Development of a surrogate-based vehicle dynamic model to reduce computational delays in a driving simulator

Fouladinejad, Nariman; Fouladinejad, Nima; Jalil, Mohamad Kasim Abdul; Taib, Jamaludin Mohd

doi:10.1177/0037549716675956

Cited by 6 publications

(1 citation statement)

References 43 publications

(76 reference statements)

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“…In addition, there is some lag in transferring data from UTMVDM to other subsystems. Thus, computational delay is the major issue to be resolved in UTMVDM [26]. Computational delays in UTMVDM cause UTMDS to be unrealistic and reduce the system fidelity.…”

Section: Case Study: Surrogate-based Vehicle Dynamic Model (Sbvdm)mentioning

confidence: 99%

Decomposition-Assisted Computational Technique Based on Surrogate Modeling for Real-Time Simulations

Fouladinejad

Jalil²,

Taib³

2017

Complexity

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The development of complex simulation systems is extremely costly as it requires high computational capability and expensive hardware. As cost is one of the main issues in developing simulation components, achieving real-time simulation is challenging and it often leads to intensive computational burdens. Overcoming the computational burden in a multidisciplinary simulation system that has several subsystems is essential in producing inexpensive real-time simulation. In this paper, a surrogate-based computational framework was proposed to reduce the computational cost in a high-dimensional model while maintaining accurate simulation results. Several well-known metamodeling techniques were used in creating a global surrogate model. Decomposition approaches were also used to simplify the complexities of the system and to guide the surrogate modeling processes. In addition, a case study was provided to validate the proposed approach. A surrogate-based vehicle dynamic model (SBVDM) was developed to reduce computational delay in a real-time driving simulator. The results showed that the developed surrogate-based model was able to significantly reduce the computing costs, unlike the expensive computational model. The response time in surrogate-based simulation was considerably faster than the conventional model. Therefore, the proposed framework can be used in developing low-cost simulation systems while yielding high fidelity and fast computational output.

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Section: Case Study: Surrogate-based Vehicle Dynamic Model (Sbvdm)mentioning

confidence: 99%

Decomposition-Assisted Computational Technique Based on Surrogate Modeling for Real-Time Simulations

Fouladinejad

Jalil²,

Taib³

2017

Complexity

Self Cite

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Real-time estimation of the vehicle sideslip angle through regression based on principal component analysis and neural networks

Martino

Farroni

Pasquino

et al. 2017

2017 IEEE International Systems Engineering Symposium (ISSE)

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The Transfer Matrix Metamodel for Dynamic Systems With Arbitrary Time-Variant Inputs

Savage

Son

2017

Journal of Mechanical Design

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This paper addresses the problem of mapping a vector of input variables (corresponding to discrete samples from a time-varying input) to a vector of output variables (discrete samples of the time-dependent response). This mapping is typically performed by a mechanistic model. However, when the mechanistic model is complex and dynamic, the computational effort to iteratively generate the response for design purposes can be burdensome. Metamodels (or, surrogate models) can be computationally efficient replacements, especially when the input variables have some amplitude and frequency bounds. Herein, a simple metamodel in the form of a transfer matrix is created from a matrix of a few training inputs and a corresponding matrix of matching responses provided by simulations of the dynamic mechanistic model. A least-squares paradigm reveals a simple way to link the input matrix to the columns of the response matrix. Application of singular value decomposition (SVD) introduces significant computational advantages since it provides matrices whose properties give, in an elegant fashion, the transfer matrix. The efficacy of the transfer matrix is shown through an investigation of a nonlinear, underdamped, double mass–spring–damper system. Arbitrary excitations and selected sinusoids are applied to check accuracy, speed and robustness of the methodology. The sources of errors are identified and ways to mitigate them are discussed. When compared to the ubiquitous Kriging approach, the transfer matrix method shows similar accuracy but much reduced computation time.

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Development of a surrogate-based vehicle dynamic model to reduce computational delays in a driving simulator

Cited by 6 publications

References 43 publications

Decomposition-Assisted Computational Technique Based on Surrogate Modeling for Real-Time Simulations

Decomposition-Assisted Computational Technique Based on Surrogate Modeling for Real-Time Simulations

Real-time estimation of the vehicle sideslip angle through regression based on principal component analysis and neural networks

The Transfer Matrix Metamodel for Dynamic Systems With Arbitrary Time-Variant Inputs

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