Coverage patterns for the molniya orbit and iridium constellation in real time with the stk
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Coverage Patterns for the Molniya Orbit and Iridium Constellation in Real Time with the STK. Pedro A. Capó-Lugo, Peter M. Bainum Howard University, Department of Mechanical Engineering Washington, D.C. 20059, USA Ijar Fonseca National Institute for Space Research—INPE

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Coverage patterns for the molniya orbit and iridium constellation in real time with the stk l.jpg

Coverage Patterns for the Molniya Orbit and Iridium Constellation in Real Time with the STK

Pedro A. Capó-Lugo, Peter M. Bainum

Howard University, Department of Mechanical Engineering

Washington, D.C. 20059, USA

Ijar Fonseca

National Institute for Space Research—INPE

Space Mechanics and Control Division—DMC

Sao Jose dos Campos, S.P. Brazil

Research Supported by NSF Alliance for Graduate Education and Professiorate (AGEP)


Introduction l.jpg
Introduction Constellation in Real Time with the STK

  • Introduce the theory of communication architecture for a single satellite and constellation.

  • Explain the communication architecture design for an satellite-Earth link.

  • Introduction and simulation with the Satellite Tool Kit (STK) software.


Communication architecture l.jpg
Communication Architecture Constellation in Real Time with the STK

  • Arrangement or configuration of different subsystems communicating from the Earth to the Satellite.

  • Architecture depends on three main objectives:

    • Mission Objectives

    • Data Rates

    • Earth-Satellite Link


Communication subsystems l.jpg

Satellite link: Constellation in Real Time with the STK

Sensor

Transponder

Transmitter

Earth link:

Ground Station

Amplifier and Receiver

Demodulation

Display

Communication Subsystems


Communication links l.jpg
Communication Links Constellation in Real Time with the STK

  • Ground Station to Satellite

    • Uplink

    • Downlink

  • Satellite to Satellite

    • Crosslink

    • Intersatellite Link

    • Forward Link

    • Return Link


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Store and Forward Constellation in Real Time with the STK

  • Has an altitude under 1000 km.

  • Receives and stores information from a group of ground stations.

  • Has a small link access time to download the information.

  • Has a low-cost launch, wider antenna bandwidth, minimum stabilization, and covers polar areas.


Molniya orbit l.jpg
Molniya Orbit Constellation in Real Time with the STK

  • Covers northern polar areas for long periods of time.

  • Has a low launch-cost.

  • Requires continuous changing of antenna pointing angles.

  • Requires satellite station keeping.


Low altitude l.jpg
Low Altitude Constellation in Real Time with the STK

  • Has an altitude higher than 1000 km.

  • Connects via satellite crosslink.

  • Has greater lifetime than other satellites

  • Depends on the inclination angle for coverage pattern.

  • Has complex dynamic controls, link acquisition, and high link quality.

  • The information moves for different paths.


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Criteria for the Communication Architecture Constellation in Real Time with the STK

  • Orbit

    • The satellite coverage depends on the altitude and inclination.

    • The transmitter and receiver power depends on the altitude of the satellite.

    • The satellite orbit dictates whether crosslink or intersatellite link is required.


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  • RF Spectrum Constellation in Real Time with the STK

    • The radio frequency is chosen for the communication.

    • The selection of the frequency changes the size, mass, and complexity.

    • The frequency is allocated depending on the mission objectives.

  • Data Rate

    • The size of the transmitter depends on the amount of data.

    • The information can be compressed in the satellite.


Slide11 l.jpg

  • Duty Factor Constellation in Real Time with the STK

    • Is the time needed to communicate between a ground station and satellite.

    • Is a function of the mission and the time the satellite takes to orbit around the Earth.

    • Is low when the ground station serves different satellites.

  • Link Availability

    • Is defined as the time the link is available for the user divided by the total time the satellite covers all the area.

    • Depends on the reliability of the equipment.


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  • Link Access Time Constellation in Real Time with the STK

    • Is the maximum time to access the satellite information.

    • Depends on the selection of the orbit.

  • Threat

    • Depends on the perturbations due to the Moon, Sun, atmosphere, and weather.

    • Depends on the noise created by human beings.


Stk software l.jpg
STK Software Constellation in Real Time with the STK

  • Used to simulate satellite orbits in real time.

  • Synthesizes the positioning of the ground antenna once the orbit has been defined.

  • Used to establish communication time intervals with the satellite.

  • Has a three dimensional window to visualize the satellite orbit.


Iridium constellation l.jpg
Iridium Constellation Constellation in Real Time with the STK

  • Has an altitude of 700 km.

  • Has 6 orbital planes with 11 satellites per orbital plane.

  • Used for phone satellite communication.

  • Can communicate to any place on the Earth.



Molniya orbit19 l.jpg
Molniya Orbit Constellation

  • Has a period of 12 hours.

  • Has an altitude of 40,000 km at apogee and an altitude of 500 km at perigee.

  • Covers the northern polar areas for a period of 8 hours.

  • Has an inclination angle of 63.14 degrees.



Conclusion l.jpg
Conclusion Constellation

  • Simulations with the STK software are very accurate.

  • Predicts the position and availability of the satellite.

  • Has a better visualization in real time for a single satellite or constellation.

  • Has different perturbations like J2, drag, models for clouds and precipitation, etc.


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