Knowt
Note
Studied by 71 peopleNoteStudied by 14 peopleNoteStudied by 19 peopleNoteStudied by 9 peopleNoteStudied by 11 peopleNoteStudied by 21 people
Waves Basics
Wave:
Definition: Waves are disturbances that transfer energy through a medium or space without permanently displacing the medium itself.
Types:
Mechanical Waves: Require a medium (solid, liquid, or gas) to propagate. Examples include sound waves, water waves, and seismic waves.
Electromagnetic Waves: Can travel through a vacuum (empty space) and do not require a medium. Examples include light waves, radio waves, and X-rays.
Medium: The substance through which a mechanical wave travels.
Wave Motion:
Longitudinal Waves:
Particles oscillate parallel to the direction of wave propagation.
Example: Sound waves.
Transverse Waves:
Particles oscillate perpendicular to the direction of wave propagation.
Example: Light waves.
Wave Properties:
Crest/Trough:
Crest: Highest point of a wave.
Trough: Lowest point of a wave.
Amplitude: Maximum displacement from the rest position of a wave. Indicates the energy of the wave.
Wavelength (λ): Distance between two consecutive crests or troughs.
Frequency (f): Number of wave cycles passing a point per unit time.
Period (T): Time taken for one complete wave cycle to pass a point. Inversely related to frequency (T = 1/f).
Wave Speed (v): Rate at which a wave travels through a medium. Calculated as the product of frequency and wavelength (v = f x λ).
Relationships and Equations:
v = f x λ
T=f/1 (Period is inversely proportional to frequency)
Inversely Proportional Relationships:
Wavelength and Frequency: Longer wavelength, lower frequency, and vice versa.
Frequency and Period: Higher frequency, shorter period, and vice versa.
Directly Proportional Relationship:
Amplitude and Energy: Higher amplitude, more energy.
Real-life Applications:
Medical Imaging: Ultrasound and X-rays use wave properties to visualize internal structures.
Communication Systems: Radio, microwaves, and light waves are used for long-distance communication.
Seismic Studies: Analysis of seismic waves helps in understanding the Earth's interior structure.
Waves Basics
Wave:
Definition: Waves are disturbances that transfer energy through a medium or space without permanently displacing the medium itself.
Types:
Mechanical Waves: Require a medium (solid, liquid, or gas) to propagate. Examples include sound waves, water waves, and seismic waves.
Electromagnetic Waves: Can travel through a vacuum (empty space) and do not require a medium. Examples include light waves, radio waves, and X-rays.
Medium: The substance through which a mechanical wave travels.
Wave Motion:
Longitudinal Waves:
Particles oscillate parallel to the direction of wave propagation.
Example: Sound waves.
Transverse Waves:
Particles oscillate perpendicular to the direction of wave propagation.
Example: Light waves.
Wave Properties:
Crest/Trough:
Crest: Highest point of a wave.
Trough: Lowest point of a wave.
Amplitude: Maximum displacement from the rest position of a wave. Indicates the energy of the wave.
Wavelength (λ): Distance between two consecutive crests or troughs.
Frequency (f): Number of wave cycles passing a point per unit time.
Period (T): Time taken for one complete wave cycle to pass a point. Inversely related to frequency (T = 1/f).
Wave Speed (v): Rate at which a wave travels through a medium. Calculated as the product of frequency and wavelength (v = f x λ).
Relationships and Equations:
v = f x λ
T=f/1 (Period is inversely proportional to frequency)
Inversely Proportional Relationships:
Wavelength and Frequency: Longer wavelength, lower frequency, and vice versa.
Frequency and Period: Higher frequency, shorter period, and vice versa.
Directly Proportional Relationship:
Amplitude and Energy: Higher amplitude, more energy.
Real-life Applications:
Medical Imaging: Ultrasound and X-rays use wave properties to visualize internal structures.
Communication Systems: Radio, microwaves, and light waves are used for long-distance communication.
Seismic Studies: Analysis of seismic waves helps in understanding the Earth's interior structure.
NoteStudied by 71 peopleNoteStudied by 14 peopleNoteStudied by 19 peopleNoteStudied by 9 peopleNoteStudied by 11 peopleNoteStudied by 21 people