Lecture 14: Sinusoidal Waveszimp.zju.edu.cn/~xinwan/courses/physI16/handouts/lecture14.pdf · A...
Transcript of Lecture 14: Sinusoidal Waveszimp.zju.edu.cn/~xinwan/courses/physI16/handouts/lecture14.pdf · A...
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General Physics IGeneral Physics I
Lecture 14: Sinusoidal WavesLecture 14: Sinusoidal Waves
Prof. WAN, Xin (万歆)
[email protected]://zimp.zju.edu.cn/~xinwan/
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MotivationMotivation
● When analyzing a linear medium—that is, one in which the restoring force acting on the particles of the medium is proportional to the displacement of the particles—we can apply the principle of superposition to determine the resultant disturbance.
● In the last lecture we discussed this principle as it applies to wave pulses.
● Here we study the superposition principle as it applies to sinusoidal waves. Examples include
− Beats− Standing wave
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OutlineOutline
● A revisit of the linear wave equation● Sinusoidal waves on strings● Rate of energy transfer by sinusoidal waves on
strings● Superposition and interference of sinusoidal waves● Beats: Interference in time● Standing waves and harmonics● Non-sinusoidal wave patterns
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The Linear Wave EquationThe Linear Wave Equation
∂2 y
∂t2= v2 ∂
2 y∂x2
The linear wave equation
v=a√ KM
where
The linear wave equation applies in general to various types of waves. For waves on strings, y represents the vertical displacement of the string. For sound waves, y corresponds to displacement of air molecules from equilibrium or variations in either the pressure or the density of the gas through which the sound waves are propagating. In the case of electromagnetic waves, y corresponds to electric or magnetic field components.
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The Speed of Waves on StringsThe Speed of Waves on Strings
Newton's second law
(μ Δ x)∂2 y
∂ t2= T x (x+Δ x)
∂ y∂ x∣
x+Δ x
− T x(x)∂ y∂x∣
x
Δm = μΔ xT x(x+Δ x) = T x(x) ≈ T
∂2 y
∂t2=
Tμ
∂2 y
∂x2
v = √Tμx x+Δ x
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General SolutionsGeneral Solutions
● Wave functions of the form y = f(x + vt) and y = f(x – vt) are obviously solutions to the linear wave equation.
● The most important family of the solutions are sinusoidal waves.
phase constant
angular wave number
angular frequency
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Various FormsVarious Forms
t = 0
t = 0
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Sinusoidal Wave on StringsSinusoidal Wave on Strings
● Each particle of the string, such as that at P, oscillates vertically with simple harmonic motion.
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Sinusoidal Wave on StringsSinusoidal Wave on Strings
● Note that although each segment oscillates in the y direction, the wave travels in the x direction with a speed v. Of course, this is the definition of a transverse wave.
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Rate of Energy TransferRate of Energy Transfer
We have learned that for simple harmonic oscillation, the total energy E = K + U is a constant, i.e.,
dE =12
μω2 A2dx
The rate of energy transfer: P =dEdt
=12
μω2 A2v
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The Principle of Superposition The Principle of Superposition
● The superposition principle states that when two or more waves move in the same linear medium, the net displacement of the medium (that is, the resultant wave) at any point equals the algebraic sum of all the displacements caused by the individual waves.
− Interference: Same frequency, wavelength, amplitude, direction. Different phase.
− Standing waves: Same frequency, wavelength, amplitude. Different direction.
− Beats: Different frequency.
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InterferenceInterference
Same frequency, wavelength, amplitude, direction. Different phase.
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InterferenceInterference
● When , the waves are said to be everywhere in phase and thus interfere constructively.
● When , the resultant wave has zero amplitude everywhere, as a consequence of destructive interference.
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Interference of Sound WavesInterference of Sound Waves
Δr=∣r 1−r2∣
: in phase
: out of phase
nλ
(n+1/2)λ
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Speakers Driven by the Same SourceSpeakers Driven by the Same Source
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Beating: Temporal InterferenceBeating: Temporal Interference
● Beating is the periodic variation in intensity at a given point due to the superposition of two waves having slightly different frequencies.
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Beating: Temporal InterferenceBeating: Temporal Interference
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Beat FrequencyBeat Frequency
● The amplitude and therefore the intensity of the resultant sound vary in time.
● The two neighboring maxima in the envelop function are separated by
2π ( f 1− f 22 )t = π
Beat frequency:
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Standing WavesStanding Waves
Same frequency, wavelength, amplitude. Different direction.
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Standing WavesStanding Waves
● A standing wave is an oscillation pattern with a stationary outline that results from the superposition of two identical waves traveling in opposite directions.
− No sense of motion in the direction of propagation of either of the original waves.
− Every particle of the medium oscillates in simple harmonic motion with the same frequency.
− Need to distinguish between the amplitude of the individual waves and the amplitude of the simple harmonic motion of the particles of the medium.
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Nodes and AntinodesNodes and Antinodes
Nodes: kx = nπ x = λ2,λ ,
3λ
2,⋯
Antinodes: kx = (n+12 ) π x = λ
4,3λ
4,5λ
4,⋯
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Nodes and AntinodesNodes and Antinodes
The distance between adjacent antinodes is equal to/2.The distance between adjacent nodes is equal to /2.The distance between a node and an adjacent antinode is /4.
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Energy in a Standing WaveEnergy in a Standing Wave
● Except for the nodes, which are always stationary, all points on the string oscillate vertically with the same frequency but with different amplitudes of simple harmonic motion.
● No energy is transmitted along the string across a node, and energy does not propagate in a standing wave.
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In a String Fixed at Both EndsIn a String Fixed at Both Ends
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Standing Waves in Air ColumnsStanding Waves in Air Columns
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Harmonic SeriesHarmonic Series
● In general, the wavelength of the various normal modes for a string of length L fixed at both ends are
● The frequencies of the normal modes are
● Frequencies of normal modes that exhibit an integer multiple relationship such as this form a harmonic series, and the normal modes are called harmonics.
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Harmonics in Musical InstrumentsHarmonics in Musical Instruments
● If we wish to excite just a single harmonic, we need to distort the string in such a way that its distorted shape corresponded to that of the desired harmonic.
● If the string is distorted such that its distorted shape is not that of just one harmonic, the resulting vibration includes various harmonics. Such a distortion occurs in musical instruments when the string is plucked (as in a guitar), bowed (as in a cello), or struck (as in a piano). When the string is distorted into a non-sinusoidal shape, only waves that satisfy the boundary conditions can persist on the string. These are the harmonics.
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Sound Quality or TimbreSound Quality or Timbre
Sounds may be generally characterized by pitch (frequency), loudness (amplitude), and quality.
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An “Almost” Square WaveAn “Almost” Square Wave
Fourier analysis of a periodic function
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Fourier AnalysisFourier Analysis
● Periodic function f(t) with period T = 2/1, i.e.,
functions such that f(t + T) = f(t) for all t, can be expanded in a Fourier series of the form
f (t) = ∑n=0
∞
[ Ansin (n2π
Tt ) + Bncos (n 2π
Tt ) ]
= B0 + ∑n=1
∞
Ansin (n 2π
Tt ) + ∑
n=1
∞
Bncos (n2π
Tt )
= B0 + ∑n=1
∞
Ansin (nω1 t ) + ∑n=1
∞
Bncos (nω1 t )
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Finding Fourier CoefficientsFinding Fourier Coefficients
● Fundamental integrals: for n > 0,
∫0
Tsin(nω1 t)dt = 0 ∫0
Tcos(nω1t)dt = 0
Am =2T∫0
Tf (t)sin(mω1 t)dt
Bm =2T∫0
Tf (t)cos(mω1 t )dt
B0 =2T∫0
Tf (t)dt
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Exercise: Square WaveExercise: Square Wave
Find out the leading Fourier coefficients of a square wave.