S.G. Telecommunications Revision for Final Exam
What is the section about ? Speed of Sound Speed of Light Wave Patterns Frequency & Wavelength Reflection Diffraction Radio Waves & Microwaves Colour Mixing Radio Telephones Television Optical Fibres Satellites
Sound and Light Speed of Sound is 340 metres per second Speed of Light is 300,000,000 m/s So light takes much less time to travel any distance than sound does speed = distance ÷ time
Wave Terms ‘amplitude’ means ‘height of wave from middle to top of crest” ‘wavelength’ means ‘distance from any point on a wave to the same point on the next wave’ ‘frequency’ means ‘number of waves each second’
Frequency To calculate frequency, use this equation frequency = number of waves ÷ time NOTE : This equation is NOT in the data booklet
Oscilloscope Traces Which wave is loudest ? Which wave has the smallest amplitude ? Which wave has the highest frequency ? Which wave has the longest wavelength ?
Speed of waves There are two equations in the data book which you may need distance = speed x time ( d = vt ) speed = frequency x wavelength ( v = f )
Telephone Transmitter Microphone in mouthpiece Turns sound energy to electrical energy Electrical signals travel through wires In mobile phone, electrical signals turned to radio signals ( microwaves ) Sent out from the aerial Travel through the air at speed of light
Telephone Receiver Components Aerial - picks up many radio signals Tuner - picks out the radio signal you want Decoder - splits signal from the carrier wave Power supply - supplies energy Amplifier - adds energy to the signal Loudspeaker- turns electrical signal into sound
TV Receiver Components signal has two parts sound signal picture signal ( vision ) sent separately aerial picks up both tuner picks out both then sound and vision have separate components decoder for each part amplifier for each part loudspeaker for sound picture tube for vision picture tube contains electrons guns to scan the screen dots on screen glow when electrons hit them
Colour TV Coloured light emitted when electrons hit dots on screen red, green and blue light only mixing red and green in equal intensities gives yellow mixing red and blue in equal intensities gives magenta mixing blue and green in equal intensities gives cyan mixing R, G and B in equal intensities gives white all switched off gives black mixing R, G and B in unequal intensities gives other colours
Diffraction This is when waves bend round things Radio waves ( big ) bend better than TV waves and microwaves ( smaller ) Radio waves can follow the curve of the earth TV waves and mobile phone waves only travel ‘in line of sight’ ( straight lines )
Reflection Always measure angles from the normal to the ray Reflected ray is always at the same angle on the other side of the normal angle of incidence = angle of reflection
Satellites Orbit the earth above the atmosphere Geostationary - 24 hours above the equator Always above same point on earth’s surface Polar - not so high, period is smaller Use curved reflectors to transmit and receive signals
Curved Reflectors This shows a satellite receiver. It gathers signals over a large area and focusses them on to the aerial to strengthen the signal. In a transmitter, the arrows would be reversed
Optical Fibres Long, thin solid piece of glass or plastic Light signals travel through it at 2 x 10 8 m/s This is SLOWER than light through air Also SLOWER than electrical signals through metal cables Light undergoes Total Internal Reflection Many advantages : size, cost, signal capacity Used in Cable TV, Computer Networks
Total Internal Reflection Angle of incidence < 42 degrees, ray escapes from glass block Angle of incidence > 42 degrees, ray reflected back into glass
Other Things to study Amplitude modulation and frequency modulation Morse Code Persistence of vision ( Image retention )