The second part of the paper continues a discussion on the topic of paralel computations in railway dynamics. The algorithms described in the first part of the paper are applied to parallel simulation on computers with multicore processors of six different models of rail vehicles and trains with the number of degrees of freedom from about one hundred to more than 20 thousands. A considerable simulation speedup is reported. In addition, an example of evaluation of wheel profile wear on multicore processors and comparison of different approaches to multi-variant computations are considered
Locomotive-track interaction is a multidimensional task because it goes in many directions depending...
Locomotive design is a highly complex task that requires the use of systems engineering that depends...
This paper presents the results of the International Benchmarking of Longitudinal Train Dynamics Sim...
Classical train simulation is the domain of low Degree-of-Freedom simulators such as Longitudinal Tr...
Railway wheel–rail contact simulations are the most important and time-consuming tasks when simulati...
Simulations of three-dimensional train system dynamics for long freight railway trains with consider...
Due to the high cost of physical testing and the increasing acceptance of computer simulation modell...
This paper introduces a new parallel co-simulation method to study vehicle-track dynamic interaction...
Simulations of three-dimensional Train System Dynamics for long freight trains with consideration be...
The forces exchanged between wheel and the rail are fundamental in order to study the railway vehicl...
This paper discusses the evolution of longitudinal train dynamics (LTD) simulations, which covers nu...
Conventionally, force elements in longitudinal train dynamics (LTD) are determined sequentially. Act...
Due to the high computing demand of whole-trip train dynamicssimulations and the iterative nature of...
Conventionally, force elements in longitudinal train dynamics (LTD) are determined sequentially. Act...
Available computing power for researchers has been increasing exponentially over the last decade. Pa...
Locomotive-track interaction is a multidimensional task because it goes in many directions depending...
Locomotive design is a highly complex task that requires the use of systems engineering that depends...
This paper presents the results of the International Benchmarking of Longitudinal Train Dynamics Sim...
Classical train simulation is the domain of low Degree-of-Freedom simulators such as Longitudinal Tr...
Railway wheel–rail contact simulations are the most important and time-consuming tasks when simulati...
Simulations of three-dimensional train system dynamics for long freight railway trains with consider...
Due to the high cost of physical testing and the increasing acceptance of computer simulation modell...
This paper introduces a new parallel co-simulation method to study vehicle-track dynamic interaction...
Simulations of three-dimensional Train System Dynamics for long freight trains with consideration be...
The forces exchanged between wheel and the rail are fundamental in order to study the railway vehicl...
This paper discusses the evolution of longitudinal train dynamics (LTD) simulations, which covers nu...
Conventionally, force elements in longitudinal train dynamics (LTD) are determined sequentially. Act...
Due to the high computing demand of whole-trip train dynamicssimulations and the iterative nature of...
Conventionally, force elements in longitudinal train dynamics (LTD) are determined sequentially. Act...
Available computing power for researchers has been increasing exponentially over the last decade. Pa...
Locomotive-track interaction is a multidimensional task because it goes in many directions depending...
Locomotive design is a highly complex task that requires the use of systems engineering that depends...
This paper presents the results of the International Benchmarking of Longitudinal Train Dynamics Sim...