Two-dimensional wavelet transform feature extraction for porous silicon chemical sensors
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Designing reliable, fast responding, highly sensitive, and low-power consuming chemo-sensory systems has long been a major goal in chemo-sensing. This goal, however, presents a difficult challenge because having a set of chemo-sensory detectors exhibiting all these aforementioned ideal conditions are still largely un-realizable to-date. This paper presents a unique perspective on capturing more in-depth insights into the physicochemical interactions of two distinct, selectively chemically modified porous silicon (pSi) film-based optical gas sensors by implementing an innovative, based on signal processing methodology, namely the two-dimensional discrete wavelet transform. Specifically, the method consists of using the two-dimensional discrete wavelet transform as a feature extraction method to capture the non-stationary behavior from the bi-dimensional pSi rugate sensor response. Utilizing a comprehensive set of measurements collected from each of the aforementioned optically based chemical sensors, we evaluate the significance of our approach on a complex, six-dimensional chemical analyte discrimination/quantification task problem. Due to the bi-dimensional aspects naturally governing the optical sensor response to chemical analytes, our findings provide evidence that the proposed feature extractor strategy may be a valuable tool to deepen our understanding of the performance of optically based chemical sensors as well as an important step toward attaining their implementation in more realistic chemo-sensing applications. © 2013 Elsevier B.V.
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Feature extraction; Gas discrimination and quantification; Optical porous silicon gas sensor; Support vector machines; Two-dimensional wavelet transform Chemically modified; Feature extraction methods; Feature extractor; Non-stationary behaviors; Optical gas sensors; Physico-chemical interactions; Porous silicon gas sensors; Two-dimensional discrete wavelet transform; Chemical analysis; Feature extraction; Gas detectors; Multiresolution analysis; Porous silicon; Signal processing; Support vector machines; Wavelet transforms; Chemical sensors; silicon; article; concentration (parameters); controlled study; extraction; feature extraction; imaging and display; intermethod comparison; molecular interaction; optical porous silicon gas sensor; physical chemistry; prediction; priority journal; quantitative analysis; sensitivity analysis; sensor; signal processing; support vector machine; two dimensional imaging; wavelet analysis; Algorithms; Electrochemical Techniques; Gases; Oxidation-Reduction; Porosity; Principal Component Analysis; Silicon; Spectrophotometry; Temperature
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