course phy 202 µÀûÜ“Ó¼¬±‘ñ§´€ó͇ôƒ‚Q°ë†þ¶Ý•assignment #019
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15:11:03 Query introductory set 6, problems 1-10 explain how we know that the velocity of a periodic wave is equal to the product of its wavelength and frequency
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RESPONSE --> Wavelength (lambda) is the peak to peak distance and frequency is the number of waves per unit time (1 cyles/sec or 1 hz is a tyical maesure). So lambda * frequency = velocity
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15:11:31 ** we know how many wavelength segments will pass every second, and we know the length of each, so that multiplying the two gives us the velocity with which they must be passing **
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RESPONSE --> ok
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15:14:13 explain how we can reason out that the period of a periodic wave is equal to its wavelength divided by its velocity
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RESPONSE --> period is the inverse of frequency. It's how long it takes for one complete cycle. If we know how fast the wave is moving (velocity) and how long each wave is (lambda) we can divide the length by the rate at which the wave moves to get the amount of time for one cycle to pass and this is called the period of the wave.
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15:14:31 ** If we know how far it is between peaks (wavelength) and how fast the wavetrain is passing (velocity) we can divide the distance between peaks by the velocity to see how much time passes between peaks at a given point. That is, period is wavelength / velocity. **
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RESPONSE --> ok
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15:24:34 explain why the equation of motion at a position x along a sinusoidal wave is A sin( `omega t - x / v) if the equation of motion at the x = 0 position is A sin(`omega t)
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RESPONSE --> Because when x = lambda, y = sin 2pi = 0
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15:25:48 ** the key is the time delay. Time for the disturbance to get from x = 0 to position x is x / v. What happens at the new position is delayed by time x/v, so what happens there at clock time t happened at x=0 when clock time was t = x/v. In more detail: If x is the distance down the wave then x / v is the time it takes the wave to travel that distance. What happens at time t at position x is what happened at time t - x/v at position x=0. That expression should be y = sin(`omega * (t - x / v)). } The sine function goes from -1 to 0 to 1 to 0 to -1 to 0 to 1 to 0 ..., one cycle after another. In harmonic waves the motion of a point on the wave (think of the motion of a black mark on a white rope with vertical pulses traveling down the rope) will go thru this sort of motion (down, middle, up, middle, down, etc.) as repeated pulses pass. If I'm creating the pulses at my end, and that black mark is some distance x down in rope, then what you see at the black mark is what I did at time x/v earlier. **
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RESPONSE --> I think I may have misunderstood the question.
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15:27:25 Query introductory set six, problems 11-14 given the length of a string how do we determine the wavelengths of the first few harmonics?
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RESPONSE --> The wavelength (lambda) = 2*length/# of the harmonic (ie, 1,2,3,..........)
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15:28:00 ** As wavelength decreases you can fit more half-waves onto the string. You can fit one half-wave, or 2 half-waves, or 3, etc.. So you get 1 half-wavelength = string length, or wavelength = 2 * string length; using `lambda to stand for wavelength and L for string length this would be 1 * 1/2 `lambda = L so `lambda = 2 L. For 2 wavelengths fit into the string you get 2 * 1/2 `lambda = L so `lambda = L. For 3 wavelengths you get 3 * 1/2 `lambda = L so `lambda = 2/3 L; etc. } Your wavelengths are therefore 2L, L, 2/3 L, 1/2 L, etc.. **
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RESPONSE --> ok
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15:30:20 Given the wavelengths of the first few harmonics and the velocity of a wave disturbance in the string, how do we determine the frequencies of the first few harmonics?
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RESPONSE --> Frequency of a given harmonic = the velocity of the wave for that harmonic divided by the wavelength of that harmonic
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15:30:40 ** The frequency is the number of crests passing per unit of time. We can imagine a 1-second chunk of the wave divided into segments each equal to the wavelength. The number of peaks is equal to the length of the entire chunk divided by the length of a 1-wavelength segment. This is the number of peaks passing per second. So frequency is equal to the wave velocity divided by the wavelength. **
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RESPONSE --> ok
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15:31:21 Given the tension and mass density of a string how do we determine the velocity of the wave in the string?
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RESPONSE --> v = sq rt of tension/mass density
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15:31:37 ** We divide tension by mass per unit length and take the square root: v = sqrt ( tension / (mass/length) ). **
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RESPONSE --> ok
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15:33:56 gen phy explain in your own words the meaning of the principal of superposition
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RESPONSE --> When two waves interfere with each other, the principle of superposition states that the resulting displacement will be the algebraic sum of their displacements. If the waves are ""in phase"" with each other, their displacements will add together. If they are ""out of phase"" with each other, their displacements will cancel each other out.
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15:34:07 ** the principle of superposition tells us that when two different waveforms meet, or are present in a medium, the displacements of the two waveforms are added at each point to create the waveform that will be seen. **
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RESPONSE --> ok
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15:36:44 gen phy what does it mean to say that the angle of reflection is equal to the angle of incidence?
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RESPONSE --> when a wave hits an object (such as a wall), the angle between the face of the wave and the object is called the angle of incidence. The wave energy that bounces back is called the reflection and it bounces back at the same angle relative to the wall.
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15:37:00 ** angle of incidence with a surface is the angle with the perpendicular to that surface; when a ray comes in at a given angle of incidence it reflects at an equal angle on the other side of that perpendicular **
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RESPONSE --> ok
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course phy 202 µÀûÜ“Ó¼¬±‘ñ§´€ó͇ôƒ‚Q°ë†þ¶Ý•assignment #019
......!!!!!!!!...................................
15:11:03 Query introductory set 6, problems 1-10 explain how we know that the velocity of a periodic wave is equal to the product of its wavelength and frequency
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RESPONSE --> Wavelength (lambda) is the peak to peak distance and frequency is the number of waves per unit time (1 cyles/sec or 1 hz is a tyical maesure). So lambda * frequency = velocity
.................................................
......!!!!!!!!...................................
15:11:31 ** we know how many wavelength segments will pass every second, and we know the length of each, so that multiplying the two gives us the velocity with which they must be passing **
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RESPONSE --> ok
.................................................
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15:14:13 explain how we can reason out that the period of a periodic wave is equal to its wavelength divided by its velocity
......!!!!!!!!...................................
RESPONSE --> period is the inverse of frequency. It's how long it takes for one complete cycle. If we know how fast the wave is moving (velocity) and how long each wave is (lambda) we can divide the length by the rate at which the wave moves to get the amount of time for one cycle to pass and this is called the period of the wave.
.................................................
......!!!!!!!!...................................
15:14:31 ** If we know how far it is between peaks (wavelength) and how fast the wavetrain is passing (velocity) we can divide the distance between peaks by the velocity to see how much time passes between peaks at a given point. That is, period is wavelength / velocity. **
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RESPONSE --> ok
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15:24:34 explain why the equation of motion at a position x along a sinusoidal wave is A sin( `omega t - x / v) if the equation of motion at the x = 0 position is A sin(`omega t)
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RESPONSE --> Because when x = lambda, y = sin 2pi = 0
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15:25:48 ** the key is the time delay. Time for the disturbance to get from x = 0 to position x is x / v. What happens at the new position is delayed by time x/v, so what happens there at clock time t happened at x=0 when clock time was t = x/v. In more detail: If x is the distance down the wave then x / v is the time it takes the wave to travel that distance. What happens at time t at position x is what happened at time t - x/v at position x=0. That expression should be y = sin(`omega * (t - x / v)). } The sine function goes from -1 to 0 to 1 to 0 to -1 to 0 to 1 to 0 ..., one cycle after another. In harmonic waves the motion of a point on the wave (think of the motion of a black mark on a white rope with vertical pulses traveling down the rope) will go thru this sort of motion (down, middle, up, middle, down, etc.) as repeated pulses pass. If I'm creating the pulses at my end, and that black mark is some distance x down in rope, then what you see at the black mark is what I did at time x/v earlier. **
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RESPONSE --> I think I may have misunderstood the question.
.................................................
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15:27:25 Query introductory set six, problems 11-14 given the length of a string how do we determine the wavelengths of the first few harmonics?
......!!!!!!!!...................................
RESPONSE --> The wavelength (lambda) = 2*length/# of the harmonic (ie, 1,2,3,..........)
.................................................
......!!!!!!!!...................................
15:28:00 ** As wavelength decreases you can fit more half-waves onto the string. You can fit one half-wave, or 2 half-waves, or 3, etc.. So you get 1 half-wavelength = string length, or wavelength = 2 * string length; using `lambda to stand for wavelength and L for string length this would be 1 * 1/2 `lambda = L so `lambda = 2 L. For 2 wavelengths fit into the string you get 2 * 1/2 `lambda = L so `lambda = L. For 3 wavelengths you get 3 * 1/2 `lambda = L so `lambda = 2/3 L; etc. } Your wavelengths are therefore 2L, L, 2/3 L, 1/2 L, etc.. **
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RESPONSE --> ok
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15:30:20 Given the wavelengths of the first few harmonics and the velocity of a wave disturbance in the string, how do we determine the frequencies of the first few harmonics?
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RESPONSE --> Frequency of a given harmonic = the velocity of the wave for that harmonic divided by the wavelength of that harmonic
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15:30:40 ** The frequency is the number of crests passing per unit of time. We can imagine a 1-second chunk of the wave divided into segments each equal to the wavelength. The number of peaks is equal to the length of the entire chunk divided by the length of a 1-wavelength segment. This is the number of peaks passing per second. So frequency is equal to the wave velocity divided by the wavelength. **
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RESPONSE --> ok
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15:31:21 Given the tension and mass density of a string how do we determine the velocity of the wave in the string?
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RESPONSE --> v = sq rt of tension/mass density
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15:31:37 ** We divide tension by mass per unit length and take the square root: v = sqrt ( tension / (mass/length) ). **
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RESPONSE --> ok
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15:33:56 gen phy explain in your own words the meaning of the principal of superposition
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RESPONSE --> When two waves interfere with each other, the principle of superposition states that the resulting displacement will be the algebraic sum of their displacements. If the waves are ""in phase"" with each other, their displacements will add together. If they are ""out of phase"" with each other, their displacements will cancel each other out.
.................................................
......!!!!!!!!...................................
15:34:07 ** the principle of superposition tells us that when two different waveforms meet, or are present in a medium, the displacements of the two waveforms are added at each point to create the waveform that will be seen. **
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RESPONSE --> ok
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15:36:44 gen phy what does it mean to say that the angle of reflection is equal to the angle of incidence?
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RESPONSE --> when a wave hits an object (such as a wall), the angle between the face of the wave and the object is called the angle of incidence. The wave energy that bounces back is called the reflection and it bounces back at the same angle relative to the wall.
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15:37:00 ** angle of incidence with a surface is the angle with the perpendicular to that surface; when a ray comes in at a given angle of incidence it reflects at an equal angle on the other side of that perpendicular **
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RESPONSE --> ok
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