Reference Hub

This research has been cited in:

Article
A biomimetic approach to machine olfaction, featuring a very large-scale chemical sensor array and embedded neuro-bio-inspired computationMicrosystem Technologies10.1007/s00542-013-2020-8
Article
Artificial Olfaction in the 21st CenturyIEEE Sensors Journal10.1109/JSEN.2021.3076412
Article
Improved Sensing Capability of Integrated Semiconducting Metal Oxide Gas Sensor DevicesSensors10.3390/s19020374
Conference
Discontinuously operated MOX sensors for low power applications2017 ISOCS/IEEE International Symposium on Olfaction and Electronic Nose (ISOEN)10.1109/ISOEN.2017.7968847

Improving the Robustness of Odor Sensing Systems by Multivariate Signal Processing

Marta Padilla, Jordi Fonollosa, Santiago Marco

Source Title: Human Olfactory Displays and Interfaces: Odor Sensing and Presentation

ISBN13: 9781466625211|ISBN10: 146662521X|EISBN13: 9781466625228

DOI: 10.4018/978-1-4666-2521-1.ch014

Cite Chapter Cite Chapter

MLA

Padilla, Marta, et al. "Improving the Robustness of Odor Sensing Systems by Multivariate Signal Processing." Human Olfactory Displays and Interfaces: Odor Sensing and Presentation, edited by Takamichi Nakamoto, IGI Global, 2013, pp. 296-316. https://doi.org/10.4018/978-1-4666-2521-1.ch014

APA

Padilla, M., Fonollosa, J., & Marco, S. (2013). Improving the Robustness of Odor Sensing Systems by Multivariate Signal Processing. In T. Nakamoto (Ed.), Human Olfactory Displays and Interfaces: Odor Sensing and Presentation (pp. 296-316). IGI Global. https://doi.org/10.4018/978-1-4666-2521-1.ch014

Chicago

Padilla, Marta, Jordi Fonollosa, and Santiago Marco. "Improving the Robustness of Odor Sensing Systems by Multivariate Signal Processing." In Human Olfactory Displays and Interfaces: Odor Sensing and Presentation, edited by Takamichi Nakamoto, 296-316. Hershey, PA: IGI Global, 2013. https://doi.org/10.4018/978-1-4666-2521-1.ch014

Export Reference

Favorite

View Full Text HTML

View Full Text PDF

Abstract

Electronic noses or artificial olfaction systems based on chemical gas sensors present lack of robustness, a problem that is mainly technological and requires more research to improve fabrication processes and develop new technologies. However, statistical signal processing can help to mathematically reduce those unwanted effects on the sensors responses before the prediction step. In this chapter, the authors explore the concept of robustness in electronic nose instruments and the use of several multivariate signal processing techniques to deal with two specific problems related to such lack of robustness: time instability (drift) and the detection of a possible faulty sensor in the array. In particular, three different techniques that deal with drift problems are reviewed. These techniques address drift by correction of unwanted variance, by taking advantage of the characteristics of a three-way data arrangement, or by using a blind strategy to extract information with chemical meaning. Finally, a method based on principal component analysis is presented for fault detection, faulty sensor identification, and correction of a fault in a sensor array.

You do not own this content. Please login to recommend this title to your institution's librarian or purchase it from the IGI Global bookstore.

Username or email: *

Password: *

Forgot individual login password?

Create individual account

Improving the Robustness of Odor Sensing Systems by Multivariate Signal Processing

MLA

APA

Chicago

Export Reference

Abstract

Request Access