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Chapter 15 Oscillatory Motion 15.1 Motion of an Object Attached to a Spring 15.2 Analysis Model: Particle in Simple Harmonic Motion 15.5 The Pendulum
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Oscillations and Mechanical Waves � Periodic motion is the repeating motion of an object in which it continues to return to a given position after a fixed time interval. � The repetitive movements are called oscillations. � A special case of periodic motion called simple harmonic motion will be the focus.
� Simple harmonic motion also forms the basis for understanding mechanical waves.
� Oscillations and waves also explain many other phenomena quantity.
� Oscillations of bridges and skyscrapers � Radio and television � Understanding atomic theory
Section Introduction Abeer Alghamdi
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Periodic Motion l Periodic motion is motion of an object that regularly returns to a given position after a fixed time interval. l A special kind of periodic motion occurs in mechanical systems when the force acting on the object is proportional to the position of the object relative to some equilibrium position.
l If the force is always directed toward the equilibrium position, the motion is called simple harmonic motion.
Introduction Abeer Alghamdi
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Motion of a Spring-Mass System � A block of mass m is attached to a spring, the block is free to move on a frictionless horizontal surface. � When the spring is neither stretched nor compressed, the block is at the equilibrium position.
� x = 0
� Such a system will oscillate back and forth if disturbed from its equilibrium position.
Section 15.1 Abeer Alghamdi
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Hooke’s Law
l Hooke’s Law states Fs = - kx l Fs is the restoring force.
l It is always directed toward the equilibrium position. l Therefore, it is always opposite the displacement from
equilibrium. l k is the force (spring) constant. l x is the displacement.
Section 15.1 Abeer Alghamdi
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Restoring Force and the Spring Mass System
l In a, the block is displaced to the right of x = 0.
l The position is positive; The restoring force is directed to the left.
l In b, the block is at the equilibrium position.
l x = 0; The spring is neither stretched nor compressed; The force is 0.
Section 15.1 Abeer Alghamdi
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Restoring Force, cont. l The block is displaced to the left of x = 0.
l The position is negative. l The restoring force is directed to the right.
Section 15.1 Abeer Alghamdi
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Acceleration l When the block is displaced from the equilibrium point and released, it is a particle under a net force and therefore has an acceleration. l The force described by Hooke’s Law is the net force in Newton’s Second Law.
l The acceleration is proportional to the displacement of the block. l The direction of the acceleration is opposite the direction of the displacement from equilibrium. l An object moves with simple harmonic motion whenever its acceleration is proportional to its position and is oppositely directed to the displacement from equilibrium.
x
x
kx mak
a xm
− =
= −
Section 15.1 Abeer Alghamdi
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Acceleration, cont. l The acceleration is not constant.
l Therefore, the kinematic equations cannot be applied.
l If the block is released from some position x = A, then the initial acceleration is –kA/m.
l When the block passes through the equilibrium position, a = 0.
l The block continues to x = -A where its acceleration is +kA/m.
Section 15.1 Abeer Alghamdi
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Motion of the Block
l The block continues to oscillate between –A and +A.
l These are turning points of the motion. l The force is conservative. l In the absence of friction, the motion will continue forever.
l Real systems are generally subject to friction, so they do not actually oscillate forever.
Section 15.1 Abeer Alghamdi
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Analysis Model: A Particle in Simple Harmonic Motion l Model the block as a particle.
l The representation will be particle in simple harmonic motion model.
l Choose x as the axis along which the oscillation occurs. l Acceleration l We let l Then a = -ω2x
2
2d x k
a xdt m
= = −
2 km
ω =
Section 15.2 Abeer Alghamdi
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A Particle in Simple Harmonic Motion, 2
l A function that satisfies the equation is needed.
l Need a function x(t) whose second derivative is the same as the original function with a negative sign and multiplied by ω2.
l The sine and cosine functions meet these requirements.
Section 15.2 Abeer Alghamdi
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Simple Harmonic Motion – Graphical Representation
l A solution is x(t) = A cos (ω t + φ)
l A, ω, φ are all constants l A cosine curve can be used to give physical significance to these constants.
Section 15.2 Abeer Alghamdi
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Simple Harmonic Motion – Definitions
� A is the amplitude of the motion. � This is the maximum position of the particle in
either the positive or negative x direction. � ω is called the angular frequency.
� Units are rad/s
� φ is the phase constant or the initial phase angle.
Section 15.2
km
ω =
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Simple Harmonic Motion, cont.
l A and φ are determined uniquely by the position and velocity of the particle at t = 0.
l If the particle is at x = A at t = 0, then φ = 0 l The phase of the motion is the quantity (ωt + φ). l x (t) is periodic and its value is the same each time ωt increases by 2π radians.
Section 15.2 Abeer Alghamdi
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Period
l The period, T, of the motion is the time interval required for the particle to go through one full cycle of its motion.
l The values of x and v for the particle at time t equal the values of x and v at t + T.
2T πω
=
Section 15.2 Abeer Alghamdi
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Frequency l The inverse of the period is called the frequency. l The frequency represents the number of oscillations that the particle undergoes per unit time interval.
l Units are cycles per second = hertz (Hz).
1ƒ2Tωπ
= =
Section 15.2 Abeer Alghamdi
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Summary Equations – Period and Frequency l The frequency and period equations can be rewritten to solve for ω. l The period and frequency can also be expressed as: l The frequency and the period depend only on the mass of the particle and the force constant of the spring. l The frequency is larger for a stiffer spring (large values of k) and decreases with increasing mass of the particle.
22 ƒTπ
ω π= =
12 ƒ2
m kTk m
ππ
= =
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Motion Equations for Simple Harmonic Motion
� Simple harmonic motion is one-dimensional and so directions can be denoted by + or - sign. � Remember, simple harmonic motion is not uniformly accelerated motion.
22
2
( ) cos ( )
sin( t )
cos( t )
x t A tdx
v Adtd x
a Adt
ω φ
ω ω φ
ω ω φ
= +
= = − +
= = − +
Section 15.2 Abeer Alghamdi
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Maximum Values of v and a l Because the sine and cosine functions oscillate between ±1, we can easily find the maximum values of velocity and acceleration for an object in SHM.
max
2max
kv A Amka A Am
ω
ω
= =
= =
Section 15.2 Abeer Alghamdi
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Graphs
l The graphs show: l (a) displacement as
a function of time l (b) velocity as a
function of time l (c ) acceleration as
a function of time l The velocity is 90o out of phase with the displacement and the acceleration is 180o out of phase with the displacement.
Section 15.2 Abeer Alghamdi
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SHM Example 1
l Initial conditions at t = 0 are
l x (0)= A l v (0) = 0
l This means φ = 0 l The acceleration reaches extremes of ± ω2A at ±A. l The velocity reaches extremes of ± ωA at x = 0. Section 15.2
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SHM Example 2
l Initial conditions at t = 0 are
l x (0)=0 l v (0) = vi
l This means φ = - π / 2 l The graph is shifted one-quarter cycle to the right compared to the graph of x (0) = A.
Section 15.2 Abeer Alghamdi
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Simple Pendulum
l A simple pendulum also exhibits periodic motion. l It consists of a particle-like bob of mass m suspended by a light string of length L. l The motion occurs in the vertical plane and is driven by gravitational force. l The motion is very close to that of the SHM oscillator.
l If the angle is <10o Section 15.5 Abeer Alghamdi
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Simple Pendulum l The forces acting on the bob are the tension and the weight.
l is the force exerted on the bob by the string.
l is the gravitational force.
l The tangential component of the gravitational force is a restoring force.
T
mg
Section 15.5 Abeer Alghamdi
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Simple Pendulum l In the tangential direction,
l The length, L, of the pendulum is constant, and for small values of θ.
l This confirms the mathematical form of the motion is the same as for SHM.
t td sF ma mg mdt
2
2sinθ= → − =
d 2θdt 2
= −gLsinθ = − g
Lθ
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Simple Pendulum
l The function θ can be written as θ = θmax cos (ωt + φ). l The angular frequency is
l The period is
gL
ω =
2 2 LTg
ππ
ω= =
Section 15.5 Abeer Alghamdi
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Simple Pendulum, Summary l The period and frequency of a simple pendulum depend only on the length of the string and the acceleration due to gravity. l The period is independent of the mass. l All simple pendula that are of equal length and are at the same location oscillate with the same period.
Section 15.5 Abeer Alghamdi
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A swinging rod
l A uniform rod of mass M and length L is pivoted about one end and oscillates in a vertical plane. Find the period of oscillation if the amplitude of the motion is small.
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HomeWork
Abeer Alghamdi
1.
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2.
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3.
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4.
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Abeer Alghamdi
5.
t=3 min=3×60=180 sec a) T=180/120=1.5 sec b) T=2π√L/g L=T2g/(4π2)=(1.5)2 9.8/(4×3.142) =0.559 m
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خاصة حا"ت
نابض لكتلة التوافقية الحركة الوحدة Simple Harmonic Motionالتوافقية الحركة ص الحركة التوافقية
هوك قانون: F=-‐kX (k constant force )
N ا"رجاع قوة (ا@ؤثرة القوة(F
X0=0, V=V0,t=0, ϕ=π/2 فإن
X=Acos(ωt-‐π/2) X=(V0/ω)sinωt
X0=A,V0=0,t=0 ϕ 0=فإن
X=Acosωt
ا@حور باتجاة الحركة مسارY ا@حور باتجاة الحركة مسارX m اLزاحةe سعة
Y=Asin(kx-‐ωt+Φ) X=Acos(ωt+Φ) X0=Acos(Φ) (t=0)
V=-‐V0cosωt
V=-‐ωAsinωt
V=-‐ωAcos(kx-‐ωt+Φ) V0=-‐ωAcos(Φ)
(t=0) Vmax=|ωA|=√ (k/m)
V=-‐ωAsin(ωt+Φ) V0=-‐ωAsin(Φ) (t=0) Vmax=|ωA|=A√ (k/m)
m/s السرعةdx/dt =v
a=-‐ω2v0sinωt a=-‐ω2A a=ω2Acos(kx-‐ωt+Φ) amax=|ω2A|=(k/m)A
a=-‐ω2Acos(ωt+Φ) amax=|ω2A|=(k/m)A
m/s2 التسارعa=dv/dt
Φ=-‐π/2 Φ=0 (kx-‐ωt+Φ) (ωt+Φ) االلططوورر ددررججةة
Φ=tan-‐1(-‐V0/ωX0) درجة phase constant الطور ثابت Φ
A=v0/ω A=X A=√ (X02+(V0/ω)2) m الحركة سعة(ازاحة اقصى(
ω=√ (k/m) Rad/sec
( the angular الزاوي التردد (frequencyω=2πf
f=√ (k/m)/(2π) Hz Or
1/sec
frequencyد f=ω/2π , f=1/T
T=(2π) √ (m/k) sec Periodi الدوري الزمنT=2π/ω, T=1/f
Rad/m ا@وجي العدد K=2π/λ
m ا@وجي الطول λ =V T, λ=V/ f
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40
البندول منظومة في البسيطة ا"هتزازية الحركة الوحدة التوافقية الحركة خصائص مماسة قوة:
F=-‐mgsinθ N ا"رجاع قوة (ا@ؤثرة القوة(
F S=Lθ m اLزاحة سعة
θ=θ0cos(ωt+Φ) ) درجةO( الزاوية السعةΘ) درجةO( القصوى الزاوية السعةθ0
dθ/dt=-θ0ωsin(ωt+Φ) Vmax=|ωA|=A√ (g/L)
rad/s السرعةdθ/dt =v
d2θ/dt2=θ0ω2cos(ωt+Φ)
amax=|ω2A|=Ag/L rad/s2 التسارع
a=d2θ/dt2
ω=√ (g/L) rad/sec الزاوي الترددω=2πf
f=√ (g/L)/(2π) Hz Or
1/sec
الترددf=ω/2π, f=1/T
T=(2π) √ (L/g) sec الدوري الزمنT=2π/ω, T=1/f
Abeer Alghamdi