1Revise, Reflect, Refine15 questions
Q.1Which observation best supports the idea that sound is a mechanical wave? (i) Sound shows reflection (ii) Sound needs a medium to propagate (iii) Sound has frequency (iv) Sound carries energyv
Answer:(ii) Sound needs a medium to propagate.
Q.2For a sound wave propagating in a medium, increasing its frequency will increase its (i) wavelength (ii) speed (iii) number of compressions per second (iv) time periodv
Answer:(iii) number of compressions per second.
Q.3If 20 compressions pass a point in 4 seconds, the frequency is (i) 80 Hz (ii) 5 Hz (iii) 10 Hz (iv) 0.2 Hzv
Q.4In a room, the reflected sound reaches the ear 0.05 s after its production. Will it produce an echo or reverberation? Justify your answer.v
Answer:It will be reverberation, not a distinct echo, because a separate echo requires about 0.1 s or more between original and reflected sound; 0.05 s is too short.
Q.5Graphs representing two sound waves are given in Fig. 10.30. If the scales on the X and Y axes of the two graphs are the same, which of the two sound waves has (i) greater wavelength, and (ii) smaller amplitude? Density Density Distance Distance (a) (b) Fig. 10.30v
Answer:From Fig. 10.30/answer key, graph (a) has the greater wavelength and graph (a) has the smaller amplitude. The graph should be visually checked after rendering.
Q.6The sound waves emitted by three sources A, B and C are represented in Fig. 10.31. If the frequency of A is maximum and C is minimum, identify the corresponding curves, and mark A, B and C on them. Density Distance Fig. 10.31v
Answer:A is the curve with the highest frequency (shortest wavelength), C is the curve with the lowest frequency (longest wavelength), and B is the remaining curve. The answer key maps them as A—green, B—red, C—blue.
Q.7Draw a graph to represent a sound wave for which the density amplitude is 3 units and wavelength is 4 cm.v
Answer:Draw a sinusoidal density-distance graph with amplitude 3 units above and below the mean density line and wavelength 4 cm between successive compressions or rarefactions.
Q.8In a movie, while showing the explosion of a spacecraft in space, a flash of light is shown along with sound at the same time. What are the errors in this depiction?v
Answer:Sound cannot travel through the vacuum of space, so the explosion should not be heard by a distant observer. Also, in a medium, light would be seen before sound because light travels much faster.
Q.9A source produces a sound wave of wavelength 3.44 m. If the wave travels with a speed of 344 m s–1 find its time period.v
Q.10A ship searching for a sunken ship sent a sonar signal and detected an echo after 5 s. If ultrasonic wave travels at 1525 m s–1 in seawater, approximately how far down in the ocean is the wreckage of the sunken ship located?v
Q.11A vehicle is fitted with an ultrasonic distance sensor as part of parking assistance system which provides echolocation, while the driver is reversing the vehicle. It emits ultrasonic wave (about 40 kHz) which is reflected by the obstacle. When the warning beep starts sounding at a distance of 1.2 m from the obstacle, how much time is taken by ultrasonic wave to travel to the obstacle and come back? Assume the speed of ultrasonic wave in air to be 345 m s–v
Q.12m s–1 at 0 ºC and nearly 344 m s–1 at 22 ºC. Roughly how much extra time will the sound of thunder take to travel a distance of 1720 m, if the air temperature changes from 22 ºC to 0 ºC? Assume that all other conditions remain unchanged.v
Answer:About 0.20 s extra.
Q.13The variation of density of medium for a sound wave propagating with a speed of 340 m s–1 is shown in Fig. 10.32. Calculate the wavelength and frequency of the sound wave. 8 cm Fig. 10.32v
Answer:Wavelength = 0.04 m; frequency = 8500 Hz.
Q.14The graphical representation of two sound waves A and B propagating at the same speed of 345 m s–1 is shown in Fig. 10.33. What is the wavelength of each of them? Also, calculate their frequencies. A 2.5 5.0 Distance (cm) Fig. 10.33v
Answer:Wavelengths: 0.025 m and 0.05 m; frequencies: 13,800 Hz and 6900 Hz.
Q.15Two identical sound sources are placed at A and B — one in air and one submerged in water (Fig. 10.34). Both produce sounds at the same time, which travel horizontally to the vertical side of the cliff and come back. .5 times than that of B, what is the ratio between the speeds of sound in air and water? A B Fig. 10.34v