Wireless Transmission The Electromagnetic Spectrum Radio Transmission Microwave Transmission Infrared and Millimeter Waves Lightwave Transmission.

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Presentation transcript:

Wireless Transmission The Electromagnetic Spectrum Radio Transmission Microwave Transmission Infrared and Millimeter Waves Lightwave Transmission

Wireless There is an opinion that the future holds only two kinds of communication: fiber and wireless. All fixed (i.e., non-mobile) computers, telephones, faxes, and so on will use fiber, and all mobile ones will use wireless Wireless has advantages when the terrain (mountains, jungles, swamps, etc.) does not allow fiber

The Electromagnetic Spectrum Main terms: – the number of oscillations per second of a wave is called its frequency, f, and is measured in Hz – the distance over which the wave's shape repeats is called the wavelength, which is universally designated by the Greek letter λ (lambda) the electromagnetic waves can be broadcast efficiently and received by the antenna (of the appropriate size) of the receiver, some distance away

Frequency, wavelength Shorter wavelength – higher frequency Longer wavelength – lower frequency c - speed of light - approximately 3 x 10 8 m/sec, in copper or fiber the speed slows to about 2/3 of this value λ* f = c

Frequency, wavelength c is a constant, if we know f, we can find λ, and vice versa as a rule of thumb, when λ is in meters and f is in MHz, λ*f ≈300 Examples: 100 MHz waves are about 3 meters long 1 GHz (1000 MHz) waves are 0.3-meters long 0.1-meter waves have a frequency of 3 GHz (3000 MHz)

The Electromagnetic Spectrum

The radio, microwave, infrared, and visible light portions of the spectrum can all be used for transmitting information by modulating the amplitude, frequency, or phase of the waves Ultraviolet light, X-rays, and gamma rays would be even better, due to their higher frequencies, but they are hard to produce and modulate, do not propagate well through buildings, and are dangerous to living things official names and are based on the wavelengths, so the LF (low frequency) band goes from 1 km to 10 km (approximately 30 kHz to 300 kHz)

The Electromagnetic Spectrum LF, MF, and HF refer to Low, Medium, and High frequency, then come VHF, UHF, SHF, EHF, THF corresponding to Very, Ultra, Super, Extremely, and Tremendously … High Frequency bands The amount of information that an electromagnetic wave can carry is related to its bandwidth (the difference between the upper and lower frequencies in a continuous set of frequencies) With current technology few bits per Hertz at low frequencies can be encoded, but often as many as 8 at high frequencies

Bandwidth A key characteristic of bandwidth is that a band of a given width can carry the same amount of information, regardless of where that band is located in the frequency spectrum For example, a 3 kHz band can carry a telephone conversation whether that band is at baseband (as in a POTS telephone line) or modulated to some higher frequency given the width of a wavelength band, Δλ, we can compute the corresponding frequency band, Δf, and from that the data rate the band can produce The wider the band, the higher the data rate

Frequency bands Most transmissions use a narrow frequency band (i.e., Δf/f 1) to get the best reception (many watts/Hz) In some cases, a wide band is used, with two variations 1) frequency hopping spread spectrum - the transmitter hops from frequency to frequency hundreds of times per second; popular for military communication because it makes transmissions hard to detect and next to impossible to jam; also and Bluetooth use it 2) direct sequence spread spectrum, which spreads the signal over a wide frequency band - dominant with the third generation mobile phones

Radio Transmission Radio waves are easy to generate, can travel long distances, and can penetrate buildings easily, so they are widely used for communication At low frequencies, radio waves pass through obstacles well, but the power falls off sharply with distance from the source, roughly as 1/r 2 in air At high frequencies, radio waves tend to travel in straight lines and bounce off obstacles, absorbed by rain At all frequencies, radio waves are subject to interference from motors and other electrical equipment

Radio Transmission In the VLF, LF, and MF bands, radio waves follow the ground waves can be detected for perhaps 1000 km at the lower frequencies Radio waves pass through buildings easily - portable radios work indoors main problem with using these bands for data communication is their low bandwidth

Radio Transmission (a) In the VLF, LF, and MF bands, radio waves follow the curvature of the earth. (b) In the HF band, they bounce off the ionosphere.

Radio Transmission In the HF and VHF bands, the ground waves tend to be absorbed by the earth. However, the waves that reach the ionosphere, a layer of charged particles circling the earth at a height of 100 to 500 km, are refracted by it and sent back to earth Under certain atmospheric conditions, the signals can bounce several times. Amateur radio operators (hams) use these bands to talk long distance. The military also communicate in the HF and VHF bands

Microwave Transmission Above 100 MHz, the waves travel in nearly straight lines and can therefore be narrowly focused Concentrating all the energy into a small beam by means of a parabolic antenna (like satellite TV dish) gives a much higher signal-to-noise ratio, but the transmitting and receiving antennas must be accurately aligned with each other multiple transmitters lined up in a row can communicate with multiple receivers in a row without interference

Microwave Transmission Repeaters are needed periodically The distance between repeaters goes up very roughly with the square root of the tower height - for 100-meter-high towers, repeaters can be spaced 80 km apart microwaves do not pass through buildings well The demand for more and more spectrum drives operators to yet higher frequencies. Bands up to 10 GHz are now in routine use, but at about 4 GHz a new problem sets in: absorption by water - only solution is to shut off links that are being rained on and route around them

The Politics of the Electromagnetic Spectrum To prevent total chaos, there are national and international agreements about who gets to use which frequencies National governments allocate spectrum for AM and FM radio, television, and mobile phones, as well as for telephone companies, police, maritime, navigation, military, government, and many other competing users Worldwide, an agency of ITU-R (WARC) tries to coordinate this allocation so devices that work in multiple countries can be manufactured (International Telecommunication Union)

The Politics of the Electromagnetic Spectrum Even when part of the spectrum has been allocated to some use (e.g. mobile phones) there is the additional issue of who is allowed to use which frequencies o By explanation that “X” is serving the best o By lottery o By auction not allocating - let everyone transmit at will

The Politics of the Electromagnetic Spectrum When there is no allocation, the power used is to be regulated so that stations have such a short range they do not interfere with each other Accordingly, most governments have set aside some frequency bands, called the ISM (Industrial, Scientific, Medical) bands for unlicensed usage o Garage door openers, cordless phones, radio- controlled toys, wireless mice, and numerous other wireless household devices use the ISM bands o To minimize interference between these uncoordinated devices all devices in the ISM bands use spread spectrum techniques

The Politics of the Electromagnetic Spectrum The ISM bands in the United States.

Infrared and Millimeter Waves Unguided infrared and millimeter waves are widely used for short-range communication The remote controls used on televisions, VCRs, and stereos all use infrared communication These waves are: (+) - relatively directional, cheap, and easy to build (-) - they do not pass through solid objects (but is also a (+) as they don’t interfere with similar systems close by

Lightwave Transmission Connect the LANs in two buildings via lasers mounted on their rooftops optical signaling using lasers is inherently unidirectional, so each building needs its own laser and its own photodetector – this approach offers very high bandwidth and very low cost A disadvantage is that laser beams cannot penetrate rain or thick fog, but they normally work well on sunny days

Lightwave Transmission Convection currents can interfere with laser communication systems. A bidirectional system with two lasers is pictured here.