Abstract
For reliable and efficient network planning and operation, accurate estimation of Quality of Transmission (QoT) before establishing or reconfiguring the connection is necessary. In optical networks, a design margin is generally included in a QoT estimation tool (Qtool) to account for modeling and parameter inaccuracies, ensuring the acceptable performance. In this article, we use monitoring information from an operating network combined with supervised machine learning (ML) techniques to understand the network conditions. In particular, we model the penalties generated due to i) Erbium Doped Fiber Amplifier (EDFA) gain ripple effect, and ii) filter spectral shape uncertainties at Reconfigurable Optical Add and Drop Multiplexer (ROADM) nodes. Enhancing the Qtool with the proposed ML regression models yields estimates for new or reconfigured connections that account for these two effects, resulting in more accurate QoT estimation and a reduced design margin. We initially propose two supervised ML regression models, implemented with Support Vector Machine Regression (SVMR), to estimate the individual penalties of the two effects and then a combined model. On Deutsche Telekom (DT) network topology with 12 nodes and 40 bidirectional links, we achieve a design margin reduction of ~1 dB for new connection requests.
Highlights
THE rapid development of emerging services and applications such as cloud computing, high-definition video streaming etc. along with the latest networking paradigms (e.g., Internet of Things) require higher capacity and Quality of Transmission (QoT) guaranteed end-to-end performance [1], [2]
We denote by Fm(pc, λc) the spectral response of the filter located at the end of mth link along pc (ROADM nodes might implement more than one filter but we focus on just one per link)
We present our proposed solution: use monitoring information in an operating network combined with machine learning (ML) to model the penalties due to these effects
Summary
THE rapid development of emerging services and applications such as cloud computing, high-definition video streaming etc. along with the latest networking paradigms (e.g., Internet of Things) require higher capacity and QoT guaranteed end-to-end performance [1], [2]. Along with the latest networking paradigms (e.g., Internet of Things) require higher capacity and QoT guaranteed end-to-end performance [1], [2]. For effective optical network planning, it is necessary to estimate the QoT of the connections prior to their establishment. This requires accurate models or tools to estimate the QoT of new or reconfigured connections. EONs provide vast optimization dimensions, optical networks are traditionally planned to be operated statically. In such static network operating mode, high margins are included in the planning phase to ensure acceptable QoT performance up to the end of life [6], [7]. Lowering the margins and increasing efficiency reduces the network cost, motivating various research directions
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