The dynamics of the skeletal muscle: a systems biophysics perspective on muscle modeling with the focus on Hill-type muscle models. GAMM--Mitteilungen, (58):e201900013, 2019. [PUMA: imported myown cbb imsb]
All leg joints contribute to quiet human stance: a mechanical analysis. Journal of Biomechanics, (42)16:2739-2746, 2009. [PUMA: imported myown cbb imsb]
Hill-type muscle model with serial damping and eccentric force-velocity relation. Journal of Biomechanics, (47)6:1531-1536, 2014. [PUMA: imported myown cbb imsb]
Running on uneven ground: leg adjustment to vertical steps and self-stability. The Journal of Experimental Biology, (211)Pt 18:2989-3000, 2008. [PUMA: imported myown cbb imsb]
Muscle force depends on the amount of transversal muscle loading. Journal of Biomechanics, (47)8:1822-1828, 2014. [PUMA: imported myown cbb imsb]
Quantifying control effort of biological and technical movements: An information-entropy-based approach. Physical Review E, (89):012716, 2014. [PUMA: imported myown cbb imsb]
On laterally perturbed human stance: experiment, model, and control. Applied Bionics and Biomechanics, ():4767624 (20pp), 2018. [PUMA: imported myown cbb imsb]
What does head movement tell about the minimum number of mechanical degrees of freedom in quiet human stance?. Archive of Applied Mechanics, (82)3:333-344, 2012. [PUMA: imported myown cbb imsb]
Diverging times in movement analysis. Journal of Biomechanics, (42)6:786-788, 2009. [PUMA: imported myown cbb imsb]
Comparative sensitivity analysis of muscle activation dynamics. Computational and Mathematical Methods in Medicine, ():585409 (16pp), 2015. [PUMA: imported myown cbb imsb]
Theoretical Hill-type muscle and stability: numerical model and application. Computational and Mathematical Methods in Medicine, ():570878 (7pp), 2013. [PUMA: imported myown cbb imsb]
Impulsive ankle push-off powers leg swing in human walking. The Journal of Experimental Biology, (217)Pt 8:1218-1228, 2014. [PUMA: imported myown cbb imsb]
Facilitating control using intelligent mechanics in animals and machines. The Physiologist, (45)4:338, 2002. [PUMA: imported myown cbb imsb]
Nature as an engineer: one simple concept of a bio-inspired functional artificial muscle. Bioinspiration & Biomimetics, (7)3:036022 (9pp), 2012. [PUMA: imported myown cbb imsb]
Proof of concept: model based bionic muscle with hyperbolic force-velocity relation. Applied Bionics and Biomechanics, (9)3:267-274, 2012. [PUMA: imported myown cbb imsb]
A forward dynamics simulation of human lumbar spine flexion predicting the load sharing of intervertebral discs, ligaments, and muscles. Biomechanics and Modeling in Mechanobiology, (14)5:1081-1105, 2015. [PUMA: imported myown cbb imsb]
Human leg impact: energy dissipation of wobbling masses. Archive of Applied Mechanics, (81)7:887-897, 2011. [PUMA: imported myown cbb imsb]
Spreading out muscle mass within a Hill-type model: A computer simulation study. Computational and Mathematical Methods in Medicine, ():848630 (13pp), 2012. [PUMA: imported myown cbb imsb]
How to model a muscle's active force-length relation: A comparative study. Computer Methods in Applied Mechanics and Engineering, (313):321-336, 2017. [PUMA: imported myown cbb imsb]
Dealing with skin motion and wobbling masses in inverse dynamics. Journal of Mechanics in Medicine and Biology, (3)3/4:309-335, 2003. [PUMA: imported myown cbb imsb]