Our approach combines quality of transmission (QoT) estimation with consideration of not exactly knowledge of component parameters and soft-failure management in one framework. The framework is driven by spectral data obtained through optical spectrum analyzers (OSAs) which are preprocessed using a variational autoencoder. We experimentally validate our approach using a comprehensive QoT estimation dataset, emulated soft-failures from experiments and compare the approach with the literature.

The exponentially growing demand for high-speed data necessitates more complex and versatile networks. Optimization and reliability assurance of such high-complexity networks is getting increasingly important. In this article, we experimentally validate our a machine learning-based framework that combines quality of transmission (QoT) estimation with soft-failure detection, identification, and localization based on the same latent space of a variational autoencoder running on optical spectra obtained by optical spectrum analyzers at high priority nodes in the network. We further investigate the advantages of a variational autoencoder-based soft-failure detection mechanism over a QoT metric-based approach. We use data acquired from optical transmission experiments involving different modulation formats and channel configurations. The results demonstrate that the proposed framework achieves reliable QoT estimation in real world scenarios. Additionally, it effectively detects soft-failures, identifies specific failure types and accurately localizes the occurrence of failures.