Waves and periodic motion Flashcards
What is a wave?
A wave is a disturbance in a medium such that each particle in the medium vibrates about an equilibrium point in a simple harmonic (periodic) motion
What is wavelength (λ)?
The distance from crest to crest (or valley to valley) of a transverse wave.
In a longitudinal wave, the wavelength is the distance from one rarefaction (or condensation) to another.
What is amplitude (A)?
The maximum displacement of a particle in one direction from its equilibrium point.
What is intensity (I)?
The square of the amplitude: A^2
What is frequency? (f)
The number of cycles per unit time (per second)
What is period (T)?
The duration of one cycle, it is the inverse of the frequency.
T = 1/f
What is velocity (of a wave)? How is it calculated?
v of a wave is the velocity of the propagation of the disturbance that forms the wave through the medium.
The velocity is inversely proportional to the inertia of the medium. It can be calculated according to the following important equation:
v = λf
What does the superposition principle state?
That the effect of two or more waves on the displacement of a particle is independent. The final displacement of the particle is the resultant effect of all the waves added algebraically, thus, the amplitude may increase or decrease.
What is wave interference? What are the five criteria for this?
Synchrony sources Coherent vibrations Parallel vibrations Interference conditions Beat frequency
The summation of the displacements of different waves in a medium. There are 5 criteria
- Synchrony sources: vibration emitted by synchrony sources have the same phase
- Coherent vibrations: the phase of the vibrations are related, this means that the duration of the light impressions on the retina is much longer than the duration of a wave train between two emissions
- Parallel vibrations: the displacements of parallel vibrations keep parallel directions in space
- Interference conditions: two or more vibrations can interfere only when they are coherent, parallel and have the same period
- Beat frequency: The difference in frequency of two waves creates a new frequency
What is constructive interference? Destructive interference?
Constructive interference: is when waves add to a larger resultant wave than either original
Destructive interference: is when the waves add to a smaller resultant wave than either original wave.
What is resonance? (In wave//particle motion)
Forced vibrations occur due to a series of waves impinging upon an object. Natural frequencies are the intrinsic frequencies of a vibrating system.
If the forced vibration causes the object to vibrate at one of its natural frequencies, the body will vibrate at maximal amplitude, this is called resonance.
Since energy and power are proportional to the amplitude squared, they also are their maximum.
What are standing waves? What are nodes?
Standing waves result when waves are reflected off a stationary object and back into the oncoming aves of the medium and superposition results.
Nodes are points where there is no particle displacement, which are similar to points of maximal destructive interference.
What is the fundamental frequency?
- The lowest frequency in a harmonic (AKA first harmonic)
- The other are called overtones
What are harmonic series?
Overtones whose frequencies are integral multiples of the fundamental (lowest) frequency (first harmonic)
What are the three interference conditions?
Two or more vibrations can only occur if:
- They are coherent (in phase)
- Parallel
- They have the same period
The first harmonic has a frequency of 100 Hz. What is the period of the second harmonic?
The second harmonic has one extra node (and therefore an extra antinode), this effectively doubles the frequency of the second harmonic (eg. to 200 Hz)
Period is simply 1/f
So the answer is 1/200 = .005
(help with this division: think of what 200 must be multiplied to get 1000 (5), then think of what that must be divided by to get 1 (1000))
If 2 is divided by 1000, how many decimal places are moved?
3, one for each zero :)
= .002
If the first harmonic has a frequency of 100 Hz and a wavelength of 1 m, what is the frequency and wavelength of the second and third harmonic?
What is the speed of the waves?
First: 100 Hz, 1 m, 100 m/s
Second: 200 Hz, .5 m, 100 m/s
Third: 300 Hz, .33 m, 100 m/s
Speed is constant (as it is dependent on the medium, not the characteristics of the wave). Speed = (frequency)(wavelength)
How can you figure out the period of a complex waveform?
You disregard all the little crests and troughs that make up the waveform, and instead look at all the repeating units. One repeating unit is one period.
What is the speed of light?
3 x 10^8 m/s
Give the relationship (formula) between wavelength, frequency and wave velocity
v = f⋅λ
This is useful when given the wavelength of something travelling at the speed of light (3 x 10^8 m/s)
Mechanical waves in a medium, such as water, function to transport:
A. matter only
B. Energy only
C. Both matter and energy
D. Neither matter not energy
B. Energy only
Mechanical waves, such as sound and water waves, are a local oscillation of material. Only the energy propagates; the oscillating material does not move far from its initial equilibrium position.
For a sound source that is moving away from an observer, why are the percentages of the change in frequency and wavelength much greater when sound waves are used instead of radio waves?
Sound waves travel more slowly.
The Doppler equation for frequency is Δf/f = -v/c for a given relative velocity v between source and detector. Thus, the frequency shift Δf depends inversely on the speed of the wave in the medium in which it propagates, c.
The velocity of sound is much smaller than that of electromagnetic radiation, so for the same relative velocity the frequency and wavelength shifts are much greater for sound than for radio waves.
The fundamental, resonant wavelength of a pipe, open at both ends that is 1 m long and .1 m in diameter is ___ m?
2.0 m
Pipes and tubes have their resonant wavelengths when standing waves develop. An open pipe has its fundamental, resonant wavelength at twice the length of the pipe. Both ends have displacement antinodes (maximum amplitudes) with a node in the middle of the pipe. Thus, the pipe is half a wavelength long. The resonant wavelength is independent of the diameter of the pipe.