satellite communication and deep space networks

1. S A T E L L I T E
C O M M U N I C A
T I O N
& D E E P
S P A C E
N E T W O R K S

2. CONTENTS
Satellite Communication
Introduction
Origin
Working
Advantages & Disadvantages
Applications
Elements
Deep Space Networks

3. Introduction
• Satellite is a microwave repeater in the space.
• There are about 750 satellites in the space, most of them are used
for communication.
• They are:
• Wide area coverage of the earth’s surface.
• Transmission delay is about 0.3 sec.
• Transmission cost is independent of distance.

4. What are Communication Satellites?
• Asatellite is an object that orbits another large object like planet.
• A communication satellite is a station in space that is used for
telecommunication, radio and television signals.
• The first satellite with radio transmitter was used in 1957.

5. The origin of Satellite
• The concept of using object in space to reflect signals for communication was proved
by Naval Research Lab in Washington D.C. when it use the Moon to establish a very
low data rate link between Washington and Hawaii in late 1940’s.
• Russian started the Space age by successfully launching SPUTNIK the first artificial
spacecraft to orbit the earth, which transmitted telemetry information for 21 days in
Oct. 1957.
• TheAmerican followed by launching an experimental satellite EXPLORER In 1958.
• In 1960 two satellite were deployed “Echo” & “Courier”
• In 1963 first GSO “Syncom” The first commercial GSO (Intelsat & Molnya) in
1965 these provides video (Television) and voice (Telephone)

6. Why Use Satellites?
• Satellite communication is just one example of wireless communication systems.
• Familiar examples of wireless systems are all around us, such as radio, television-
broadcasting, mobile and cordless telephones.
• These systems rely on a network of ground-based transmitters and receivers and for
this reason they are often referred to as “ terrestrial " systems.
• One major use of satellites familiar to everyone is satellite television broadcasting.
• Other applications of satellite communications include high speed internet,
telephony and corporate networks for multinational businesses.

7. How do satellites work?
• Two Stations on Earth want to communicate through radio broadcast but
are too far away to use conventional means.
• The two stations can use a satellite as a relay station for their
communication.
• One Earth Station sends a transmission to the satellite. This is called a
Uplink.
• The satellite Transponder converts the signal and sends it down to the
second earth station. This frequency is called a Downlink.

8. Transponder

9. HOW DO SATELLITES WORK?

10. Early satellites
• Telstar
• Allowed live transmission across theAtlantic
• Syncom 2
• First Geosynchronous satellite.
TELSTAR SYNCOM 2

11. ADVANTAGES OF SATELLITES
• The advantages of satellite communication over terrestrial communication are:
 The coverage area of a satellite greatly exceeds that of a terrestrial system.
 Transmission cost of a satellite is independent of the distance from the center of the
coverage area.
 Satellite to Satellite communication is very precise.
 Higher Bandwidths are available for use.
DISADVANTAGES OF SATELLITES
• The disadvantages of satellite communication:
 Launching satellites into orbit is costly.
 Satellite bandwidth is gradually becoming used up.
 There is a larger propagation delay in satellite communication than in terrestrial
communication.

12. ELEMENTS OF SATELLITE COMMUNICATION
• The basic elements of a communication satellite service are divided between;
– Space Segment
– Ground Segment
• The space segment consist of the spacecraft & launch mechanism.
• The ground segment comprises the earth station and network control center of entire
satellite system.

13. SPACE SEGMENT
• Space segment consist of a satellite in suitable orbit.
• Space segment classified on the basis of orbit.
• LEO
• MEO
• GEO
• MOLNIYA
• HAP

14. LOW EARTH ORBIT (LEO)
• LEO satellites are much closer to the earth than GEO satellites, ranging from 500 to 1,500 km
above the surface.
• LEO satellites don’t stay in fixed position relative to the surface, and are only visible for 15 to 20
minutes each pass.
• A network of LEO satellites is necessary for LEO satellites to be useful.
• Advantages
 A LEO satellite’s proximity to earth compared to a GEO satellite gives it a better signal strength and less
of a time delay, which makes it better for point to point communication.
 A LEO satellite’s smaller area of coverage is less of a waste of bandwidth.
• Disadvantages
 A network of LEO satellites is needed, which can be costly
 LEO satellites have to compensate for Doppler shifts cause by their relative movement.
 Atmospheric drag effects LEO satellites, causing gradual orbital deterioration.

15. MEDIUM EARTH ORBIT (MEO)
• A MEO satellite is in orbit somewhere between 8,000 km and 18,000 km above the earth’s
surface.
• MEO satellites are similar to LEO satellites in functionality.
• MEO satellites are visible for much longer periods of time than LEO satellites, usually
between 2 to 8 hours.
• MEO satellites have a larger coverage area than LEO satellites.
• Advantage
 A MEO satellite’s longer duration of visibility and wider footprint means fewer satellites are
needed in a MEO network than a LEO network.
• Disadvantage
 A MEO satellite’s distance gives it a longer time delay and weaker signal than a LEO satellite,
though not as bad as a GEO satellite.

16. GEOSTATIONARY EARTH ORBIT (GEO)
• These satellites are in orbit 35,863 km above the earth’s surface along the equator.
• Objects in Geostationary orbit revolve around the earth at the same speed as the earth
rotates. This means GEO satellites remain in the same position relative to the surface of
earth.
• Advantages
 A GEO satellite’s distance from earth gives it a large coverage area, almost a fourth of the earth’s
surface.
 GEO satellites have a 24 hour view of a particular area.
 These factors make it ideal for satellite broadcast and other multipoint applications.
• Disadvantages
 A GEO satellite’s distance also cause it to have both a comparatively weak signal and a time
delay in the signal, which is bad for point to point communication.
 GEO satellites, centered above the equator, have difficulty broadcasting signals to near polar
regions

17. OTHER ORBITS
• Molniya Orbit Satellites
 Used by Russia for decades.
 Molniya Orbit is an elliptical orbit. The satellite remains in a nearly fixed position relative to
earth for eight hours.
 A series of three Molniya satellites can act like a GEO satellite.
 Useful in near polar regions.
• High Altitude Platform (HAP)
 One of the newest ideas in satellite communication.
 A blimp or plane around 20 km above the earth’s surface is used as a satellite.
 HAPs would have very small coverage area, but would have a comparatively strong signal.
 Cheaper to put in position, but would require a lot of them in a network.

18. GROUND SEGMENT
• The ground Segment of each service has distinct characteristics.
• Services like;
– FSS
– BSS
– MSS
– Maritime,Aeronautical & Land base
– DBS etc..

19.  Service Types
• Fixed Service Satellites (FSS)
• Example: Point to Point Communication
• Broadcast Service Satellites (BSS)
• Example: Satellite Television/Radio(Dish TV, Tata sky, Videocon D2H etc)
• Also called Direct Broadcast Service (DBS).
• Mobile Service Satellites (MSS)
• Example: Satellite Phones

20. MAJOR CHALLENGES IN SATELLITE COMMUNICATION
• Positioning in orbit
• Stability
• Power
• Harsh Environment

21. APPLICATIONS
• Telephony
- Fixed points, earth station, Satellite, earth station, fixed points.
• Television & Radio
- e.g. Direct broadcast satellite (DBS) & Fixed service satellite (FFS)
• Mobile satellite technology
- Special antenna called mobile satellite antenna.
- No matter where or how this antenna is mounted on.
• Amateur radio
- Access to OSCAR satellite.
- Low earth orbits.
• Internet
- High Speed.
- Useful for far away places.
• Military
- Uses geostationary satellites.
- Example: The Defense Satellite Communications System (DSCS).

22. https://www.youtube.com/watch?v=vFypCugyFoM
https://www.youtube.com/watch?v=hXa3bTcIGPU

23. DEEP
SPACE
NETWORK
S

24. THE CHALLENGE
• Tracking and Communicating with Spacecraft beyond Earth Orbit :
– Lunar Exploration
– Planetary Exploration
– Interplanetary Exploration
– Astronomical Exploration
• DSNs include communication with satellites and spacecrafts active in the outer space
region as well as collecting radio and radar astronomy observations for the exploration
of solar system.

25. NASA DEEP SPACE NETWORK
• Three complexes, approximately 120°apart:
– Goldstone
– Madrid
– Canberra
• Functions
– Acquire telemetry data from spacecraft
– Transmit commands to spacecraft
– Gather science data radio astronomy (on space- available basis)
– Very Long Baseline Interferometry – determine location of radio sources
– Radio Science – determine transmission characteristics between ground and
spacecraft
– Monitor and Control of real-time data

26. OPERATIONAL CONCEPT
• Signals to/from Spacecraft are Line of Sight
• Coverage of DSN Stations overlap beyond
30,000km (18.000 miles), providing 8-14 hours of
daily view.
• This ensures reliable and useable two station
coverage for lunar and deep space coverage for
“uplinks” (transmission) to spacecraft and
“downlinks” (receive data) from spacecraft.

27. CANBERRA GROUND STATION COMPLEX
• One of three space communications complexes making up DSN
– multiple steerable antennae
– remote locations protected by terrain from radio interference and away from population
centers.
• Each complex consists of ultrasensitive receiving and processing systems

28. OTHER GROUND STATION COMPLEXES
Goldstone Ground Station Complex Madrid Ground Station Complex

29. DETAILS OF DSN FACILITIES
• DSN Network also includes:
– The Demonstration Test Facility at Jet Propulsion Laboratory (JPL) where spacecraft-to-DSN
compatibility is demonstrated and tested prior to launch.
– The Merritt Island facility at Kennedy Space Center in Florida, which supports launch
operations.
– The Ground Communications Facility which connects all voice and data communications.
The GCF uses land lines, submarine cable, terrestrial microwave, and communications
satellites.
• JPL in Pasadena houses the Network’s Operations Control Center.

30. PROGRESSION OF DSN-SUPPORTED SPACE
MISSIONS
• DSN has been continually upgraded to
improve technologies and support
technical demands for new missions.
• Locating the spacecraft's signal over vast
distances, commanding the spacecraft,
verifying that the transmission has been
correctly understood, and receiving and
decoding the faint transmitted signal are
fundamentals the DSN must meet.
• Challenges include larger data streams,
longer distance, multiple spacecraft being
tracked and increased terrestrial radio
interference.
New
Horizons
Juno
Mariner 2 Mars Rovers
Apollo
Voyager

31. ANTENNA ARRAYS
• When the spacecraft’s signal arrives at Earth, it is spread
over a large area, and the ground antenna is able to
receive just a small part of the signal. Arraying allows the
capture of these very weak signals and enables a higher
data rate.
• For the Galileo mission to Jupiter, the DSN arrayed up to
five antennas from three tracking facilities. The result was
a factor of 3 improvement in data return compared with
that of a single 70-meter (230-foot) antenna.
• The smaller antennas generally are easier to build and
maintain than the larger dishes.
• NASA and other space agencies are using arrayed
antennas more and most of the future system
improvements are based on arrays plus advances in data
compression and encoding techniques.
Very Large Array of antennas in
New Mexico

32. CHALLENGES OF DSN
• Distance: The main problem in space communication, since the electromagnetic
radiation decreases as the distance increases.
• Speed of light
– Electromagnetic radiation cannot move faster than speed of light
– There is a considerable time lag which makes communication impossible.
– It takes over 5 hours to reach a signal from earth to pluto in the outer part of solar sytem
• Line of sight:
– To communicate with earth the spacecraft must have a free line of sight to earth, as radio
waves cannot pass through large solid objects.
• Antenna alignment
– Even if the probe has a free line of sight to the earth, the receiving antenna could be on the
wrong side of earth

33. EARLY PIONEER PROBES 1959-1960
• DSN was originally developed by JPL (under the Air Force contract) to support initial series of Pioneer
probes and became operational in 1958.
• Pioneer 4 – launched March 3, 1959 was the first US spacecraft to escape earth’s gravity – intended to
hit Moon, but missed. Communication maintained to 650,000 kilometers (nearly 400,000 miles)
• Pioneer 5 – launched March 11, 1960 -- First spacecraft to explore interplanetary space between
Earth and Venus
Pioneer 4 Pioneer 5

34. THANKYOU!