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Driving Mode Estimation Model Based in Machine Learning Through PID’s Signals Analysis Obtained From OBD II

  • Juan José Molina CampoverdeEmail author
Conference paper
  • 51 Downloads
Part of the Communications in Computer and Information Science book series (CCIS, volume 1194)

Abstract

In this paper a driving mode estimation model based in machine learning architecture is presented. With the statistic method, Random Forest, the highest inference of driving variables is determined through the best attributes for a training model based in OBD II data. Engine sensors variables are obtained with the aim of explaining the behavior of the PID signals in relation to the driving mode of a person, according to specific consumption and engine performance, characterizing the signals behavior in relation to the different driving modes. The investigation consists of 4 power tests in the dynamometer bank at 25%, 50%, 75% and 100% throttle valve opening to determine the relationship between engine performance and normal vehicle circulation, through the engine most influential variables like MAP, TPS, VSS, Ax and each the transmission ratio infer in the fuel consumption study and engine performance. In this study Random Forest is used achieving an accuracy rate of 0.98905.

Keywords

Random forest OBD II Fuel consumption Eco drive K-means S-Golay 

Notes

Acknowledgment

To Mr. Nestor Diego Rivera Campoverde, for his direction and unconditional collaboration in the realization of the paper with his contributions and his knowledge throughout the entire process, in addition to the GIIT Transportation Engineering Research Group for his support for the completion of the paper.

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Copyright information

© Springer Nature Switzerland AG 2020

Authors and Affiliations

  1. 1.Automotive Mechanical Engineering: GIIT Transport Engineering Research GroupSalesian Polytechnic UniversityCuencaEcuador

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