Papers
Topics
Authors
Recent
Gemini 2.5 Flash
Gemini 2.5 Flash 99 tok/s
Gemini 2.5 Pro 48 tok/s Pro
GPT-5 Medium 40 tok/s
GPT-5 High 38 tok/s Pro
GPT-4o 101 tok/s
GPT OSS 120B 470 tok/s Pro
Kimi K2 161 tok/s Pro
2000 character limit reached

Enhancing Biomechanical Simulations Based on A Posteriori Error Estimates: The Potential of Dual Weighted Residual-Driven Adaptive Mesh Refinement (2403.00401v1)

Published 1 Mar 2024 in math.NA and cs.NA

Abstract: The Finite Element Method (FEM) is a well-established procedure for computing approximate solutions to deterministic engineering problems described by partial differential equations. FEM produces discrete approximations of the solution with a discretisation error that can be an be quantified with \emph{a posteriori} error estimates. The practical relevance of error estimates for biomechanics problems, especially for soft tissue where the response is governed by large strains, is rarely addressed. In this contribution, we propose an implementation of \emph{a posteriori} error estimates targeting a user-defined quantity of interest, using the Dual Weighted Residual (DWR) technique tailored to biomechanics. The proposed method considers a general setting that encompasses three-dimensional geometries and model non-linearities, which appear in hyperelastic soft tissues. We take advantage of the automatic differentiation capabilities embedded in modern finite element software, which allows the error estimates to be computed generically for a large class of models and constitutive laws. First we validate our methodology using experimental measurements from silicone samples, and then illustrate its applicability for patient-specific computations of pressure ulcers on a human heel.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (62)
  1. M. Ainsworth and J. T. Oden. A posteriori error estimation in finite element analysis. Pure and Applied Mathematics. Wiley-Interscience, New York, 2000.
  2. R. Becker and R. Rannacher. A feed-back approach to error control in finite element methods: basic analysis and examples. East-West Journal of Numerical Mathematics, 4(4):237–264, 1996.
  3. R. Becker and R. Rannacher. An optimal control approach to a posteriori error estimation in finite element methods. Acta Numerica, 10:1–102, 2001.
  4. R. Becker and B. Vexler. A posteriori error estimation for finite element discretization of parameter identification problems. Numerische Mathematik, 96(3):435–459, 2004.
  5. R. Becker and B. Vexler. Mesh refinement and numerical sensitivity analysis for parameter calibration of partial differential equations. Journal of Computational Physics, 206(1):95–110, 2005.
  6. Atlas-based automatic generation of subject-specific finite element tongue meshes. Annals of Biomedical Engineering, 44(1):16–34, 2016.
  7. A few remarks about the computer implementation and the verification of some hyperelastic constitutive laws and an illustration with the mechanical response of an artery. hal-03637834, Apr. 2022.
  8. Simulations of the consequences of tongue surgery on tongue mobility: implications for speech production in post-surgery conditions. The International Journal of Medical Robotics and Computer Assisted Surgery, 3(3):252–261, 2007.
  9. Jacobian-based repair method for finite element meshes after registration. Engineering with Computers, 27(3):285–297, 2011.
  10. Controlling the error on target motion through real-time mesh adaptation: Applications to deep brain stimulation. International Journal for Numerical Methods in Biomedical Engineering, pages e2958–n/a, 2017. e2958 cnm.2958.
  11. Real-time error control for surgical simulation. IEEE Transactions on Biomedical Engineering, 65(3):596–607, March 2018.
  12. Application of soft tissue modelling to image-guided surgery. Medical Engineering & Physics, 27(10):893 – 909, 2005. Advances in the finite element modelling of soft tissue deformation.
  13. Comparison of the performance of some finite element discretizations for large deformation elasticity problems. Computers & Structures, 88(11-12):664–673, 2010.
  14. Real-time simulation of contact and cutting of heterogeneous soft-tissues. Medical Image Analysis, 18(2):394–410, 2014.
  15. W. Dörfler. A convergent adaptive algorithm for Poisson’s equation. SIAM Journal on Numerical Analysis, 33(3):1106–1124, 1996.
  16. Quantifying discretization errors for soft tissue simulation in computer assisted surgery: a preliminary study. Applied Mathematical Modelling, 77(part 1):709–723, 2020.
  17. DWR-hyperelastic-soft-tissue. figshare, 4 2023.
  18. A. Gefen. The biomechanics of heel ulcers. Journal of Tissue Viability, 19(4):124–131, 2010.
  19. A. N. Gent. A New Constitutive Relation for Rubber. Rubber Chemistry and Technology, 69(1):59–61, 03 1996.
  20. M. B. Giles and E. Süli. Adjoint methods for PDEs: a posteriori error analysis and postprocessing by duality. Acta Numerica, 11:145–236, 2002.
  21. Mesh adaptivity driven by goal-oriented locally equilibrated superconvergent patch recovery. Computational Mechanics, 53(5):957–976, 2014.
  22. Adjoint-based error estimation and mesh adaptation for stabilized finite deformation elasticity. Computer Methods in Applied Mechanics and Engineering, 337:263–280, 2018.
  23. T. Grätsch and K.-J. Bathe. A posteriori error estimation techniques in practical finite element analysis. Computers & Structures, 83(4):235–265, 2005.
  24. T. Gustafsson and G. D. Mcbain. scikit-fem: A python package for finite element assembly. Journal of Open Source Software, 5(52):2369, 2020.
  25. F. Hecht. New development in freefem++. Journal of Numerical Mathematics, 20(3-4):251–266, 2012.
  26. V. Heuveline and R. Rannacher. Duality-based adaptivity in the hp-finite element method. Journal of Numerical Mathematics, 11:95–113, 2003.
  27. Strain energy functions of rubber. i. characterization of gum vulcanizates. Journal of Applied Polymer Science, 19(7):2033–2058, 1975.
  28. Algorithms for the prevention of postoperative nausea and vomiting: An efficacy and efficiency simulation. European Journal of Anaesthesiology, 24:856–67, 10 2007.
  29. Endoscopic surgery training using virtual reality and deformable tissue simulation. Computers & Graphics, 24(5):671 – 682, 2000.
  30. Strategies for computing goal-oriented a posteriori error measures in non-linear elasticity. Internat. J. Numer. Methods Engrg., 55(8):879–894, 2002.
  31. The effects of deformation, ischemia, and reperfusion on the development of muscle damage during prolonged loading. Journal of Applied Physiology, 111(4):1168–1177, 2011.
  32. Personalized modeling for real-time pressure ulcer prevention in sitting posture. Journal of Tissue Viability, 27(1):54–58, 2018.
  33. Influence of the calcaneus shape on the risk of posterior heel ulcer using 3d patient-specific biomechanical modeling. Annals of Biomedical Engineering, 43:325–335, 2015.
  34. Y. Maday and A. T. Patera. Numerical analysis of a posteriori finite element bounds for linear functional outputs. Mathematical Models and Methods in Applied Sciences, 10(5):785–799, 2000.
  35. Sonics: Develop intuition on biomechanical systems through interactive error controlled simulations. arXiv preprint arXiv:2208.11676, 2022.
  36. Mechanical experimental characterisation and numerical modelling of an unfilled silicone rubber. Polymer Testing, 27(6):765–777, 2008.
  37. B. Mielczarek and J. Uziałlko-Mydlikowska. Application of computer simulation modeling in the health care sector: a survey. SIMULATION, 88(2):197–216, 2012.
  38. M. Mooney. A theory of large elastic deformation. Journal of Applied Physics, 11(9):582–592, 1940.
  39. Theory of adaptive finite element methods: an introduction. In Multiscale, nonlinear and adaptive approximation, pages 409–542. Springer, Berlin, 2009.
  40. J. Oden and S. Prudhomme. Goal-oriented error estimation and adaptivity for the finite element method. Computers & Mathematics with Applications, 41(5):735 – 756, 2001.
  41. A posteriori finite element bounds for linear-functional outputs of elliptic partial differential equations. Computer Methods in Applied Mechanics and Engineering, 150(1-4):289–312, 1997. Symposium on Advances in Computational Mechanics, Vol. 2 (Austin, TX, 1997).
  42. Y. Payan and J. Ohayon. Biomechanics of living organs: hyperelastic constitutive laws for finite element modeling. Academic Press Series in Biomedical Engineering. Elsevier, 2017.
  43. Hospital acquired pressure ulcers. risk factors and use of preventive devices. Arch Intern Med, 158(17):1940 – 1945, 1998.
  44. Biomechanical modelling of the foot. In Y. Payan and J. Ohayon, editors, Biomechanics of Living Organs: Hyperelastic Constitutive Laws for Finite Element Modeling, pages 545–563. Elsevier, 2017.
  45. Patient-specific numerical simulation of stent-graft deployment: validation on three clinical cases. Journal of Biomechanics, 48(10):1868–1875, 2015.
  46. S. Prudhomme and J. T. Oden. On goal-oriented error estimation for elliptic problems: application to the control of pointwise errors. Computer Methods in Applied Mechanics and Engineering, 176(1-4):313–331, 1999. New advances in computational methods (Cachan, 1997).
  47. Y. Renard and K. Poulios. Getfem: Automated fe modeling of multiphysics problems based on a generic weak form language. ACM Transactions on Mathematical Software (TOMS), 47(1):1–31, 2020.
  48. M. E. Rognes and A. Logg. Automated goal-oriented error control I: Stationary variational problems. SIAM Journal on Scientific Computing, 35(3):C173–C193, 2013.
  49. In vitro analysis of localized aneurysm rupture. Journal of Biomechanics, 47(3):607–616, 2014.
  50. Effect of multilevel lumbar disc arthroplasty on spine kinematics and facet joint loads in flexion and extension: a finite element analysis. European Spine Journal, 21(5):663–674, 2012.
  51. Analysis of vasculature for liver surgical planning. IEEE Transactions on Medical Imaging, 21(11):1344–1357, Nov 2002.
  52. Finite element-based method for determining an optimal offloading design for treating and preventing heel ulcers. Computers in Biology and Medicine, 131:104261, 2021.
  53. Mri based 3d finite element modelling to investigate deep tissue injury. Computer methods in biomechanics and biomedical engineering, 21(14):760–769, 2018.
  54. Patient specific stress and rupture analysis of ascending thoracic aneurysms. Journal of Biomechanics, 48(10):1836–1843, 2015.
  55. Non-operable glioblastoma: proposition of patient-specific forecasting by image-informed poromechanical model. Brain Multiphysics, page 100067, 2023.
  56. Risk factors for developing heel ulcers for bedridden patients: A finite element study. Clinical Biomechanics, 78:105094, 2020.
  57. Three dimensional ct reconstruction images for craniofacial surgical planning and evaluation. Radiology, 150(1):179–184, 1984. PMID: 6689758.
  58. R. Verfürth. A posteriori error estimation techniques for finite element methods. Oxford University Press, Oxford, 2013.
  59. Real-time registration of volumetric brain mri by biomechanical simulation of deformation during image guided neurosurgery. Computing and Visualization in Science, 5(1):3–11, Jul 2002.
  60. Error estimation and adaptivity for incompressible hyperelasticity. International Journal for Numerical Methods in Engineering, 99(5):313–332, 2014.
  61. Clinically relevant modeling of tumor growth and treatment response. Science Translational Medicine, 5(187):187ps9–187ps9, 2013.
  62. O. Zienkiewicz and J. Zhu. The superconvergent patch recovery (spr) and adaptive finite element refinement. Computer Methods in Applied Mechanics and Engineering, 101(1):207–224, 1992.
List To Do Tasks Checklist Streamline Icon: https://streamlinehq.com

Collections

Sign up for free to add this paper to one or more collections.

User Circle Single Streamline Icon: https://streamlinehq.com Sign Up

Summary

We haven't generated a summary for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Summarize Now
Ai Generate Text Spark Streamline Icon: https://streamlinehq.com

Paper Prompts

Sign up for free to create and run prompts on this paper using GPT-5.

List Streamline Icon: https://streamlinehq.com Explore 10 Community Prompts
Dice Question Streamline Icon: https://streamlinehq.com

Follow-up Questions

We haven't generated follow-up questions for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Generate Now