REFERENCES
- AutoSculpt, http://www.infinitycadsystems.com, Infinity CAD Systems.
- Baars, E. C. T.; Geertzen, J. H. B.: Literature review of the possible advantages of silicon liner socket use in trans-tibial prostheses, Prosthetics and Orthotics International, 29(1), 2005, 27–37. doi: 10.1080/17461550500069612
- Canfit, http://www.vorum.com, Vorum Res-earch Corporation.
- Colombo, G.; Facoetti, G.; Rizzi, C.: A digital patient for computer-aided prosthesis design, Interface Focus, 3(2), 2013. doi: 10.1098/rsfs.2012.0082
- Colombo, G.; Facoetti, G.; Morotti, R.; Rizzi, C.: Physically based modelling and simulation to innovate socket design, Computer-Aided Design and Applications, 8(4), 2011, 617–631. doi: 10.3722/cadaps.2011.617-631
- Duffy, V. D.: Digital Human Modeling, Proc. First International Conference on Digital Human Modeling, ICDHM 2007, Held as Part of HCI International 2007, Springer, 2007.
- Facoetti, G.; Gabbiadini, S.; Colombo, G.; Rizzi, C.: Knowledge-based system for guided modeling of sockets for lower limb prostheses, Computer-Aided Design and Applications, 7(5), 2010, 723–737. doi: 10.3722/cadaps.2010.723-737
- Goh, J. C. H.; Lee, R. S.; Toh, S. L.; Ooi, C. K.: Development of an integrated CAD-FEA process for below-knee prosthetic sockets, Clinical Biomechanics, 20(6), 2005, 623–629. doi: 10.1016/j.clinbiomech.2005.02.005
- Hong, J. H.: Effect of hip moment on socket interface pressure during stance phase gait of transfemoral amputee, Gait & Posture, 24, Supplement 2(0), 2006, S259–S261.
- Jia, X. H.; Zhang, M.; Lee, W. C. C.: Load transfer mechanics between trans-tibial prosthetic socket and residual limb - dynamic effects, Journal of Biomechanics, 37(9), 2004, 1371–1377. doi: 10.1016/j.jbiomech.2003.12.024
- Jia, X. H.; Zhang, M.; Li, X. B.; Lee, W. C. C.: A quasi-dynamic nonlinear finite element model to investigate prosthetic interface stresses during walking for trans-tibial amputees, Clinical Biomechanics, 20(6), 2005, 630–635. doi: 10.1016/j.clinbiomech.2005.03.001
- Kovacs, L.; Eder, M.; Volf, S.; Raith, S.; Pecher, M.; Pathak, H.; Müller, C.; Gottinger, F.: Patient-Specific Optimization of Prosthetic Socket Construction and Fabrication Using Innovative Manufacturing Processes: A Project in Progress, Proc. Materialise World Conference 2010.
- Lee, W. C. C.; Zhang, M.: Using computational simulation to aid in the prediction of socket fit: A preliminary study, Medical Engineering & Physics, 29(8), 2007, 923–929. doi: 10.1016/j.medengphy.2006.09.008
- Lee, W. C. C.; Zhang, M.; Jia, X. H.; Cheung, J. T. M.: Finite element modeling of the contact interface between trans-tibial residual limb and prosthetic socket, Medical Engineering & Physics, 26(8), 2004, 655–662. doi: 10.1016/j.medengphy.2004.04.010
- Magnenat-Thalmann, N.; Thalmann, D.: Handbook of virtual humans, John Wiley & Sons, Chichester, UK., 2004.
- Mak, A. F. T.; Zhang, M.; Boone, D. A.: State-of-the-art research in lower-limb prosthetic biomechanics-socket interface: A review, Journal of Rehabilitation Research and Development, 38(2), 2001, 161–173.
- OMEGA, http://www.willowwoodco.com, The Ohio Willow Wood Company.
- R4D-CADCAM, http://www.rodin4d.com, Rodin4D – Lagarrigue Group.
- Sanders, J. E.; Daly, C. H.: Normal and shear stresses on a residual limb in a prosthetic socket during ambulation - comparison of finite-element results with experimental measurements, Journal of Rehabilitation Research and Development, 30(2), 1993, 191–204.
- Sewell, P.; Noroozi, S.; Vinney, J.; Andrews, S.: Developments in the trans-tibial prosthetic socket fitting process: a review of past and present research, Prosthetics and Orthotics International, 24(2), 2000, 97–107. doi: 10.1080/03093640008726532
- SilverThorn, M. B.; Childress, D. S.: Parametric analysis using the finite element method to investigate prosthetic interface stresses for persons with trans-tibial amputation, Journal of Rehabilitation Research and Development, 33(3), 1996, 227–238.
- Wu, C. L.; Chang, C. H.; Hsu, A. T.; Lin, C. C.; Chen, S. I.; Chang, G. L.: A proposal for the pre-evaluation protocol of below-knee socket design - Integration pain tolerance with finite element analysis, Journal of the Chinese Institute of Engineers, 26(6), 2003, 853–860. doi: 10.1080/02533839.2003.9670840
- Zhang, M.; Mak, A. F. T.: In vivo friction properties of human skin, Prosthetics and Orthotics International, 23(2), 1999, 135–141.
- Zhang, M.; Roberts, C.: Comparison of computational analysis with clinical measurement of stresses on below-knee residual limb in a prosthetic socket, Medical Engineering & Physics, 22(9), 2000, 607–612. doi: 10.1016/S1350-4533(00)00079-5
- Zhang, M.; Mak, A. F. T.; Roberts, V. C.: Finite element modelling of a residual lower-limb in a prosthetic socket: a survey of the development in the first decade, Medical Engineering & Physics, 20(5), 1998, 360–373. doi: 10.1016/S1350-4533(98)00027-7
- Zhang, M.; Lord, M.; Turnersmith, A. R.; Roberts, V. C.: Development of a nonlinear finite-element modeling of the below-knee prosthetic socket interface, Medical Engineering & Physics, 17(8), 1995, 559–566. doi: 10.1016/1350-4533(95)00002-5
- Zhang, M.; Turner-Smith, A. R.; Tanner, A.; Roberts, V. C.: Clinical investigation of the pressure and shear stress on the trans-tibial stump with a prosthesis, Medical Engineering & Physics, 20(3), 1998, 188–198. doi: 10.1016/S1350-4533(98)00013-7
- Zheng, Y. P.; Mak, A. F. T.; Leung, A. K. L.: State-of-the-art methods for geometric and biomechanical assessments of residual limbs: A review, Journal of Rehabilitation Research and Development, 38(5), 2001, 487–504.