Journal
SENSORS AND ACTUATORS B-CHEMICAL
Volume 387, Issue -, Pages -Publisher
ELSEVIER SCIENCE SA
DOI: 10.1016/j.snb.2023.133709
Keywords
Transfer calibration; Drift compensation; Electronic nose; Mixture gases; Concentration measurement
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In order to address the performance issues of gas sensor systems in complex gas mixtures, we propose a comprehensive algorithm called HATN-DA. This algorithm utilizes multi-head transformers and channelwise attention mechanisms for feature extraction, and encodes gas species into concentration information using capsule vectors. It also achieves label-free drift compensation and transfer calibration effects through a domain discriminator.
For most applications, the sensor system needs to identify/measure target gases in mixture conditions simultaneously, while countering the performance degradation caused by the drift deviation and batch to batch discrepancy. To solve these problems, we propose a comprehensive algorithm, hybrid attention-based transformer network with domain adversarial learning (HATN-DA). Inside it, multi-head transformer and channelwise attention mechanism serving as main blocks of the feature extractor effectively capture temporal dependencies and lays emphasis on the diversities of sensors. Then, the capsule vector is applied in the predictor to encode gas species into the concentration information. Besides, the domain discriminator calculates Wasserstein distance of gas features between source and target domains, which is optimized through the back propagation by the feature extractor during the training process. Based on this, label-free drift compensation and transfer calibration effects are achieved: for public dataset, HATN-DA achieves 97.50 similar to 100% accuracies for drift compensation experiment; for dataset of mixture gases, in the batch transfer tasks, HATN-DA achieves an accuracy of 98.79%, significantly improved compared to 90.16% (before transfer). Besides, in the cross-domain real-time concentration prediction tasks, HATN-DA achieves a normalized root mean squared error of 3.32%, 3.25%, 6.62% and 3.01% for ethanol, methane, carbon monoxide and ethylene.
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