Data-Driven Safe Deliveries: The Synergy of IoT and Machine Learning in Shared Mobility

Shared mobility is one of the smart city applications in which traditional individually owned vehicles are transformed into shared and distributed ownership. Ensuring the safety of both drivers and riders is a fundamental requirement in shared mobility. This work aims to design and implement an adeq...

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Bibliographic Details
Published inFuture internet Vol. 15; no. 10; p. 333
Main Authors Elwy, Fatema, Aburukba, Raafat, Al-Ali, A. R., Nabulsi, Ahmad Al, Tarek, Alaa, Ayub, Ameen, Elsayeh, Mariam
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.10.2023
Subjects
Accidents
Accuracy
Algorithms
Automation
Case studies
Data collection
Data entry
Decision trees
Delivery services
Helmets
Internet of Things
IoT
Machine learning
Microelectromechanical systems
Motorcycle industry
Motorcycles
Passenger safety
Safety and security measures
Sensors
shared mobility
smart cities
smart transportation
Smartphones
Software
Support vector machines
Traffic accidents
Traffic safety
Urban areas
Vehicles
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Summary:Shared mobility is one of the smart city applications in which traditional individually owned vehicles are transformed into shared and distributed ownership. Ensuring the safety of both drivers and riders is a fundamental requirement in shared mobility. This work aims to design and implement an adequate framework for shared mobility within the context of a smart city. The characteristics of shared mobility are identified, leading to the proposal of an effective solution for real-time data collection, tracking, and automated decisions focusing on safety. Driver and rider safety is considered by identifying dangerous driving behaviors and the prompt response to accidents. Furthermore, a trip log is recorded to identify the reasons behind the accident. A prototype implementation is presented to validate the proposed framework for a delivery service using motorbikes. The results demonstrate the scalability of the proposed design and the integration of the overall system to enhance the rider’s safety using machine learning techniques. The machine learning approach identifies dangerous driving behaviors with an accuracy of 91.59% using the decision tree approach when compared against the support vector machine and K-nearest neighbor approaches.
ISSN:1999-5903
1999-5903
DOI:10.3390/fi15100333