Angular Kinetics Review

Slides:

Advertisements

Similar presentations

AP Physics C Mechanics Review.

Advertisements

Chapter 6 Angular Momentum

Angular Quantities Correspondence between linear and rotational quantities:

Chapter 9 Objectives Calculate the torque created by a force.

Foundations of Physics

Week 12 – Angular Kinetics Objectives Identify and provide examples the angular analogues of mass, force, momentum, and impulse. Explain why changes in.

Angular Impulse Chapter 13 KINE 3301 Biomechanics of Human Movement.

Angular Kinetics Review

READING QUIZ angular acceleration. angular velocity. angular mass.

Rotational Dynamics and Static Equilibrium. Torque From experience, we know that the same force will be much more effective at rotating an object such.

Warm Up Ch. 9 & 10 1.What is the relationship between period and frequency? (define and include formulas) 2.If an object rotates at 0.5 Hz. What is the.

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

Chapter Eight Rotational Dynamics Rotational Dynamics.

I G is the “mass moment of inertia” for a body about an axis passing through the body’s mass center, G. I G is defined as: I G =  r 2 dm Units: kg-m 2.

Week 12 – Angular Kinetics Objectives Identify and provide examples the angular analogues of mass, force, momentum, and impulse. Explain why changes in.

Angular Momentum. Inertia and Velocity  In the law of action we began with mass and acceleration F = maF = ma  This was generalized to use momentum:

Week 12 – Angular Kinetics Objectives Identify the angular analogues of mass, force, momentum, and impulse. Explain why changes in the configuration of.

Biomechanical Considerations for Striking Implements - Background Relationship between linear motion and rotary motion –Radius of rotation –Axis of rotation.

Force and Motion Relationships Instantaneous Effect of force on motion is to accelerate the object: F=ma Force applied through a distance: work- energy.

Chapter 14: Angular Kinetics of Human Movement

Chapter 8 Rotational Equilibrium and Rotational Dynamics.

Units of angular measurement Degrees Radians Revolutions.

Angular Kinetics Explaining the Causes of Angular Motion

College of Physics Science & Technology YANGZHOU UNIVERSITYCHINA Chapter 11ROTATION 11.1 The Motion of Rigid Bodies Rigid bodies A rigid body is.

 Torque: the ability of a force to cause a body to rotate about a particular axis.  Torque is also written as: Fl = Flsin = F l  Torque= force x.

Physics 1210/1310 Mechanics& Thermodynamics Thermodynamics Lecture R1-7 Rotational Motion.

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

Angular Kinetics Objectives Identify and provide examples of the angular equivalents of mass, force, momentum, and impulse Explain the relationships between.

8.4. Newton’s Second Law for Rotational Motion

Chapter 9: Rotational Dynamics

Chapter 10 - Rotation Definitions: –Angular Displacement –Angular Speed and Velocity –Angular Acceleration –Relation to linear quantities Rolling Motion.

Copyright © 2010 Pearson Education, Inc. Lecture Outline Chapter 11 Physics, 4 th Edition James S. Walker.

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

Rotational Motion Chapter 6, 8 and 9. Acceleration in a Circle  Acceleration occurs when velocity changes  This means either speed OR direction changes.

Torqued An investigation of rotational motion. Think Linearly Linear motion: we interpret – position as a point on a number line – velocity as the rate.

Chapter 8 Rotational Motion.

Rotational Mechanics. Rotary Motion Rotation about internal axis (spinning) Rate of rotation can be constant or variable Use angular variables to describe.

Angular Kinetics Review Readings: –Hamill Ch 11 esp pp –Kreighbaum pp , –Adrian (COM calculations) Homework problem on calculating.

Chapter 11 Rotational Mechanics. Recall: If you want an object to move, you apply a FORCE.

Rigid Body Particle Object without extent Point in space Solid body with small dimensions.

Angular Kinematics Chapter 11. Angular Motion All parts of a body move through the same angle, in the All parts of a body move through the same angle,

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

9.4. Newton’s Second Law for Rotational Motion A model airplane on a guideline has a mass m and is flying on a circle of radius r (top view). A net tangential.

© 2005 Pearson Prentice Hall This work is protected by United States copyright laws and is provided solely for the use of instructors in teaching their.

Moment Of Inertia.

Linear and Angular Motion. The greater the applied impulse the greater the increase in velocity. Principle 4 – Linear Motion.

Angular Kinetics of Human Movement

Angular Momentum Section 8.1 (Ewen et al. 2005) Objectives: Define and calculate moment of inertia. Define and calculate moment of inertia. Define and.

Chapter 9 Rotational Dynamics

Chapter 11 – Rotational Dynamics & Static Equilibrium.

Rotational Dynamics Rode, Kiana, Tiana, and Celina.

 The metric system – units, prefixes  Unit conversions  Algebra and trigonometry  Orders of magnitude.

Angular Kinetics Review Readings: –Hamill Ch 11 esp pp –Kreighbaum pp , –Adrian (COM calculations) Homework problem on calculating.

AP Phys B Test Review Momentum and Energy 4/28/2008.

Rotational Motion AP Physics C. Introduction The motion of a rigid body (an object with a definite shape that does not change) can be analyzed as the.

Today: (Ch. 8)  Rotational Motion.

UNIT 6 Rotational Motion & Angular Momentum Rotational Dynamics, Inertia and Newton’s 2 nd Law for Rotation.

Biomechanical Considerations for Striking Implements - Background

Chapter 14 Angular Kinetics of Human Movement Basic Biomechanics, 7 th edition By Susan J. Hall, Ph.D. © 2014 The McGraw-Hill Companies, Inc. All rights.

Ch 8 : Rotational Motion .

College Physics, 7th Edition

Rotational Inertia and Torque

Angular Kinetics of Human Movement

Chapter 8 Rotational Motion

Factors Influencing Movement

Angular Momentum & its Conservation

Factors Influencing Movement

Translational-Rotational Analogues

Moment of Inertia ( I ) The property of an object that serves as a resistance to angular motion. Chapter 7 in text 5/14/2019 Dr. Sasho MacKenzie HK 376.

Presentation transcript:

Angular Kinetics Review Readings: Hamill Ch 11 Sources for PPt presentation: Chapter 12 of Basic Biomechanics by Susan Hall and Kreighbaum’s text Reference to figures in this presentation refer to the former text by Kreighbaum, which is on reserve

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

Relationship between linear and angular motion (kinematics)

Instnataneous effect of net torque: Moment of Inertia Constant What is torque?

Instantaneous effect of net torque: Torque is constant What is rotational inertia, Or moment of inertia?

Instantaneous effect of net torque: Ang acc constant

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

What is radius of gyration (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

Determining MOI & K Irregularly shaped bodies 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!

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

MOI & K – Geometric Objects

Changing I and k in the human body

Changing I and k in the human body

MOI around principal axes of human body in different positions

Angular 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

What is angular impulse?

Angular Impulse: Mediolateral axis

Angular Impulse around vertical axis

What is angular momentum (L)?

Conservation of Momentum

Conservation of Momentum

COM Questions What is COM (or COG) and why is it important? How is COM location different for infants and how does this affect their movement? Is COM location different for men vs women? How is COM different if you lose an arm and how does this affect movement? How does COM relate to stability? Why do you lean to one side when carrying a load with one arm? Can Vince Carter, or any athlete really hang in the air?

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

Segmental concept of center of mass

Segmental concept of center of mass