Please with complete solutions from Given, Unknown, Steps of Solutions and final answer. Please answer all of the problems. Thank you VP15.3.1 A boat is at anchor outside a harbor. A steady sinusoidalocean wave makes the boat bob up and down with a period of 5.10 sand an amplitude of 1.00 m. The wave has wavelength 30.5 m. For thiswave, what are (a) the frequency, (b) the wave speed, (c) the angularfrequency, and (d) the wave number?VP15.3.2 Sound waves in the thin Martian atmosphere travel at245 m/s. (a) What are the period and wavelength of a 125 Hz soundwave in the Martian atmosphere? (b) What are the frequency and an-gular frequency of a sound wave in the Martian atmosphere that haswavelength 3.00 m?VP15.3.3 You are testing a mountain climbing rope that has a linearmass density of 0.0650 kg/m. The rope is held horizontal and is undera tension of 8.00 × 10² N to simulate the stress of supporting a moun-tain climber's weight. (a) What is the speed of transverse waves on thisrope? (b) You oscillate one end of the rope up and down in SHM withfrequency 25.0 Hz and amplitude 5.00 mm. What is the wavelength ofthe resulting waves on the rope? (c) At 1 = 0 the end you are oscillat-ing is at its maximum positive displacement and is instantaneously atrest. Write an equation for the displacement as a function of time at apoint 2.50 m from that end. Assume that no wave bounces back fromthe other end.VP15.3.4 The tension in a long string is 25.0 N. You oscillate one endof the string up and down with frequency 45.0 Hz. When this end isat its maximum upward displacement, the nearest point that is at itsmaximum negative displacement is 0.400 m down the string. What are(a) the speed of waves on the string and (b) the linear mass density ofthe string? VP15.5.2 A length of piano wire (mass density 5.55 × 10* kg/m) isunder 185 N of tension. A sinusoidal wave of frequency 256 Hz carriesa maximum power of 5.20 W along the wire. What is the amplitude ofthis wave?VP15.5.3 A portable audio speaker has a power output of 8.00 W.(a) If the speaker emits sound equally in all directions, what is the soundintensity at a distance of 2.00 m from the speaker? (b) At what distancefrom the speaker is the intensity equal to 0.045 W/m²?VP15.5.4 The "ears" of a frog are two circular membranes locatedbehind the frog's eyes. In one species of frog each membrane is 0.500 cmin radius. If a source of sound has a power output of 2.50 × 10-6 w,emits sound equally in all directions, and is located 1.50 m from thefrog, how much sound energy arrives at one of the membranes eachsecond?

Answered: Image /qna-images/answer/12c080c2-8d81-47a0-a86f-9334e57b557d.jpg

VP15.3.1 A boat is at anchor outside a harbor. A steady sinusoidal ocean wave makes the boat bob up and down with a period of 5.10 s and an amplitude of 1.00 m. The wave has wavelength 30.5 m. For this wave, what are (a) the frequency, (b) the wave speed, (c) the angular frequency, and (d) the wave number?

VP15.3.1 A boat is at anchor outside a harbor. A steady sinusoidal ocean wave makes the boat bob up and down with a period of 5.10 s and an amplitude of 1.00 m. The wave has wavelength 30.5 m. For this wave, what are (a) the frequency, (b) the wave speed, (c) the angular frequency, and (d) the wave number?

Physics for Scientists and Engineers, Technology Update (No access codes included)

9th Edition

ISBN:9781305116399

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter16: Wave Motion

Section: Chapter Questions

Problem 16.13P

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