论文信息 - Parallel Computing Enables Whole-Trip Train Dynamics Optimizations

Parallel Computing Enables Whole-Trip Train Dynamics Optimizations

Due to the high computing demand of whole-trip train dynamics simulations and the iterative nature of optimizations, whole-trip train dynamics optimizations using sequential computing schemes are practically impossible. This paper reports advancements in whole-trip train dynamics optimizations enabled by using the parallel computing technique. A parallel computing scheme for whole-trip train dynamics optimizations is presented and discussed. Two case studies using parallel multiobjective particle swarm optimization (pMOPSO) and parallel multiobjective genetic algorithm (pMOGA), respectively, were performed to optimize a friction draft gear design. Linear speed-up was achieved by using parallel computing to cut down the computing time from 18 months to just 11 days. Optimized results using pMOPSO and pMOGA were in agreement with each other; Pareto fronts were identified to provide technical evidence for railway manufacturers and operators.

[1] Javier García de Jalón,et al. Real-Time Dynamic Simulations of Large Road Vehicles Using Dense, Sparse, and Parallelization Techniques , 2015 .

[2] Colin Cole,et al. Computing Schemes for Longitudinal Train Dynamics: Sequential, Parallel and Hybrid , 2015 .

[3] Colin Cole,et al. Vertical dynamic behavior of three-piece bogie suspensions with two types of friction wedge , 2008 .

[4] Enrique Alba,et al. Parallel Evolutionary Computations , 2006, Studies in Computational Intelligence.

[5] Maksym Spiryagin,et al. A review of dynamics modelling of friction draft gear , 2014 .

[6] Maksym Spiryagin,et al. Methodology for Optimization of Friction Draft Gear Design , 2014 .

[7] Ahmed K. Aboubakr,et al. Use of the Non-Inertial Coordinates in the Analysis of Train Longitudinal Forces , 2012 .

[8] Hammad Mazhar,et al. Parallel Computing in Multibody System Dynamics: Why, When, and How , 2014 .

[9] Olivier L. de Weck,et al. Adaptive Weighted Sum Method for Multiobjective Optimization , 2004 .

[10] Oldrich Polach,et al. Creep force modelling for rail traction vehicles based on the Fastsim algorithm , 2013 .

[11] Maksym Spiryagin,et al. Advanced dynamic modelling for friction draft gears , 2015 .

[12] Mats Berg,et al. Challenges in simulation of rail vehicle dynamics , 2009 .

[13] I. Kim,et al. Adaptive weighted sum method for multiobjective optimization: a new method for Pareto front generation , 2006 .