This excerpt from NSCA’s Essentials of Sport Science briefly explains the force-velocity-power profile and how it can give strength and conditioning coaches a more holistic view of athletes.
Bo Sandoval, Director of Strength and Conditioning for the UFC Performance Institute, walks through weightlifting examples used to elicit changes in the force-velocity curve.
Weightlifting movements and their derivatives can be programmed effectively by considering their force–velocity characteristics and physiological underpinnings to meet the specific training goals of resistance training phases in accordance with the typical application of periodized training programs.
Tim Suchomel, Assistant Professor of Exercise Science and the Program Director for the Sport Physiology and Performance Coaching graduate program at Carroll University, discusses the literature surrounding the force-velocity curve, identifies potential periodization and programming strategies to improve these characteristics in athletes, and provides example programs to show how to implement different resistance training methods.
It is important for coaches to understand the relationship between commonly measured variables (e.g., displacement, velocity, and force) and their relationship to the derived variable of power.
CoachesExercise Sciencekinetic selectpowertesting for powerexercise testingstrength and conditioning
This info-graphic describes research on velocity decrements to increase propulsive and horizontal force applications to increase acceleration kinetics.
Personal trainersCoachesExercise ScienceProgram designVelocity Based TrainingAccelerationSled PushHorizontal Force Applicationinfographics
Acceleration and maximal velocity are two factors that are key for any position in football and can determine success in many situations out on the field. This article will review several aspects of sprint mechanics and training to enhance linear (straight-ahead) speed for football players.