Spectral processing techniques for efficient monitoring in optical networks

Abstract: Having ubiquitous optical monitors in dense wavelength-division multiplexing (DWDM) or flex-grid networks allows the estimation in real time of crucial parameters. Such monitoring would be even more important in disaggregated optical networks, to inspect performance issues related to inter-vendor interoperability. Several important parameters can be retrieved using optical spectrum analyzers (OSAs). However, omnipresent OSAs represents an infeasible solution. Nevertheless, the advent of new, relatively cheap, … Show more

“…OSA: optical spectrum analyzer (OSA) is an instrument used to measure the properties of optical spectrum and display the distribution of power over a specified wavelength range [21]. OSA is one of the most useful tools for optical performance monitoring (OPM), quality of signal (QoS) analysis, and network resource management (NRM) [22]. Thus, optical spectral data are crucial for failure management, and lots of information can be obtained from the optical spectrum, such as channel distribution condition, optical signal parameters (wavelength, bandwidth, OSNR, power), and non-ideal filter effects.…”

A review of machine learning-based failure management in optical networks

“…OSA: optical spectrum analyzer (OSA) is an instrument used to measure the properties of optical spectrum and display the distribution of power over a specified wavelength range [21]. OSA is one of the most useful tools for optical performance monitoring (OPM), quality of signal (QoS) analysis, and network resource management (NRM) [22]. Thus, optical spectral data are crucial for failure management, and lots of information can be obtained from the optical spectrum, such as channel distribution condition, optical signal parameters (wavelength, bandwidth, OSNR, power), and non-ideal filter effects.…”

A review of machine learning-based failure management in optical networks

“…In particular, in [19], we proposed and experimentally validated an ML-based method for estimating the ASE noise relying on optical spectral data collected in the egress monitor placement scenario. We further experimentally verified such a solution under different circumstances in [128] and [127]. In [126], we proposed and experimentally validated a method to extract filterrelated parameters from optical spectral data acquired within the ingress placement scenario.…”

“…In [126], we proposed and experimentally validated a method to extract filterrelated parameters from optical spectral data acquired within the ingress placement scenario. We further validate such a solution in [127]. Finally, in [127], we compared the two identified placement scenarios and the accuracy of the related methods for the parameter estimation, providing some guidelines on their employment.…”

“…We further validate such a solution in [127]. Finally, in [127], we compared the two identified placement scenarios and the accuracy of the related methods for the parameter estimation, providing some guidelines on their employment. In this chapter, when we mention the monitored spectral data, we refer to the monitored PSD; therefore, we will use these two terms interchangeably.…”

“…The first one, subtask B1, refers to identifying adequate strategies for the placement of optical spectral monitors within the optical network. To this aim, in [126] and in [127], we defined an ingress and an egress placement scenario. The second subtask, B2, identifies two spectral-based solutions for signal and filter-related parameters estimation within the two previously identified placement scenarios.…”

Study and application of spectral monitoring techniques for optical network optimization

Non Intrusive Optical Performance Monitoring in Fiber Optic Networks Using Coherent Receivers as Spectrum Analyzers