P-33 Machine Learning Analysis of Multimodal Data from a Smartphone-Based Electrochemiluminescence Sensor
Presenter Status
Professor, Engineering
Second Presenter Status
Professor, Engineering
Third Presenter Status
Professor, Computing
Preferred Session
Poster Session
Location
Buller Hall Hallways
Start Date
21-10-2022 2:00 PM
End Date
21-10-2022 3:00 PM
Presentation Abstract
A Machine learning based data analysis was performed for the data analysis obtained from a low-cost alternative, smartphone based, portable electrochemiluminescence (ECL) sensor for phenolic compounds. While the phenolic compounds, vanillic acid and p-coumaric acid, effectively quench the ECL reaction, the light intensity and electric current were simultaneously recorded by the smartphone apps. Due to common problems present in sensor data such as non-linearity, multimodality, sensor-to-senor variations, presence of anomalies, and ambiguity in key features, several machine learning strategies were explored. In contrast to the traditional calibration approach of extracting predetermined key features, the ML methods such as tri-layer neural net or boosted trees carried out effective regression tasks by learning higher patterns without processing the key features. Combined multimodal characteristics made 80% enhanced performance with multilayer neural net algorithms than the traditional approaches. The results demonstrated that the ML methods could provide robust analysis framework for sensor data with noises and variability without preprocessing to extract features or examine ambiguous anomaly.
P-33 Machine Learning Analysis of Multimodal Data from a Smartphone-Based Electrochemiluminescence Sensor
Buller Hall Hallways
A Machine learning based data analysis was performed for the data analysis obtained from a low-cost alternative, smartphone based, portable electrochemiluminescence (ECL) sensor for phenolic compounds. While the phenolic compounds, vanillic acid and p-coumaric acid, effectively quench the ECL reaction, the light intensity and electric current were simultaneously recorded by the smartphone apps. Due to common problems present in sensor data such as non-linearity, multimodality, sensor-to-senor variations, presence of anomalies, and ambiguity in key features, several machine learning strategies were explored. In contrast to the traditional calibration approach of extracting predetermined key features, the ML methods such as tri-layer neural net or boosted trees carried out effective regression tasks by learning higher patterns without processing the key features. Combined multimodal characteristics made 80% enhanced performance with multilayer neural net algorithms than the traditional approaches. The results demonstrated that the ML methods could provide robust analysis framework for sensor data with noises and variability without preprocessing to extract features or examine ambiguous anomaly.
Acknowledgments
National Science Foundation CBET division (#1706597)