RU2614049C2 - Global satellite communication and data transmission system with spacecraft at low circular orbit - Google Patents

Abstract

FIELD: communication equipment.

SUBSTANCE: invention relates to communication equipment and can be used in satellite information systems. For this purpose a satellite communication and data transmission system consists of an orbital group of spacecraft with multi-beam antennae at low circular orbits, regional stations to facilitate communication and provide connection to external networks. Available frequency-orbital resource is uniformly distributed between different orbital planes. For each satellite a recovered width of the frequency band is uniformly distributed between the beams forming the satellite coverage area.

EFFECT: technical result is creation of a global satellite communication system making it possible to provide within the area of servicing various information services: voice communication, short messages sending, locating mobile users, collection and transmission of monitoring information to users with small-size user terminals.

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Description

The invention relates to global satellite information systems and can be used to provide satellite communications services, data transmission and monitoring in the global service area.

At present, the Russian Federation does not have its own fully deployed satellite system that provides uninterrupted service for the entire territory of the country and provides services for the collection and transmission of data, short messages, monitoring information for stationary and mobile objects, as well as personal voice communications. Foreign systems (for example, Inmarsat and Iridium systems) operating on the territory of Russia are distinguished by the high cost of their services, do not provide the entire list of services needed by Russian consumers, and a significant part of the territory of the Russian Federation, especially hard-to-reach and northern regions, is outside the coverage of foreign systems. All this limits the possibilities of their application and makes it necessary to create a domestic satellite communications and data transmission system.

The main area of improvement of the system is the efficient use of the frequency-orbit resource, optimization of the structure of the orbital constellation to provide global service, as well as the use of a modernized ground segment and subscriber terminals in the system in order to provide various telematic services to a large number of subscribers in the global service area.

Currently, various systems of multifunctional space communication systems are known, in which it is proposed to use many satellites in non-geostationary orbit (see patents RU No. 2158480, 2496233, 98100084).

Known satellite cellular telephone system and data transmission with an inclined orbit (patent RU 2158480 C2), providing dual satellite coverage of at least 85% of the earth's surface. The technical result consists in establishing communication with portable and mobile cell phones. The system provides two-way communication anywhere on the Earth and above the Earth to a certain height above sea level, amounting to several hundred kilometers. The system uses several satellites in low Earth orbits. The satellite orbits have an inclination of 30 to 90 °. Satellites provide communication lines directly with subscribers and through a public telephone network with other subscribers. Satellites are interconnected via communication lines into a ring structure surrounding the Earth. Switching is carried out by each of the satellites.

The disadvantage of this system is the complex composition of the orbital constellation of spacecraft in low orbits with different inclinations from 30 to 90 °, which makes the system more expensive and complicates its commissioning and further maintenance.

Also known is a low-orbit satellite communications system using light satellites operating in low Earth orbits (patent RU 2496233 C2). The technical result is to ensure global continuous communication between subscribers, the possibility of implementing mobile telephony and high-speed data transfer anywhere in the world using the minimum necessary (optimal) number of light satellites in the system and the minimum cost of creating a satellite communication system. For this, artificial Earth satellites are formed into two groups of communication satellites, one of which consists of N communication satellites, where N is an integer, and is located in n near-earth orbits with a height of less than 2000 km with an inclination of 0-30 °, по / n satellites per each orbit, the other grouping consists of M communication satellites, where M is an integer, and is located in m near-earth orbits with a height of less than 2000 km with an inclination of 60-90 °, M / m satellites in each orbit, while the longitudes of the ascending nodes of the orbits inside of each group differ by 360 / n and 360 / m ° respectively.

The disadvantage of this system is the complex, incompletely defined composition of the orbital constellations of spacecraft in differently high orbits, which complicates the commissioning of the system and its further maintenance. In addition, the application does not determine the number of required spacecraft (SC) in different orbits.

The closest (prototype) to the proposed system is a communication system between earth gateway stations via low-orbit satellites (patent RU 98100084 A), containing at least the first and second satellites in low Earth orbits, which are part of a group of relay satellites in low Earth orbits , which contains 48 satellites distributed in eight orbital planes, six equidistant satellites in a plane, and orbital planes are inclined 52 ° relative to the equator.

The disadvantage of this system is the large number of spacecraft in the orbital constellation, which makes the system more expensive and complicates its commissioning and further maintenance. The application also says about two frequency ranges, but it does not say which and how they are distributed among consumers, which is a fundamental factor determining the structure of building subscriber terminals. Communication in this system is proposed to be carried out only between fixed ground gateway stations.

The objective of the present invention is to provide a global satellite communications and data transmission system that allows providing a wide range of telecommunication services, such as data transmission (short messages, monitoring information) and voice communication.

The problem is solved by using a global satellite communication system and data transmission with spacecraft in a low circular orbit, consisting of an orbital constellation of spacecraft in low circular orbits equipped with multi-beam antennas, regional stations for organizing communications and interfacing with external networks (for example, landline telephone networks, mobile operators, the Internet) and terrestrial consumer facilities (subscriber terminals), and the frequency-orbital plan is applied , reducing mutual influence of subscribers from intersecting service areas of spacecraft from different orbital planes.

The invention is illustrated by drawings, which do not cover and, moreover, do not limit the entire scope of the claims of this technical solution, but are only illustrative materials of a particular case of execution:

in FIG. 1 presents the results of modeling the orbital constellation of satellites (using the example of an orbital constellation of 24 spacecraft with an orbit height of 1,500 km);

in FIG. 2 shows the service areas of the orbital constellation of satellites (using the example of an orbital constellation of 24 spacecraft with an orbit height of 1,500 km);

in FIG. Figure 3 presents a frequency plan showing the distribution of frequencies between spacecraft in different orbital planes (using the example of a frequency resource distribution of 3 MHz and an orbital group of 24 spacecraft distributed over 6 orbital planes).

The system should consist of an orbital grouping of low-orbit spacecraft equipped with multi-beam antennas, a flight control center, regional stations for organizing communications, spacecraft control and interfacing with external networks (for example, landline telephone networks, cellular operators, the Internet) and terrestrial consumer facilities ( subscriber terminals).

The results of numerical simulations, as well as the experience of creating the Gonets-D1M space system with the Gonets-M spacecraft, showed that the most appropriate in this system would be to use the orbital constellation of spacecraft in low circular orbits. The use of low circular orbits allows the use of inexpensive small-sized spacecraft (weighing up to 500 kg), which simplifies their launch into orbit and allows the use of group launches, which significantly reduces the cost of creating a system. A low orbit height improves the energy of the radio links, since the losses due to the propagation of electromagnetic waves in free space are significantly reduced, which allows the use of simple omnidirectional antennas in subscriber terminals, without the need for satellite tracking with full-circle antennas. This greatly simplifies and reduces the cost of subscriber terminals, making them light and small. The optimal composition of the orbital group for reliable service of the entire territory of the Earth is the uniform distribution of vehicles over several orbital planes.

The simulation results showed that the most optimal is the construction of the exhaust gas, consisting of 4 planes of 6 KA.

The presence in the system of regional stations for organizing communications and interfacing with external networks (for example, landline telephone networks, mobile operators, the Internet) and the use of multi-beam antennas on spacecraft to improve the energy of radio lines allows us to provide a wide range of consumers who use small-sized subscriber terminals , in the global service area, information services such as voice communication, short message transmission, location of mobile Users collecting and transmitting monitoring information.

The use of multi-beam antennas on board spacecraft increases the antenna gain in each partial service area compared to the gain of a single-beam antenna in the same service area. Despite the complexity of the antenna design, this gives a big gain in energy, which allows to increase the system throughput and reduce the requirements for the gain of the receiving antennas on the ground equipment of end users.

The presence of consumer facilities (subscriber terminals) in the system allows the provision of various information services (voice communication, short message transmission, location of mobile users, collection and transmission of monitoring information) to a wide range of users both in the Russian Federation and in the global service area . The use of orbital constellation of satellites in low circular orbits equipped with multi-beam antennas increases the energy of radio lines and allows the use of simple small-sized omnidirectional antennas in subscriber terminals. This reduces the size, weight and power consumption of subscriber terminals, thereby increasing the number of promising users and expanding the possible areas of application of the system.

It is also proposed to optimize the frequency-orbital plan. This is necessary to reduce the interference of a large number of nearby subscribers and intersecting spacecraft service areas from adjacent orbital planes. A uniform distribution of the available frequency resource between different orbital planes is proposed. Satellites in the same orbital plane use the same frequency band 3 MHz wide. The fulfillment of this requirement will allow avoiding interference between the spacecraft in the same orbital plane of the system.

For each satellite, a bandwidth is allocated that is evenly distributed between several beams. To reduce the mutual influence between adjacent beams of a single spacecraft, a frequency-orbital plan with alternation between orbital planes, shown in FIG. 3.

The technical result achieved by the application of the proposed system is to ensure sustainable global coverage of the entire territory of the Earth and the provision of various telecommunication services throughout the territory. Also, the proposed system configuration allows the manufacture of simple subscriber terminals with omnidirectional antennas through the use of multi-beam antennas with improved energy.

Claims (1)

Global system of satellite communications and data transmission with spacecraft in a low circular orbit, consisting of an orbital constellation of spacecraft in low circular orbits, characterized in that it includes regional stations for organizing communications, control and interfacing with external networks, and ground-based facilities consumers, spacecraft are equipped with multi-beam antennas, and an optimized frequency-orbit plan is also used to reduce the interference of subscribers and cross service areas of spacecraft from different orbital planes.

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