Choice and control of routes in crossover optical interconnection network

被引：1

作者：

Yang J.-B. ^{[1
]}

Yang J.-K. ^{[1
]}

Li X.-J. ^{[1
]}

Liu J. ^{[1
]}

Su X.-Y. ^{[2
]}

Xu P. ^{[3
]}

机构：

[1] Tech-physical Research Center, College of Science National University of Defense Technology

[2] Department of Optoelectronics, College of Electronic Information Sichuan University

[3] College of Electronic Science and Technology, Shenzhen University

来源：

Guangxue Jingmi Gongcheng/Optics and Precision Engineering | 2010年 / 18卷 / 06期

关键词：

Banyan network; Crossover network; Matrix computing; Optical communication; Optical interconnection network;

D O I：

10.3788/OPE.20101806.1249

中图分类号：

学科分类号：

摘要：

A novel algorithm is proposed and designed to route and process the optical signals of a crossover network. Firstly, based on the link rule and function principle of the crossover network, the corresponding processing matrixes are achieved to denote and illustrate the relative signal operating and control and to establish the relation between input and output signals. According to the performing matrixes and the orders of input/output signal arrays, the node controlling and signal routing are determined. Finally, the signals are routed and controlled. It is shown that the proposed algorithm can not only be used in the routing control for a 8×8 crossover optical interconnection network, but also can be used in those for 16×16, 32×32 and 64×64 networks. Furthermore, it also has excellent transplant ability and compatibility for perfect shaffle networks and Banyan networks. These results indicate that the routing algorithm is useful for optical switching applications, optical computing, and optical information processing in the future.

引用

下载

页码：1249 / 1257

页数：8

共 36 条

[1] Popolek J., Yao L., Free-space-fiber hybrid distributed optical cross-connect interconnect module, Optics Letters, 24, 3, pp. 142-144, (1999)
[2] Chen H.W., Chen M.H., Qiu C.Y., Et al., Orthogonal polarization shift keying label rewriting method in all-optical label switching network, Optics Letters, 32, 9, pp. 1050-1052, (2007)
[3] Chen Q.D., Lin X.F., Li G.N., Et al., Dammann grating as integratable micro-optical elements created by laser micronanofabrication via two-photon photopolymerization, Optics Letters, 33, 21, pp. 2559-2561, (2008)
[4] Bortolozzo U., Haudin F., Residori S., Diffraction properties of optical localized structures, Optics Letters, 33, 22, pp. 2698-2700, (2008)
[5] Sapiens N., Weissbrod A., Aharon J., Fast electroholographic switching, Optics Letters, 34, 3, pp. 353-355, (2009)
[6] Omel Mendoza Y., Gladys M.V., Mercedes F.A., Optics filters with fracal transmission spectra based on diffractive optics, Optics Letters, 34, 5, pp. 560-562, (2009)
[7] Sluijter M., Kgde B.D., Urbach H.P., Simulations of a liquid-crystal-based electro-optical switch, Optics Letters, 34, 1, pp. 94-96, (2009)
[8] Ziping H., Pramode V., James S., Improved reliability of free-space optical mesh networks through topology design, Journal of Optical Networking, 7, 5, pp. 436-448, (2008)
[9] Reardon C., Di Falco A., Wella K., Et al., Integrated polymer microprisms for free space optical beam deflecting, Optics Express, 17, 5, pp. 3424-3428, (2009)
[10] Yang J.B., Su X.Y., Xu P., Implementation of Two-dimensional perfect shuffle transform using step-based micro-blazed grating planar-array, Opt. Precision Eng., 15, 10, pp. 1495-1502, (2007)

← 1 2 3 4 →