Presentation is loading. Please wait.

Presentation is loading. Please wait.

Waves and Radiation Wave Parameters and Behaviours.

Published byOsborn Randall Modified over 8 years ago

Similar presentations

Presentation on theme: "Waves and Radiation Wave Parameters and Behaviours."— Presentation transcript:

1 Waves and Radiation Wave Parameters and Behaviours

2 Learning Outcomes Energy can be transferred as waves. Determination of frequency, wavelength, amplitude and wave speed for transverse and longitudinal waves. Use of the relationship between wave speed, frequency, wavelength, distance and time. Diffraction and practical limitations. Comparison of long wave and short wave diffraction.

3 Energy can be transferred as waves Imagine trying to lift someone up a distance of 5m. It is actually hard work. You need lots of energy to do it. Now think about how the waves lift up ships in the ocean. Where is the energy coming from to lift these massive ships? See Virtual Nation 5 Physics – Waves Introduction

4 Energy in Waves All waves transfer energy from one location to the other. Waves may be transverse – water waves, radio waves, etc or longitudinal like sound waves. See Virtual Nation 5 Physics – Transverse and Longitudinal Waves

5 Speed of Sound in Air

6 The speed of sound in air is less than the speed of light in air. This can be seen, for example, during a thunderstorm. You can see the lightning before you hear the thunder (unless the storm is overhead).

7

8 Speed of sound = 340 m/s Speed of light =300 000 000 m/s =3 x 10 8 m/s Speed of light is MUCH FASTER.

9 Methods for Measuring the Speed of Sound in Air

10 When measuring the speed of sound we need a DISTANCE and a TIME.

11 Method 1 1.A pupil with a source of sound (e.g. cymbals) stands at one end of a field. 2.At the other end is a pupil with a stop-watch. 3.The length of the field is measured in metres. 4.The timekeeper starts the watch when they see the cymbals coming together. 5.When the timekeeper hears the sound, the watch is stopped and the time noted in seconds.

12 Pupil with cymbals Pupil with stop-watch There will always be an uncertainty with this – so repeat experiment and take an average (mean) time. Then use d = vt to calculate speed of sound. Distance

13 Method 2 A more accurate method uses a computer and timer interface to measure the time interval. Distance Hammer Metal Plate Microphone YMicrophone X Timer / Computer

14 1.The distance between the microphones is measured with a metre stick. 2.Hitting a metal plate with the hammer makes a loud sound. 3.When the sound reaches microphone X, the timer starts timing. 4.When the sound reaches microphone Y, the timer stops timing.

15 Typical Results Distance between microphones = 1.0 m Time on timer = 3 ms = 0.003 s (ms is a millisecond which is 1/1000 s) Speed of sound = distance / time = 1 / 0.003 = 330 m/s

16 2005 Q15

17 Video – Calculating Speed http://www.bbc.co.uk/scotland/learning/lear ningzone/clips/23 http://www.bbc.co.uk/scotland/learning/lear ningzone/clips/23

Download ppt "Waves and Radiation Wave Parameters and Behaviours."

Similar presentations

Lightning is seen before thunder is heard because 1.Sound travels faster than light 2.The thunder has a greater distance to travel than the lightning 3.Light.

Lightning is seen before thunder is heard because 1.Sound travels faster than light 2.The thunder has a greater distance to travel than the lightning 3.Light.
Waves/Sound. The Nature of Waves What is a wave? –A wave is a repeating ____________ or ____________ that transfers _________ through ________or_________.

Waves/Sound. The Nature of Waves What is a wave? –A wave is a repeating ____________ or ____________ that transfers _________ through ________or_________.
Waves Chapter 8 Waves.

Waves Chapter 8 Waves.
SOUND WAVES.

SOUND WAVES.
Waves and Energy Transfer Chapter 15 pages 250-265.

Waves and Energy Transfer Chapter 15 pages
Do Now: Identify the type of wave Click to replay

Do Now: Identify the type of wave Click to replay
Learning Goals: Define wavelength, frequency, period, and amplitude. Describe the relationship between frequency and wavelength. Explain how a wave’s energy.

Learning Goals: Define wavelength, frequency, period, and amplitude. Describe the relationship between frequency and wavelength. Explain how a wave’s energy.
IPC Notes The Nature of Waves. A wave is a repeating disturbance or movement that transfers energy through matter or space. ex) light, sound & radio.

IPC Notes The Nature of Waves. A wave is a repeating disturbance or movement that transfers energy through matter or space. ex) light, sound & radio.
SPH3U Exam Review Waves and Sound.

SPH3U Exam Review Waves and Sound.
The Nature of Sound https://www.youtube.com/watch?v=7cDAYFTXq3E.

The Nature of Sound
Waves Transferring Energy. Waves: traveling disturbance that carries energy from one place to another Waves travel through water, but they do not carry.

Waves Transferring Energy. Waves: traveling disturbance that carries energy from one place to another Waves travel through water, but they do not carry.
Waves.

Waves.
Electromagnetic Radiation The speed of electromagnetic radiation (speed of light) is constant at 2.998 x 10 m/s – We’ll express it as 3x10 m/s – The symbol.

Electromagnetic Radiation The speed of electromagnetic radiation (speed of light) is constant at x 10 m/s – We’ll express it as 3x10 m/s – The symbol.
Measuring the Speed of Sound

Measuring the Speed of Sound
20 pt 30 pt 40 pt 50 pt 10 pt 20 pt 30pt 40 pt 50 pt 10 pt 20 pt 30 pt 40 pt 50 pt 10 pt Sound.

20 pt 30 pt 40 pt 50 pt 10 pt 20 pt 30pt 40 pt 50 pt 10 pt 20 pt 30 pt 40 pt 50 pt 10 pt Sound.
Waves 5/22/2012. Waves Waves travel and transfer energy in an oscillating fashion (they wiggle). The amplitude, y, of a wave describes its height from.

Waves 5/22/2012. Waves Waves travel and transfer energy in an oscillating fashion (they wiggle). The amplitude, y, of a wave describes its height from.
WAVES AS 2.3: Demonstrate an understanding of wave phenomenon.

WAVES AS 2.3: Demonstrate an understanding of wave phenomenon.
Waves.

Waves.
 Waves  What are they?  How is energy transferred?  Medium  Describe  Mechanical Wave  Describe  Two types  Transverse Wave  Describe  Parts.

 Waves  What are they?  How is energy transferred?  Medium  Describe  Mechanical Wave  Describe  Two types  Transverse Wave  Describe  Parts.
Waves Introduction Chapter 10 Section 1 and 2 Physics Standard 4.

Waves Introduction Chapter 10 Section 1 and 2 Physics Standard 4.

Similar presentations

Ads by Google