Litcius/Paper detail

DAS-MAE: A Self-Supervised Framework for Universal and High-Performance Representation Learning of Distributed Acoustic Sensing

Junyi Duan, Jiageng Chen, Zuyuan He

2025Journal of Lightwave Technology6 citationsDOIOpen Access PDF

Abstract

Distributed fiber-optic acoustic sensing (DAS) has emerged as a transformative approach for distributed vibration measurement with high spatial resolution and long measurement range while maintaining cost-efficiency. However, the two-dimensional spatial-temporal DAS signals present analytical challenges. The abstract signal morphology lacking intuitive physical correspondence complicates human interpretation, and its unique spatial-temporal coupling renders conventional image processing methods suboptimal. This study investigates spatial-temporal characteristics and proposes a self-supervised pre-training framework that learns signals' representations through a mask-reconstruction task. This framework is named the DAS Masked AutoEncoder (DAS-MAE). The DAS-MAE learns high-level representations (e.g., event class) without using labels. It achieves up to 1% error and 64.5% relative improvement (RI) over the semi-supervised baseline in few-shot classification tasks. In a practical external damage prevention application, DAS-MAE attains a 5.0% recognition error, marking a 75.7% RI over supervised training from scratch. These results demonstrate the high-performance and universal representations learned by the DAS-MAE framework, highlighting its potential as a foundation model for analyzing massive unlabeled DAS signals.

Topics & Concepts

AutoencoderComputer scienceRepresentation (politics)Artificial intelligencePattern recognition (psychology)Signal processingEvent (particle physics)Range (aeronautics)SIGNAL (programming language)Baseline (sea)Feature learningCoupling (piping)Deep learningMachine learningRangingSupervised learningTransformative learningDistributed learningSequence (biology)Detection theoryDistributed acoustic sensingComputer visionVibrationImage resolutionArtificial neural networkFeature extractionContextual image classificationObject detectionResolution (logic)Image (mathematics)Advanced Fiber Optic SensorsSeismic Waves and AnalysisUltrasonics and Acoustic Wave Propagation
DAS-MAE: A Self-Supervised Framework for Universal and High-Performance Representation Learning of Distributed Acoustic Sensing | Litcius