Deck 16: Waves I

A)The shape of the string at time t = 0 is given by f(x).
B)The shape of the waveform does not change as it moves along the string.
C)The waveform moves in the positive x direction.
D)The speed of the waveform is a.
E)The speed of the waveform is x/t.

A)0.10 rad/m
B)3 $\pi$ rad/m
C)10 rad/m
D)10 $\pi$ rad/m
E)3.0 rad/m

A)A
B)B
C)C
D)D
E)E

A)wavelength/2
B)wavelength
C)2 * amplitude
D)period/2
E)period

A)A
B)B
C)C
D)D
E)E

A)A
B)B
C)C
D)D
E)E

A)"2 $\pi$ k/ $\omega$ "
B)"k/ $\omega$ "
C)" $\omega$ k"
D)"2 $\pi$ /k"
E)"k/2 $\pi$ "

A)0.6 s
B)1.0 s
C)3.0 s
D)6.7 s
E)10 s

A)"2 $\pi$ k/ $\omega$ "
B)" $\omega$ /k"
C)" $\omega$ k"
D)"2 $\pi$ /k"
E)"k/2 $\pi$ "

A)Mechanical waves are transverse waves while electromagnetic waves are longitudinal.
B)Plane waves are transverse waves while spherical waves are longitudinal.
C)Only longitudinal waves transmit matter.
D)Only transverse waves transmit energy.
E)In transverse waves the displacement is perpendicular to the direction of propagation of the wave, while in longitudinal waves the displacement is parallel to the direction of propagation.

A)"v₀/ $\omega$ y₀"
B)" $\omega$ y₀/v₀"
C)" $\omega$ v₀/y₀"
D)"y₀/ $\omega$ v₀"
E)" $\omega$ v₀y₀"

A)The displacement of wave y₁ is always greater than the displacement of wave y₂.
B)Wave y₁ has a smaller amplitude than wave y₂.
C)Wave y₁ has a higher frequency than wave y₂.
D)Wave y₁ has a shorter wavelength than wave y₂.
E)The two waves are identical except for their displacement at time t = 0.

A)0.10 rad/s
B)3.0 rad/s
C)10 $\pi$ rad/s
D)20 $\pi$ rad/s
E)10 rad/s

A)45 $\degree$
B)90 $\degree$
C)135 $\degree$
D)180 $\degree$
E)270 $\degree$

A)0 $\degree$
B)90 $\degree$
C)135 $\degree$
D)180 $\degree$
E)270 $\degree$

A)transverse, longitudinal, linear
B)plane, spherical, transverse
C)mechanical, electromagnetic, matter
D)transverse, linear, water
E)plane, longitudinal, mechanical

A)A
B)B
C)C
D)D
E)E

A)A
B)B
C)C
D)D
E)E

A)0.16 s
B)0.47 s
C)2.5 s
D)7.5 s
E)10 s

A)f = 1/T
B)f = v + T
C)f = vT
D)f = v/T
E)f = T/v

A)1/T
B)2 $\pi$ /T
C)vT
D)f/T
E)T/f

A)independent of wavelength
B)proportional to wavelength
C)inversely proportional to wavelength
D)proportional to the amplitude
E)inversely proportional to the amplitude

A)7.7 x 10^-3 kg/m
B)0.13 kg/m
C)7.7 kg/m
D)46 kg/m
E)130 kg/m

A)the frequency decreases by a factor of 4
B)the frequency decreases by a factor of 2
C)the wavelength decreases by a factor of 4
D)the wavelength decreases by a factor of 2
E)the wavelength increases by a factor of 2

A)the linear mass density of the cord
B)the length between A and B
C)the shape of the pulse
D)the tension in the cord
E)none of the above (changes in all alter the time)

A)moves in the same direction as the wave
B)moves in simple harmonic motion with a different frequency than that of the wave
C)moves in simple harmonic motion with the same angular frequency as the wave
D)moves in uniform circular motion with a different angular speed than the wave
E)moves in uniform circular motion with the same angular speed as the wave

A)y(x,t)= (2 cm)sin (2x - 4t)
B)y(x,t)= (2 cm)sin (4x - 10t)
C)y(x,t)= (2 cm)sin (6x - 12t)
D)y(x,t)= (2 cm)sin (8x - 16t)
E)y(x,t)= (2 cm)sin (10x - 20t)

A)"2 $\lambda$ , v"
B)" $\lambda$ /2, v"
C)" $\lambda$ , 2v"
D)" $\lambda$ , v/2"
E)" $\lambda$ /2, 2v"

A)the frequency of the wave
B)the wavelength of the wave
C)the length of the string
D)the tension in the string
E)the amplitude of the wave

A)0 m/s²
B)200 m/s²
C)390 m/s²
D)790 m/s²
E)1600 m/s²

A)the magnitude of its acceleration is a maximum
B)the magnitude of its displacement is a maximum
C)the magnitude of its displacement is a minimum
D)the magnitude of its displacement is half the amplitude
E)the magnitude of its displacement is one fourth the amplitude

A)100 s
B)4.0 s
C)2.0 s
D)0.5 s
E)0.25 s

A)0.00023 m/s
B)2.1 m/s
C)21 m/s
D)4300 m/s
E)none of these

A)2.0 m/s
B)4.0 m/s
C)6.3 m/s
D)13 m/s
E)unknown (not enough information is given)

A)v_s/2
B)2v_s
C)v_s/4
D)3v_s/4
E)v_s/2

A)1, 2, 3
B)1, 3, 2
C)2, 1, 3
D)2, 3, 1
E)3, 1, 2

A)0.20 m/s
B)1.3 m/s
C)4.0 m/s
D)15 m/s
E)25 m/s

A)0
B)π/6
C)π/4
D)π/2
E)3π/2

A)wave 1 has the greatest wave speed and the greatest maximum transverse string speed
B)wave 2 has the greatest wave speed and wave 1 has the greatest maximum transverse string speed
C)wave 3 has the greatest wave speed and the greatest maximum transverse string speed
D)wave 2 has the greatest wave speed and wave 3 has the greatest maximum transverse string speed
E)wave 3 has the greatest wave speed and wave 2 has the greatest maximum transverse string speed

A)0.20 cm
B)2.0 cm
C)5.0 cm
D)20 cm
E)400 cm

A)"the distance S₁S₂"
B)"the angle S₁PS₂
C)" $\pi$ /2"
D)"the phase difference between the two sources"
E)"zero for transverse waves, $\pi$ for longitudinal waves"

A)1
B)2
C)3
D)1 and 3 tie
E)2 and 3 tie

A)"y_1m + y_2m and occurs when they are 180 $\degree$ out of phase"
B)" $\vert$ y_1m - y_2m $\vert$ and occurs when they are 180 $\degree$ out of phase"
C)"y_1m + y_2m and occurs when they are in phase"
D)" $\vert$ y_1m - y_2m $\vert$ and occurs when they are in phase"
E)" $\vert$ y_1m - y_2m $\vert$ and occurs when they are 90 $\degree$ out of phase"

A)half
B)twice
C)one-fourth
D)four times
E)eight times

A)cannot solve without knowing the wavelength
B)5.1 mm, 0.51 rad
C)5.1 mm, 0.79 rad
D)6.5 mm, 1.3 rad
E)7.0 mm, 1.3 rad

A)an odd multiple of $\lambda$ /2
B)an odd multiple of $\lambda$ /4
C)a multiple of $\lambda$
D)an odd multiple of $\pi$ /2
E)a multiple of $\pi$

A)half
B)twice
C)one-fourth
D)four times
E)eight times

A)y₁(x,t)= (y_m/3)sin (kx + $\omega$ t)and y₂(x,t)= (y_m/3)sin (kx + $\omega$ t + $\phi$ )
B)y₁(x,t)= 0.7y_m sin (kx - $\omega$ t)and y₂(x,t)= 0.7y_m sin (kx - $\omega$ t + $\phi$ )
C)y₁(x,t)= 0.7y_m sin (kx - $\omega$ t)and y₂(x,t)= 0.7y_m sin (kx + $\omega$ t + $\phi$ )
D)y₁(x,t)= 0.7y_m sin [(kx/2)- ( $\omega$ t/2)] and y₂(x,t)= 0.7y_m sin [(kx/2)- ( $\omega$ t/2)+ $\phi$ ]
E)y₁(x,t)= 0.7y_m sin (kx + $\omega$ t)and y₂(x,t)= 0.7y_m sin (kx + $\omega$ t + $\phi$ )

A)0.065 m/s
B)0.25 m/s
C)2.0 m/s
D)3.9 m/s
E)15 m/s

A)an odd multiple of $\lambda$ /2
B)an odd multiple of $\lambda$ /4
C)a multiple of $\lambda$
D)an odd multiple of $\pi$ /2
E)a multiple of $\pi$

A)1, 2, 3
B)3, 2, 1
C)2, 3, 1
D)3, 1, 2
E)they all take the same time

A)200 Hz and 20 cm
B)141 Hz and 10 cm
C)100 Hz and 20 cm
D)100 Hz and 14 cm
E)50 Hz and 14 cm

A)travel in the same direction and are 270 $\degree$ out of phase
B)travel in the same direction and are 45 $\degree$ out of phase
C)travel in the same direction and are in phase
D)travel in the same direction and are 180 $\degree$ out of phase
E)travel in the same direction and are 90 $\degree$ out of phase

A)0.64 y_m
B)1.3 y_m
C)0.91 y_m
D)1.8 y_m
E)0.35 y_m

A)the frequency decreases by a factor of 4
B)the frequency decreases by a factor of 2
C)the wave speed decreases by a factor of 4
D)the wave speed decreases by a factor of 2
E)the wave speed increases by a factor of 2

A)has its greatest acceleration
B)has its greatest displacement
C)has half its greatest displacement
D)has one fourth its greatest displacement
E)has its least displacement

A)travel in the same direction and are 270 $\degree$ out of phase
B)travel in the same direction and are 45 $\degree$ out of phase
C)travel in the same direction and are in phase
D)travel in the same direction and are 180 $\degree$ out of phase
E)travel in the same direction and are 90 $\degree$ out of phase

A)has its least acceleration
B)has its greatest displacement
C)has half its greatest displacement
D)has one fourth its greatest displacement
E)has its least displacement

A)their amplitudes are the same and they travel in the same direction
B)their amplitudes are the same and they travel in opposite directions
C)their frequencies are the same and they travel in the same direction
D)their frequencies are the same and they travel in opposite directions
E)their frequencies are the same and their amplitudes are the same

A)50, 100, 150, and 200 Hz
B)50, 150, 250, and 300 Hz
C)100, 200, 300, and 400 Hz
D)25, 50 75, and 100 Hz
E)75, 150, 225, and 300 Hz

A)y_msin(kx + $\omega$ t)
B)-y_msin(kx + $\omega$ t)
C)y_msin(kx + $\omega$ t - kL)
D)y_msin(kx + $\omega$ t - 2kL)
E)-y_msin(kx + $\omega$ t + 2kL)

A)400 cm
B)200 cm
C)100 cm
D)67 cm
E)50 cm

A)10 cm
B)30 cm
C)40 cm
D)60 cm
E)120 cm

A)" $\lambda$ /4"
B)" $\lambda$ /2"
C)"3 $\lambda$ /4"
D)" $\lambda$ "
E)"2 $\lambda$ "

A)3
B)4
C)5
D)7
E)8

A)L
B)2L
C)L/2
D)2L/3
E)4L

A)25 Hz
B)50 Hz
C)75 Hz
D)125 Hz
E)225 Hz

A)33 cm
B)67 cm
C)150 cm
D)300 cm
E)need to know the frequency

A)0.25 m
B)0.5 m
C)1 m
D)2 m
E)4 m

A)is in phase with the original wave at the end
B)is 180 $\degree$ out of phase with the original wave at the end
C)has a larger amplitude than the original wave
D)has a larger speed than the original wave
E)cannot be transverse

A)0 rad
B)" $\pi$ rad"
C)" $\pi$ /2 rad"
D)"depends on the velocity of the wave"
E)"depends on the frequency of the wave"

A)50 cm
B)40 cm
C)30 cm
D)20 cm
E)15 cm

A)more
B)less
C)the same (zero)
D)the same (non-zero)
E)sometimes more, sometimes less, and sometimes the same

A)can be constructed from two similar waves traveling in opposite directions
B)must be transverse
C)must be longitudinal
D)has motionless points that are closer than half a wavelength
E)has a wave velocity that differs by a factor of two from what it would be for a traveling wave

A)y = (6.0 mm)sin[(3.0 m^-1)x + (2.0 s^-1)t] - (6.0 mm)cos[(3.0 m^-1)x + 2.0]
B)y = (6.0 mm)cos[(3.0 m^-1)x - (2.0 s^-1)t] + (6.0 mm)cos[(2.0 s^-1)t + (3.0 m^-1)x]
C)y = (6.0 mm)cos[(3.0 m^-1)x - (2.0 s^-1)t] - (6.0 mm)sin[(2.0 s^-1)t - 3.0]
D)y = (6.0 mm)sin[(3.0 m^-1)x - (2.0 s^-1)t] - (6.0 mm)cos[(2.0 s^-1)t + (3.0 m^-1)x]
E)y = (6.0 mm)sin[(3.0 m^-1)x] + (6.0 mm)cos[(2.0 s^-1)t]

A)y = (6.0 mm)sin[(3.0 m^-1)x + (2.0 s^-1)t]
B)y = (6.0 mm)cos[(3.0 m^-1)x - (2.0 s^-1)t]
C)y = (6.0 mm)cos[(3.0 m^-1)x + (2.0 s^-1)t]
D)y = (6.0 mm)sin[(3.0 m^-1)x
E)y = (6.0 mm)cos[(2.0 s^-1)t

A)32 Hz
B)16 Hz
C)8 Hz
D)4 Hz
E)2 Hz

A)10 cm
B)20 cm
C)40 cm
D)80 cm
E)160 cm

A)"vt/ $\pi$ "
B)"vt/2 $\pi$ "
C)" $\pi$ /2k"
D)" $\pi$ /k"
E)"2 $\pi$ /k"