Muscle contributions to fore-aft and vertical body mass center accelerations over a range of running speeds
about
Predictive simulation generates human adaptations during loaded and inclined walkingGeneration of the Human Biped Stance by a Neural Controller Able to Compensate Neurological Time DelayModeling and simulating the neuromuscular mechanisms regulating ankle and knee joint stiffness during human locomotion.Which muscles compromise human locomotor performance with age?Is my model good enough? Best practices for verification and validation of musculoskeletal models and simulations of movement.Setting standards for medically-based running analysis.Stretching Your Energetic Budget: How Tendon Compliance Affects the Metabolic Cost of RunningSimulating Ideal Assistive Devices to Reduce the Metabolic Cost of Running.Adaptive Remodeling of Achilles Tendon: A Multi-scale Computational ModelEffects of two neuromuscular training programs on running biomechanics with load carriage: a study protocol for a randomised controlled trial.A musculoskeletal model of human locomotion driven by a low dimensional set of impulsive excitation primitives.The Differential Effect of Arm Movements during Gait on the Forward Acceleration of the Centre of Mass in Children with Cerebral Palsy and Typically Developing Children.A public dataset of running biomechanics and the effects of running speed on lower extremity kinematics and kinetics.The functional roles of muscles during sloped walking.Human ankle plantar flexor muscle-tendon mechanics and energetics during maximum acceleration sprintingFull-Body Musculoskeletal Model for Muscle-Driven Simulation of Human Gait.Masseter Muscle Activity in Track and Field Athletes: A Pilot StudyComputing muscle, ligament, and osseous contributions to the elbow varus moment during baseball pitchingIn Vivo Neuromechanics: Decoding Causal Motor Neuron Behavior with Resulting Musculoskeletal Function.Muscle contributions to the acceleration of the whole body centre of mass during recovery from forward loss of balance by stepping in young and older adults.Activity and functions of the human gluteal muscles in walking, running, sprinting, and climbing.Does a two-element muscle model offer advantages when estimating ankle plantar flexor forces during human cycling?Modelling error distribution in the ground reaction force during an induced-acceleration analysis of running in rear-foot strikers.The effect of unilateral arm swing motion on lower extremity running mechanics associated with injury risk.Running quietly reduces ground reaction force and vertical loading rate and alters foot strike technique.Forces Generated by Vastus Lateralis and Vastus Medialis Decrease with Increasing Stair Descent Speed.Why are Antagonist Muscles Co-activated in My Simulation? A Musculoskeletal Model for Analysing Human Locomotor Tasks.Effect of sagittal plane mechanics on ACL strain during jump landing.Operating length and velocity of human vastus lateralis muscle during walking and running.In vivo behavior of the human soleus muscle with increasing walking and running speeds.
P2860
Q27310976-AC38655C-691A-4C31-9F09-DB6356C06646Q27321710-B619D3AC-93F9-43AC-A25A-C7ACBEDFE2BAQ30670562-F6CF9A82-03A0-4450-AD58-88CECF8BE599Q34311952-D736C255-07B4-4FBA-9635-E6CDB37E433FQ35062172-6AE6F3F4-09F6-42B7-A21A-28213BDF34F9Q35748321-2007F265-A8AB-48BC-A786-57774AE6EC4FQ35941106-14561C88-8271-42BF-924B-3FF8A5812999Q36140552-315C3D96-1E31-458C-86F8-B229ECBFE277Q36148012-B898D3CE-B9E9-482F-81DF-EC797000A15CQ36172061-5D8F85EB-4A63-4288-8DC3-1D7DDAB66034Q36955926-BACFF723-9A12-4A3F-918D-2FDDB39E37F8Q37672422-15E758BC-771B-4352-B349-7431565C6A2EQ38786702-D48AC53E-6634-4CE6-8B10-B7394281E827Q38808561-61621BBB-3166-4461-B9FB-5C9F5276FFC6Q39434654-ED173C1D-056E-4021-9B5B-C1A74218DEE9Q39620699-8C4E1DA7-4C89-433C-A89D-B09A82FC95F5Q40410728-F9949E4E-13BF-47D3-A1E0-CCCB9DF6FCC6Q41904716-2F6D18F5-88A8-4607-9A79-6A9CB263428FQ42658955-9F38B7DD-3E91-4EB7-B199-8D430BE6325EQ43262615-1C0E906E-4AC6-4F57-AA2C-04FC82C7E610Q44282387-32BF55F0-F849-401E-BC3A-65F0C9EA78BBQ47233188-D99D4CEB-8CB4-48D0-ACB2-4A83F1888ED0Q47792152-80424B93-229D-4656-B219-BA9D19759EB3Q47851049-4094A541-6DC1-47B5-8F59-756FE3FA9CECQ48054746-A6B3916B-F10A-458D-9084-EFD7ED29C7D3Q50013226-7CA41F0A-1C2A-4702-962E-0A8C31FE8735Q50125213-E488B4B0-3625-460A-B35F-1032746370BFQ51560738-1A1E9D93-9D12-4318-B3FD-C77E2D5BCE8DQ52641786-FF5CE265-9188-4C46-9129-497A1F8CAFAAQ53280530-6DF4C775-9A2B-40AD-B9A5-01E57E9E35E1
P2860
Muscle contributions to fore-aft and vertical body mass center accelerations over a range of running speeds
description
2012 nî lūn-bûn
@nan
2012 թուականի Դեկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2012 թվականի դեկտեմբերին հրատարակված գիտական հոդված
@hy
2012年の論文
@ja
2012年論文
@yue
2012年論文
@zh-hant
2012年論文
@zh-hk
2012年論文
@zh-mo
2012年論文
@zh-tw
2012年论文
@wuu
name
Muscle contributions to fore-a ...... over a range of running speeds
@ast
Muscle contributions to fore-a ...... over a range of running speeds
@en
type
label
Muscle contributions to fore-a ...... over a range of running speeds
@ast
Muscle contributions to fore-a ...... over a range of running speeds
@en
prefLabel
Muscle contributions to fore-a ...... over a range of running speeds
@ast
Muscle contributions to fore-a ...... over a range of running speeds
@en
P2860
P1476
Muscle contributions to fore-a ...... over a range of running speeds
@en
P2093
Samuel R Hamner
Scott L Delp
P2860
P304
P356
10.1016/J.JBIOMECH.2012.11.024
P577
2012-12-11T00:00:00Z