Angular Kinetics Review

1. Angular Kinetics Review • Readings: • Hamill Ch 11 esp pp 382-410 • Kreighbaum pp 318-324, 326-331 • Adrian 33-40 (COM calculations) • Homework problem on calculating MOI of lower extremity will be distributed in class

2. Angular Kinetics Outline • Torque and motion relationships Musculoskeletal machines • Mechanical advantage • Length-tension relationship • Center of Mass – segmental method • Angular analogue of Newton’s third law • Angular impulse and momentum • Conservation of angular momentum • Calculating moment of inertia of body segments using cadaver data • Homework problem – calculating MOI of lower extremity

3. Torque and Motion Relationships • Relationship between linear and angular motion • displacement, velocity, and acceleration • Angular analogue of Newton’s third law (F=ma), the instantaneous effect of a force or torque • Torque = moment of inertia (I) X angular acc ( What is torque? • What is moment of inertia ? • What is radius of gyration • Changing moment of inertia and radius of gyration in the body Calculations using a 3-segment system • Homework problem

4. What is torque, or a moment of force? Torque is the turning effect of a force and is the product of force magnitude and moment arm, or perpendicular distance from the force’s line of action to the axis of rotation:

5. Angle of Pull of Muscle & degree of force application Turning component equals Force times sin θ

6. Mechanical Advantage of Elbow Flexors

7. Length of Elbow Flexors as Joint Angle Changes

8. Length-tension, angle of pull combined Sine of

9. Sample Problem #2, p 433

10. Example of total body torques Torque and impulse about the center of mass

11. What is the COM and why is it important? • What is COM (or COG) and why is it important? • It simplifies mechanical analysis of a complicated system • It is the point at which all of the mass of the system may be considered to be located • It is the only point that represents movement of the total system The acceleration of the COM is proportional to the net force and inversely proportional to the mass. • It is the only point that follows a parabolic flight pattern when free of contact with earth • External forces through the COM cause produce only linear motion • External forces not through the COM (eccentric forces) create a torque, or moment, and produce both linear and rotary motion

12. COM/COG Concept and Calculation Method (Adrian pp 33-41) • Concept of balancing segmental torques • Segmental Calculation of COM • General calculation method • Information needed • Proportionate mass of each segment • location of COM of each segment

13. Segmental concept of center of mass

15. Hanavan Model used for Segmental Calculation of COM and MOI

16. Segmental concept of center of mass Information needed: 1. Segmental COMlocation 2. Segmental proportionate mass

18. Instantaneous effect of net torque: Moment of Inertia (MOI) Constant T = I What are torque and MOI?

19. Instantaneous effect of net torque: Torque is constant

20. Instantaneous effect of net torque: Ang acc constant

21. What is Moment of Inertia? It is the resistance of a system to rotational acceleration, and is calculated at follows: Here, r (the radius of rotation) is equal to k (the radius of gyration), but that is not the case with extended bodies

22. What is radius of gyration (k)? k 35 An indicator of distribution of mass about the axis. It is the distance from the axis to a point at which all the mass of a system of equal mass would be concentrated to have the MOI equal the original system. It is, then, the average weighted distance of the mass of a system to the axis. Equivalent systems k 35

23. Determining MOI & K • Simple 3-segment system: • I = 3mi di2 = m1 d12 + m2 d22+ m3 d32 + . . . . . . .+ mi di2 • I = mk2 ; k = (I/m).5 • Irregularly shaped bodies But we can’t measure all of these small masses!

24. Physical pendulum method of determining MOI and K • Suspend object at axis • Measure mass (m), and distance from axis to COM, r • Measure period of oscillation (T) • Moment of inertia (I) = T2 mr * .248387 m/sec • Radius of gyration (K) = ( I/m).5

25. MOI & K – Geometric Objects

26. ChangingIandk in the human body

27. ChangingIand k in the human body

28. MOI around principal axes of human body in different positions

29. Angular Impulse and Momentum • Impulse-momentum relationship - effect of force or torque applied over time • Linear: Ft = mv Rotational: Tt = I  • What is angular impulse? • Torque X time • What is angular momentum? • Amount of angular movement: I  • Conservation of angular momentum • Angular momentum is constant if net impulse is zero

30. Total body torque and angular impulse: Mediolateral axis

31. Angular Impulse around vertical axis

32. What is angular momentum (L)?

33. Example of angular momentum

34. Conservation of Momentum

35. Conservation of Momentum

36. Addendum to angular kinetics: estimates of body segment parameters • The calculation of the linear and rotational inertial properties (mass, moment of inertia) of the human body requires estimates of body segment parameters • Chapter 3 of Roberson provides an excellent summary of these estimation techniques • Each of you will be assigned selected portions of this chapter to summarize for the class on February 27

37. Next topic: Biomechanics of Skeletal Muscle and Electroymography • Biomechanics of skeletal muscle • Readings: Hamill pp 76-81, 103-109 • Electromyography • Readings: Hamill pp 81-85; Cram pp 32-37, Ch 3; DeLuca website tutorial (http://www.delsys.com ),