Mass estimation of ground vehicles based on longitudinal dynamics using IMU and CAN-bus data

Mass estimation of ground vehicles based on longitudinal dynamics using IMU and CAN-bus data

This paper considers the problem of real-time estimation of ground vehicle mass, based on longitudinal dynamics. Compared to previous contributions, this work relies on basic data from the vehicle controller area network bus. This allows for application to a very broad range of vehicles, by not usin...

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Bibliographic Details
Published in:Mechanical systems and signal processing Vol. 162; p. 107982
Main Authors: Jensen, Kenneth M., Santos, Ilmar F., Clemmensen, Line K.H., Theodorsen, Søren, Corstens, Harry J.P.
Format: Journal Article
Language:English
Published: Berlin Elsevier Ltd 01-01-2022
Elsevier BV
Subjects:
Accelerometers
Air flow
Automatic transmissions
Automobiles
Buses (vehicles)
CAN-bus
Controller area network
Controllers
Driving conditions
Dynamic modelling
Experimental validation
Flow velocity
Gear ratios
Inertial measurement unit
Inertial platforms
Mass estimation
Recursive least squares
Torque
Traffic speed
Transmissions (automotive)
Vehicles
Experimental validation
Inertial measurement unit
Mass estimation
Dynamic modelling
Recursive least squares
CAN-bus
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Summary:This paper considers the problem of real-time estimation of ground vehicle mass, based on longitudinal dynamics. Compared to previous contributions, this work relies on basic data from the vehicle controller area network bus. This allows for application to a very broad range of vehicles, by not using vehicle specific parameters such as current gear indicator and engine torque. The current gear ratio is predicted based on the engine and vehicle speeds. The engine torque is modelled by the mass air flow rate of the engine. The road gradient is estimated with an inertial measurement unit, with fusion of gyroscope and accelerometer using a complementary filter. To handle prolonged dynamic conditions affecting the performance of the filter, compensation of external accelerations is made by use of the vehicle speed from the controller area network bus. The mass is estimated with a recursive least squares filter with forgetting factor. The model is validated experimentally with data obtained from test drives with two different petrol powered passenger cars, equipped with a manual transmission and dual clutch automatic transmission respectively. The test drives consist of various driving conditions with different vehicle loads. The resulting mass estimates are generally good for both vehicles with variations within ±5% of the actual masses.
ISSN:0888-3270
1096-1216
DOI:10.1016/j.ymssp.2021.107982