Search results for "Biomechanics of sprint running"

showing 3 items of 3 documents

Force-, EMG-, and elasticity-velocity relationships at submaximal, maximal and supramaximal running speeds in sprinters.

1986

The relationships between ground reaction forces, electromyographic activity (EMG), elasticity and running velocity were investigated at five speeds from submaximal to supramaximal levels in 11 male and 8 female sprinters. Supramaximal running was performed by a towing system. Reaction forces were measured on a force platform. EMGs were recorded telemetrically with surface electrodes from the vastus lateralis and gastrocnemius muscles, and elasticity of the contact leg was evaluated with spring constant values measured by film analysis. Data showed increases in most of the parameters studied with increasing running speed. At supramaximal velocity (10.36 +/- 0.31 m X s-1; 108.4 +/- 3.8%) the…

AdultMaleSpecific forcePhysiologyElectromyographyPublic Health Environmental and Occupational HealthSTRIDEGeneral MedicineAnatomyConcentricElasticityBiomechanical PhenomenaRunningPhysiology (medical)EccentricHumansOrthopedics and Sports MedicineForce platformFemaleGround reaction forceBiomechanics of sprint runningLung ComplianceBiomedical engineeringResultant forceMathematicsEuropean journal of applied physiology and occupational physiology
researchProduct

Biomechanics of sprint running. A review.

1992

Understanding of biomechanical factors in sprint running is useful because of their critical value to performance. Some variables measured in distance running are also important in sprint running. Significant factors include: reaction time, technique, electromyographic (EMG) activity, force production, neural factors and muscle structure. Although various methodologies have been used, results are clear and conclusions can be made. The reaction time of good athletes is short, but it does not correlate with performance levels. Sprint technique has been well analysed during acceleration, constant velocity and deceleration of the velocity curve. At the beginning of the sprint run, it is importa…

Malemedicine.medical_specialtyComputer scienceeducationAccelerationNeural ConductionPhysical Therapy Sports Therapy and RehabilitationElectromyographyPropulsionRunningAccelerationmedicineHumansOrthopedics and Sports MedicineSimulationmedicine.diagnostic_testElectromyographyWork (physics)BiomechanicsBiomechanical PhenomenaSprintDragPhysical therapyFemaleBiomechanics of sprint runninghuman activitiesSports medicine (Auckland, N.Z.)
researchProduct

Force-Time Characteristics and Running Velocity of Male Sprinters during the Acceleration Phase of Sprinting

1988

Abstract In an effort to investigate the force-time characteristics during the acceleration phase of the sprint start, eight male sprinters were used as subjects. Runs up to 3 m were analyzed from film, and force-time parameters were measured on a force platform. In a starting stance the reaction time of the group was .118 ± .016 s and the force production lasted .342 ± .022 s. The maximal resultant force at the moment of maximal horizontal force was 19.3 ± 2.2 N x kg1, and the direction of the force was 32 ± 7°. In the very last instant before leaving the blocks the velocity of the center of gravity was 3.46 ± .32 m x s−1. In the first contact after leaving the blocks there was a braking p…

PhysicsPhase (waves)Physical Therapy Sports Therapy and RehabilitationGeometryGeneral MedicineAccelerationCenter of gravitySprintNephrologyMoment (physics)Orthopedics and Sports MedicineForce platformBiomechanics of sprint runningResultant forceResearch Quarterly for Exercise and Sport
researchProduct