Muscle power at joint is product of net muscle moment and angular velocity.

Slides:

Advertisements

Similar presentations

Angular Quantities Correspondence between linear and rotational quantities:

Advertisements

Chapter 4 Work and Energy Additional Concepts For Describing Motion.

Lecture 5 Dimitar Stefanov. Definitions: Purpose of the muscles is to produce tension Metabolic efficiency – the measure of a muscle’s ability to convert.

Angular Momentum (of a particle) O The angular momentum of a particle, about the reference point O, is defined as the vector product of the position, relative.

Chapter 11 Angular Momentum.

PHYS16 – Lecture 15 Work and Energy October 13, 2010.

Moment Power Analysis and Absolute Power Method D. Gordon E. Robertson, PhD, FCSB Biomechanics Laboratory, School of Human Kinetics, University of Ottawa,

Chapter 12: Rolling, Torque and Angular Momentum.

Chapter 10: Rotation. Rotational Variables Radian Measure Angular Displacement Angular Velocity Angular Acceleration.

Department of Physics and Applied Physics , F2010, Lecture 20 Physics I LECTURE 20 11/21/10.

Phy 211: General Physics I Chapter 10: Rotation Lecture Notes.

Kinematics, Momentum and Energy BU Photon Outreach December 14, 2010.

Angular Momentum. Moments  The moment of a vector at a point is the wedge product.  This is applied to physical variables in rotating systems. Applied.

Center of Mass and Linear Momentum

Mechanical Energy, Work and Power D. Gordon E. Robertson, Ph.D. Biomechanics Laboratory, School of Human Kinetics, University of Ottawa, Ottawa, CANADA.

AP Physics 1 – Unit 5 WORK, POWER, AND ENERGY. Learning Objectives: BIG IDEA 3: The interactions of an object with other objects can be described by forces.

Kinetic energy Vector dot product (scalar product) Definition of work done by a force on an object Work-kinetic-energy theorem Lecture 10: Work and kinetic.

Velocities and Static Force

Angular Kinetics Explaining the Causes of Angular Motion

PLANAR KINETICS OF A RIGID BODY:

Work Let us examine the work done by a torque applied to a system. This is a small amount of the total work done by a torque to move an object a small.

Mechanics and Materials Forces Displacement Deformation (Strain) Translations and Rotations Stresses Material Properties.

Spring Topic Outline for Physics 1 Spring 2011.

KINESIOLOGY دکترامیر هوشنگ واحدی متخصص طب فیزیکی و توانبخشی قسمت 3.

Chapter 11 Angular Momentum. The Vector Product There are instances where the product of two vectors is another vector Earlier we saw where the product.

Physics Midterm Review Terms - Measurements time elapsed = duration of an event – there is a beginning, a middle, and an end to any event. distance.

Rotation Rotational Variables Angular Vectors Linear and Angular Variables Rotational Kinetic Energy Rotational Inertia Parallel Axis Theorem Newton’s.

Chapter 9: Rotational Dynamics

Systems of Particles.

Forms of Energy Mechanical Focus for now May be kinetic (associated with motion) or potential (associated with position) Chemical Electromagnetic Nuclear.

Angular Kinetics After reading this chapter, the student should be able to: Define torque and discuss the characteristics of a torque. State the angular.

11 rotation The rotational variables Relating the linear and angular variables Kinetic energy of rotation and rotational inertia Torque, Newton’s second.

Circular motion Objectives: understand that acceleration is present when the magnitude of the velocity, or its direction, or both change; understand that.

KINETICS OF PARTICLES: ENERGY AND MOMENTUM METHODS s2s2 A1A1 A2A2 A s1s1 s drdr F  ds Consider a force F acting on a particle A. The work of F.

Chapter 6: Work and Energy Essential Concepts and Summary.

Joint Reaction Forces Muscle Moments Joint Power

Engineering Mechanics: Statics

Exam 2 Review 8.02 W08D1. Announcements Test Two Next Week Thursday Oct 27 7:30-9:30 Section Room Assignments on Announcements Page Test Two Topics: Circular.

Chapter 7: Linear Momentum Along with conservation of energy, we will now include other conserved quantities of linear and angular momentum. Linear momentum.

DYNAMICS VECTOR MECHANICS FOR ENGINEERS: DYNAMICS Tenth Edition Ferdinand P. Beer E. Russell Johnston, Jr. Phillip J. Cornwell Lecture Notes: Brian P.

Chapter 11 Angular Momentum. Angular momentum plays a key role in rotational dynamics. There is a principle of conservation of angular momentum.  In.

Definitions ! Forces and Motion. Acceleration ! Acceleration is the rate of change of velocity, with respect to time. Velocity ! Velocity is the rate.

Moment Of Inertia.

Chapter 14 SYSTEMS OF PARTICLES The effective force of a particle P i of a given system is the product m i a i of its mass m i and its acceleration a i.

Work and Energy. Scalar (Dot) Product When two vectors are multiplied together a scalar is the result:

Forces and Motion Unit Vocabulary. Newton’s 1 st law Law states: An object at rest stays at rest. An object in motion stays in motion unless an unbalanced.

1 Rotation of a Rigid Body Readings: Chapter How can we characterize the acceleration during rotation? - translational acceleration and - angular.

1 Work in Rotational Motion Find the work done by a force on the object as it rotates through an infinitesimal distance ds = r d  The radial component.

Chapter 14 Systems of Particles.

Work Readings: Chapter 11.

Kinematics Variables Time: temporal characteristics of a performance, either of the total skill or its phases Displacement: length and direction of the.

AP Physics C Montwood High School R. Casao. When a wheel moves along a straight track, the center of the wheel moves forward in pure translation. A point.

Chapter 5 Energy. Forms of Energy Mechanical Focus for now May be kinetic (associated with motion) or potential (associated with position) Chemical Electromagnetic.

Work, Energy and Power Ms Houts AP Physics C Chapters 7 & 8.

Chapter 1: Survey of Elementary Principles

Physical Modeling, Fall WORK Work provides a means of determining the motion of an object when the force applied to it is known as a function of.

1 Chapter-3 (Electric Potential) Electric Potential: The electrical state for which flow of charge between two charged bodies takes place is called electric.

Particle Kinematics Direction of velocity vector is parallel to path Magnitude of velocity vector is distance traveled / time Inertial frame – non accelerating,

Components of Torque (Moment of Force)

Rotational Kinetic Energy

Kinematic Analysis (position, velocity and acceleration)

CHAPTER 4: Systems of Particles

Systems of Particles.

Rolling, Torque, and Angular Momentum

Potential Energy and Conservation of Energy

Chapter 7 Kinetic Energy and Work

Chapter 7 Kinetic Energy and Work

Kinetic Energy and Work

Systems of Particles.

Physics Chapter 6 Equilibrium.

Presentation transcript:

Muscle power at joint is product of net muscle moment and angular velocity

Work done by a muscle Differential work Work along a path

Special case: F and v are collinear

Reaction forces and velocities at a joint. Mechanical power (rate of mechanical energy transfer) equals dot product of force and velocity.

Eta+, eta- are efficiencies of positive and negative work

Flow of energy from metabolic to external mechanical work

Total energy in a muiltisegment system

Center of mass approach Energy for movement is reflected in the kinetic and potential energy associated with translation of the body cnetr of mass. Cavanaugh et al 1966 & many more. CoM is a vector sum of masses and accelerations, so ppositely directed accelerations cancel. B ut energy is a scalar. CoM approach neglects energy associated with causing limb movements in opposite directions. Therefore this approach grossly underestimates mechanical energy of body movement.

Sum of segment energies approach Fixes some of the shortcomings of the CoM approach. Still underestimates work done since it fails to capture positive and negative work done at multiple joints.

Joint power and work Improvement on the sum of segment energies approach. Identifies positive and negative work done at each joint. Still underestimates work associated with muscle co-contraction.