Presentation is loading. Please wait.

Presentation is loading. Please wait.

Resonance - a vibration of large amplitude in a mechanical or electrical system caused by a relatively small periodic stimulus of the same or nearly the.

Published byPhoebe Bell Modified over 8 years ago

Similar presentations

Presentation on theme: "Resonance - a vibration of large amplitude in a mechanical or electrical system caused by a relatively small periodic stimulus of the same or nearly the."— Presentation transcript:

1

2 Resonance - a vibration of large amplitude in a mechanical or electrical system caused by a relatively small periodic stimulus of the same or nearly the same period as the natural vibration period of the system. Requires:  a system capable to vibrate with a reasonable small damping;  an external driving force with a frequency close to that of the system. http://www.youtube.com/w atch?v=YLBt_07-Vek

3 Question: why are we discussing resonance now and have not discussed it while talking about propagating waves? Fundamental mode Higher harmonics Propagating waves transport energy. So, it is continuously carried away and does not get accumulated in specific locations. Propagating waves do not have any special natural wavelengths and frequencies. Both wavelengths and frequencies can vary continuously. Standing waves have a particular set of allowed frequencies, which are characteristic for the system.

4 Doppler effect – change in the wave frequency and/or wave length due to motion of the source or the observer (or both). Case #1 – moving observer. L The train is moving at a speed v, and the cars have a length L. When the observer is at rest there are cars passing by every second

5 Doppler effect – change in the wave frequency and/or wave length due to motion of the source or the observer. Case #1 – moving observer. L The train is moving at a speed v, and the cars have a length L. When the observer is moving in the same direction as the train at a speed u, the relative speed is v – u and there are cars passing by every second

6 Doppler effect – change in the wave frequency and/or wave length due to motion of the source or the observer. Case #1 – moving observer. L The train is moving at a speed v, and the cars have a length L. When the observer is moving in the direction opposite to the train at a speed u, the relative speed is v + u and there are cars passing by every second

7 The general equation is The original frequency is Therefore, With “+” and “-” corresponding to the opposite and same directions of motion, respectively. The wave length does not change (of course!), but the relative velocity does. + ­

8 I love hearing that lonesome wail of the train whistle as the magnitude of the frequency of the wave changes due to the Doppler effect…

9 Doppler effect. Stationary Sound Source Source moving with v source < v sound ( Mach 0.7 ) Car horn small high f large low f

10 Case #2 – moving source. Imagine splashing water with time intervals T, and making a circular wave every T seconds. In the time intervals between two consecutive splashes, a circle travels a distance = T  v, where v is the wave speed. So the distance between the consecutive circles is  Imagine now moving your hand a distance  x during the time T. Then the distance between the consecutive circles in front of your hand will be ’  =  –  x. And behind your hand the distance will be ’  =  +  x. Your hand is the source of waves here and its speed is u =  x/T. Therefore the distance between the circles is

11 Case #2 – moving source. The wavelength changes if the source of the waves moves. It decreases if the source and the wave move in the same direction (approaching source) The wavelength increases if the source moves in the direction opposite to the wave motion (receding source), “+” in the equation. What about the wave speed? does it change? What about the frequency registered by an observer at rest?

12 The wave speed does NOT change, since the circles (wave crests), once generated, loose any connection with the source, and cannot “know” about motion of the source. They only care about the mechanical properties of the medium. Therefore the wave length and the frequency are connected by the usual equation What about the wave speed? does it change? What about frequency registered by an observer at rest? Here again “-” is for approaching source – higher frequency. “+” is for receding source – lower frequency.

13 Doppler effect. Stationary Sound Source Source moving with v source < v sound ( Mach 0.7 ) Car horn small high f large low f

14 Police radar – sends frequency f. The car moving toward the radar at a speed u receives a frequency It reflects the received frequency f’, but the car is a source moving toward the radar, so that the radar receives a frequency If u/v is small, which is typical for electromagnetic waves. The frequency of the received signal is higher by

15 Why the equations for moving source and moving observer are different ? Isn’t any motion relative? There is third player in the game – the medium for the waves. It makes a lot of difference, whether or not the source of the wave moves with respect to the material medium. The mechanical waves (surface waves, string waves, sound etc.) absolutely need a material medium to propagate. Any waves that do not need a material medium?

16 Electromagnetic waves can propagate in vacuum and do not require any medium. Does it make any difference? A lot of difference! The whole theory of relativity can be derived from it. For light and other electromagnetic waves only the relative velocity of the source and the observer matter. If this velocity is much lower than the speed of light, c (the normal situation), the equations become: The upper sign is for motion away from each other; the light becomes more red. The lower sign is for motion toward each other; the light becomes more violet. Red light has a larger wavelength than green or white light.

17 Waves from a source, which is receding from us, are perceived to have lower frequency and larger wavelength. Red shift (shift toward larger wavelengths) in the spectra of distant galaxies is an evidence of expanding universe.

Download ppt "Resonance - a vibration of large amplitude in a mechanical or electrical system caused by a relatively small periodic stimulus of the same or nearly the."

Similar presentations

Mechanical Waves and Sound

Mechanical Waves and Sound
WAVES. Properties of Waves All waves carry energy from one point to another without transferring matter. As an example, when sound travels through air.

WAVES. Properties of Waves All waves carry energy from one point to another without transferring matter. As an example, when sound travels through air.
SOUND WAVES Sound is a longitudinal wave produced by a vibration that travels away from the source through solids, liquids, or gases, but not through a.

SOUND WAVES Sound is a longitudinal wave produced by a vibration that travels away from the source through solids, liquids, or gases, but not through a.
Chapter 14 Sound AP Physics B Lecture Notes.

Chapter 14 Sound AP Physics B Lecture Notes.
Refraction Minimize t with respect to x dt/dx=0 using dL 1 /dx=x/L 1 =sin  1 and dL 2 /dx=(x-d)/L 2 = -sin  2 dt/dx=(n 1 sin  1 - n 2 sin  2 )/c =

Refraction Minimize t with respect to x dt/dx=0 using dL 1 /dx=x/L 1 =sin  1 and dL 2 /dx=(x-d)/L 2 = -sin  2 dt/dx=(n 1 sin  1 - n 2 sin  2 )/c =
Waves.

Waves.
Doppler Effect(1) Stationary source Stationary observer Moving source

Doppler Effect(1) Stationary source Stationary observer Moving source
Doppler Effect & Redshift Gharib ESS

Doppler Effect & Redshift Gharib ESS
Sound Review. What type of wave is a sound wave? 1.Mechanical and Transverse 2.Mechanical and Longitudinal 3.Electromagnetic and Transverse 4.Electromagnetic.

Sound Review. What type of wave is a sound wave? 1.Mechanical and Transverse 2.Mechanical and Longitudinal 3.Electromagnetic and Transverse 4.Electromagnetic.
Chapter 3: Sound Wave Intensity of Periodic Sound Waves

Chapter 3: Sound Wave Intensity of Periodic Sound Waves
HC The Professional Development Service for Teachers is funded by the Department of Education and Science under the National Development Plan Waves and.

HC The Professional Development Service for Teachers is funded by the Department of Education and Science under the National Development Plan Waves and.
Lots of fun! Win valuable prizes!. 1. The source of all wave motion is a A. region of variable high and low pressure. B. movement of matter. C. harmonic.

Lots of fun! Win valuable prizes!. 1. The source of all wave motion is a A. region of variable high and low pressure. B. movement of matter. C. harmonic.
Waves & Sound.

Waves & Sound.
Vibrations, Waves, & Sound

Vibrations, Waves, & Sound
Welcome to 306!   Today is a new marking period – a new start!   DO NOW: Please write three goals you have for yourself in Integrated Science for.

Welcome to 306!   Today is a new marking period – a new start!   DO NOW: Please write three goals you have for yourself in Integrated Science for.
Waves.

Waves.
Doppler Effect.

Doppler Effect.
Doppler Effect The Doppler effect is the apparent change in the frequency of a wave motion when there is relative motion between the source of the waves.

Doppler Effect The Doppler effect is the apparent change in the frequency of a wave motion when there is relative motion between the source of the waves.
Ch. 11 Waves.

Ch. 11 Waves.
Waves A wave is a rhythmic disturbance that carries energy through matter or space.

Waves A wave is a rhythmic disturbance that carries energy through matter or space.

Similar presentations

Ads by Google