Ethernet passive optical network (EPON): building a next-generation optical access network
IEEE Communications Magazine
IPACT a dynamic protocol for an Ethernet PON (EPON)
IEEE Communications Magazine
Efficient transport of packets with QoS in an FSAN-aligned GPON
IEEE Communications Magazine
Ethernet PONs: a survey of dynamic bandwidth allocation (DBA) algorithms
IEEE Communications Magazine
Vulnerability assessment and security of scalable and bandwidth elastic next generation PONs
ICCOM'07 Proceedings of the 11th Conference on 11th WSEAS International Conference on Communications - Volume 11
Vulnerabilities and security strategy for the next generation bandwidth elastic PON
WSEAS TRANSACTIONS on COMMUNICATIONS
Fast and secure handover schemes based on proposed WiMAX over EPON network security architecture
WSEAS TRANSACTIONS on COMMUNICATIONS
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Long haul optical networks have been on focus for more than two decades. With the advent of dense wavelength division multiplexing technology, optical long haul fiber networks have been so successful in delivering an unprecedented amount of bandwidth that they outperformed the traffic deliverability from/to the access network by orders of magnitude. The reason was a cost-efficiency mismatch; long haul ultra-high bandwidth networks can take advantage of state of the art and costly technology, which cost-sensitive access networks cannot. The result was an unbalanced traffic flow from/to access points to the network if one compares the aggregate flow of the long haul network with that of the access. Nevertheless, over the last decade technology at the access advanced and new standards have been developed so that in the access layer of the overall communications network the focus has shifted onto fiber optic access again. Thus, in the optical regime, two proposals have prevailed. One uses a time division multiplexing (TDM) scheme over a single wavelength and a comprehensive timing protocol, and the other uses coarse wavelength division multiplexing (CWDM) technology. Each technology has advantages and disadvantages, and the one attempts to address the disadvantages of the other. In this paper we describe a hierarchical CWDM/TDM passive optical network (PON). Our access network architecture is scalable, it is flexible to accommodate one of several topologies simultaneously, and it delivers any type of payload, synchronous and asynchronous that spans from DS0 to Gbps. We discuss the bandwidth flexibility, versatility, resiliency and cost efficiency of the access network. We also demonstrate that our network can deliver payload to more than 16,000 end-users using simple and existing optical technology. Thus, if one considers cost per bandwidth or per user, the cost-efficiency outperforms any previous PON access network. Moreover, we provide simulation results to support the viability of our network architecture. ure.