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Fundamentals of Microwave & Satellite Technologies

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Presentation on theme: "Fundamentals of Microwave & Satellite Technologies"— Presentation transcript:

1 Fundamentals of Microwave & Satellite Technologies
Telekomunikasi Dasar

2 Historical Perspective
Founded during WWII Used for long-haul telecommunications Displaced by fiber optic networks Still viable for right-of-way bypass and geographic obstruction avoidance

3 Microwave Spectrum Range is approximately 1 GHz to 40 GHz
Total of all usable frequencies under 1 GHz gives a reference on the capacity of in the microwave range

4 Microwave Impairments
Equipment, antenna, and waveguide failures Fading and distortion from multipath reflections Absorption from rain, fog, and other atmospheric conditions Interference from other frequencies

5 Microwave Engineering Considerations
Free space & atmospheric attenuation Reflections Diffractions Rain attenuation Skin affect Line of Sight (LOS) Fading Range Interference

6 Free Space & Atmospheric Attenuation
Free space & atmospheric attenuation is defined by the loss the signal undergoes traveling through the atmosphere. Changes in air density and absorption by atmospheric particles.

7 Reflections Reflections can occur as the microwave signal traverses a body of water or fog bank; cause multipath conditions

8 Diffraction Diffraction is the result of variations in the terrain the signal crosses

9 Rain Attenuation Raindrop absorption or scattering of the microwave signal can cause signal loss in transmissions.

10 Skin Affect Skin Affect is the concept that high frequency energy travels only on the outside skin of a conductor and does not penetrate into it any great distance. Skin Affect determines the properties of microwave signals.

11 Line of Sight Fresnel Zone Clearance
Fresnel Zone Clearance is the minimum clearance over obstacles that the signal needs to be sent over. Reflection or path bending will occur if the clearance is not sufficient.

12 LOS & FZC-cont’d Fresnel Zone D2 D1 D1 X D2 F x D 72.2 secret formula

13 Caused by multi-path reflections and heavy rains
Microwave Fading Normal Signal Reflective Path Caused by multi-path reflections and heavy rains

14 Range The distance a signal travels and its increase in frequency are inversely proportional Repeaters extend range Back-to-back antennas Reflectors

15 Range-cont’d High frequencies are repeated/received at or below one mile Lower frequencies can travel up to 100 miles but miles is the typical placement for repeaters

16 Interference Adjacent Channel Interference Overreach
digital not greatly affected Overreach caused by signal feeding past a repeater to the receiving antenna at the next station in the route. Eliminated by zigzag path alignment or alternate frequency use between adjacent stations

17 Components of a Microwave System
Digital Modem Radio Frequency (RF) Unit Antenna

18 Digital Modem The digital modem modulates the information signal (intermediate frequency or IF).

19 RF Unit IF is fed to the RF unit which is mounted as close physically to the antenna as possible (direct connect is optimal).

20 Antenna The antenna is a passive device that radiates the modulated signal. It is fed by direct connect of the RF unit, coaxial cable, or waveguides at higher frequencies.

21 Waveguides Waveguides are hollow channels of low-loss material used to direct the signal from the RF unit to the antenna.

22 Modulation Methods Primarily modulated today with digital FM or AM signals Digital signal remains quiet until failure threshold bit error rate renders it unusable

23 Bit Error Rate (BER) The BER is a performance measure of microwave signaling throughput 10 or one error per million transmitted bits of information Data fail over is at 10; voice traffic can withstand this error rate -6 -3

24 Diversity Space Diversity Frequency Diversity Hot Standby PRI

25 Space Diversity Normal Signal Faded Signal Transmitter Receiver

26 Space Diversity-cont’d
Space Diversity protects against multi-path fading by automatic switch over to another antenna place below the primary antenna. This is done at the BER failure point or signal strength attenuation point to the secondary antenna that is receiving the transmitted signal at a stronger power rating.

27 Frequency Diversity Transmitter Receiver Rx Frequency #1 Active Tx
Protect Tx Frequency #2 Transmitter Receiver

28 Frequency Diversity-cont’d
Frequency Diversity uses separate frequencies (dual transmit and receive systems); it monitors primary for fail over and switches to standby. Interference usually affects only one range of frequencies. Not allowed in non-carrier applications because of spectrum scarcity.

29 Hot Standby* failure switch Transmitter Receiver
Active Rx #1 System Tx Primary #1 Standby Rx #2 System Tx Standby #2 failure switch Transmitter Receiver *Hot standby is designed for equipment failure only

30 PRI (Primary Rate Interface)
PRI is an ISDN service providing user with 23,64 kbps for channel message and 1,64 kbps data channel for control & signalling. PRI is ISDN E1 interface. System Transmission Facilities System Receiver Facilities Connect to PRI interface & PSTN Connect to PRI interface & PSTN Transmitter Receiver To PSTN To PSTN

31 Percent Availability equals:
Availability Formula Percent Availability equals: 1 – (outage hours/8760 hours per year) Private microwaves have 99.99% availability

32 Microwave Path Analysis
Transmitter output power Antenna gain proportional to the physical characteristics of the antenna (diameter) Free space gain Antenna alignment factor Unfaded received signal level

33 Microwave Radio Applications

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38 Satellite Communications

39 Satellite-Related Terms
Earth Stations – antenna systems on or near earth Uplink – transmission from an earth station to a satellite Downlink – transmission from a satellite to an earth station Transponder – electronics in the satellite that convert uplink signals to downlink signals

40 Ways to Categorize Communications Satellites
Coverage area Global, regional, national Service type Fixed service satellite (FSS) Broadcast service satellite (BSS) Mobile service satellite (MSS) General usage Commercial, military, amateur, experimental

41 Classification of Satellite Orbits
Circular or elliptical orbit Circular with center at earth’s center Elliptical with one foci at earth’s center Orbit around earth in different planes Equatorial orbit above earth’s equator Polar orbit passes over both poles Other orbits referred to as inclined orbits Altitude of satellites Geostationary orbit (GEO) Medium earth orbit (MEO) Low earth orbit (LEO)

42 Geometry Terms Elevation angle - the angle from the horizontal to the point on the center of the main beam of the antenna when the antenna is pointed directly at the satellite Minimum elevation angle Coverage angle - the measure of the portion of the earth's surface visible to the satellite

43 Minimum Elevation Angle
Reasons affecting minimum elevation angle of earth station’s antenna (>0o) Buildings, trees, and other terrestrial objects block the line of sight Atmospheric attenuation is greater at low elevation angles Electrical noise generated by the earth's heat near its surface adversely affects reception

44 GEO Orbit Advantages of the the GEO orbit
No problem with frequency changes Tracking of the satellite is simplified High coverage area Disadvantages of the GEO orbit Weak signal after traveling over 35,000 km Polar regions are poorly served Signal sending delay is substantial GEO : Geosynchronous equatorial orbit

45 LEO Satellite Characteristics
Circular/slightly elliptical orbit under 2000 km Orbit period ranges from 1.5 to 2 hours Diameter of coverage is about 8000 km Round-trip signal propagation delay less than 20 ms Maximum satellite visible time up to 20 min System must cope with large Doppler shifts Atmospheric drag results in orbital deterioration LEO : Low earth orbit

46 LEO Categories Little LEOs Big LEOs Frequencies below 1 GHz
5MHz of bandwidth Data rates up to 10 kbps Aimed at paging, tracking, and low-rate messaging Big LEOs Frequencies above 1 GHz Support data rates up to a few megabits per sec Offer same services as little LEOs in addition to voice and positioning services

47 MEO Satellite Characteristics
Circular orbit at an altitude in the range of 5000 to 12,000 km Orbit period of 6 hours Diameter of coverage is 10,000 to 15,000 km Round trip signal propagation delay less than 50 ms Maximum satellite visible time is a few hours MEO : Medium Earth Orbit

48 SOURCE: WASHINGTON UNIV.
Satellite Systems GEO (22,300 mi., equatorial) high bandwidth, power, latency MEO LEO (400 mi.) low power, latency more satellites small footprint V-SAT (Very Small Aperture Terminal) private WAN SATELLITE MAP GEO M EO LEO SOURCE: WASHINGTON UNIV.

49 Geostationary Orbit SOURCE: BILL LUTHER, FCC

50 GPS Satellite Constellation
Global Positioning System Operated by USAF 28 satellites 6 orbital planes at a height of 20,200 km Positioned so a minimum of 5 satellites are visible at all times Receiver measures distance to satellite SOURCE: NAVSTAR

51 Frequency Bands Available for Satellite Communications

52 Satellite Link Performance Factors
Distance between earth station antenna and satellite antenna For downlink, terrestrial distance between earth station antenna and “aim point” of satellite Displayed as a satellite footprint (Figure 9.6) Atmospheric attenuation Affected by oxygen, water, angle of elevation, and higher frequencies

53 Satellite Footprint

54 Satellite Network Configurations

55 Capacity Allocation Strategies
Frequency division multiple access (FDMA) Time division multiple access (TDMA) Code division multiple access (CDMA)

56 Frequency-Division Multiplexing
Alternative uses of channels in point-to-point configuration 1200 voice-frequency (VF) voice channels One 50-Mbps data stream 16 channels of Mbps each 400 channels of 64 kbps each 600 channels of 40 kbps each One analog video signal Six to nine digital video signals

57 Frequency-Division Multiple Access
Factors which limit the number of subchannels provided within a satellite channel via FDMA Thermal noise Intermodulation noise Crosstalk

58 Forms of FDMA Fixed-assignment multiple access (FAMA)
The assignment of capacity is distributed in a fixed manner among multiple stations Demand may fluctuate Results in the significant underuse of capacity Demand-assignment multiple access (DAMA) Capacity assignment is changed as needed to respond optimally to demand changes among the multiple stations

59 FAMA-FDMA FAMA – logical links between stations are preassigned
FAMA – multiple stations access the satellite by using different frequency bands Uses considerable bandwidth

60 DAMA-FDMA Single channel per carrier (SCPC) – bandwidth divided into individual VF channels Attractive for remote areas with few user stations near each site Suffers from inefficiency of fixed assignment DAMA – set of subchannels in a channel is treated as a pool of available links For full-duplex between two earth stations, a pair of subchannels is dynamically assigned on demand Demand assignment performed in a distributed fashion by earth station using CSC

61 Reasons for Increasing Use of TDM Techniques
Cost of digital components continues to drop Advantages of digital components Use of error correction Increased efficiency of TDM Lack of intermodulation noise

62 FAMA-TDMA Operation Transmission in the form of repetitive sequence of frames Each frame is divided into a number of time slots Each slot is dedicated to a particular transmitter Earth stations take turns using uplink channel Sends data in assigned time slot Satellite repeats incoming transmissions Broadcast to all stations Stations must know which slot to use for transmission and which to use for reception

63 FAMA-TDMA Uplink

64 FAMA-TDMA Downlink


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