RU2107990C1 - Method for building system of satellite communications between subscribers - Google Patents

Abstract

FIELD: satellite communication systems using artificial earth satellites on low-altitude circular orbits. SUBSTANCE: system uses satellites flying on geostationary orbits. Communication between any subscribers located within visibility zone of low-orbit satellite is established directly through this satellite. In case communications should be provided between subscribers who are beyond visibility zone of one satellite, this communication is established as follows. Posts of geostationary-orbit satellites are installed at ground control stations. Signal is retransmitted from sending subscriber through low-orbit satellite 1 to ground station 4 which is in visibility zone of this satellite, then to geostationary-orbit satellite post 5 (satellite 2), to control service 7 of receiving subscriber, wherefrom it is passed through low-orbit satellite directly to station of subscriber 8 receiving the signal. In this way, communication is ensured between subscribers located both within visibility zone of low-orbit satellite and in any point of globe thereby making it possible to solve the following problems: locating and watching condition of valuable, costly, and dangerous cargo on moving objects; instant data transmission from them to services controlling and tracking these objects as well as yielding, if necessary, control instructions (so-called radio detection satellite services RDSS); dispatching messages informing about state and functioning results of stationary objects. EFFECT: improved economic efficiency of building systems for satellite communication between subscribers located within visibility zone of low-orbit satellite or in any point of globe. 3 dwg

Description

 The invention relates to the field of communications, and more specifically to methods of radio communications using artificial Earth satellites.

 A known method of radio communication and television transmission using artificial Earth satellites (AS N 302840, class H 04 B 7/185, 1971), operating in the general frequency range with frequency-spatial separation of signals, which consists in relaying signals television through on-board devices having a maximum radiated power, and communication signals are relayed through on-board devices emitting power that is economically optimal, while receiving television signals with antennas of the minimum for the selected power minute diameter, and communication signals are received by antennas economically optimum size.

 This communication method increases the efficiency of using a stationary orbit, however, this method can only be used by subscribers located in the satellite visibility zone.

 There is a method of constructing a satellite communication system between subscribers (RF patent, N 2032988, class H 04 B 7/185), which consists in bringing N artificial Earth satellites, which are equipped with radio stations, to elliptical synchronous orbits lying in planes other than equatorial, according to which the value of the parameters of elliptical synchronous orbits of artificial Earth satellites is selected from the conditions under which at apogee sections of the trajectories of elliptical synchronous orbits in the zones between the lines of intersection of the planes of elliptical synchronous of orbits, the average value of the absolute values of the angular velocities of artificial Earth satellites relative to the axis of rotation of the planet of the Earth for a certain period Tp = 24 / N coincides with the absolute value of the angular velocity of the Earth, and the magnitude of the drift of artificial Earth satellites in azimuth and elevation relative to subscribers does not exceed the value of the angle subscriber radio station antenna pattern.

 The disadvantage of this method of constructing a satellite communication system between subscribers is the limited service area of subscribers, i.e. this method of satellite communications can only serve a strictly limited, certain area of the globe.

 Known combined satellite system for global communications and / or to determine the location (DE, patent N 3605096 class. HO 04 B 7/185, 1987), which proposes a satellite system consisting of 18 satellites equipped with communications, of which 6 are evenly distributed in geostationary orbit and 12 satellites moving in elliptical orbits with a large inclination to the equator, providing communication for subscribers of high northern and southern latitudes.

 In the description, only a grouping of satellites of a combined system moving in different elliptical and geostationary orbits is presented and it is not shown how communication between subscribers is carried out using these satellites.

 From the analysis it follows that this system cannot, in principle, communicate with small-sized subscriber stations, since communication with small-sized stations can only be established via low-flying satellites.

 A known method of satellite communications using satellites in low orbits (900 ... 1800 km) (Telecommunications, 1995, No. 9, pp. 19-24). This method consists of launching N artificial Earth satellites into circular low orbits, and user signals sent to a satellite in a dedicated frequency band are converted on the satellite into a feeder line band and sent to a gateway station (AC) included in a common switched ground communication network, which sends them to the addressee. The response signals over the ground network are fed to the gateway AP, from where they arrive at the satellite in the frequency band of the feeder line, are converted in it and sent to the users AP. The specified method is the closest to the claimed object and is selected as a prototype. This method, using the advantages of satellite communications (coverage of large areas), allows us to simplify the user’s AP to such an extent that it can be designed as a portable device slightly larger than the handset.

 The disadvantages of a satellite communication system using satellites in low orbits include the need to have a large number of satellites in orbits located in different planes to ensure continuity of communication. In addition, this method of communication between subscribers located both in the visibility range of a low-flying satellite and located anywhere in the world, requires autumn of great economic costs.

 The objective of the invention is to provide the most economical way to build satellite communications between subscribers located both in the visibility range of a low-flying satellite and located anywhere in the world.

 The solution to this problem is achieved by the fact that according to the method of constructing a satellite communication system between subscribers, which consists in launching N artificial Earth satellites equipped with radio stations operating in the general frequency range with code division of signals into low circular orbits and using them to provide communication between all subscribers artificial, located in the field of view of one satellite, to provide communication between subscribers located outside the zone of visibility of one satellite, artificial satellites are additionally displayed on geostationary orbits and set their earth stations at the Earth’s control stations, and the signal is relayed from the subscriber via satellite in low orbit to the control station located in the satellite’s visibility range, then through the earth’s satellite stations in geostationary orbit and the satellite itself to the control station of the receiving subscriber, from where through a satellite in low orbit the signal is relayed to the receiving subscriber.

 Distinctive features from the prototype are that, according to the proposed method for constructing a satellite-based communication system between subscribers located outside the visibility range of one satellite, artificial satellites are additionally placed in circular geostationary orbits and their earth stations are installed at Earth’s control stations, and the signal is relayed from the subscriber via satellite in low orbit to a control station located in the satellite’s field of view, then through the satellite’s earth station in geostationary orbits e - to the control station of the receiver of the signal, from where, through the satellite in low orbit, the signal is relayed directly to the receiver of the signal.

 The authors are not aware of technical solutions with the essential features given in the characterizing part of the claims.

 In FIG. 1 relay satellites are shown: 1 - in low orbit, 2 - in geostationary orbit, 3 - station sending a subscriber signal, 4 - dispatching station, 5, 6 - satellite stations in geostationary orbit, 7 - dispatching station receiving a subscriber signal, 8 - station receiving the subscriber signal.

Consider a specific example of the implementation of the proposed method of a satellite communication system between subscribers. A group of spacecraft (1 and 2) equipped with means of radio-technical complexes-repeaters to circular low and spacecraft, to geostationary orbits is displayed. The spacecraft constellation includes 36 satellites located in 6 orbital planes of 6 satellites each. The movement of satellites in each plane and between planes is rigidly phased with an error of 5 ^o (500 km) and is maintained throughout the life of each satellite by regular corrections (1 time per month). Following this, a message is generated in the equipment of the escort terminal, which includes: the addressee code and the route along which the message will have to go to the addressee; location coordinates; data on the state of the object received from the sensors of the equipment; sender code.

 The system adopts the latest channel separation method - code division. In the channels, information signals (bits) are represented in the form of pseudo-random sequences of phase-manipulated packets with the number of elements 512 in the up channels and 128 in the down channels. The required frequency band is 5 MHz. Moreover, in the “up” channels, information bits are transmitted at a speed of 4.8 kbit / s, in the remaining channels 19.2 kbit / s. The total performance of one satellite in the direction of the subscriber-satellite is 48 kbit / s.

 As calculations and modeling have shown, with the number of satellites equal to 36, the time of obsolescence (delivery) of the message is 9 - 12 minutes. Thus, a connection is established between any subscribers in the field of view of one satellite. If it is necessary to establish communication between subscribers located outside the range of one satellite, the communication between them is established as follows.

 At Earth’s control stations, geostationary orbit satellite stations are installed. The signal is relayed from the transmitting subscriber via satellite 1 in low orbit to the dispatch station 4, which is in the range of the satellite, from which the satellite station 2 in geostationary orbit 5 is satellite 2 to the dispatching service 7 of the receiving subscriber, with which the satellite is in low orbit - directly to the station receiving the signal of the subscriber 8.

Thus, the proposed method for constructing a satellite communication system between subscribers provides communication between subscribers located both in the low-flying satellite visibility zone and located anywhere in the world, which in turn allows us to solve the following problems:
- monitoring the location and condition of valuable, expensive and dangerous goods at moving objects;
- prompt transfer of data from them to the services that control and accompany these objects, as well as issuing, if necessary, control commands (the so-called RDSS service - detecting objects by radio from satellites);
- delivery of messages on the status and functioning of stationary objects.

 Additional services - data transfer between arbitrary subscribers of the system.

 The characteristics of the system are focused on a certain class of consumers in the Russian and world markets associated with the control of mobile valuable and dangerous goods.

The analysis of published materials and partly conducted marketing of the Ural and Siberian regions showed that consumers of the system can be:
- organizations and departments that own various types of transport, including road, river, sea and rail;
- enterprises with a distributed structure of production, including the oil and gas complex, forestry and agriculture;
- organizations that monitor the state of the environment and environmental management, control of hazardous and hazardous industries, the state of dangerous and especially valuable goods;
- organizations that need operational emergency call systems, including rescue teams, geologists, tourists, hunters, fishermen;
- organizations involved in the aftermath of disasters, emergency disasters;
- special services, including police, ambulance, fire brigades, etc .;
- private individuals (entrepreneurs, farmers, reindeer herders, shepherds, etc.).

 In addition, it should be noted that the solution to all these problems, the proposed method allows for the most economical way compared to the existing one.

 In all numerous projects of satellite communication systems using satellites in low orbits, offered by domestic and foreign companies, the most difficult task is to organize communication between subscribers located outside the range of one satellite. In some projects, they try to solve this problem using inter-satellite communication lines. The organization of inter-satellite communication lines leads to a complication of the spacecraft, an increase in its mass, an increase in the requirements for orientation systems, and as a result to a significant increase in the cost of manufacturing the spacecraft and its launch.

 In other systems, this problem is solved with the help of terrestrial gateway stations connected to a terrestrial switched global public network. The signal in these systems is transmitted from the transmitting subscriber via a low-flying satellite to the gateway station and via landlines to the receiving subscriber.

 In third systems, it is proposed to solve this problem using ground-based relay stations, which, transmitting information from satellite to satellite, bring it to the receiving subscriber.

 This method leads to a significant reduction in system bandwidth.

 The project "Specialized Satellite Information and Communication System" (SI-SS) used inter-satellite communication lines.

 According to the proposed method, inter-satellite communication lines were excluded by arranging channels between dispatch stations using the latest satellite communications systems in Russia and the CIS countries Ruslan RS and, globally, the Intersputnik 8 system.

 At the same time, it is possible to organize service channels between dispatching stations and the main control station of the connected complex, which will help to improve the management of the system and increase its profitability.

 The latest satellite communications systems Intersputnik 8 and Ruslan - RS are based on the use of heavy vehicles in geostationary orbit. The systems are optimized for earth and space stations, thanks to which it was possible to minimize the size and weight of earth stations, the cost of deploying earth infrastructure.

 Within the framework of these systems, it is most efficient to organize the required communications between dispatch stations and the main national stations of the SI-SS system, thereby eliminating inter-satellite channels. The inter-satellite channels in the SI-SS system have the worst energy, and their organization greatly complicates the on-board equipment.

 The exclusion of these channels and the simplification of on-board equipment will more than double the capacity of the SI-SS system and make it competitive with similar domestic and foreign systems.

 We give economic calculations of the development, manufacture and commissioning of the SI-SS system, taking into account the proposed method.

 Cost estimation was carried out in stages: development, deployment, operation; and in its component parts: information and communication complex, space complex, complex of launch vehicles; system-wide expenses (at the development stage).

 System-wide expenses include the costs of developing communications and space equipment and amount to $ 77 million.

 The deployment of the system includes the cost of manufacturing and launching spacecraft, which amount to $ 180.5 million.

 Thus, the total cost of developing and deploying SI-SS is $ 257.50 million.

 Operating costs for the operation of SI-SS are composed of the following components: depreciation; expenses for replenishment of failed satellites; costs of maintaining control centers.

 Depreciation charges are determined on the basis of the satellite’s active life of 5 years and the total cost of the space constellation (36 spacecraft), including the cost of its removal. Based on the cost of the spacecraft and its launch of $ 4.24 million, annual depreciation will amount to $ 30.53 million.

 The costs of replenishing satellites that failed within a 5-year period are determined by their reliability. With the probability of satellite failure-free operation over a 5-year period equal to 0.85, the replenishment expenses will amount to $ 4.6 million per year.

 Thus, the annual operating costs will amount to $ 37.63 million.

 Cost and price of services.

The total number of messages transmitted per year will be 150,000 • 12 • 365 = 657 • 10 ⁶ .

The cost of transmitting one message will be 37.63 • 10 ⁶ : 657 • 10 ⁶ = 0.057 dollars.

 Based on a comparison with world prices, the cost of transmitting 1 message 100 bytes is accepted - 0.1 dollars.

 The sale of subscriber terminals by year and the receipt of annual income and expenses by year are presented in FIG. 2 and 3.

 The good economic performance of the new system makes it possible to carry out the development and deployment of the system at the expense of credit funds.

 If you receive a loan of 189 million US dollars for 10 years at 8% per annum, a loan can be repaid and profit for 10 years 217 million dollars, for 12 years - 462 million dollars and for 15 years - 828 million dollars

Claims (1)

 A method of constructing a satellite communication system between subscribers, which consists in launching N artificial Earth satellites equipped with radio stations operating in the general frequency range with code division of signals into low circular orbits, characterized in that the artificial satellites are placed in circular geostationary orbits and earth stations of the geostationary system communications are established at the Earth’s control stations, and the signal is relayed from the subscriber via satellite in low orbit to the control station located in the zone idimosti given satellite, then through the satellite earth station in a geostationary orbit, and the satellite - a supervision station receiving the subscriber signal, which via a satellite in low orbit relay signal directly receiving the subscriber signal.

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