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A Computational Model Quantifies the Effect of Anatomical Variability on Velopharyngeal FunctionA predictive model of muscle excitations based on muscle modularity for a large repertoire of human locomotion conditionsAnticipatory control of motion-to-force transitions with the fingertips adapts optimally to task difficultyMuscle redundancy does not imply robustness to muscle dysfunction.Challenges and new approaches to proving the existence of muscle synergies of neural origin.Estimation of musculoskeletal models from in situ measurements of muscle action in the rat hindlimbFunctional inference of complex anatomical tendinous networks at a macroscopic scale via sparse experimentationA single muscle's multifunctional control potential of body dynamics for postural control and running.A Novel Synthesis of Computational Approaches Enables Optimization of Grasp Quality of Tendon-Driven Hands.Extrapolatable analytical functions for tendon excursions and moment arms from sparse datasets.Medial knee joint contact force in the intact limb during walking in recently ambulatory service members with unilateral limb loss: a cross-sectional study.Altering length and velocity feedback during a neuro-musculoskeletal simulation of normal gait contributes to hemiparetic gait characteristicsExploring the high-dimensional structure of muscle redundancy via subject-specific and generic musculoskeletal models.Transferring synergies from neuroscience to robotics: Comment on "Hand synergies: Integration of robotics and neuroscience for understanding the control of biological and artificial hands" by M. Santello et al.Are muscle synergies useful for neural control?On neuromechanical approaches for the study of biological and robotic grasp and manipulation.Robot-assisted assessment of muscle strength.Transducer and base compliance alter the in situ 6 dof force measured from muscle during an isometric contraction in a multi-joint limb.An improved inverse dynamics formulation for estimation of external and internal loads during human sagittal plane movements.A comparison of models of the isometric force of locust skeletal muscle in response to pulse train inputs.Neuromorphic meets neuromechanics, part II: the role of fusimotor drive.Optimal isn't good enough.Physiological tremor increases when skeletal muscle is shortened: implications for fusimotor control.Neuromorphic meets neuromechanics, part I: the methodology and implementation.Sensory uncertainty and stick balancing at the fingertip.Uncertainty in Limb Configuration Makes Minimal Contribution to Errors Between Observed and Predicted Forces in a Musculoskeletal Model of the Rat Hindlimb.An Inverse Optimal Control Approach to Explain Human Arm Reaching Control Based on Multiple Internal Models.Feasibility Theory Reconciles and Informs Alternative Approaches to Neuromuscular ControlOptimal Control Modeling of Human Movement
P2860
Q30360689-F751D63A-5743-48A2-88D5-458BB9087A30Q30488401-4F8B2689-95C5-4103-865F-4D34C2A774B5Q33593491-A8E95248-EE71-493F-93A7-C5C1F72C166BQ34171998-EEC5FC56-6BD1-4159-A379-613419CE5E65Q34262993-D409ED29-588A-4E41-B485-0738D573BDA2Q34564014-995C26FB-99BE-45CB-9493-9A0C472E0D85Q34645271-5830714B-82D0-4A2A-A23D-963A523E000BQ35088622-D52E7F4B-E3CD-4784-8FBF-09B99DAFE551Q36537285-DD27BA23-0C0F-4EAA-8577-8FBF55D7B5FDQ36546566-EAA15E2C-E098-4A33-AAD5-5E0B5AAC5C8CQ37624686-F60B228D-5D1D-4A96-BFD0-82AA20CC48B8Q39865899-FA520C5C-ED12-4FA3-9246-55D358ADBAC2Q41217744-8A4136FD-AD58-4A6B-A8B9-AFC529EC5360Q41232227-65F4D3C1-CBF3-4244-ADD9-011052B1AEC8Q42076581-75E84E30-36E8-4069-B34E-F98520A528C1Q42374477-01752826-5423-4EAF-834B-AE588473ACA5Q42375281-EB03D3A0-1BB6-4E47-A34F-A451A6EE2F4FQ43067018-E360DA20-440D-4403-BDAA-995633B42D8CQ43508126-E2571138-70AF-450D-AA8D-D646E2D98ED2Q44764110-C8ABB188-100A-4F51-AB7F-4B78D691C9ADQ45937716-6DE757F9-DB66-49EE-84D3-78122E7CBCF2Q46177754-56F1A86E-2278-466A-AD16-04AF70E9DFA9Q46544819-0985F635-0D8D-462F-81AB-56E89052D9BDQ48012700-ADCD81FE-4534-4BC5-A4A1-113D5E048B85Q48520013-3E13D479-9B2E-4D83-95B8-AB597AC39521Q49966690-A49AB1BB-32C8-4098-B45D-E7EBACB9EDA3Q53418887-25F9B44B-610D-4086-B578-57DD84D47A88Q58750481-24AD029B-C2DE-477D-AA09-4BB94DB93F1EQ59325072-CAF137E4-ECFD-46B4-9419-1C84BF7EE1FF
P2860
description
2009 nî lūn-bûn
@nan
2009 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2009 թվականի հունվարին հրատարակված գիտական հոդված
@hy
2009年の論文
@ja
2009年論文
@yue
2009年論文
@zh-hant
2009年論文
@zh-hk
2009年論文
@zh-mo
2009年論文
@zh-tw
2009年论文
@wuu
name
Computational Models for Neuromuscular Function
@ast
Computational Models for Neuromuscular Function
@en
type
label
Computational Models for Neuromuscular Function
@ast
Computational Models for Neuromuscular Function
@en
prefLabel
Computational Models for Neuromuscular Function
@ast
Computational Models for Neuromuscular Function
@en
P2093
P2860
P1476
Computational Models for Neuromuscular Function
@en
P2093
Evangelos A Theodorou
Francisco J Valero-Cuevas
Jason J Kutch
Manish U Kurse
P2860
P304
P356
10.1109/RBME.2009.2034981
P577
2009-01-01T00:00:00Z