TY - GEN
T1 - Gas identification with Pairwise comparison in an artificial olfactory system
AU - Hassan, M.
AU - Bermak, A.
AU - Amira, A.
N1 - Publisher Copyright:
© 2015 Taylor & Francis Group, London.
PY - 2015
Y1 - 2015
N2 - An artificial olfactory system, referred to an electronic nose, is a multi-sensor platform used for gas classification. Lack of selectivity and low repeatability of the gas sensors are the major challenges in all gas identification problems. Pattern recognition algorithms are combined with a sensor array to address these challenges. The implementation of these algorithms is another challenge for the hardware friendly system. In this paper, we introduce a hardware friendly algorithm for gas identification. In this algorithm, we use sensitivity difference of any two sensors in the array as an input feature and a subset of the features is extracted by evaluating the capability of each pair of sensor to split the gases into two branches. The learning process of the pairs of sensors continues at every split point on the way until all individual gases are identified. The learned pairs of sensors at each split point are used for the identification of a new test response pattern and plurality voting is used for the distribution of the gases in cases of contention among the pairs. In order to assess the performance of our approach, a 4x4 tin-oxide gas sensor array is used to acquire the data of three gases in a laboratory. Accuracy rate of 100% is achieved with our algorithm on this experimental data set.
AB - An artificial olfactory system, referred to an electronic nose, is a multi-sensor platform used for gas classification. Lack of selectivity and low repeatability of the gas sensors are the major challenges in all gas identification problems. Pattern recognition algorithms are combined with a sensor array to address these challenges. The implementation of these algorithms is another challenge for the hardware friendly system. In this paper, we introduce a hardware friendly algorithm for gas identification. In this algorithm, we use sensitivity difference of any two sensors in the array as an input feature and a subset of the features is extracted by evaluating the capability of each pair of sensor to split the gases into two branches. The learning process of the pairs of sensors continues at every split point on the way until all individual gases are identified. The learned pairs of sensors at each split point are used for the identification of a new test response pattern and plurality voting is used for the distribution of the gases in cases of contention among the pairs. In order to assess the performance of our approach, a 4x4 tin-oxide gas sensor array is used to acquire the data of three gases in a laboratory. Accuracy rate of 100% is achieved with our algorithm on this experimental data set.
UR - http://www.scopus.com/inward/record.url?scp=84962136612&partnerID=8YFLogxK
M3 - Conference contribution
AN - SCOPUS:84962136612
SN - 9781138028128
T3 - Testing and Measurement: Techniques and Applications - Proceedings of the 2015 International Conference on Testing and Measurement: Techniques and Applications, TMTA 2015
SP - 309
EP - 312
BT - Testing and Measurement
A2 - Chan, Kennis
PB - CRC Press/Balkema
T2 - International Conference on Testing and Measurement: Techniques and Applications, TMTA 2015
Y2 - 16 January 2015 through 17 January 2015
ER -