Design and performance of an optical path cross-connect system based on wavelength path concept

“…We assume each type of ring has 10, 15, 20, 25, or 30 nodes. The number of wavelengths per fiber is set to eight, considering the current WDM technologies [5], which follows the OPXC development and transmission experiment [8]- [10]. For each traffic distribution pattern, the simulation examined the OP scheme (WP-UR/2 versus VWP-UR/2 and WP-BR/4 versus VWP-BR/4 ) and different types of rings (WP-UR/2 versus WP-BR/4 ).…”

“…The developed OPXC's have a highly sophisticated architecture which offers high modularity and upgradability from WP to VWP through the use of delivery and coupling type matrix switches (DC-SW's) [4]- [6]. The maximum designed total throughput is 900 Gb/s employing the main-and-junction-frame architecture [7], and successful transport experiments have been conducted using stand-alone OPXC with a designed total throughput of 320 Gb/s (2.5 Gb/s 128 OP's) [8], [9]. The switching experiments have confirmed the technical feasibility of the newly developed 8 16 DC-SW board [10].…”

Architectural analysis of multiple fiber ring networks employing optical paths

“…We assume each type of ring has 10, 15, 20, 25, or 30 nodes. The number of wavelengths per fiber is set to eight, considering the current WDM technologies [5], which follows the OPXC development and transmission experiment [8]- [10]. For each traffic distribution pattern, the simulation examined the OP scheme (WP-UR/2 versus VWP-UR/2 and WP-BR/4 versus VWP-BR/4 ) and different types of rings (WP-UR/2 versus WP-BR/4 ).…”

“…The developed OPXC's have a highly sophisticated architecture which offers high modularity and upgradability from WP to VWP through the use of delivery and coupling type matrix switches (DC-SW's) [4]- [6]. The maximum designed total throughput is 900 Gb/s employing the main-and-junction-frame architecture [7], and successful transport experiments have been conducted using stand-alone OPXC with a designed total throughput of 320 Gb/s (2.5 Gb/s 128 OP's) [8], [9]. The switching experiments have confirmed the technical feasibility of the newly developed 8 16 DC-SW board [10].…”

Architectural analysis of multiple fiber ring networks employing optical paths

“…In [2,[4][5][6], the crossconnection of the various wavelength channels is implemented using space switches with either a crossbar fabric or a bus fabric, something that generates interrelation (crosstalk) between the channels. Large crossbar switches are lossy and their performance is optimum only for one wavelength channel.…”

“…Various optical cross connects architectures have been proposed [2][3][4][5][6][7]. In [2,[4][5][6], the crossconnection of the various wavelength channels is implemented using space switches with either a crossbar fabric or a bus fabric, something that generates interrelation (crosstalk) between the channels.…”

“…Space switches in the form of amplifier gate switch arrays [9][10][11] are attractive but again their complexity should be traded with performance [12] and their scalability per node is limited due to ASE accumulation to a switch size of 32 x 32 [9,10]. In [4][5][6], for each delivery-and-coupling switch, a power combiner is used with number of ports equal to the number of wavelength channels something that is scaling up the passive losses for a considerable number of channels. This architecture is suitable for a large number of links populated with a small number of wavelength channels something that under-utilize the fibre bandwidth.…”

Optical cross-connect architecture for high-capacity WDM wavelength routed networks

Optical Switching in Communications Networks