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Physics 218: Mechanics. Instructor: Dr. Tatiana Erukhimova Lecture 42. Please turn in your optional homework. If the block is pulled a distance x 1 to the right and released from rest, how long will it take the block to return to its equilibrium position? - PowerPoint PPT Presentation
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Physics 218: Mechanics Instructor: Dr. Tatiana Erukhimova
Lecture 42
Please turn in your optional homework
If the block is pulled a distance x1 to the right and released from rest, how long will it take the block to return to its equilibrium position?
How does this time change if the displacement is increased from x1 to 2x1?
How fast will the block be moving at its equilibrium position for the x1 displacement?
A bullet of mass m is fired with velocity of magnitude into a block of mass M. The block is connected to a spring constant k and rests on a frictionless surface. Find the velocity of the block as a function of time. (Assume the bullet comes to rest infinitely quickly in the block, i.e. during the collision the spring doesn’t get compressed.)
mV
mV
Simple pendulum
How long does it take to return to the equilibrium?
Resonance
)cos()(
cos
2
2222
0
02
2
t
mb
mk
mF
tx
tFkxdt
dxb
dt
xdm
D
DD
D
tF Dcos0
amplitude
D
Frames of reference
An airplane flies from Houston to Tokyo in 14 hours, while the return trip takes only 10 hours. Find the wind velocity and plane speed with respect to air, if the distance is 7000 miles.
T HW
€
Va - airplane speed with respect to air.
In the freely-falling elevator cabin you don’t feel any effects of gravity! You and all objects around you experience the same acceleration.
In outer space you can imitate the effect of gravity by acceleration.
Final exam: room 204 MPHY, 10:30 am - 12:30 pm,
Wednesday, December 11.
Help Sessions: By appointmentMonday, December 2, 7:15 pm 204 MPHYTuesday, December 3, 7:00 pm 204 MPHYWednesday, December 4, 7:00 pm 204 MPHY
Newton’s First Law
Second Law
Third Law
F
F1N
gm1
1N
1N
gm2
1N
2N
Kinematics
dt
dVa
dt
dVa
dt
Vda y
yx
x ;;
dt
dyV
dt
dxV
dt
rdV yx ;;
dtVydtVx
dtaVdtaV
yx
yyxx
;
;;
is given, you can find If V
and a
r
Work Energy Theorem
22
222
1
initialfinalr
r
total
mVmVrdFW
22
222
1
2
1
initialfinaly
y
totaly
x
x
totalx
mVmVdyFdxFW
veconservatinonveconservati WWW
veconservatiW does NOT depend on path!
)]()([ 12 rUrUW veconservati
y
UF
x
UF yx
;
22)]()([
21
22
12
mVmVWrUrU
WWW
veconservatinon
veconservatinonveconservati
2)(
2)(
21
1
22
2
mVrU
mVrUW veconservatinon
2)(
2)(
21
1
22
2
mVrU
mVrUW veconservatinon
2)(
2)(
,02
11
22
2
mVrU
mVrU
WIf veconservatinon
Mechanical energy is conserved!
Conservation of Momentum
extFdt
pd
)()(
)()(
,0,0
afterpbeforep
afterpbeforep
ConstpConstp
Constpdt
pdFIf
yy
xx
yx
ext
If the collision is perfectly elastic, the kinetic energy is conserved!
Circular Motion
rdt
drar
dt
rda
maFmaF
r
rr
2;
;
22
2
y
x
r
ri
i
rirr
r
dt
drV
dt
drVr ;
Conservation of Angular Momentum
Fr
rhrmriridt
drmrprL
dt
Ldrext
tot
);(][; 2
ConstLIf totext
,0
For symmetrical objects rotating about their axis of symmetry:
2);( ii
irmIrhrIL
22
2
1
2
1 IVmKE ii
i
)(rhrIdt
Ld totext
Second Law: m1
m2
R I
Harmonic Motion
m
k
tBtAtx
kxdt
xdm
sincos)(
02
2
Resonance:
)cos()(
cos
2
2222
0
02
2
t
mb
mk
mF
tx
tFkxdt
dxb
dt
xdm
D
DD
D
Thank you for the great semester!
