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

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Presentation on theme: "Particle Kinematics Direction of velocity vector is parallel to path Magnitude of velocity vector is distance traveled / time Inertial frame – non accelerating,"— Presentation transcript:

1 Particle Kinematics Direction of velocity vector is parallel to path Magnitude of velocity vector is distance traveled / time Inertial frame – non accelerating, non rotating reference frame Particle – point mass at some position in space Position Vector Velocity Vector Acceleration Vector

2 Particle Kinematics Simple Harmonic Motion Circular Motion at const speed Straight line motion with constant acceleration

3 Summary General circular motion Arbitrary path

4 Summary Polar Coords

5 Newton’s laws For a particle For a rigid body in motion without rotation, or a particle on a massless frame You MUST take moments about center of mass

6 Calculating forces required to cause prescribed motion of a particle Idealize system Free body diagram Kinematics F=ma for each particle. (for rigid bodies or frames only) Solve for unknown forces or accelerations

7 Deriving Equations of Motion for particles 1. Idealize system 2. Introduce variables to describe motion (often x,y coords, but we will see other examples) 3. Write down r, differentiate to get a 4. Draw FBD 5. 6. If necessary, eliminate reaction forces 7. Result will be differential equations for coords defined in (2), e.g. 8. Identify initial conditions, and solve ODE

8 Motion of a projectile

9 Work and Energy relations Rate of work done by a force (power developed by force) Total work done by a force Kinetic energy Work-kinetic energy relation Power-kinetic energy relation

10 Potential energy Potential energy of a conservative force (pair)

11 Energy relations for conservative systems subjected to external forces Internal Forces: (forces exerted by one part of the system on another) External Forces: (any other forces) Work done by external forces System is conservative if all internal forces are conservative forces (or constraint forces) Energy relation for a conservative system Kinetic and potential energy at time

12 Linear Impulse of a force Linear momentum of a particle Impulse-momentum relations Total external impulse Total linear momentum Conservation law Impulse-momentum for a system of particles Impulse-momentum for a single particle

13 Collisions

14 Angular Impulse-Momentum Equations for a Particle Impulse-Momentum relations Useful for central force problems Angular Momentum Angular Impulse

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