Detection of Formaldehyde in Mixed VOCs Gases Using Sensor Array With Neural Networks

A four-sensor array with neural networks was developed to identify formaldehyde in three possible interfering volatile organic vapors, such as acetone, ethanol, and toluene. The sensor array consisted of four metal oxide-based gas sensors: two of them are commercial SnO2 sensors, other two sensors are made in our laboratory. The responses of the sensors to each gas and to the mixture of two or all of them were tested and evaluated. It was found that every sensor has response to these four kinds of gases, and the response value of each sensor to the mixture gases was lower than the simple added value of the responses to each gas. This phenomenon is due to the properties of gas and the sensing materials. For recognizing formaldehyde in the background of ethanol, acetone, and toluene in air, 108 gas samples were tested taking into account of possible practical concentrations. Among these samples, 91 samples were used for training the pattern recognition methods and 17 samples for testing the robustness. Three neural networks were used in this report, including back propagation neural network support vector machines (SVM) and extreme learning machine (ELM) with principal component analysis (PCA). The PCA helps to improve the accuracy of the ELM by preprocessing the sensor data, while the SVM method achieves the best accuracy. The ELM method indicates a better way to train the sensor array and to identify the particular gas species with very less training time and good accuracy.

[1]  Kai Song,et al.  A Wireless Electronic Nose System Using a Fe2O3 Gas Sensing Array and Least Squares Support Vector Regression , 2011, Sensors.

[2]  Sadique Sheik,et al.  Reservoir computing compensates slow response of chemosensor arrays exposed to fast varying gas concentrations in continuous monitoring , 2015 .

[3]  Wei Wu,et al.  Convergence analysis of online gradient method for BP neural networks , 2011, Neural Networks.

[4]  Hyuntae Kim,et al.  Electronic-nose for detecting environmental pollutants: signal processing and analog front-end design , 2012 .

[5]  Robert F. Stengel,et al.  Smooth function approximation using neural networks , 2005, IEEE Transactions on Neural Networks.

[6]  Chunyan Miao,et al.  Comparing the learning effectiveness of BP, ELM, I-ELM, and SVM for corporate credit ratings , 2014, Neurocomputing.

[7]  Nicolae Barsan,et al.  Conduction mechanism in undoped and antimony doped SnO2 based FSP gas sensors , 2013 .

[8]  G. Teschl,et al.  The role of mathematical modeling in VOC analysis using isoprene as a prototypic example , 2011, Journal of breath research.

[9]  Jing Wang,et al.  Hollow hierarchical SnO2-ZnO composite nanofibers with heterostructure based on electrospinning method for detecting methanol , 2014 .

[10]  Elfed Lewis,et al.  Principal component analysis and artificial neural network based approach to analysing optical fibre sensors signals , 2007 .

[11]  Yoshio Suzuki,et al.  Portable sick house syndrome gas monitoring system based on novel colorimetric reagents for the highly selective and sensitive detection of formaldehyde. , 2003, Environmental science & technology.

[12]  Kenji Kawashima,et al.  Concentration measurement systems with stable solutions for binary gas mixtures using two flowmeters , 2011 .

[13]  Hongming Zhou,et al.  Optimization method based extreme learning machine for classification , 2010, Neurocomputing.

[14]  J. Bosset,et al.  The electronic nose applied to dairy products: a review , 2003 .

[15]  Il-Doo Kim,et al.  Selective and sensitive detection of trimethylamine using ZnO-In2O3 composite nanofibers , 2013 .

[16]  Alexandre Perera,et al.  Drift compensation of gas sensor array data by Orthogonal Signal Correction , 2010 .

[17]  Thorsten Hesjedal,et al.  Development of an electronic nose sensing platform for undergraduate education in nanotechnology , 2011 .

[18]  Donald J. Sirbuly,et al.  Detection and discrimination of pure gases and binary mixtures using a dual-modality microcantilever sensor , 2010 .

[19]  Terry A. Ring,et al.  NiO thin-film formaldehyde gas sensor , 2001 .

[20]  Jing Wang,et al.  Synthesis, characterization and formaldehyde gas sensitivity of La0.7Sr0.3FeO3 nanoparticles assembled nanowires , 2012 .

[21]  E. M. El-M. Shokir,et al.  Artificial neural networks modeling for hydrocarbon gas viscosity and density estimation , 2011 .

[22]  Joachim Biermann,et al.  A new feature extraction method for odour classification , 2011 .

[23]  Andreas Schütze,et al.  Influence of MOS Gas-Sensor Production Tolerances on Pattern Recognition Techniques in Electronic Noses , 2012, IEEE Transactions on Instrumentation and Measurement.

[24]  M. Pardo,et al.  Classification of electronic nose data with support vector machines , 2005 .

[25]  Yanchun Liang,et al.  Successive approximation training algorithm for feedforward neural networks , 2002, Neurocomputing.

[26]  G. Ingrosso Free radical chemistry and its concern with indoor air quality: an open problem , 2002 .

[27]  Behzad Bahraminejad,et al.  Application of a sensor array based on capillary-attached conductive gas sensors for odor identification , 2010 .

[28]  George-John E. Nychas,et al.  Rapid qualitative and quantitative detection of beef fillets spoilage based on Fourier transform infrared spectroscopy data and artificial neural networks , 2010 .

[29]  N. Yamazoe,et al.  Proposal of contact potential promoted oxide semiconductor gas sensor , 2013 .

[30]  Xiaojie Shi,et al.  A portable embedded toxic gas detection device based on a cross-responsive sensor array , 2012 .