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Abstract

Accurate estimation of road roughness is crucial for vehicle dynamics analysis and road performance evaluation. To enhance the accuracy of estimating road roughness, this study introduces an estimation method utilizing the improved Kalman filter (KF) with discrete trapezoidal load. Firstly, the theoretical formulation of the vehicle response under road roughness load is derived, and the system equation is derived in a continuous time state-space form. Next, the vehicle system equation is discretized and an improved KF algorithm with trapezoidal load is proposed, along with the derivation of the structural state estimation formula. Then, a vehicle model with seven degrees of freedom (DOFs) is established for numerical calculation, with the improved KF algorithm is utilized to estimate road roughness based on the vehicle response. Finally, the estimation accuracy of the proposed method is verified via field tests involving the vehicle driving through bumps and driving on a rough road.

Keywords

road roughness Kalman filter (KF)trapezoidal load numerical calculation field tests

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References

González

O’brien

Y-Y

, et al. (2008) The use of vehicle acceleration measurements to estimate road roughness. Vehicle System Dynamics 46(6): 483–499.

Hettiarachchi

Yuan

Amirkhanian

, et al. (2023) Measurement of pavement unevenness and evaluation through the IRI parameter—an overview. Measurement 206: 112284.

Zeng

Duan

, et al. (2024) Estimation of road roughness based on both the sprung and unsprung response of a moving vehicle over ordinary roads: modeling, experiments and discussions. International Journal of Structural Stability and Dynamics 24(10): 2450115.

Imine

Delanne

M’Sirdi

(2006) Road profile input estimation in vehicle dynamics simulation. Vehicle System Dynamics 44(4): 285–303.

Kang

S-W

Kim

J-S

Kim

G-W

(2018) Road roughness estimation based on discrete Kalman filter with unknown input. Vehicle System Dynamics: 1–15.

Kuncham

Sen

(2024) Fatigue assessment of bridges using interacting filtering approach with sub-structured predictor model based on current health. Structural Health Monitoring 1–19.

Leanza

De Carolis

Soria

, et al. (2024) Road roughness identification in vehicle dynamics: the role of measurements in ensuring system observability. IEEE Access 12: 105778–105791.

J-A

Feng

(2023) Fatigue life evaluation of bridge stay cables subject to monitoring traffic and considering road roughness. Engineering Structures 293: 116572.

Lan

Lin

(2023a) Indirect damage detection for bridges using sensing and temporarily parked vehicles. Engineering Structures 291: 116459.

10.

Lin

Zhang

(2023b) Bridge frequency scanning using the contact-point response of an instrumented 3d vehicle: theory and numerical simulation. Structural Control and Health Monitoring 2023: 1–23.

11.

Múčka

(2017) Road roughness limit values based on measured vehicle vibration. Journal of Infrastructure Systems 23(2): 04016029.

12.

Nguyen

Lechner

Wong

(2019) Response-based methods to measure road surface irregularity: a state-of-the-art review. European Transport Research Review 11(1): 43.

13.

Qiao

Rahmatalla

(2021) Dynamics of interaction between an Euler-Bernoulli beam and a moving damped sprung mass: effect of beam surface roughness. Structures 32: 2247–2265.

14.

Wang

Nagayama

Zhao

, et al. (2017) Identification of moving vehicle parameters using bridge responses and estimated bridge pavement roughness. Engineering Structures 153: 57–70.

15.

Wenzel

Burnham

Blundell

, et al. (2006) Dual extended Kalman filter for vehicle state and parameter estimation. Vehicle System Dynamics 44(2): 153–171.

16.

Yang

Wang

, et al. (2020) Bridge surface roughness identified from the displacement influence lines of the contact points by two connected vehicles. International Journal of Structural Stability and Dynamics 20(14): 2043003.

17.

Yang

Kim

B-G

J-S

, et al. (2022a) Simultaneous estimation of vehicle mass and unknown road roughness based on adaptive extended Kalman filtering of suspension systems. Electronics 11(16): 2544.

18.

Yang

Wang

, et al. (2022b) Scanning of bridge surface roughness from two-axle vehicle response by EKF-UI and contact residual: theoretical study. Sensors 22(9): 3410.

19.

Zeng

Shi

, et al. (2022) Estimation of road roughness based on tire pressure monitoring. International Journal of Structural Stability and Dynamics 22(06): 2250073.

20.

Zhan

FTK

(2019) Bridge surface roughness identification based on vehicle–bridge interaction. International Journal of Structural Stability and Dynamics 19(07): 1950069.

21.

Zhang

Hou

Duan

, et al. (2021) Road roughness estimation based on the vehicle frequency response function. Actuators 10(5): 89.

22.

Zhang

Hou

, et al. (2022) Vehicle parameter identification and road roughness estimation using vehicle responses measured in field tests. Measurement 199: 111348.

23.

Zhang

Wang

(2024) Human-bus-road coupled vibration considering effect of braking forces. Advances in Structural Engineering 28(2): 327–340.

Road roughness estimation using an improved Kalman filter with discrete trapezoidal load

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