 15.1E: The speed of sound in air at 20o C is 344 m/s. (a) What is the wave...
 15.3DQ: What kinds of energy are associated with waves on a stretched strin...
 15.15E: One end of a horizontal rope is attached to a prong of an electrica...
 15.16DQ: In a transverse wave on a string, the motion of the string is perpe...
 15.16E: With what tension must a rope with length 2.50 m and mass 0.120 kg ...
 15.2DQ: Under a tension F, it takes 2.00 s for a pulse to travel the length...
 15.35E: Interference of Rectangular Pulses. Figure E15.35 shows two rectang...
 15.36E: CALC Adjacent antinodes of a standing wave on a string are 15.0 cm ...
 15.2E: BIO Audible Sound. Provided the amplitude is sufficiently great, th...
 15.37E: Standing waves on a wire are described by Eq. (15.28), with The lef...
 15.57P: When a transverse sinusoidal wave is present on a string, the parti...
 15.65P: (a) Explain why any wave described by a function of the form y(x, t...
 15.3E: Tsunami! On December 26, 2004, a great earthquake occurred off the ...
 15.66P: CP A vertical, 1.20m length of 18gauge (diameter of 1.024 mm) cop...
 15.4DQ: The amplitude of a wave decreases gradually as the wave travels dow...
 15.67P: (a) Show that Eq. (15.25) can also be written as where k is the wav...
 15.68P: Equation (15.7) for a sinusoidal wave can be made more general by i...
 15.4E: BIO Ultrasound Imaging. Sound having frequencies above the range of...
 15.70P: Energy in a Triangular Pulse. A triangular wave pulse on a taut str...
 15.5DQ: For the wave motions discussed in this chapter, does the speed of p...
 15.85CP: CALC (a) Show that for a wave on a string, the kinetic energy per u...
 15.5E: (a) Audible wavelengths. The range of audible frequencies is from a...
 15.6DQ: The speed of ocean waves depends on the depth of the water; the dee...
 15.6E: A fisherman notices that his boat is moving up and down periodicall...
 15.7DQ: Is it possible to have a longitudinal wave on a stretched string? W...
 15.7E: Transverse waves on a string have wave speed 8.00 m/s, amplitude 0....
 15.8DQ: An echo is sound reflected from a distant object, such as a wall or...
 15.8E: A certain transverse wave is described by Determine the wave’s (a) ...
 15.9DQ: Why do you see lightning before you hear the thunder? A familiar ru...
 15.9E: CALC Which of the following wave functions satisfies the wave equat...
 15.10DQ: For transverse waves on a string, is the wave speed the same as the...
 15.10E: A water wave traveling in a straight line on a lake is described by...
 15.11DQ: Children make toy telephones by sticking each end of a long siring ...
 15.11E: A sinusoidal wave is propagating along a stretched string that lies...
 15.12DQ: The four strings on a violin have different thicknesses, but are al...
 15.12E: CALC Speed of Propagation vs. Particle Speed. (a) Show that Eq. (15...
 15.13DQ: A sinusoidal wave can be described by a cosine function, which is n...
 15.13E: A transverse wave on a string has amplitude 0.300 cm, wavelength 12...
 15.14DQ: Two strings of different mass per unit length µ1 and µ2 are tied to...
 15.14E: A wave on a string is described by y(x, t) = A cos(kx – ?t). (a) Gr...
 15.15DQ: A long rope with mass m is suspended from the ceiling and hangs ver...
 15.17DQ: Both wave intensity and gravitation obey inversesquare laws. Do th...
 15.17E: The upper end of a 3.80mlong steel wire is fastened to the ceilin...
 15.18DQ: Energy can be transferred along a string by wave motion. However, i...
 15.18E: A 1.50m string of weight 0.0125 N is tied to the ceiling at its up...
 15.19DQ: Can a standing wave be produced on a string by superposing two wave...
 15.19E: A thin, 75.0cm wire has a mass of 16.5 g. One end is tied to a nai...
 15.20DQ: If you stretch a rubber band and pluck it, you hear a (somewhat) mu...
 15.20E: Weighty Rope. If in Example 15.3 (Section 15.4) we do not neglect t...
 15.21DQ: A musical interval of an octave corresponds to a factor of 2 in fre...
 15.21E: A simple harmonic oscillator at the point x = 0 generates a wave on...
 15.22DQ: By touching a string lightly at its center while bowing, a violinis...
 15.22E: A piano wire with mass 3.00 g and length 80.0 cm is stretched with ...
 15.23DQ: As we discussed in Section 15.1, water waves are a combination of l...
 15.23E: A horizontal wire is stretched with a tension of 94.0 N, and the sp...
 15.24DQ: Violins are short instruments, while cellos and basses are long. In...
 15.24E: A light wire is tightly stretched with tension F. Transverse travel...
 15.25DQ: What is the purpose of the frets on a guitar? In terms of the frequ...
 15.25E: A jet plane at takeoff can produce sound of intensity 10.0 W/m2 at ...
 15.26E: Threshold of Pain. You are investigating the report of a UFO landin...
 15.27E: Energy Output. By measurement you determine that sound waves are sp...
 15.28E: A fellow student with a mathematical bent tells you that the wave f...
 15.29E: At a distance of 7.00 X 1012 m from a star, the intensity of the ra...
 15.30E: Reflection. A wave pulse on a string has the dimensions shown in Fi...
 15.31E: Reflection. A wave pulse on a string has the dimensions shown in Fi...
 15.32E: Interference of Triangular Pulses. Two triangular wave pulses are t...
 15.33E: Suppose that the lefttraveling pulse in Exercise 15.32 is below th...
 15.34E: Two pulses are moving in opposite directions at 1.0 cm/s on a taut ...
 15.38E: CALC Wave Equation and Standing Waves. (a) Prove by direct substitu...
 15.39E: CALC Let is also a solution to the wave equation.
 15.40E: A 1.50mlong rope is stretched between two supports with a tension...
 15.41E: A wire with mass 40.0 g is stretched so that its ends are tied down...
 15.42E: A piano tuner stretches a steel piano wire with a tension of 800 N....
 15.43E: CALC A thin, taut string tied at both ends and oscillating in its t...
 15.44E: The wave function of a standing wave is y(x, t) = 4.44 mm sin[(32.5...
 15.45E: Consider again the rope and traveling wave of the Exercise seen bel...
 15.46E: One string of a certain musical instrument is 75.0 cm long and has ...
 15.47E: The portion of the string of a certain musical instrument between t...
 15.48E: (a) A horizontal string tied at both ends is vibrating in its funda...
 15.49E: Guitar String. One of the 63.5cmlong strings of an ordinary guita...
 15.50E: Waves on a Stick. A flexible stick 2.0 m long is not fixed in any w...
 15.51P: CALC A transverse sine wave with an amplitude of 2.50 mm and a wave...
 15.52P: A transverse wave on a rope is given byy(x, t) = (0.750 cm) cos?[(0...
 15.53P: Three pieces of string, each of length L, are joined together end t...
 15.54P: A 1750N irregular beam is hanging horizontally by its ends from th...
 15.55P: Ant Joy Ride. You place your pet ant Klyde (mass m) on top of a hor...
 15.56P: Weightless Ant. An ant with mass m is standing peacefully on top of...
 15.58P: Music. You are designing a twostring instrument with metal strings...
 15.59P: The lower end of a uniform bar of mass 45.0 kg is attached to a wal...
 15.60P: CP You are exploring a newly discovered planet. The radius of the p...
 15.61P: For a string stretched between two supports, two successive standin...
 15.62P: CP A 5.00m, 0.732kg wire is used to support two uniform 235N po...
 15.63P: A 1.80mlong uniform bar that weighs 536 N is suspended in a horiz...
 15.64P: A continuous succession of sinusoidal wave pulses are produced at o...
 15.69P: A sinusoidal transverse wave travels on a string. The string has le...
 15.71P: CALC Instantaneous Power in a Wave. (a) Graph y(x, t) as given by E...
 15.72P: A vibrating string 50.0 cm long is under a tension of 1.00 N. The r...
 15.73P: Clothesline Nodes. Cousin Throckmorton is once again playing with t...
 15.74P: CALC A guitar string is vibrating in its fundamental mode, with nod...
 15.75P: CALC A string that lies along the +xaxis has a free end at x= 0. (...
 15.76P: A string with both ends held fixed is vibrating in its third harmon...
 15.77P: A uniform cylindrical steel wire, 55.0 cm long and 1.14 mm in diame...
 15.78P: Holding Up Under Stress. A string or rope will break apart if it is...
 15.79P: A guitar string of length L is plucked in such a way that the total...
 15.80P: When a massive aluminum sculpture is hung from a steel wire, the fu...
 15.81P: CP A large rock that weighs 164.0 N is suspended from the lower end...
 15.82P: Tuning an Instrument. A musician tunes the Cstring of her instrume...
 15.83P: One type of steel has a density of 7.8 × 103 kg/m3 and a breaking s...
 15.84CP: CP CALC A deepsea diver is suspended beneath the surface of Loch ...
 15.15.1: The speed of sound in air at is (a) What is the wavelength of a sou...
 15.15.2: Audible Sound. Provided the amplitude is suffi ciently great, the ...
 15.15.3: Tsunami! On December 26, 2004, a great earthquake occurred off the ...
 15.15.4: BIO Ultrasound Imaging. Sound having frequencies above the range of...
 15.15.5: BIO (a) Audible wavelengths. The range of audible frequencies is fr...
 15.15.6: A fisherman notices that his boat is moving up and down periodicall...
 15.15.7: Transverse waves on a string have wave speed amplitude 0.0700 m, an...
 15.15.8: A certain transverse wave is described by Determine the waves (a) a...
 15.15.9: CALC Which of the following wave functions satisfies the wave equat...
 15.15.10: A water wave traveling in a straight line on a lake is described by...
 15.15.11: A sinusoidal wave is propagating along a stretched string that lies...
 15.15.12: Speed of Propagation vs. Particle Speed. (a) Show that Eq. (15.3) m...
 15.15.13: A transverse wave on a string has amplitude 0.300 cm, wavelength 12...
 15.15.14: A wave on a string is described by (a) Graph y, and as functions of...
 15.15.15: One end of a horizontal rope is attached to a prong of an electrica...
 15.15.16: With what tension must a rope with length 2.50 m and mass 0.120 kg ...
 15.15.17: The upper end of a 3.80mlong steel wire is fastened to the ceilin...
 15.15.18: A 1.50m string of weight 0.0125 N is tied to the ceiling at its up...
 15.15.19: A thin, 75.0cm wire has a mass of 16.5 g. One end is tied to a nai...
 15.15.20: Weighty Rope. If in Example 15.3 (Section 15.4) we do not neglect t...
 15.15.21: A simple harmonic oscillator at the point generates a wave on a rop...
 15.15.22: A piano wire with mass 3.00 g and length 80.0 cm is stretched with ...
 15.15.23: A horizontal wire is stretched with a tension of 94.0 N, and the sp...
 15.15.24: A light wire is tightly stretched with tension F. Transverse travel...
 15.15.25: A jet plane at takeoff can produce sound of intensity 10.0 W>m at 3...
 15.15.26: Threshold of Pain. You are investigating the report of a UFO landin...
 15.15.27: Energy Output. By measurement you determine that sound waves are sp...
 15.15.28: A fellow student with a mathematical bent tells you that the wave f...
 15.15.29: At a distance of from a star, the intensity of the radiation from t...
 15.15.30: Reflection. A wave pulse on a string has the dimensions shown in Fi...
 15.15.31: Reflection. A wave pulse on a string has the dimensions shown in Fi...
 15.15.32: Interference of Triangular Pulses. Two triangular wave pulses are t...
 15.15.33: Suppose that the lefttraveling pulse in Exercise 15.32 is below th...
 15.15.34: Two pulses are moving in opposite directions at on a taut string, a...
 15.15.35: Interference of Rectangular Pulses. Figure E15.35 shows two rectang...
 15.15.36: CALC Adjacent antinodes of a standing wave on a string are 15.0 cm ...
 15.15.37: Standing waves on a wire are described by Eq. (15.28), with and The...
 15.15.38: CALC Wave Equation and Standing Waves. (a) Prove by direct substitu...
 15.15.39: CALC Let and be two solutions to the wave equation, Eq. (15.12), fo...
 15.15.40: A 1.50mlong rope is stretched between two supports with a tension...
 15.15.41: A wire with mass 40.0 g is stretched so that its ends are tied down...
 15.15.42: A piano tuner stretches a steel piano wire with a tension of 800 N....
 15.15.43: CALC A thin, taut string tied at both ends and oscillating in its t...
 15.15.44: The wave function of a standing wave is For the two traveling waves...
 15.15.45: Consider again the rope and traveling wave of Exercise 15.28. Assum...
 15.15.46: One string of a certain musical instrument is 75.0 cm long and has ...
 15.15.47: The portion of the string of a certain musical instrument between t...
 15.15.48: (a) A horizontal string tied at both ends is vibrating in its funda...
 15.15.49: Guitar String. One of the 63.5cmlong strings of an ordinary guita...
 15.15.50: Waves on a Stick. A flexible stick 2.0 m long is not fixed in any w...
 15.15.51: CALC A transverse sine wave with an amplitude of 2.50 mm and a wave...
 15.15.52: A transverse wave on a rope is given by (a) Find the amplitude, per...
 15.15.53: Three pieces of string, each of length L, are joined together end t...
 15.15.54: CP A 1750N irregular beam is hanging horizontally by its ends from...
 15.15.55: CALC Ant Joy Ride. You place your pet ant Klyde (mass m) on top of ...
 15.15.56: Weightless Ant. An ant with mass m is standing peacefully on top of...
 15.15.57: CP When a transverse sinusoidal wave is present on a string, the pa...
 15.15.58: Music. You are designing a twostring instrument with metal strings...
 15.15.59: CP The lower end of a uniform bar of mass 45.0 kg is attached to a ...
 15.15.60: You are exploring a newly discovered planet. The radius of the plan...
 15.15.61: For a string stretched between two supports, two successive standin...
 15.15.62: CP A 5.00m, 0.732kg wire is used to support two uniform 235N pos...
 15.15.63: CP A 1.80mlong uniform bar that weighs 536 N is suspended in a ho...
 15.15.64: A continuous succession of sinusoidal wave pulses are produced at o...
 15.15.65: CALC Waves of Arbitrary Shape. (a) Explain why any wave described b...
 15.15.66: A vertical, 1.20m length of 18gauge (diameter of 1.024 mm) copper...
 15.15.67: (a) Show that Eq. (15.25) can also be written as where k is the wav...
 15.15.68: CALC Equation (15.7) for a sinusoidal wave can be made more general...
 15.15.69: A sinusoidal transverse wave travels on a string. The string has le...
 15.15.70: CALC Energy in a Triangular Pulse. A triangular wave pulse on a tau...
 15.15.71: CALC Instantaneous Power in a Wave. (a) Graph as given by Eq. (15.7...
 15.15.72: A vibrating string 50.0 cm long is under a tension of 1.00 N. The r...
 15.15.73: Clothesline Nodes. Cousin Throckmorton is once again playing with t...
 15.15.74: CALC A guitar string is vibrating in its fundamental mode, with nod...
 15.15.75: CALC A string that lies along the axis has a free end at (a) By us...
 15.15.76: A string with both ends held fixed is vibrating in its third harmon...
 15.15.77: A uniform cylindrical steel wire, 55.0 cm long and 1.14 mm in diame...
 15.15.78: Holding Up Under Stress. A string or rope will break apart if it is...
 15.15.79: Combining Standing Waves. A guitar string of length L is plucked in...
 15.15.80: When a massive aluminum sculpture is hung from a steel wire, the fu...
 15.15.81: A large rock that weighs 164.0 N is suspended from the lower end of...
 15.15.82: Tuning an Instrument. A musician tunes the Cstring of her instrume...
 15.15.83: One type of steel has a density of and a breaking stress of A cylin...
 15.15.84: CP CALC A deepsea diver is suspended beneath the surface of Loch N...
 15.15.85: CALC (a) Show that for a wave on a string, the kinetic energy per u...
Solutions for Chapter 15: Sears and Zemansky's University Physics with Modern Physics 13th Edition
Full solutions for Sears and Zemansky's University Physics with Modern Physics  13th Edition
ISBN: 9780321696861
Solutions for Chapter 15
Get Full SolutionsThis textbook survival guide was created for the textbook: Sears and Zemansky's University Physics with Modern Physics, edition: 13. Sears and Zemansky's University Physics with Modern Physics was written by and is associated to the ISBN: 9780321696861. This expansive textbook survival guide covers the following chapters and their solutions. Chapter 15 includes 194 full stepbystep solutions. Since 194 problems in chapter 15 have been answered, more than 542751 students have viewed full stepbystep solutions from this chapter.

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