Low-Complexity Modulation Format Identification Based on Amplitude Histogram Distributions for Digital Coherent Receivers

Abstract: In this work, a prior-training-free and low-complexity modulation format identification (MFI) scheme, based on amplitude histogram distributions, was proposed and demonstrated, both numerically and experimentally, for autonomous digital coherent receivers. In the proposed scheme, after having performed power normalization, incoming polarization division multiplexed (PDM) signals were classified into QPSK, 8QAM, 16QAM, 32QAM and 64QAM signals, according to their ratios. Ratios were defined according to specific… Show more

“…Although there are nine amplitude levels for 64QAM, its corresponding amplitude histogram does not, however, clearly illustrate nine distinguishable levels in the presence of noise. Since the associated probability for the sixth amplitude level of 64QAM is highest [3], N 5 , representing the number of symbols within the range of (A 5 ~B5 ), can thus be calculated to extract the feature for 64QAM. N 1 , N 2 , N 3 , N 4 and N 5 mainly represent the features located in the front and middle of the relevant histograms, whilst N 6 for 128QAM extracts the feature located in the last part of the histogram.…”

“…Meanwhile, the optical network is required to meet heterogeneous and dynamic demands for supporting diverse data services, such as 5G, cloud computing, big data and the internet of things by optimizing the allocation of the bandwidth and modulation format. As a direct result, the optical network is evolving from fixed network architectures to flexible and elastic ones [2,3]. In elastic optical networks (EONs), according to different channel characteristics and various data services, the involved transceivers can dynamically adjust the modulation formats utilized for encoding the optical signals, which raises new demands on digital coherent receivers.…”

Modulation Format Identification Based on Multi-Dimensional Amplitude Features for Elastic Optical Networks

“…Although there are nine amplitude levels for 64QAM, its corresponding amplitude histogram does not, however, clearly illustrate nine distinguishable levels in the presence of noise. Since the associated probability for the sixth amplitude level of 64QAM is highest [3], N 5 , representing the number of symbols within the range of (A 5 ~B5 ), can thus be calculated to extract the feature for 64QAM. N 1 , N 2 , N 3 , N 4 and N 5 mainly represent the features located in the front and middle of the relevant histograms, whilst N 6 for 128QAM extracts the feature located in the last part of the histogram.…”

“…Meanwhile, the optical network is required to meet heterogeneous and dynamic demands for supporting diverse data services, such as 5G, cloud computing, big data and the internet of things by optimizing the allocation of the bandwidth and modulation format. As a direct result, the optical network is evolving from fixed network architectures to flexible and elastic ones [2,3]. In elastic optical networks (EONs), according to different channel characteristics and various data services, the involved transceivers can dynamically adjust the modulation formats utilized for encoding the optical signals, which raises new demands on digital coherent receivers.…”

Modulation Format Identification Based on Multi-Dimensional Amplitude Features for Elastic Optical Networks