Blocking performance of tree establishment in time-space switched optical networks

Multicasting in the optical layer has gained significant importance in the recent years due to several factors. Most of the research work in this area concentrate either on minimizing the number of wavelengths required to meet a given static demand or on multicast route selection algorithms to achieve efficient utilization of fiber bandwidth. Very few significant research has been found, to the best of authors\u27 knowledge, in developing an analytical model for evaluating the blocking performance of tree establishment in optical networks, which motivates this research. In this paper, an analytical model for evaluating the blocking performance of multicast tree establishment in time-space switched optical networks is developed. The performance of different switch architectures are then studied using the analytical model. it is observed that if the multicast tree has very low degree of branching, the blocking probability of establishing the tree is the same as that of establishing a path with same number of links

PAM Performance Analysis in Multicast-Enabled Wavelength-Routing Data Centers

Multilevel pulse amplitude modulation (M-PAM) is gaining momentum for high-capacity and power-efficient cloud computing. Compared to the classic on-off keying (OOK) modulation, high-order PAM yields better spectral efficiency but is also more susceptible to physical layer degradation effects. We develop a cross-layer analysis framework to examine the PAM transmission performance in data center network environments supporting both optical multicasting and wavelength routing. Our analysis is conducted on a switch architecture based on an arrayed-waveguide grating (AWG) core and distributed broadcast domains, exhibiting different physical paths, and random, uncontrolled crosstalk noise. Reed-Solomon coding with rate adaptation is incorporated into PAM transceivers to compensate for impairments. Our Monte Carlo simulations point to the significant impact of AWG crosstalk on higher order PAM in wavelength-reuse architectures and the importance of code rate adaptation for signals traversing multiple routing stages. According to our study, 8-PAM offers the highest effective bit rates for signals terminating in one broadcast domain and performs poorly when considering interdomain connectivity. On the other hand, the impairment-induced degradation of interdomain capacity for 4-PAM can be limited to 20.7%, making it better suited for connections spanning two broadcast domains and a crosstalk-rich stage. Our results call for software-defined PAM transceiver designs in support of both modulation order and code rate adaptation

IP multicast over WDM networks

Ph.DDOCTOR OF PHILOSOPH

Cost-effective constructions for nonblocking wdm multicast switching networks

Abstract — Constructing wavelength division multiplexing (WDM) multicast switches with cheap components and low complexity is an important problem in optical networking, since multicasting is one of the key requirements of emerging bandwidth-intensive applications such as video conferencing, video on demand and online gaming. In this paper we present several new cost-effective designs for constructing non-blocking WDM multicast switching networks. More specifically, we provide a wide-sense nonblocking switch architecture, which uses fewer semiconductor optical amplifiers than existing architectures. In addition, for the first time we have presented a rearrangeably nonblocking WDM switch architecture using array waveguide grating routers and wavelength converters. I