SPRING-MASS OSCILLATORS AP Physics Unit 8. Recall Hooke’s Law Applied force (F applied ) stretches...
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Transcript of SPRING-MASS OSCILLATORS AP Physics Unit 8. Recall Hooke’s Law Applied force (F applied ) stretches...
![Page 1: SPRING-MASS OSCILLATORS AP Physics Unit 8. Recall Hooke’s Law Applied force (F applied ) stretches or compresses spring from its natural length Restoring.](https://reader035.fdocuments.us/reader035/viewer/2022080917/56649ec65503460f94bd2732/html5/thumbnails/1.jpg)
SPRING-MASS OSCILLATORS
AP Physics
Unit 8
![Page 2: SPRING-MASS OSCILLATORS AP Physics Unit 8. Recall Hooke’s Law Applied force (F applied ) stretches or compresses spring from its natural length Restoring.](https://reader035.fdocuments.us/reader035/viewer/2022080917/56649ec65503460f94bd2732/html5/thumbnails/2.jpg)
Recall Hooke’s Law
• Applied force (Fapplied) stretches or compresses spring from its natural length
• Restoring force (Fr) acts to return spring to lowest energy state
kxF
FF
r
appliedr
![Page 3: SPRING-MASS OSCILLATORS AP Physics Unit 8. Recall Hooke’s Law Applied force (F applied ) stretches or compresses spring from its natural length Restoring.](https://reader035.fdocuments.us/reader035/viewer/2022080917/56649ec65503460f94bd2732/html5/thumbnails/3.jpg)
An energy approach to SHM
• Stretched/compressed spring stores elastic potential energy: Us = ½kx2
• When released, mass oscillates about its equilibrium position as PE KE etc– Amplitude of oscillation is xmax
– At x=0, Us = 0 so K is maximized
– At x=A, Us is maximized, so K=0
Us, max = ½kA2
![Page 4: SPRING-MASS OSCILLATORS AP Physics Unit 8. Recall Hooke’s Law Applied force (F applied ) stretches or compresses spring from its natural length Restoring.](https://reader035.fdocuments.us/reader035/viewer/2022080917/56649ec65503460f94bd2732/html5/thumbnails/4.jpg)
Example #1
• A 2.0 kg block is attached to an ideal spring with a force constant of 500 N/m. The spring is stretched 8.0 cm and released.
• When the block is 4.0 cm from equilibrium– what is the total
energy of the system?– what is the velocity of
the block?
JE
kAE
KUE
o
o
ooo
6.1
)08.0)(500(2102
1 22
By energy conservation, E=1.6J at every spring position
smv
Jv
Emvkx
/1.1
6.1)0.2(21)04.0(5002
121
21
22
22
![Page 5: SPRING-MASS OSCILLATORS AP Physics Unit 8. Recall Hooke’s Law Applied force (F applied ) stretches or compresses spring from its natural length Restoring.](https://reader035.fdocuments.us/reader035/viewer/2022080917/56649ec65503460f94bd2732/html5/thumbnails/5.jpg)
An energy approach to SHM
Since energy is conserved and– at x=A, Us is maximized and K=0
– at x=0, Us = 0 so K is maximized
it follows that2max
2
21
21 mvkA
thereforem
kAv max
![Page 6: SPRING-MASS OSCILLATORS AP Physics Unit 8. Recall Hooke’s Law Applied force (F applied ) stretches or compresses spring from its natural length Restoring.](https://reader035.fdocuments.us/reader035/viewer/2022080917/56649ec65503460f94bd2732/html5/thumbnails/6.jpg)
SHM and the Reference Circle
• Motion of the shadow cast by a particle moving in a vertical circle mimics SHM– Amplitude corresponds to the radius of the circle– Period of the oscillation corresponds to the period
of the UCM
T
A
T
Rv
22 or
v
AT
2
sincem
kAv max
km
vk
mvT
2
2
![Page 7: SPRING-MASS OSCILLATORS AP Physics Unit 8. Recall Hooke’s Law Applied force (F applied ) stretches or compresses spring from its natural length Restoring.](https://reader035.fdocuments.us/reader035/viewer/2022080917/56649ec65503460f94bd2732/html5/thumbnails/7.jpg)
Example #2
A 2.0kg block is attached to a spring with a force constant of 300 N/m.
Determine the period and frequency of the oscillations.
kmT 2
sT 51.03000.22
HzT
f 9.11
![Page 8: SPRING-MASS OSCILLATORS AP Physics Unit 8. Recall Hooke’s Law Applied force (F applied ) stretches or compresses spring from its natural length Restoring.](https://reader035.fdocuments.us/reader035/viewer/2022080917/56649ec65503460f94bd2732/html5/thumbnails/8.jpg)
Vertical Spring-Mass Oscillators
• As it turns out, the behavior is the same regardless of the orientation, i.e. gravity does not affect the period or frequency of the oscillations.
• Sounds improbable? Let’s see why it is not…
![Page 9: SPRING-MASS OSCILLATORS AP Physics Unit 8. Recall Hooke’s Law Applied force (F applied ) stretches or compresses spring from its natural length Restoring.](https://reader035.fdocuments.us/reader035/viewer/2022080917/56649ec65503460f94bd2732/html5/thumbnails/9.jpg)
Vertical SMOs
• Consider a spring with constant k on which a mass m is hung, stretching the spring some distance x
• The spring is in equilibrium:
Fapplied= Fr or kx=mg
• If the spring is further displaced by some amount A, the restoring force increases to
k(x+A) while the weight remains mg
![Page 10: SPRING-MASS OSCILLATORS AP Physics Unit 8. Recall Hooke’s Law Applied force (F applied ) stretches or compresses spring from its natural length Restoring.](https://reader035.fdocuments.us/reader035/viewer/2022080917/56649ec65503460f94bd2732/html5/thumbnails/10.jpg)
Vertical SMOs
The net force on the block is nowF= k(x+A)- mg
But since kx=mg, the force on the block is F= kA. This is Hooke’s Law!
Instead of oscillating about the natural length of the spring as happens with a horizontal SMO, oscillations of a vertical SMO are about the point at which the hanging mass is in equilibrium!
![Page 11: SPRING-MASS OSCILLATORS AP Physics Unit 8. Recall Hooke’s Law Applied force (F applied ) stretches or compresses spring from its natural length Restoring.](https://reader035.fdocuments.us/reader035/viewer/2022080917/56649ec65503460f94bd2732/html5/thumbnails/11.jpg)
Example #3
• A 1.5 kg block is attached to the end of a vertical spring with a constant of 300 N/m. After the block comes to rest, it is stretched an additional 2.0 cm and released.– What is the frequency of
the oscillation?– What are the maximum &
minimum amounts of stretch in the spring?
Hzf
mkf
3.25.1300
2
12
1
cmmx
x
mgkx
9.4049.0
)8.9)(5.1(300
Since A=2.0 cm, the spring is stretched a maximum of 6.9 cm and a minimum of 2.9 cm