Optimising driver profiling through behaviour modelling of in-car sensor and global positioning system data

Gabriela Ahmadi-Assalemi; Haider M. al-Khateeb; Carsten Maple; Gregory Epiphaniou; Mohammad Hammoudeh; Hamid Jahankhani; Prashant Pillai

doi:10.1016/j.compeleceng.2021.107047

Optimising driver profiling through behaviour modelling of in-car sensor and global positioning system data

Gabriela Ahmadi-Assalemi
, Haider M. al-Khateeb^*
, Carsten Maple
, Gregory Epiphaniou
, Mohammad Hammoudeh
, Hamid Jahankhani
, Prashant Pillai

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

Connected cars have a massive impact on the automotive sector, and whilst this catalyst and disruptor technology introduce threats, it brings opportunities to address existing vehicle-related crimes such as carjacking. Connected cars are fitted with sensors, and capable of sophisticated computational processing which can be used to model and differentiate drivers as means of layered security. We generate a dataset collecting 14 h of driving in the city of London. The route was 8.1 miles long and included various road conditions such as roundabouts, traffic lights, and several speed zones. We identify and rank the features from the driving segments, classify our sample using Random Forest, and optimise the learning-based model with 98.84% accuracy (95% confidence) given a small 10 s driving window size. Differences in driving patterns were uncovered to distinguish between female and male drivers especially through variations in longitudinal acceleration, driving speed, torque and revolutions per minute.

Original language	English
Article number	107047
Journal	Computers and Electrical Engineering
Volume	91
DOIs	https://doi.org/10.1016/j.compeleceng.2021.107047
State	Published - May 2021
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2021 Elsevier Ltd

Keywords

Behaviour profiling
Classification
Connected cars
Cybersecurity threat
Driver identification
GPS
Incident response
Machine learning
Random forest

ASJC Scopus subject areas

Control and Systems Engineering
General Computer Science
Electrical and Electronic Engineering

Access to Document

10.1016/j.compeleceng.2021.107047

Cite this

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title = "Optimising driver profiling through behaviour modelling of in-car sensor and global positioning system data",

abstract = "Connected cars have a massive impact on the automotive sector, and whilst this catalyst and disruptor technology introduce threats, it brings opportunities to address existing vehicle-related crimes such as carjacking. Connected cars are fitted with sensors, and capable of sophisticated computational processing which can be used to model and differentiate drivers as means of layered security. We generate a dataset collecting 14 h of driving in the city of London. The route was 8.1 miles long and included various road conditions such as roundabouts, traffic lights, and several speed zones. We identify and rank the features from the driving segments, classify our sample using Random Forest, and optimise the learning-based model with 98.84\% accuracy (95\% confidence) given a small 10 s driving window size. Differences in driving patterns were uncovered to distinguish between female and male drivers especially through variations in longitudinal acceleration, driving speed, torque and revolutions per minute.",

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author = "Gabriela Ahmadi-Assalemi and al-Khateeb, \{Haider M.\} and Carsten Maple and Gregory Epiphaniou and Mohammad Hammoudeh and Hamid Jahankhani and Prashant Pillai",

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year = "2021",

month = may,

doi = "10.1016/j.compeleceng.2021.107047",

language = "English",

volume = "91",

journal = "Computers and Electrical Engineering",

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AU - Ahmadi-Assalemi, Gabriela

AU - al-Khateeb, Haider M.

AU - Maple, Carsten

AU - Epiphaniou, Gregory

AU - Hammoudeh, Mohammad

AU - Jahankhani, Hamid

AU - Pillai, Prashant

PY - 2021/5

Y1 - 2021/5

N2 - Connected cars have a massive impact on the automotive sector, and whilst this catalyst and disruptor technology introduce threats, it brings opportunities to address existing vehicle-related crimes such as carjacking. Connected cars are fitted with sensors, and capable of sophisticated computational processing which can be used to model and differentiate drivers as means of layered security. We generate a dataset collecting 14 h of driving in the city of London. The route was 8.1 miles long and included various road conditions such as roundabouts, traffic lights, and several speed zones. We identify and rank the features from the driving segments, classify our sample using Random Forest, and optimise the learning-based model with 98.84% accuracy (95% confidence) given a small 10 s driving window size. Differences in driving patterns were uncovered to distinguish between female and male drivers especially through variations in longitudinal acceleration, driving speed, torque and revolutions per minute.

AB - Connected cars have a massive impact on the automotive sector, and whilst this catalyst and disruptor technology introduce threats, it brings opportunities to address existing vehicle-related crimes such as carjacking. Connected cars are fitted with sensors, and capable of sophisticated computational processing which can be used to model and differentiate drivers as means of layered security. We generate a dataset collecting 14 h of driving in the city of London. The route was 8.1 miles long and included various road conditions such as roundabouts, traffic lights, and several speed zones. We identify and rank the features from the driving segments, classify our sample using Random Forest, and optimise the learning-based model with 98.84% accuracy (95% confidence) given a small 10 s driving window size. Differences in driving patterns were uncovered to distinguish between female and male drivers especially through variations in longitudinal acceleration, driving speed, torque and revolutions per minute.

KW - Behaviour profiling

KW - Classification

KW - Connected cars

KW - Cybersecurity threat

KW - Driver identification

KW - GPS

KW - Incident response

KW - Machine learning

KW - Random forest

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Optimising driver profiling through behaviour modelling of in-car sensor and global positioning system data

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

Access to Document

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Cite this