1 / 110

Intro to Waves

Learn the basics of waves, including wave types, mediums, transverse and longitudinal waves, parts of a wave, periodic motion, damping, pulse vs wave, wave speed, frequency, wavelength, amplitude, and wave interactions.

harville
Download Presentation

Intro to Waves

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Intro to Waves

  2. Intro to Waves • All things wiggle/vibrate/oscillate. • A wave is a wiggle in time. • The equilibrium is the resting position of a wave. • An object is at rest when experiencing a balance of forces. • An object will remain in this position until it is disturbed. • Forced vibration: The force which sets the resting object into motion.

  3. Intro to Waves • Waves transfer energywithout transferring matter. • Two types of waves: • Mechanical (through a medium) • Electromagnetic (through a “vacuum”, an empty space)

  4. Mediums • A medium is a substance or material that carries the wave from its source to other locations. • The medium consists of particles that interact with each other. • Each particle interacts with the adjacent particle, which allows the disturbance to travel through the medium • Examples: air, metal, string, people • Waves travel at different speeds based on the medium

  5. Mechanical Waves • Requires a medium • Ex: water, sound, slinky, stadium • 2 types: • Transverse – particles of the medium move perpendicular to the direction that the wave moves • Longitudinal – particles of the medium move parallel to the direction that the wave moves

  6. Transverse Wave: • Wave particles move perpendicular to the direction the wave travels • Ex: strings of a musical instrument Perpendicular to the direction of travel Direction of travel

  7. Longitudinal Wave: • Particles vibrate parallel to the direction the wave travels • Ex: sound wave Direction of travel Particles vibrate parallel to the direction of travel

  8. Parts of a transverse wave Crest Wavelength (ג) amplitude Equilibrium Position Wavelength (ג) amplitude Wavelength (ג) Trough

  9. Parts of a Transverse Wave – Sine Curve • Crest- highest point on a wave, maximum positive displacement from equilibrium • Trough- lowest point on a wave, maximum negative displacement from equilibrium • Equilibrium position- resting position • Amplitude- from the equilibrium position to the crest or trough • Wavelength – distance between any two identical points on a wave

  10. Periodic Motion • A wave moves over the same path over the course of time • The object not only repeats the same motion, it does so in a regular fashion • If it takes 3.2 sec to complete the 1st cycle, it will take 3.2 sec to complete the 2nd, 3rd, 4th… • A motion that is regular and repeating is called periodic motion

  11. Damping • Some energy is being dissipated over the course of time. • The mechanical energy of the vibrating object is lost to other objects. • The amount of displacement from its equilibrium position changes slightly with each vibration cycle. • Eventually the vibrations will cease.

  12. Pulse vs. Wave • Pulse: A single disturbance of the medium particles. • The energy passes through the medium in a single cycle and then the disturbance ceases. • Wave: A repeated and periodic disturbance of the medium particles. • A wave vibrates back and forth over a period of time.

  13. Wave pulse is a single wave disturbance • Wave train (continuous wave) - is a series of pulses at intervals

  14. Speed of waves • Speed: how fast an object is moving. • For a wave, speed is the distance traveled by a given point on the wave, such as the crest, in a given time interval • V = d/t • Ex: If a crest moves 20 m in 10 sec, what is the speed? • V = 20/10 • V = 2 m/s

  15. Frequency • Frequency (f) is a measure of the number of cycles per unit of time. • Measures in hertz (Hz) • F = # cycles/time

  16. Period • Period (p) is the time for a particle on a medium to make one complete vibrational cycle. • Measured in seconds • P = time/# cycles

  17. Frequency and Period • Frequency and Period are inversely related • P = 1/F F = 1/P

  18. Relationship between Wavelength, Frequency and Wave Speed (velocity)

  19. velocity ( v ): speed of the wave • unit: m/s (meter/second) • frequency ( f ): number of wave vibrations per second • unit: Hz (hertz) • wavelength ( ג ): length of one wave (crest to crest or trough to trough) • unit: m (meter)

  20. Relationship between frequency and wavelength: • Wavelength and frequency are inversely related • As frequency goes up the wavelength gets shorter (assuming no change in velocity)

  21. Amplitude • Amplitude is a measure of the amount of energy carried by a wave • High energy = large amplitude • Low energy = small amplitude

  22. Parts of a Longitudinal Wave: • Compression- point where the particles are closest together • Rarefaction- point where the particles are furthest apart Rarefaction Compression

  23. Wave Boundary Behavior • As a wave travels through a medium it will often reach the end of the medium and encounter an obstacle or another medium • Boundary – the interface of the 2 media • Boundary behavior – the behavior of a wave upon reaching the end of a medium

  24. Wave Interactions • Reflection • Refraction • Diffraction

  25. Wave interactions Reflection: • The bouncing back of a wave when it encounters a new medium or boundary • Ex: light off a mirror, or sound echo • Incident wave- incoming wave • Reflected wave – the wave that returns

  26. Fixed End Reflection • A fixed boundary is one not allowed to move

  27. Fixed End Reflection • Reflected wave is inverted (upside down) WHY? • Speed of the reflected pulse is the same as incident pulse – WHY? • Wavelength is the same – WHY? • Amplitude of the reflected pulse is LESS than the incident wave – WHY?

  28. Flexible End Reflection • A flexible boundary is allowed to move • Waves reflected off a flexible boundary are upright.

  29. Flexible End Reflection • Speed of the reflected pulse is the same as incident pulse • Wavelength is the same • Amplitude of the reflected pulse is LESS than the incident wave

  30. Transmission of pulse in different mediums • Wave speed differs in different types of media • Waves are faster in less dense media • At the boundary, waves will either reflect back or transmit through the other medium

  31. Less to more dense media

  32. Less to More Dense media • If a pulse crosses a boundary from LESS to MORE dense medium: • The reflected pulse will be inverted • The transmitted pulse will be displaced upwards – transmitted pulses are NEVER inverted • The transmitted pulse (more dense) is traveling slower than the reflected pulse (less dense) • Transmitted pulse has a smaller wavelength than the reflected pulse • Speed and wavelength are the same for the reflected and incident pulse

  33. More to Less Dense

  34. More to Less Dense • Reflected pulse will NOT be inverted • Transmitted pulse is NEVER inverted • Transmitted pulse (less dense) is traveling faster than reflected pulse (more dense) • Transmitted pulse has a larger wavelength • Speed and wavelength of the reflected and incident pulse are the same

  35. Summary: • Wave speed is always greatest in least dense material • Wavelength is always greatest in least dense material • Frequency of a wave is not altered by crossing a boundary • Reflected pulse becomes inverted when wave goes from less dense to more dense • Amplitude of incident pulse is always greater than amplitude of the reflected pulse.

  36. Reflection • Law of Reflection: The angle of incidence is equal to the angle of reflection

  37. Refraction • The bending of a wave path as it enters a new medium • Caused by difference in speed of the new medium • When crossing a boundary into a different medium, the wavelength decreases • The frequency stays the same • The decrease in wavelength causes a decrease in the velocity

  38. Diffraction • Spreading of waves around edges or through an opening of a boundary • Is greatest when size of opening is smaller than wavelength The amount of diffraction (sharpness of bending) increases with increasing wavelength and decreases with decreasing wavelength.

  39. Superposition Principle of Superposition: • Displacement of a medium by two or more waves is the algebraic sum of the displacements of the waves alone

  40. Interference of Waves • Result of the superposition of two or more waves meeting while traveling along the same medium. • Constructive- when the wave displacements are in the same direction; amplitudes add • Destructive – when the waves have opposite amplitudes; amplitudes subtract • Only temporary as paths cross

  41. Constructive interference Only temporary as paths cross

  42. Destructive interference Only temporary as paths cross

  43. Standing Wave • A wave that appears to be standing still • Result from the interference between the incident wave and the reflected wave • The point of no displacement is the node • The point of maximum displacement is the antinode Node Antinode

  44. Standing Waves • Standing waves are produced only at specific frequencies, called “harmonics” • Different frequencies create different standing wave patterns:

  45. 1st harmonic pattern • 2 nodes and 1 antinode • Simplest harmonic pattern • Low frequencies 2nd harmonic pattern • 3 nodes and 2 antinodes • 2 times the frequency as 1st 3rd harmonic pattern • 4 nodes and 3 antinodes

  46. Standing waves • Other ways to indicate the patterns:

  47. Standing Waves • Each node is separated by the adjacent node by a distance that is equal to ½ of a wavelength. • So if the following length below is 1.2 m long – determine the wavelength of a complete wave.

  48. Sound Waves • Sound waves are produced by a vibrating object . • Sound waves are longitudinal mechanical waves. • Often demonstrated with a tuning fork – as tines vibrate, they disturb the surrounding air molecules

  49. Sound as a Longitudinal Wave • Individual particles of medium move parallel to the direction of the wave • As particles push on adjacent particles, some regions are created where particles are pressed together (high pressure) and in some regions they are spread apart (low pressure).

  50. Sound waves • Compressions – the areas of high pressure • Rarefactions – the areas of low pressure • Since there is a repeating pattern of compressions and rarefactions, sound waves are also called “pressure waves” • A wavelength is the distance from compression to compression (or rarefaction to rarefaction)

More Related