Boost Your Skills with On-Site Courses Tailored to Your Needs

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2 Boost Your Skills with On-Site Courses Tailored to Your Needs The Applied Technology Institute specializes in training programs for technical professionals. Our courses keep you current in the state-of-the-art technology that is essential to keep your company on the cutting edge in today s highly competitive marketplace. Since 1984, ATI has earned the trust of training departments nationwide, and has presented on-site training at the major Navy, Air Force and NASA centers, and for a large number of contractors. Our training increases effectiveness and productivity. Learn from the proven best. For a Free On-Site Quote Visit Us At: For Our Current Public Course Schedule Go To:

3 Outline PART 1: THE SPACECRAFT AND ITS ORBIT 1. Mission Analysis 2. Transfer Orbit 3. Orbital Perturbations and Stationkeeping 4. The Spacecraft Environment 5. Earth-Satellite Geometry 6. Constellation Design PART 2: PRINCIPLES OF SATELLITE COMMUNICATION 7. Signals and Spectra 8. Analog Modulation 9. Digital Modulation 10. Coding 11. The Electromagnetic Spectrum 12. The RF Link 13. Earth Stations 14. Multiple Access 15. Antennas 16. System Temperature 17. Polarization 18. Rain Loss PART 3: APPLICATIONS TO SATELLITE COMMUNICATION SYSTEMS 19. Link Budgets for Geostationary Satellites 20. Link Budgets for Nongeostationary Satellites 2 Satellite Engineering Research Corporation

4 The RF Link (Excerpt) 3 Satellite Engineering Research Corporation

5 Antenna pattern, beamwidth, and gain sidelobes main lobe Ω A = total solid angle of radiation Ω = solid angle between HP points D Ω 3 db points gain G α = half power beamwidth Ω A Beamwidth shows size of beam. λ HPBW = α = k = 70 D λ D Gain shows relative strength of radiation. The maximum (boresight) gain is 4π 4π 29,000 4π π D G = η* = η = = η A= η 2 2 ΩA Ω α λ λ where k = antenna taper factor Gain and beamwidth are linked: As the gain increases, the beamwidth decreases, and vice versa. 2 An isotropic antenna radiates equally in all directions like a light bulb Ω = 4 π where η*, η, η = measures of antenna efficiency 4 Satellite Engineering Research Corporation

6 Example: Earth terminal antenna Ku band downlink frequency f = 12 GHz 8 c 3 10 m/s λ = = = m 9 f Hz λ m HPBW = α = 70 = 70 = 0.35 D 5.0 m G 2 π D π 5.0 m = η = 0.60 = 237,000 λ m 2 [ G ] = 10log 10(237,000) = 53.7 db Prime Focus Feed; 5 meter reflector; Tx and Rx C-Band gain 46 db; Beamwidth = 1 o Ku-Band gain 54 db; Beamwidth = 0.4 o 5 Satellite Engineering Research Corporation

7 Equivalent isotropic radiated power (EIRP) The equivalent isotropic radiated power (EIRP) is the transmit power of a hypothetical antenna radiating equally in all directions (like a light bulb) so as to have the same power flux density over the coverage area as the actual antenna. The power flux density of the actual antenna is P η * P 4π P P Φ= = = η * = G S Ω d d d A in in in 2 2 t 2 ΩA 4π 4π where η* is the antenna power loss efficiency, P = η* P in is the transmitted power, S is the total coverage area at distance d, Ω A is the antenna beam solid angle, and G t = η* (4π / Ω A ) is the transmit gain. By the definition of EIRP Therefore, EIRP Φ= 2 4π d EIRP = Gt Pin The EIRP is the product of the antenna transmit gain and the power applied to the input terminals of the antenna. The antenna efficiency η* is absorbed in the definition of gain. 6 Satellite Engineering Research Corporation

8 Example 1 numeric form logarithmic (db) form G t = 100 [G t ] = 10 log 10 (100) = 20.0 db P in = 50 W [P in ] = 10 log 10 (50 W) = 17.0 dbw EIRP = G t P in [EIRP] = [G t ] + [P in ] = (100)(50 W) = 20.0 db dbw = 5000 W = 37.0 dbw 10 log 10 (5000 W) = 37.0 dbw 7 Satellite Engineering Research Corporation

9 Example 2 [P HPA ] = 10 log 10 (100 W) = 20 dbw [P in ] = [P HPA ] [L] = 20 dbw 1 db = 19 dbw [EIRP] = [G t ] + [P in ] = 60 db + 19 dbw = 79 dbw 8 Satellite Engineering Research Corporation

10 Figure of Merit (G / T) The ratio of the receive antenna gain G to the total system temperature T is called the figure of merit. [ G / T ] = [ G ] [ T ] (db/k) where [ G ] = receive antenna gain (db) [ T ] = total system temperature (dbk) The figure of merit is independent of the point where it is calculated. However, the gain and system temperature must be specified at the same point. Example: Suppose the antenna gain is 53.7 db and the system temperature is 150 K. Then [ T ] = 10 log 10 (150 K) = 21.7 dbk [ G / T ] = [ G ] [ T ] = 53.7 db 21.7 dbk = 32.0 db/k 9 Satellite Engineering Research Corporation

11 Satellite communications payload architecture 10 Satellite Engineering Research Corporation

12 Transponder 11 Satellite Engineering Research Corporation

13 Satellite transponder frequency plan (C-band) 12 Satellite Engineering Research Corporation

14 Began service: 7/ 97 Station-keeping ± 0.05 degrees Mission Life 12 years Transponders: MHz 4 54 MHz MHz Coverage: Continental US, Alaska, Hawaii, Puerto Rico, the Caribbean, and into Canada and Latin America. Markets: Strong broadcast and syndication neighborhood anchored by ABC and FOX; host to SNG, data, business television, Internet, direct-to-home programming and digital data applications Typical satellite data Telstar 5 97º W C/Ku band EIRP (dbw) C- band Kuband CONUS Alaska Hawaii Puerto Rico/U.S. Virgin Islands Mexico Southern Canada Caribbean Orbital Location 97 degrees W Transponders 24 C-band 4 Ku-band 24 Ku-band Useable Bandwidth 36 MHz 54 MHz 27 MHz Power 20 W nominal 100 W nominal 100 W nominal G/T (db/k) C- band Kuband CONUS Alaska Hawaii Saturation Flux Density - Typical CONUS -71 to -92 (dbw/m²) at C-band adjustable in 1 db steps -75 to -96 (dbw/m²) at Ku-band adjustable in 1 db steps Polarization Orthogonal linear polarization at C-band and Ku-band. Puerto Rico/U.S. Virgin Islands Mexico Southern Canada Caribbean Frequency Band 4/6 GHz and 12/14 GHz Ku-band Optional "Automatic Level Control" Mode Mitigates the effects of uplink rain fade by maintaining the transponder at a specific fixed operating point between saturation and 8 db input backoff. 13 Satellite Engineering Research Corporation

15 Satellite EIRP footprint P = 100 W [ P ] = 20 dbw [ G ] = 30 db [ EIRP ] = [ G ] + [ P ] = 30 db + 20 dbw = 50 dbw (COC) 14 Satellite Engineering Research Corporation

16 Satellite Figure of Merit G / T T = 630 K [ T ] = 28 dbk [ G ] = 30 db [ G / T ] = [ G ] [ T ] = 30 db 28 dbk = 2 db/k (COC) 15 Satellite Engineering Research Corporation

17 Earth-satellite geometry Telstar 5 97º W C / Ku band City/Country Latitude W Longitude Azimuth Elevation Anchorage, AK/USA Boston, MA/USA Calgary/Canada Dallas, TX/USA Guatemala City/Guatemala Halifax/Canada Havana/Cuba Honolulu, HI/USA Houston, TX/USA Jacksonville, FL/USA Los Angeles, CA/USA Merida/Mexico Mexico City/Mexico Example: Earth terminal in Los Angeles cosγ = cosφ cos λ = cos(34.03 )cos( ) = γ = sin λ sin Az = sinγ sin( ) = sin(39.38 ) = Miami, FL/USA Nassau/Bahamas Az = = New York, NY/USA Reno, NV/USA San Francisco, CA/USA San Juan/Puerto Rico Seattle, WA/USA Toronto/Canada Vancouver/Canada Washington, DC/USA cos γ RE / r tanθ = sinγ cos(39.38 ) (6378 km) /(42,164 km) = sin(39.38 ) = θ = Satellite Engineering Research Corporation

18 Free space loss The free space loss takes into account that electromagnetic waves spread out into spherical wavefronts as they propagate through space due to diffraction. L s 2 2 4π d 4π d f = = λ c 4π d 4π d [ Ls ] = 10 log10 = 20log10 λ λ For a geostationary satellite, the free space loss is on the order of 200 db (or a factor of ). The received power at the earth terminal is typically on the order of tens of picowatts Satellite Engineering Research Corporation

19 Example Problem: Determine the free space loss for a Ku band downlink between Telstar 5 at 97 W Longitude and Los Angeles if the frequency is 12 GHz and the angle of elevation is Solution: The wavelength is The slant range is 8 c 3 10 m/s λ = = = 9 f Hz m d = r ( R cos θ) R sinθ 2 2 E E = 2 2 (42,164 km) (6378 km cos44.4 ) 6378 km sin 44.4 r = orbit radius R E = Earth s radius θ = elevation angle = 37,453 km Thus L s 2 2 4π d 4π 37,453, 000 m = = = λ m 20 [ L s ] = 10 log 10( ) = db Satellite Engineering Research Corporation

20 Received carrier power Received carrier power C A P S L e = =Φ A e Transmit gain Receive gain G t 4π 4π d = η* = η* Ω S G Received carrier power r A 4π = A 2 e λ 2 Footprint area S 4π d =η * G Receiver equivalent area A e 2 = G λ r 4π t 2 C Gr ( G P ) G G = = = 4 π d / G η* L (4 π d/ λ) L L L 2 ( λ /4 π ) P 1 t in r EIRP 2 2 t s r Equivalent isotropic radiated power EIRP = Gt Pin Free space loss L s 4π d = λ 2 19 Satellite Engineering Research Corporation

21 Example Problem: Determine the received carrier power for the Ku band downlink between Telstar 5 and an Earth terminal in Los Angeles if the frequency is 12 GHz and the antenna has an efficiency of 0.60 and a diameter of 5.0 m. Allow a rain attenuation loss of 1.9 db, a gaseous atmospheric loss of 0.1 db, and a pointing loss of 0.2 db. Solution: The satellite EIRP in Los Angeles is 49.2 dbw. At 12 GHz, the antenna gain is 53.7 db and the free space loss is db. Therefore, the received carrier power is [ C] = [EIRP] + [ G ] [ L ] [ L ] [ L ] [ L ] r s r a p = 49.2 dbw db db 1.9 db 0.1 db 0.2 db = dbw Therefore, C = = = W W 33 pw 20 Satellite Engineering Research Corporation

22 Noise power Thermal noise power in bandwidth B N = N0 B= kb T B where the spectral noise density is N = 0 B k T for system temperature T and Boltzmann s constant is k B = W / K Hz [ k B ] = dbw / K Hz 21 Satellite Engineering Research Corporation

23 Link budget equation Carrier power Noise power C = B EIRP G LLL s r o N = k T B= N B r 0 Carrier to noise ratio Carrier to noise density ratio 0 C G = EIRP N T L L L k B s r o B C C G = B = EIRP N N T L L L k s r o B 22 Satellite Engineering Research Corporation

24 Link budget equation (continued) The link budget equation is expressed in logarithmic (db) form as follows (db values indicated by brackets): Uplink [ C/ N ] = [EIRP] + [ G/ T] [ L ] [ L ] [ L ] [ k ] 0 s r o B at satellite E/S satellite at uplink frequency Downlink [ C/ N ] = [EIRP] + [ G/ T] [ L ] [ L ] [ L ] [ k ] 0 s r o B at E/S satellite E/S at downlink frequency 23 Satellite Engineering Research Corporation

25 Combined uplink and downlink Only thermal noise (Average White Gaussian Noise) C C C = + N N N net up down (numeric) Include interference C C C C = + + N N N I net up down Noise power N = N B 0 C C 1 = N N B 0 24 Satellite Engineering Research Corporation

26 Power flux density The EIRP of the uplink Earth station antenna must be adjusted to match an acceptable power flux density (PFD) at the satellite. PFD EIRP 1 1 EIRP 1 1 =Φ= = d L L L L L π r s ( λ /4 π) r 2 [ Φ ] = [EIRP] [4 π d ] [ Lr ] [ L] or 2 [ Φ ] = [EIRP] [ Ls ] [ λ /4 π ] [ Lr ] [ L] 25 Satellite Engineering Research Corporation

27 Example Problem: For an uplink between an Earth station in Washington, DC and Telstar 5, the EIRP is 79.0 dbw, the slant range is 37,722 km, the rain attenuation is 5.9 db, and the antenna pointing loss is 0.2 db. Determine the power flux density incident on the satellite. Solution: 2 [ Φ ] = [EIRP] [4 π d ] [ Lr ] [ L] 10 { π 2 } = 79.0 dbw 10 log 4 (37,722,000 m) 5.9 db 0.2 db 2 = 89.6 dbw / m This PFD is within the specifications for Telstar 5. Saturation Flux Density - Typical CONUS -75 to -96 (dbw/m²) at Ku-band adjustable in 1 db steps Ku-band Optional "Automatic Level Control" Mode Mitigates the effects of uplink rain fade by maintaining the transponder at a specific fixed operating point between saturation and 8 db input backoff. 26 Satellite Engineering Research Corporation

28 Example link budget Signal architecture Information bit rate Mbps 22.5 dbhz 73.5 Modulation QPSK Coding V(7,1/2) Bits per symbol 2 Code rate 1/2 Satellite Name Telstar 5 Longitude deg 97.0 Transponder bandwidth MHz 27.0 EIRP dbw 49.2 G/T db/k 2.0 Percentage of raised cosine filtering 20 Noise bandwidth MHz 22.5 Occupied bandwidth MHz 27.0 BER Eb/No (uncoded) db 9.6 Coding gain db 5.1 Eb/No (ideal) db 4.5 Modem implementation loss db 0.5 Eb/No (required) db 5.0 C/No (required) dbhz Satellite Engineering Research Corporation

29 Example link budget (continued) Uplink Earth station transmit terminal City Washington Longitude deg 77.0 Latitude deg 38.5 Earth central angle deg 42.7 Elevation angle deg 40.8 Slant range km HPA Power W dbw 20.0 Antenna diameter m 9.2 Antenna half power beamwidth deg 0.16 Antenna efficiency 0.55 Antenna transmit gain dbw 60.0 Line loss db 1.0 EIRP dbw 79.0 Link calculation Frequency GHz 14.0 Wavelength m Earth station EIRP dbw 79.0 Satellite G/T db/k 2.0 Free space loss db Rain region D2 Availability percent Rain attenuation db 5.9 Antenna pointing error deg 0.02 Antenna pointing loss db 0.2 Boltzmann's constant dbw/k Hz C/No (uplink) dbhz 96.6 Noise bandwidth dbhz 73.5 C/N (uplink) db 23.1 Power flux density dbw/m Satellite Engineering Research Corporation

30 Example link budget (continued) Downlink Earth station receive terminal City Los Angeles Longitude deg Latitude deg 34.0 Earth central angle deg 39.4 Elevation angle deg 44.4 Slant range km Antenna diameter m 5.0 Antenna half power beamwidth deg 0.35 Antenna efficiency 0.60 Antenna receive gain db 53.7 Clear sky antenna noise temperature K 25 Receiver equivalent temperature K 125 System temperature K 150 dbk 21.8 G/T (clear sky) db/k 32.0 Link calculation Frequency GHz 12.0 Wavelength m Satellite EIRP dbw 49.2 Earth station G/T (clear sky) db/k 32.0 Free space loss db Rain region F Availability percent Rain attenuation db 1.9 Degradation in G/T db 2.2 Gaseous atmospheric loss db 0.1 Antenna pointing error deg 0.05 Antenna pointing loss db 0.2 Boltzmann's constant dbw/k Hz C/No (downlink) dbhz 99.9 Noise bandwidth dbhz 73.5 C/N (downlink) db Satellite Engineering Research Corporation

31 Example link budget (continued) Combined uplink and downlink C/N (uplink) db 23.1 C/N (downlink) db 26.3 C/I (adjacent satellite) db 20.0 C/I (cross polarization) db 24.0 C/N (net) db 16.7 Noise bandwidrh dbhz 73.5 C/No (net) dbhz 90.3 Information bit rate dbhz 73.5 Eb/No (available) db 16.7 Eb/No (required) db 5.0 C/No (required) dbhz 78.5 Margin db Satellite Engineering Research Corporation

32 Power levels in satellite link dbw Output of modulator and upconverter Power Level Uplink path (dbw) db Driver gain 20.0 db Earth station HPA gain 1.0 db Line loss db Earth station antenna gain 6.1 db Rain attenuation + other losses db Free space loss From 0 Satellite modulator 30.0 db Satellite receive antenna gain 69.0 db Receiver amplifier gain 57.0 db Satellite TWTA saturated gain db Output losses 29.2 db Satellite transmit antenna gain Earth Station EIRP = Uplink Satellite EIRP = To demodulator Downlink Downlink path db Free space loss 2.2 db Rain attenuation + other losses 53.7 db Earth station antenna gain 0.2 db Line loss 40.0 db LNA gain 35.0 db Downconverter and IF amplifier gain dbw Input to demodulator Transmit earth station Uplink path Satellite Downlink path Receive terminal 31 Satellite Engineering Research Corporation

33 Antenna half power beamwidth λ HPBW = α = k = D Antenna gain G c k fd 4π 4π 4π π D η* η η A η = = = = 2 ΩA Ω λ λ Free space loss L s RF link (summary) 2 2 4π d 4π d f = = λ c Carrier to noise density ratio C E G G P EIRP ( G / T) = R = = N N LL kt LLk b t r in r b 0 0 s B s B 2 α = half power beamwidth λ = wavelength f = frequency c = speed of light D = antenna diameter k = antenna taper factor η*, η, η = antenna efficiency factors Ω A = antenna beam solid angle d = slant range S = footprint area A = antenna area C = carrier power N 0 = noise density R b = information bit rate E b = energy per information bit EIRP = equivalent isotropic radiated power G t = transmit antenna gain G r = receive antenna gain P in = input power L s = free space loss L = net attenuative loss T = system noise temperature k B = Boltzmann s constant 32 Satellite Engineering Research Corporation

34 Boost Your Skills with On-Site Courses Tailored to Your Needs The Applied Technology Institute specializes in training programs for technical professionals. Our courses keep you current in the state-of-the-art technology that is essential to keep your company on the cutting edge in today s highly competitive marketplace. For 20 years, we have earned the trust of training departments nationwide, and have presented on-site training at the major Navy, Air Force and NASA centers, and for a large number of contractors. Our training increases effectiveness and productivity. Learn from the proven best. ATI s on-site courses offer these cost-effective advantages: You design, control, and schedule the course. Since the program involves only your personnel, confidentiality is maintained. You can freely discuss company issues and programs. Classified programs can also be arranged. Your employees may attend all or only the most relevant part of the course. Our instructors are the best in the business, averaging 25 to 35 years of practical, realworld experience. Carefully selected for both technical expertise and teaching ability, they provide information that is practical and ready to use immediately. Our on-site programs can save your facility 30% to 50%, plus additional savings by eliminating employee travel time and expenses. The ATI Satisfaction Guarantee: You must be completely satisfied with our program. We suggest you look at ATI course descriptions in this catalog and on the ATI website. Visit and bookmark ATI s website at for descriptions of all of our courses in these areas: Communications & Computer Programming Radar/EW/Combat Systems Signal Processing & Information Technology Sonar & Acoustic Engineering Spacecraft & Satellite Engineering I suggest that you read through these course descriptions and then call me personally, Jim Jenkins, at (410) , and I ll explain what we can do for you, what it will cost, and what you can expect in results and future capabilities. Our training helps you and your organization remain competitive in this changing world. Register online at or call ATI at or