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TinyML-Based Real-Time Drift Compensation for Gas Sensors Using Spectral–Temporal Neural Networks

Adir Krayden, M. Avraham, Halim Ashkar, T. Blank, Sara Stolyarova, Y. Nemirovsky

2025Chemosensors10 citationsDOIOpen Access PDF

Abstract

The implementation of low-cost sensitive and selective gas sensors for monitoring fruit ripening and quality strongly depends on their long-term stability. Gas sensor drift undermines the long-term reliability of low-cost sensing platforms, particularly in precision agriculture. We present a real-time drift compensation framework based on a lightweight Temporal Convolutional Neural Network (TCNN) combined with a Hadamard spectral transform. The model operates causally on incoming sensor data, achieving a mean absolute error below 1 mV on long-term recordings (equivalent to <1 particle per million (ppm) gas concentration). Through quantization, we compress the model by over 70%, without sacrificing accuracy. Demonstrated on a combustion-type gas sensor system (dubbed GMOS) for ethylene monitoring, our approach enables continuous, drift-corrected operation without the need for recalibration or dependence on cloud-based services, offering a generalizable solution for embedded environmental sensing—in food transportation containers, cold storage facilities, de-greening rooms and directly in the field.

Topics & Concepts

Real-time computingComputer scienceConvolutional neural networkEnvironmental scienceCompensation (psychology)DetectorArtificial intelligenceTelecommunicationsPsychologyPsychoanalysisAdvanced Chemical Sensor TechnologiesAnalytical Chemistry and SensorsInsect Pheromone Research and Control