Konsep Dasar Komunikasi Data Ir. Hary Nugroho MT.

Simplified Communications Model - Diagram

Protocols in Simplified Architecture

Data Transmission

The Successful transmission of data depends principally on two factor : The quality of the signal being transmitted The characteristics of transmission medium

Terminology (1) Transmitter Receiver Medium Guided medium e.g. twisted pair, optical fiber Unguided medium e.g. air, water, vacuum

Terminology (2) Direct link Point-to-point Multi-point No intermediate devices Point-to-point Only 2 devices share link Multi-point More than two devices share the link

Terminology (3) Simplex Half duplex Full duplex One direction e.g. Television Half duplex Either direction, but only one way at a time e.g. police radio Full duplex Both directions at the same time e.g. telephone

Frequency, Spectrum and Bandwidth Time domain concepts Analog signal Various in a smooth way over time Digital signal Maintains a constant level then changes to another constant level Periodic signal Pattern repeated over time Aperiodic signal Pattern not repeated over time

Analogue & Digital Signals

Periodic Signals s(t + T) = s(t) - ~ < t < + ~

Sine Wave Peak Amplitude (A) Frequency (f) Phase () maximum strength of signal volts Frequency (f) Rate of change of signal Hertz (Hz) or cycles per second Period = time for one repetition (T) T = 1/f Phase () Relative position in time

Varying Sine Waves s(t) = A sin(2ft +)

Wavelength Distance occupied by one cycle Distance between two points of corresponding phase in two consecutive cycles  Assuming signal velocity v  = vT f = v c = 3*108 ms-1 (speed of light in free space)

Frequency Domain Concepts Signal usually made up of many frequencies Components are sine waves Can be shown (Fourier analysis) that any signal is made up of component sine waves Can plot frequency domain functions

Addition of Frequency Components (T=1/f)

Contoh Jika gelombang memiliki perioda 1 s maka frekuensinya adalah 1 Hz Jika periodanya 1 ms maka frekuensinya adalah 1 Khz Jika sebuah gelombang memiliki perioda 100 ms, berapa frekuensi gelombang tersebut dalam kilohertz 100 ms = 100 x 10e-3 s = 10e-1 s F = 1/T = 1/10e-1 = 10 Hertz = 10e-2 Khz

Frequency Domain Representations

Spectrum & Bandwidth Often just bandwidth Spectrum Absolute bandwidth range of frequencies contained in signal Absolute bandwidth width of spectrum Effective bandwidth Often just bandwidth Narrow band of frequencies containing most of the energy DC Component Component of zero frequency

Signal with DC Component

Data Rate and Bandwidth Any transmission system has a limited band of frequencies This limits the data rate that can be carried

Analog and Digital Data Transmission Definition : Data Entities that convey meaning Signals Electric or electromagnetic representations of data Transmission Communication of data by propagation and processing of signals

Analog and Digital Data Continuous values within some interval e.g. sound, video Digital Discrete values e.g. text, integers

Acoustic Spectrum (Analog)

Analog and Digital Signals Means by which data are propagated Analog Continuously variable Various media wire, fiber optic, space Speech bandwidth 100Hz to 7kHz Telephone bandwidth 300Hz to 3400Hz Video bandwidth 4MHz Digital Use two DC components

Advantages & Disadvantages of Digital Cheaper Less susceptible to noise Greater attenuation Pulses become rounded and smaller Leads to loss of information

Attenuation of Digital Signals

Example #1 Components of Speech Frequency range (of hearing) 20Hz-20kHz Speech 100Hz-7kHz Easily converted into electromagnetic signal for transmission Sound frequencies with varying volume converted into electromagnetic frequencies with varying voltage Limit frequency range for voice channel 300-3400Hz

Conversion of Voice Input into Analog Signal

Example #1 Video Components USA - 483 lines scanned per frame at 30 frames per second 525 lines but 42 lost during vertical retrace So 525 lines x 30 scans = 15750 lines per second 63.5s per line 11s for retrace, so 52.5 s per video line Max frequency if line alternates black and white Horizontal resolution is about 450 lines giving 225 cycles of wave in 52.5 s Max frequency of 4.2MHz

Example #1 Binary Digital Data From computer terminals etc. Two dc components Bandwidth depends on data rate

Conversion of PC Input to Digital Signal

Data and Signals Usually use digital signals for digital data and analog signals for analog data Can use analog signal to carry digital data Modem Can use digital signal to carry analog data Compact Disc audio

Analog Signals Carrying Analog and Digital Data

Digital Signals Carrying Analog and Digital Data

Analog Transmission Analog signal transmitted without regard to content May be analog or digital data Attenuated over distance Use amplifiers to boost signal Also amplifies noise

Digital Transmission Concerned with content Integrity endangered by noise, attenuation etc. Repeaters used Repeater receives signal Extracts bit pattern Retransmits Attenuation is overcome Noise is not amplified

Advantages of Digital Transmission Digital technology Low cost LSI/VLSI technology Data integrity Longer distances over lower quality lines Capacity utilization High bandwidth links economical High degree of multiplexing easier with digital techniques Security & Privacy Encryption Integration Can treat analog and digital data similarly

Transmission Impairments Signal received may differ from signal transmitted Analog - degradation of signal quality Digital - bit errors Caused by Attenuation and attenuation distortion Delay distortion Noise

Attenuation Signal strength falls off with distance Depends on medium Received signal strength: must be enough to be detected must be sufficiently higher than noise to be received without error Attenuation is an increasing function of frequency

Delay Distortion Only in guided media Propagation velocity varies with frequency

Noise (1) Additional signals inserted between transmitter and receiver Thermal Due to thermal agitation of electrons Uniformly distributed White noise Intermodulation Signals that are the sum and difference of original frequencies sharing a medium

Noise (2) Crosstalk Impulse A signal from one line is picked up by another Impulse Irregular pulses or spikes e.g. External electromagnetic interference Short duration High amplitude

Channel Capacity Data rate Bandwidth In bits per second Rate at which data can be communicated Bandwidth In cycles per second of Hertz Constrained by transmitter and medium

Nyquist Bandwidth If rate of signal transmission is 2B then signal with frequencies no greater than B is sufficient to carry signal rate Given bandwidth B, highest signal rate is 2B Given binary signal, data rate supported by B Hz is 2B bps Can be increased by using M signal levels C= 2B log2M

Shannon Capacity Formula Consider data rate,noise and error rate Faster data rate shortens each bit so burst of noise affects more bits At given noise level, high data rate means higher error rate Signal to noise ration (in decibels) SNRdb=10 log10 (signal/noise) Capacity C=B log2(1+SNR) This is error free capacity

Required Reading Stallings chapter 3

Transmission Media

Overview Guided - wire Unguided - wireless Characteristics and quality determined by medium and signal For guided, the medium is more important For unguided, the bandwidth produced by the antenna is more important Key concerns are data rate and distance

Design Factors Bandwidth Transmission impairments Interference Higher bandwidth gives higher data rate Transmission impairments Attenuation Interference Number of receivers In guided media More receivers (multi-point) introduce more attenuation

Electromagnetic Spectrum

Guided Transmission Media Twisted Pair Coaxial cable Optical fiber

Transmission Characteristics of Guided Media     Frequency Range Typical Attenuation Typical Delay Repeater Spacing Twisted pair (with loading) 0 to 3.5 kHz 0.2 dB/km @ 1 kHz 50 µs/km 2 km Twisted pairs (multi-pair cables) 0 to 1 MHz 0.7 dB/km @ 1 kHz 5 µs/km Coaxial cable 0 to 500 MHz 7 dB/km @ 10 MHz 4 µs/km 1 to 9 km Optical fiber 186 to 370 THz 0.2 to 0.5 dB/km 40 km

Twisted Pair

Twisted Pair - Applications Most common medium Telephone network Between house and local exchange (subscriber loop) Within buildings To private branch exchange (PBX) For local area networks (LAN) 10Mbps or 100Mbps

Twisted Pair - Pros and Cons Cheap Easy to work with Low data rate Short range

Twisted Pair - Transmission Characteristics Analog Amplifiers every 5km to 6km Digital Use either analog or digital signals repeater every 2km or 3km Limited distance Limited bandwidth (1MHz) Limited data rate (100MHz) Susceptible to interference and noise

Near End Crosstalk Coupling of signal from one pair to another Coupling takes place when transmit signal entering the link couples back to receiving pair i.e. near transmitted signal is picked up by near receiving pair

Unshielded and Shielded TP Unshielded Twisted Pair (UTP) Ordinary telephone wire Cheapest Easiest to install Suffers from external EM interference Shielded Twisted Pair (STP) Metal braid or sheathing that reduces interference More expensive Harder to handle (thick, heavy)

UTP Categories Cat 3 Cat 4 Cat 5 Cat 5E (Enhanced) –see tables Cat 6 up to 16MHz Voice grade found in most offices Twist length of 7.5 cm to 10 cm Cat 4 up to 20 MHz Cat 5 up to 100MHz Commonly pre-installed in new office buildings Twist length 0.6 cm to 0.85 cm Cat 5E (Enhanced) –see tables Cat 6 Cat 7

Comparison of Shielded and Unshielded Twisted Pair   Attenuation (dB per 100 m) Near-end Crosstalk (dB) Frequency (MHz) Category 3 UTP Category 5 UTP 150-ohm STP 1 2.6 2.0 1.1 41 62 58 4 5.6 4.1 2.2 32 53 16 13.1 8.2 4.4 23 44 50.4 25 — 10.4 6.2 47.5 100 22.0 12.3 38.5 300 21.4 31.3

Twisted Pair Categories and Classes   Category 3 Class C Category 5 Class D Category 5E Category 6 Class E Category 7 Class F Bandwidth 16 MHz 100 MHz 200 MHz 600 MHz Cable Type UTP UTP/FTP SSTP Link Cost (Cat 5 =1) 0.7 1 1.2 1.5 2.2

Coaxial Cable

Coaxial Cable Applications Most versatile medium Television distribution Ariel to TV Cable TV Long distance telephone transmission Can carry 10,000 voice calls simultaneously Being replaced by fiber optic Short distance computer systems links Local area networks

Coaxial Cable - Transmission Characteristics Analog Amplifiers every few km Closer if higher frequency Up to 500MHz Digital Repeater every 1km Closer for higher data rates

Optical Fiber

Optical Fiber - Benefits Greater capacity Data rates of hundreds of Gbps Smaller size & weight Lower attenuation Electromagnetic isolation Greater repeater spacing 10s of km at least

Optical Fiber - Applications Long-haul trunks Metropolitan trunks Rural exchange trunks Subscriber loops LANs

Optical Fiber - Transmission Characteristics Act as wave guide for 1014 to 1015 Hz Portions of infrared and visible spectrum Light Emitting Diode (LED) Cheaper Wider operating temp range Last longer Injection Laser Diode (ILD) More efficient Greater data rate Wavelength Division Multiplexing

Optical Fiber Transmission Modes

Frequency Utilization for Fiber Applications Wavelength (in vacuum) range (nm) Frequency range (THz) Band label Fiber type Application 820 to 900 366 to 333   Multimode LAN 1280 to 1350 234 to 222 S Single mode Various 1528 to 1561 196 to 192 C WDM 1561 to 1620 185 to 192 L

Attenuation in Guided Media

Wireless Transmission Frequencies 2GHz to 40GHz Microwave Highly directional Point to point Satellite 30MHz to 1GHz Omnidirectional Broadcast radio 3 x 1011 to 2 x 1014 Infrared Local

Antennas Electrical conductor (or system of..) used to radiate electromagnetic energy or collect electromagnetic energy Transmission Radio frequency energy from transmitter Converted to electromagnetic energy By antenna Radiated into surrounding environment Reception Electromagnetic energy impinging on antenna Converted to radio frequency electrical energy Fed to receiver Same antenna often used for both

Radiation Pattern Power radiated in all directions Not same performance in all directions Isotropic antenna is (theoretical) point in space Radiates in all directions equally Gives spherical radiation pattern

Parabolic Reflective Antenna Used for terrestrial and satellite microwave Parabola is locus of point equidistant from a line and a point not on that line Fixed point is focus Line is directrix Revolve parabola about axis to get paraboloid Cross section parallel to axis gives parabola Cross section perpendicular to axis gives circle Source placed at focus will produce waves reflected from parabola in parallel to axis Creates (theoretical) parallel beam of light/sound/radio On reception, signal is concentrated at focus, where detector is placed

Parabolic Reflective Antenna

Antenna Gain Measure of directionality of antenna Power output in particular direction compared with that produced by isotropic antenna Measured in decibels (dB) Results in loss in power in another direction Effective area relates to size and shape Related to gain

Terrestrial Microwave Parabolic dish Focused beam Line of sight Long haul telecommunications Higher frequencies give higher data rates

Satellite Microwave Satellite is relay station Satellite receives on one frequency, amplifies or repeats signal and transmits on another frequency Requires geo-stationary orbit Height of 35,784km Television Long distance telephone Private business networks

Satellite Point to Point Link

Satellite Broadcast Link

Broadcast Radio Omnidirectional FM radio UHF and VHF television Line of sight Suffers from multipath interference Reflections

Infrared Modulate noncoherent infrared light Line of sight (or reflection) Blocked by walls e.g. TV remote control, IRD port

Wireless Propagation Signal travels along three routes Ground wave Follows contour of earth Up to 2MHz AM radio Sky wave Amateur radio, BBC world service, Voice of America Signal reflected from ionosphere layer of upper atmosphere (Actually refracted) Line of sight Above 30Mhz May be further than optical line of sight due to refraction More later…

Ground Wave Propagation

Sky Wave Propagation

Line of Sight Propagation

Refraction Velocity of electromagnetic wave is a function of density of material ~3 x 108 m/s in vacuum, less in anything else As wave moves from one medium to another, its speed changes Causes bending of direction of wave at boundary Towards more dense medium Index of refraction (refractive index) is Sin(angle of incidence)/sin(angle of refraction) Varies with wavelength May cause sudden change of direction at transition between media May cause gradual bending if medium density is varying Density of atmosphere decreases with height Results in bending towards earth of radio waves

Optical and Radio Horizons

Line of Sight Transmission Free space loss Signal disperses with distance Greater for lower frequencies (longer wavelengths) Atmospheric Absorption Water vapour and oxygen absorb radio signals Water greatest at 22GHz, less below 15GHz Oxygen greater at 60GHz, less below 30GHz Rain and fog scatter radio waves Multipath Better to get line of sight if possible Signal can be reflected causing multiple copies to be received May be no direct signal at all May reinforce or cancel direct signal Refraction May result in partial or total loss of signal at receiver

Free Space Loss

Multipath Interference

Required Reading Stallings Chapter 4