Abstract
Road roughness is an important factor in road network maintenance and ride quality. This paper proposes a road-roughness estimation method using the frequency response function (FRF) of a vehicle. First, based on the motion equation of the vehicle and the time shift property of the Fourier transform, the vehicle FRF with respect to the displacements of vehicle–road contact points, which describes the relationship between the measured response and road roughness, is deduced and simplified. The key to road roughness estimation is the vehicle FRF, which can be estimated directly using the measured response and the designed shape of the road based on the least-squares method. To eliminate the singular data in the estimated FRF, the shape function method was employed to improve the local curve of the FRF. Moreover, the road roughness can be estimated online by combining the estimated roughness in the overlapping time periods. Finally, a half-car model was used to numerically validate the proposed methods of road roughness estimation. Driving tests of a vehicle passing over a known-sized hump were designed to estimate the vehicle FRF, and the simulated vehicle accelerations were taken as the measured responses considering a 5% Gaussian white noise. Based on the directly estimated vehicle FRF and updated FRF, the road roughness estimation, which considers the influence of the sensors and quantity of measured data at different vehicle speeds, is discussed and compared. The results show that road roughness can be estimated using the proposed method with acceptable accuracy and robustness.
Highlights
Road surface conditions play an important role in road driving quality, comfort, and safety [1,2,3], and they are essential for vehicle dynamics design and fatigue life [4,5,6]
Based on the above reduction, the measured vehicle responses can be expressed by the product of the related frequency response function Hyr and road roughness R(ω) corresponding to the displacements of the vehicle–road contact points
With the estimated vehicle frequency response function (FRF) Hyr and the measured responses Y(ω), the road roughness R(ω) can be obtained by solving the linear equation shown in Equation (8) and is expressed in Equation (11), where the matrix H+yr(ω) denotes the generalized inverse of matrix Hyr(ω)
Summary
Road surface conditions play an important role in road driving quality, comfort, and safety [1,2,3], and they are essential for vehicle dynamics design and fatigue life [4,5,6]. Using the measured vertical accelerations and displacements of vehicle wheels, and rotational movement of the vehicle body, Imine et al [15] developed a method for road profile estimation based on sliding mode observers considering the full car model with known vehicle parameters. Doumiati et al [17] studied a real-time estimation method based on a Kalman filter using the measured dynamic responses of a vehicle. Qin et al [28] developed a method to estimate road roughness by measuring and calculating the PSD of unsprung mass accelerations using a two degrees-of-freedom (DOFs) quarter-car model through a transform function related to the vehicle parameters. The component elements of the system matrices are shown in Equation (3)
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