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Physics 207, Lecture 5, Sept. 20

Physics 207, Lecture 5, Sept. 20. Agenda. Chapter 4 Kinematics in 2 or 3 dimensions Independence of x , y and/or z components Circular motion Curved paths and projectile motion Frames of reference Radial and tangential acceration.

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Physics 207, Lecture 5, Sept. 20

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  1. Physics 207, Lecture 5, Sept. 20 Agenda • Chapter 4 • Kinematics in 2 or 3 dimensions • Independence of x, y and/or z components • Circular motion • Curved paths and projectile motion • Frames of reference • Radial and tangential acceration Assignment: For Monday read Chapter 5 and look at Chapter 6 • WebAssign Problem Set 2 due Tuesday next week (start ASAP)

  2. See text: 4-1 Chapter 4: Motion in 2 (and 3) dimensions3-D Kinematics • The position, velocity, and acceleration of a particle in 3-dimensions can be expressed as: r = x i + y j + z k v = vx i + vy j + vz k(i,j,kunit vectors ) a = ax i + ay j + az k • Which can be combined into the vector equations: r = r(t) v = dr / dt a = d2r / dt2

  3. v Instantaneous Velocity • The instantaneous velocity is the limit of the average velocity as ∆t approaches zero • The direction of the instantaneous velocity is alonga line that is tangent to the path of the particle’s direction of motion. • The magnitude of the instantaneous velocity vector is the speed. (The speed is a scalar quantity)

  4. Average Acceleration • The average acceleration of a particle as it moves is defined as the change in the instantaneous velocity vector divided by the time interval during which that change occurs. • The average acceleration is a vector quantity directed along ∆v

  5. Instantaneous Acceleration • The instantaneous acceleration is the limit of the average acceleration as ∆v/∆t approaches zero • The instantaneous acceleration is a vector with components parallel (tangential) and/or perpendicular (radial) to the tangent of the path • Changes in a particle’s path may produce an acceleration • The magnitude of the velocity vector may change • The direction of the velocity vector may change (Even if the magnitude remains constant) • Both may change simultaneously (depends: path vs time)

  6. 3-D Kinematics : vectorequations: r = r(t) v = dr / dt a = d2r / dt2 v2 Velocity : v1 vav = r / t v = dr / dt aav = v / t a = dv / dt Acceleration : Motion along a path ( displacement, velocity, acceleration ) y path v2 -v1 v x

  7. = + = 0 Change in the magnitude of = 0 = 0 Change in the direction of a a a a a a path andtime t v v v a a a General 3-D motion with non-zero acceleration: • Uniform Circular Motion is one specific case: Two possible options: Animation

  8. See text: 4-4 Uniform Circular Motion • What does it mean ? • How do we describe it ? • What can we learn about it ?

  9. v2 v2 -v1 R v1 v See text: 4-4 Average acceleration in UCM: • Even though the speed is constant, velocity is not constant since the direction is changing: must be some acceleration ! • Consider average acceleration in timet aav = v / t seems like v (hence v/t ) points toward the origin !

  10. See text: 4-4 Instantaneous acceleration in UCM: • Again: Even though the speed is constant, velocity is not constant since the direction is changing. • As t goes to zero in v / t dv / dt = a a = dv / dt R Now apoints in the - Rdirection.

  11. v Similar triangles: v1 v2 v2 R So: v1 R Acceleration in UCM: • This is called Centripetal Acceleration. • Calculating the magnitude: • |v1| = |v2| = v But R = vt for smallt

  12. v v R s R s   = 2 / T = 2f Period and Frequency • Recall that 1 revolution = 2 radians • Period (T) = seconds / revolution = distance / speed = 2pR / v • Frequency(f) = revolutions / second = 1/T (a) • Angular velocity () = radians / second(b) • By combining(a)and (b) •  = 2 f • Realize that: • Period (T) = seconds / revolution • So T = 1 / f = 2/

  13. See text: 4-4 Recap: Centripetal Acceleration • UCM results in acceleration: • Magnitude: a= v2 / R =R • Direction: - r (toward center of circle) a R 

  14. Lecture 5, Exercise 1Uniform Circular Motion • A fighter pilot flying in a circular turn will pass out if the centripetal acceleration he experiences is more than about 9 times the acceleration of gravity g. If his F18 is moving with a speed of 300 m/s, what is the approximate radius of the tightest turn this pilot can make and survive to tell about it ? (Let g = 10 m/s2) (a) 10 m (b) 100 m (c) 1000 m (d) 10,000 m UCM (recall) Magnitude: a= v2 / R Direction: (toward center of circle)

  15. Answer (c) Lecture 5, Exercise 1Solution

  16. Example: Newton & the Moon • What is the acceleration of the Moon due to its motion around the earth? • T = 27.3 days = 2.36 x 106 s (period ~ 1 month) • R = 3.84 x 108 m (distance to moon) • RE= 6.35 x 106 m (radius of earth) R RE

  17. Moon... • Calculate angular frequency: • So  = 2.66 x 10-6 rad s -1. • Now calculate the acceleration. • a = 2R= 0.00272 m/s2 = .000278 g • direction of a is toward center of earth (-R).

  18. Radial and Tangential Quantities For uniform circular motion v a

  19. Radial and Tangential Quantities What about non-uniform circular motion ? v aq is along the direction of motion a ar is perpendicular to the direction of motion

  20. Lecture 5, Exercise 2The Pendulum q = 30° Which statement best describes the motion of the pendulum bob at the instant of time drawn ? • the bob is at the top of its swing. • which quantities are non-zero ? 1m B) Vr = 0 ar 0 vq 0 aq= 0 C) vr = 0 ar 0 vq= 0 aq 0 A) vr = 0 ar = 0 vq 0 aq 0

  21. a Lecture 5, Exercise 2The PendulumSolution O NOT uniform circular motion : is circular motion so must be arnot zero, Speed is increasing so aq not zero q = 30° 1m At the top of the swing, the bob temporarily stops, so v = 0. aq ar C) vr = 0 ar 0 vq= 0 aq g In the next lecture we will learn about forces and how to calculate just what a is.

  22. Relative motion and frames of reference • Reference frame S is stationary • Reference frame S’ is moving at vo • This also means that S moves at – vo relative to S’ • Define time t = 0 as that time when the origins coincide

  23. Relative Velocity • Two observers moving relative to each other generally do not agree on the outcome of an experiment • For example, observers A and B below see different paths for the ball

  24. Relative Velocity, equations • The positions as seen from the two reference frames are related through the velocity • r’ = r – vot • The derivative of the position equation will give the velocity equation • v’ = v – vo • These are called the Galilean transformation equations

  25. Reference frame on the ground. Central concept for problem solving: “x” and “y” components of motion treated independently. • Again: man on the cart tosses a ball straight up in the air. • You can view the trajectory from two reference frames: y(t) motion governed by 1) a = -gy 2) vy = v0y – g t 3) y = y0 + v0y – g t2/2 Reference frame on the moving train. x motion: x = vxt Net motion: R = x(t) i + y(t) j(vector)

  26. Acceleration in Different Frames of Reference • The derivative of the velocity equation will give the acceleration equation • v’ = v – vo • a’ = a • The acceleration of the particle measured by an observer in one frame of reference is the same as that measured by any other observer moving at a constant velocity relative to the first frame.

  27. a) b) c) 2m/s 50m 1m/s d) Lecture 5, Exercise 3Relative Motion • You are swimming across a 50 mwide river in which the current moves at 1 m/s with respect to the shore. Your swimming speed is 2 m/s with respect to the water. You swim across in such a way that your path is a straight perpendicular line across the river. • How many seconds does it take you to get across?

  28. y x 1m/s y 2m/s 1m/s m/s x Lecture 5, Exercise 3Solution Choose x axis along riverbank and y axis across river • The time taken to swim straight across is (distance across) / (vy ) • Since you swim straight across, you must be tilted in the water so that your x component of velocity with respect to the water exactly cancels the velocity of the water in the x direction:

  29. The y component of your velocity with respect to the water is • The time to get across is m/s 50m y x Lecture 5, Exercise 3Solution Answer (c)

  30. Recap First mid-term exam in just two weeks, Thursday Oct. 5 • Chapter 4 • Kinematics in 2 or 3 dimensions • Independence of x, y and/or z components • Circular motion • Curved paths and projectile motion • Frames of reference • Radial and tangential acceration Assignment: For Monday read Chapter 5 and look at Chapter 6 • WebAssign Problem Set 2 due Tuesday next week (start ASAP)

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