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This lecture discusses sinusoidal waves, the rate of wave energy transfer, reflection and transmission, superposition and interference. It also covers the speed of transverse waves on strings and the properties of sinusoidal waves on strings.
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PHYS 1443 – Section 501Lecture #26 Monday, May 3, 2004 Dr. Andrew Brandt • Waves • Sinusoidal Waves • Rate of Wave Energy Transfer • Reflection and Transmission • Superposition and Interference PHYS 1443-501, Spring 2004 Dr. Andrew Brandt
Announcements • On May 5, I will answer any questions that you may have on any of the material. If you have none it will be a short class—if you can use the time better with independent study that’s fine • Final exam will be Monday May 10 @5:30. It will be multiple choice only, so bring a Scantron form. It will be comprehensive, perhaps with a little more emphasis on ch 10-14. PHYS 1443-501, Spring 2004 Dr. Andrew Brandt
Waves • Waves are closely related to vibrations. • Mechanical waves involve oscillations of a medium and carry energy from one place to another • Two forms of waves • Pulse • Continuous or periodic wave • Wave can be characterized by • Amplitude • Wave length • Period • Two types of waves • Transverse Wave • Longitudinal wave • Sound wave PHYS 1443-501, Spring 2004 Dr. Andrew Brandt
Speed of Transverse Waves on Strings How do we determine the speed of a transverse pulse traveling on a string? If a string under tension is pulled sideways and released, the tension is responsible for accelerating a particular segment of the string back to the equilibrium position. The acceleration of a particular segment increases So what happens when the tension increases? Which means? The speed of the wave increases. Now what happens when the mass per unit length of the string increases? For a given tension, acceleration decreases, so the wave speed decreases. Newton’s second law of motion Which law is this hypothesis based on? Based on the hypothesis we have laid out above, we can construct a hypothetical formula for the speed of wave T: Tension on the string m: Unit mass per length T=[MLT-2], m=[ML-1] (T/m)1/2=[L2T-2]1/2=[LT-1] Is the above expression dimensionally sound? PHYS 1443-501, Spring 2004 Dr. Andrew Brandt
v Ds q q Fr T T q q R O Speed of Waves on Strings cont’d Let’s consider a pulse moving right and look at it in the frame that moves along with the the pulse. Since in the reference frame moving with the pulse, the segment is moving to the left with the speed v, and the centripetal acceleration of the segment is Now what are the force components when q is small? What is the mass of the segment when the line density of the string is m? Using the radial force component Therefore the speed of the pulse is PHYS 1443-501, Spring 2004 Dr. Andrew Brandt
5.00m 1.00m M=2.00kg Example for Traveling Wave A uniform cord has a mass of 0.300kg and a length of 6.00m. The cord passes over a pulley and supports a 2.00kg object. Find the speed of a pulse traveling along this cord. Since the speed of wave on a string with line density m and under the tension T is The line density m is The tension on the string is provided by the weight of the object. Therefore Thus the speed of the wave is PHYS 1443-501, Spring 2004 Dr. Andrew Brandt
Amplitude Wave Length A x -A Equation of motion of a simple harmonic oscillation is a cosine/sine function. Sinusoidal Waves But it does not travel. What is the expression for a travelling wave? The wave form can be described by the y-position (displacement) of a particle of the medium at a location x. First for t=0: Note this gives same displacement at x=0, l, 2l,… We want the wave form of the wave traveling at the speed v in +x at any given time t After time t the original wave form (crest in this case) has moved to the right by vt thus the wave form at x becomes the wave form which used to be at x-vt PHYS 1443-501, Spring 2004 Dr. Andrew Brandt
Travels to left Travels to right Sinusoidal Waves cont’d By definition, the speed of wave in terms of wave length and period T is Thus the wave form can be rewritten Defining, angular wave number k and angular frequency w, Wave speed (or phase velocity) v Frequency, f, The wave form becomes Generalized wave form PHYS 1443-501, Spring 2004 Dr. Andrew Brandt
Example for Waves A sinusoidal wave traveling in the positive x direction has an amplitude of 15.0cm, a wavelength of 40.0cm, and a frequency of 8.00Hz. The vertical displacement of the medium at t=0 and x=0 is also 15.0cm. a) Find the angular wave number k, period T, angular frequency w, and speed v of the wave. Using the definition, angular wave number k is Angular frequency is Period is Using period and wave length, the wave speed is b) Determine the phase constant f, and write a general expression of the wave function. At x=0 and t=0, y=15.0cm, therefore the phase f becomes Thus the general wave function is PHYS 1443-501, Spring 2004 Dr. Andrew Brandt
Sinusoidal Waves on Strings Let’s consider the case where a string is being oscillated in the y-direction. The trains of waves generated by the motion will travel through the string, causing the particles in the string to undergo simple harmonic motion in the y-direction. What does this mean? If the wave at t=0 is The wave function can be written This wave function describes the vertical motion of any point on the string at any time t. Therefore, we can use this function to obtain transverse speed, vy, and acceleration, ay. These are the speed and acceleration of the particle in the medium not of the wave. The maximum speed and the acceleration of the particle in the medium at position x at time t are Do these look familiar? PHYS 1443-501, Spring 2004 Dr. Andrew Brandt
Dx, Dm Rate of Energy Transfer by Sinusoidal Waves on Strings Waves traveling through a medium carry energy. When an external source performs work on the string, the energy enters into the string and propagates through the medium as wave. What is the potential energy stored in one wavelength of a traveling wave? Elastic potential energy of a particle in a simple harmonic motion Since w2=k/m The energy DU of the segment Dm is As Dx0, the energy DU becomes Beware of the k! k here is wave # Using the wave function,the energy is For the wave at t=0, the potential energy stored in one wavelength, l, is Recall k=2p/l PHYS 1443-501, Spring 2004 Dr. Andrew Brandt
Rate of Energy Transfer by Sinusoidal Waves cont’d What about the kinetic energy of each segment of the string in the wave? Since the vertical speed of the particle is The kinetic energy, DK, of the segment Dm is As Dx0, the energy DK becomes For the wave at t=0, the kinetic energy in one wave length, l, is Recall k=2p/l Just like harmonic oscillation, the total mechanical energy in one wave length, l, is So the power, the rate of energy transfer, becomes: P of any sinusoidal wave is proportion to the square of angular frequency, the square of the amplitude, the density of medium, and wave speed. PHYS 1443-501, Spring 2004 Dr. Andrew Brandt
Example for Wave Energy Transfer A taut string for which m=5.00x10-2 kg/m is under a tension of 80.0N. How much power must be supplied to the string to generate sinusoidal waves at a frequency of 60.0Hz and an amplitude of 6.00cm? The speed of the wave is Using the frequency, angular frequency w is Since the rate of energy transfer is PHYS 1443-501, Spring 2004 Dr. Andrew Brandt
Reflection and Transmission A pulse or a wave undergoes various changes when the medium it travels in changes. Depending on how rigid the support is, two radically different reflection patterns can be observed. • The support is rigidly fixed: The reflected pulse will be inverted to the original due to the force exerted on to the string by the support in reaction to the force on the support due to the pulse on the string. (equivalent to a phase change of ) • The support is freely moving: The reflected pulse will maintain the original shape but move in the reverse direction. PHYS 1443-501, Spring 2004 Dr. Andrew Brandt
Transmission Through Different Media If the boundary is intermediate between the previous two extremes, part of the pulse reflects, and part undergoes transmission, passing through the boundary and propagating in the new medium. • When a wave pulse travels from medium A to B: • vA> vB (or mA<mB), the pulse is inverted upon reflection. • vA< vB(or mA>mB), the pulse is not inverted upon reflection. PHYS 1443-501, Spring 2004 Dr. Andrew Brandt
Superposition Principle of Waves If two or more traveling waves are moving through a medium, the resultant wave function at any point is the algebraic sum of the wave functions of the individual waves. The waves that follow this principle are called linear waves which in general have small amplitudes. The ones that don’t are nonlinear waves with larger amplitudes. Thus, one can write the resultant wave function as PHYS 1443-501, Spring 2004 Dr. Andrew Brandt
Wave Interferences Two traveling linear waves can pass through each other without being destroyed or altered. What do you think will happen to the water waves when you throw two stones in the pond? They will pass right through each other. The shape of wave will change Interference What happens to the waves at the point where they meet? Constructive interference: The amplitude increases when the waves meet Destructive interference: The amplitude decreases when the waves meet PHYS 1443-501, Spring 2004 Dr. Andrew Brandt Out of phase not by p/2 Partially destructive In phase constructive Out of phase by p/2 destructive