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Physics 101: Lecture 19, Pg 1 Physics 101: Lecture 19 Elasticity and Oscillations Exam III.

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Presentation on theme: "Physics 101: Lecture 19, Pg 1 Physics 101: Lecture 19 Elasticity and Oscillations Exam III."— Presentation transcript:

1 Physics 101: Lecture 19, Pg 1 Physics 101: Lecture 19 Elasticity and Oscillations Exam III

2 Physics 101: Lecture 19, Pg 2 Hour exam results

3 Physics 101: Lecture 19, Pg 3 Hour exam results Avg (ex 1&2), max grade, median grade, min grade 53- 56 C-, D-, F N: 10 57- 60 C, D+, F N: 18 61- 64 C+, D+, F N: 19 65- 68 B+, C, D N: 37 69- 72 A-, C, D- N: 52 73- 76 A-, C+, D- N: 52 77- 80 A, B, D- N: 55 81- 84 A+, B+, C- N: 39 85- 88 A+, A-, D- N: 47 89- 92 A+, A, C N: 32 93- 96 A+, A+, A- N: 22 97-100 A+, A+, A+ N: 03

4 Physics 101: Lecture 19, Pg 4 Overview l Springs (review) è Restoring force proportional to displacement è F = -k x (often a good approximation) è U = ½ k x 2 l Today è Young’s Modulus (where does k come from?) è Simple Harmonic Motion è Springs Revisited

5 Physics 101: Lecture 19, Pg 5 Springs l Hooke’s Law: l Hooke’s Law: The force exerted by a spring is proportional to the distance the spring is stretched or compressed from its relaxed position. è F X = – k xWhere x is the displacement from the relaxed position and k is the constant of proportionality. relaxed position F X = 0 x x=0 18

6 Physics 101: Lecture 19, Pg 6 Springs ACT l Hooke’s Law: l Hooke’s Law: The force exerted by a spring is proportional to the distance the spring is stretched or compressed from its relaxed position. è F X = -k xWhere x is the displacement from the relaxed position and k is the constant of proportionality. What is force of spring when it is stretched as shown below. A) F > 0 B) F = 0 C) F < 0 x F X = - kx < 0 x > 0 relaxed position x=0

7 Physics 101: Lecture 19, Pg 7 Springs l Hooke’s Law: l Hooke’s Law: The force exerted by a spring is proportional to the distance the spring is stretched or compressed from its relaxed position. è F X = – k x Where x is the displacement from the relaxed position and k is the constant of proportionality. relaxed position F X = –kx > 0 x x  0 x=0 18

8 Physics 101: Lecture 19, Pg 8 Potential Energy in Spring l Hooke’s Law force is Conservative è F = -k x è W = -1/2 k x 2 è Work done only depends on initial and final position è Define Potential Energy U spring = ½ k x 2 Force x work

9 Physics 101: Lecture 19, Pg 9 Young’s Modulus l SpringF = -k x [demo] è What happens to “k” if cut spring in half? è A) decreases B) sameC) increases l k is inversely proportional to length! l Define  Strain =  L / L è Stress = F/A l Now è Stress = Y Strain  F/A = Y  L/L è k = Y A/L from F = k x l Y (Young’s Modules) independent of L

10 Physics 101: Lecture 19, Pg 10 Simple Harmonic Motion l Vibrations è Vocal cords when singing/speaking è String/rubber band l Simple Harmonic Motion è Restoring force proportional to displacement è Springs F = -kx

11 Physics 101: Lecture 19, Pg 11 Spring ACT II A mass on a spring oscillates back & forth with simple harmonic motion of amplitude A. A plot of displacement (x) versus time (t) is shown below. At what points during its oscillation is the magnitude of the acceleration of the block biggest? 1. When x = +A or -A (i.e. maximum displacement) 2. When x = 0 (i.e. zero displacement) 3. The acceleration of the mass is constant +A t -A x CORRECT F=ma

12 Physics 101: Lecture 19, Pg 12 X=0 X=A X=-A X=A; v=0; a=-a max X=0; v=-v max ; a=0X=-A; v=0; a=a max X=0; v=v max ; a=0 X=A; v=0; a=-a max Springs and Simple Harmonic Motion

13 Physics 101: Lecture 19, Pg 13 ***Energy *** l A mass is attached to a spring and set to motion. The maximum displacement is x=A   W nc =  K +  U  0 =  K +  U or Energy U+K is constant! Energy = ½ k x 2 + ½ m v 2 è At maximum displacement x=A, v = 0 Energy = ½ k A 2 + 0 è At zero displacement x = 0 Energy = 0 + ½ mv m 2 Since Total Energy is same ½ k A 2 = ½ m v m 2 v m = sqrt(k/m) A m x x=0 0 x PE S

14 Physics 101: Lecture 19, Pg 14 Preflight 1+2 A mass on a spring oscillates back & forth with simple harmonic motion of amplitude A. A plot of displacement (x) versus time (t) is shown below. At what points during its oscillation is the speed of the block biggest? 1. When x = +A or -A (i.e. maximum displacement) 2. When x = 0 (i.e. zero displacement) 3. The speed of the mass is constant +A t -A x CORRECT “At x=0 all spring potential energy is converted into kinetic energy and so the velocity will be greatest at this point.” Its 5:34 in the morning. Answer JUSTIFIED.

15 Physics 101: Lecture 19, Pg 15 Preflight 3+4 A mass on a spring oscillates back & forth with simple harmonic motion of amplitude A. A plot of displacement (x) versus time (t) is shown below. At what points during its oscillation is the total energy (K+U) of the mass and spring a maximum? (Ignore gravity). 1. When x = +A or -A (i.e. maximum displacement) 2. When x = 0 (i.e. zero displacement) 3. The energy of the system is constant. +A t -A x CORRECT The energy changes from spring to kinetic but is not lost.

16 Physics 101: Lecture 19, Pg 16 What does moving in a circle have to do with moving back & forth in a straight line ?? y x -R R 0  1 1 22 33 4 4 55 66 R  8 7 8 7 x x = R cos  = R cos (  t ) since  =  t

17 Physics 101: Lecture 19, Pg 17 SHM and Circles

18 Physics 101: Lecture 19, Pg 18 Simple Harmonic Motion: x(t) = [A]cos(  t) v(t) = -[A  ]sin(  t) a(t) = -[A  2 ]cos(  t) x(t) = [A]sin(  t) v(t) = [A  ]cos(  t) a(t) = -[A  2 ]sin(  t) x max = A v max = A  a max = A  2 Period = T (seconds per cycle) Frequency = f = 1/T (cycles per second) Angular frequency =  = 2  f = 2  /T For spring:  2 = k/m OR

19 Physics 101: Lecture 19, Pg 19Example A 3 kg mass is attached to a spring (k=24 N/m). It is stretched 5 cm. At time t=0 it is released and oscillates. Which equation describes the position as a function of time x(t) = A) 5 sin(  t)B) 5 cos(  t)C) 24 sin(  t) D) 24 cos(  t)E) -24 cos(  t) We are told at t=0, x = +5 cm. x(t) = 5 cos(  t) only one that works.

20 Physics 101: Lecture 19, Pg 20Example A 3 kg mass is attached to a spring (k=24 N/m). It is stretched 5 cm. At time t=0 it is released and oscillates. What is the total energy of the block spring system? A) 0.03 JB).05 JC).08 J E = U + K At t=0, x = 5 cm and v=0: E = ½ k x 2 + 0 = ½ (24 N/m) (5 cm) 2 = 0.03 J

21 Physics 101: Lecture 19, Pg 21Example A 3 kg mass is attached to a spring (k=24 N/m). It is stretched 5 cm. At time t=0 it is released and oscillates. What is the maximum speed of the block? A).45 m/s B).23 m/sC).14 m/s E = U + K When x = 0, maximum speed: E = ½ m v 2 + 0.03 = ½ 3 kg v 2 v =.14 m/s

22 Physics 101: Lecture 19, Pg 22Example A 3 kg mass is attached to a spring (k=24 N/m). It is stretched 5 cm. At time t=0 it is released and oscillates. How long does it take for the block to return to x=+5cm? A) 1.4 sB) 2.2 sC) 3.5 s  = sqrt(k/m) = sqrt(24/3) = 2.83 radians/sec Returns to original position after 2  radians T = 2  /  = 6.28 / 2.83 = 2.2 seconds

23 Physics 101: Lecture 19, Pg 23Summary l Springs è F = -kx è U = ½ k x 2   = sqrt(k/m) l Simple Harmonic Motion è Occurs when have linear restoring force F= -kx  x(t) = [A] cos(  t) or [A] sin(  t)  v(t) = -[A  ] sin(  t) or [A  ] cos(  t)  a(t) = -[A   ] cos(  t) or -[A   ] sin(  t) 50

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