论文信息 - Bridge weigh-in-motion using a moving force identification algorithm

Bridge weigh-in-motion using a moving force identification algorithm

Abstract Bridge weigh-in-motion technology is the process of using measurements from a bridge to calculate the weight of a passing vehicle. This paper investigates the use of a moving force identification (MFI) algorithm to calculate vehicle axle loads. The calculation of forces exerted on a bridge from bridge measurements is an inverse dynamics process. Like many inverse dynamics processes, it is ill-conditioned in nature and a regularisation technique is needed. Tikhonov regularisation is used in the algorithm in this paper. The choice of the Tikhonov regularisation parameter is achieved commonly using the L-curve method. This paper investigates the use of a new, simpler type of curve to choose the regularisation parameter for bridge weigh-in-motion applications. It is based on calculated vehicle axle-weight ratios for a range of regularisation parameters. The method has the advantage of allowing the choice of regularisation parameter to be based on a realistic calculated axle-weight ratio. Calculated vehicle axle loads of quite good accuracy are achieved using this method.

Eugene J. O'Brien | Abdollah Malekjafarian | Enrique Sevillano | Paul C. Fitzgerald

[1] Eugene J. O'Brien,et al. A general solution to the identification of moving vehicle forces on a bridge , 2008 .

[2] R. Bellman. Introduction To Matrix Analysis Second Edition , 1997 .

[3] D. M. Trujillo. The direct numerical integration of linear matrix differential equations using pade approximations , 1975 .

[4] Bernard Jacob,et al. Improving truck safety: Potential of weigh-in-motion technology , 2010 .

[5] F. C. Hadipriono,et al. ANALYSIS OF RECENT BRIDGE FAILURES IN THE UNITED STATES , 2003 .

[6] D. M. Trujillo. Application of dynamic programming to the general inverse problem , 1978 .

[7] Eugene J. O'Brien,et al. Reduction of bridge dynamic amplification through adjustment of vehicle suspension damping , 2007 .

[8] David Cebon,et al. Handbook of vehicle-road interaction , 1999 .

[9] Per Christian Hansen,et al. Analysis of Discrete Ill-Posed Problems by Means of the L-Curve , 1992, SIAM Rev..

[10] S. S. Law,et al. MOVING FORCE IDENTIFICATION: OPTIMAL STATE ESTIMATION APPROACH , 2001 .

[11] Fred Moses,et al. Weigh-In-Motion System Using Instrumented Bridges , 1979 .

[12] John Casti. Review of "Introduction to the Mathematical Theory of Control Processes, Volume I: Linear Equations and Quadratic Criteria, Volume II: Nonlinear Processes" by Richard Bellman. , 1978 .