Network traffic demands are forecast to increase for the foreseeable future, with the challenge being to meet the demand while maintaining or lowering network costs. Simply increasing capacity will not be sufficient; overall bandwidth utilization also needs to improve. A combination of improved transport capacity through increased spectral efficiency and bit rate along with better network utilization by integrating subchannel electrical grooming into the transmission system will be required. Smarter ways to utilize optical capacity are key since transmission costs have been decreasing slower than grooming and switching costs. Integrated transport and switching can improve the efficiency of the client network using techniques such as port virtualization and transit traffic reduction. The baseline for transport networks will be 100 Gb/s PM-QPSK using 50 GHz channel spacing. Moving from a fixed DWDM channel arrangement to support flexible grid and super channels will allow tighter channel (carrier) spacing and should increase capacity by 30 to 50 percent. For shorter distances higher-order modulation such as 16-QAM can double network capacity. To better optimize network efficiency, an architecture that flexibly combines lower rate (sub-100 Gb/s) clients to form channels (carriers) and then superchannels will be required.
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机译:预计在可预见的将来,网络流量需求将增加,而挑战是在保持或降低网络成本的同时满足需求。仅仅增加容量是不够的。整体带宽利用率也需要提高。将需要通过提高频谱效率和比特率来提高传输容量,以及通过将子信道电疏导集成到传输系统中来更好地利用网络。利用光容量的更智能方法是关键,因为传输成本下降的速度比梳理和交换成本的下降速度慢。集成的传输和交换可以使用端口虚拟化和减少传输流量之类的技术来提高客户端网络的效率。传输网络的基线将是使用50 GHz信道间隔的100 Gb / s PM-QPSK。从固定的DWDM信道安排转变为支持灵活的网格和超级信道,将允许更紧密的信道(载波)间距,并且应将容量增加30%到50%。对于较短的距离,高阶调制(例如16-QAM)可使网络容量增加一倍。为了更好地优化网络效率,将需要一种将低速率(低于100 Gb / s)客户端灵活组合以形成通道(载波)然后再形成超通道的架构。
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