Jansen van Rensburg, Gerhardus JKok, SWilke, DN2015-08-172015-08-172014-09Jansen van Rensburg, G.J, Kok, S and Wilke, D.N. 2014. Simultaneous boundary value and material parameter estimation using imperfect compression data. In: Proceedings of the 4th International Engineering Optimization Conference 2014 (EngOpt2014), Instituto Superior Tecnico, Lisbon, Portugal, 8-11 September 20149781138027251http://www.crcnetbase.com/doi/abs/10.1201/b17488-186http://hdl.handle.net/10204/8009Proceedings of the 4th International Engineering Optimization Conference 2014 (EngOpt2014), Instituto Superior Tecnico, Lisbon, Portugal, 8-11 September 2014. . Due to copyright restrictions, the attached PDF file only contains the abstract of the full text item. For access to the full text item, please consult the publisher's websiteData is available for different hard metal samples tested in compression using a modified tensile test specimen. Three strain gauges were placed 120 degrees apart around the circumference of the centre of the test section. The spread of the strain data obtained from these tests indicate non-uniform compression. In this paper, the benefits of surrogate modelling is investigated using a virtual experiment with parameterised displacement boundary condition that mimics the responses observed in experimental data. The known boundary condition and material parameter values used to perform the finite element analysis in the virtual experiment allows investigation on the accuracy of the parameter identification strategies employed. The unknown material parameters and boundary conditions are first sampled within a reasonable range using a Latin hypercube. Finite element simulations are performed for each sample point and radial basis function interpolation is used to approximate the error function across the design space. A global optimisation algorithm is used to minimise the error function. The associated parameters can then be compared to the known real solution. In another surrogate modelling approach, the interpolation is set up using the full data set obtained from all sample points. Radial basis function interpolations are set up for each of the unknown parameters as output, using the data as input. Now, given the virtual data set as input, each parameter is simply determined by evaluating the associated radial basis function. Sensitivities are also investigated for both strategies by applying 2% random noise to the virtual experiment data. This is done to investigate the effect of noise on the parameter estimation since the real experimental data would contain some noise.enHard metalNon-uniform compression tensile testBoundary conditionsMaterial parameter valuesRadial basis function interpolationImperfect compression dataConference PresentationJansen van Rensburg, G. J., Kok, S., & Wilke, D. (2014). Simultaneous boundary value and material parameter estimation using imperfect compression data. Taylor & Francis. http://hdl.handle.net/10204/8009Jansen van Rensburg, Gerhardus J, S Kok, and DN Wilke. "Simultaneous boundary value and material parameter estimation using imperfect compression data." (2014): http://hdl.handle.net/10204/8009Jansen van Rensburg GJ, Kok S, Wilke D, Simultaneous boundary value and material parameter estimation using imperfect compression data; Taylor & Francis; 2014. http://hdl.handle.net/10204/8009 .TY - Conference Presentation AU - Jansen van Rensburg, Gerhardus J AU - Kok, S AU - Wilke, DN AB - Data is available for different hard metal samples tested in compression using a modified tensile test specimen. Three strain gauges were placed 120 degrees apart around the circumference of the centre of the test section. The spread of the strain data obtained from these tests indicate non-uniform compression. In this paper, the benefits of surrogate modelling is investigated using a virtual experiment with parameterised displacement boundary condition that mimics the responses observed in experimental data. The known boundary condition and material parameter values used to perform the finite element analysis in the virtual experiment allows investigation on the accuracy of the parameter identification strategies employed. The unknown material parameters and boundary conditions are first sampled within a reasonable range using a Latin hypercube. Finite element simulations are performed for each sample point and radial basis function interpolation is used to approximate the error function across the design space. A global optimisation algorithm is used to minimise the error function. The associated parameters can then be compared to the known real solution. In another surrogate modelling approach, the interpolation is set up using the full data set obtained from all sample points. Radial basis function interpolations are set up for each of the unknown parameters as output, using the data as input. Now, given the virtual data set as input, each parameter is simply determined by evaluating the associated radial basis function. Sensitivities are also investigated for both strategies by applying 2% random noise to the virtual experiment data. This is done to investigate the effect of noise on the parameter estimation since the real experimental data would contain some noise. DA - 2014-09 DB - ResearchSpace DP - CSIR KW - Hard metal KW - Non-uniform compression tensile test KW - Boundary conditions KW - Material parameter values KW - Radial basis function interpolation KW - Imperfect compression data LK - https://researchspace.csir.co.za PY - 2014 SM - 9781138027251 T1 - Simultaneous boundary value and material parameter estimation using imperfect compression data TI - Simultaneous boundary value and material parameter estimation using imperfect compression data UR - http://hdl.handle.net/10204/8009 ER -