Binary Fingerprints at Fluctuation-Enhanced Sensing
Abstract
We developed a simple way to generate binary patterns based on spectral slopes in different frequency ranges at fluctuation-enhanced sensing. Such patterns can be considered as binary "fingerprints" of odors. The method has experimentally been demonstrated with a commercial semiconducting metal oxide (Taguchi) sensor exposed to bacterial odors (Escherichia coli and Anthrax-surrogate Bacillus subtilis) and processing their stochastic signals. With a single Taguchi sensor, the situations of empty chamber, tryptic soy agar (TSA) medium, or TSA with bacteria could be distinguished with 100% reproducibility. The bacterium numbers were in the range of 25 thousands to 1 million. To illustrate the relevance for ultra-low power consumption, we show that this new type of signal processing and pattern recognition task can be implemented by a simple analog circuitry and a few logic gates with total power consumption in the microWatts range.
Cite
@article{arxiv.0912.5212,
title = {Binary Fingerprints at Fluctuation-Enhanced Sensing},
author = {Hung-Chih Chang and Laszlo B. Kish and Maria D. King and Chiman Kwan},
journal= {arXiv preprint arXiv:0912.5212},
year = {2010}
}
Comments
submitted for publication