUS:0030145846
SN - 0733-8724
VL - 14
SP - 678
EP - 692
JO - Journal of Lightwave Technology
JF - Journal of Lightwave Technology
IS - 5
ER -