Explanation Beat frequency is equal to the difference in the frequency of two simultaneous notes. The general expression for the wave function of a wave is. y = A sin ( k x − ω t ) (I) Here, A is the amplitude, k is the wave number, ω is the angular frequency, t is the time. The wave function of first wave is. y 1 = A sin ( 0.25 x − 420 π t ) (II) The wave function of second wave is. y 2 = A sin ( 0.25 x − 426 π t ) (III) Comparing equation (I) and (II), the angular velocity of first wave is 420 π , and comparing equation (I) and (III) is 426 π . Write the expression for frequency in terms of angular frequency of first wave. f 1 = ω 1 2 π (IV) Write the expression for frequency in terms of angular frequency of second wave

Bundle: Physics For Scientists And Engineers: Foundations And Connections, Volume 1, Loose-leaf Version + Webassign Printed Access Card For Katz's ... And Connections, Single-term Courses

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ISBN: 9781337759359

Author: Debora M. Katz

Publisher: Cengage Learning

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Electromagnetic Waves

Electromagnetic waves are waves that consist of magnetic field and electric field components perpendicular to each other. These field components are also perpendicular to the direction of propagation of the wave.

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Chapter 18, Problem 57PQ

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The beat frequency between two hypothetical waves.

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Chapter 18, Problem 56PQ

Chapter 18, Problem 58PQ

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Chapter 18 Solutions

Bundle: Physics For Scientists And Engineers: Foundations And Connections, Volume 1, Loose-leaf Version + Webassign Printed Access Card For Katz's ... And Connections, Single-term Courses

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The beat frequency between two hypothetical waves.

Solution Summary: The author explains the beat frequency between two hypothetical waves, which is equal to the difference in the frequency of two simultaneous notes.

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The beat frequency between two hypothetical waves.

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Chapter 18 Solutions