RU2609586C2 - Method for power distribution of board transmitters between signals in forward channels of satellite system for accessing information resources with repeated use of frequency bands - Google Patents

Abstract

FIELD: communication.

SUBSTANCE: invention relates to communication equipment and can be used in multibeam satellite systems for accessing information resources. Power distribution of board transmitters allows different users to obtain an information resource with different speed depending on their needs. Invention discloses a method for power distribution of board transmitters between signals of a multibeam satellite system for accessing information resources, wherein search for optimum power of signals is carried out using an algorithm of dynamic distribution of power.

EFFECT: technical result of invention is power distribution of board transmitters between signals of multibeam satellite system for accessing information resources with limitations on lower thresholds of speeds of transmitting information in user agreements.

1 cl, 1 dwg

Description

The invention relates to the field of communication technology and can be used in multipath satellite systems for access to information resources. A known method of regulating the transmission power over the information channel of a direct communication line (RU No. 1232200085, 03/20/2008), in which the power is transmitted over a straight line to a subscriber terminal as part of a radio communication system containing many beams, is controlled by determining the source power level, P baseline, according to the accepted current signal-to-noise ratio (SNR) in the control channel, determine the threshold power value, Pmargin, determine the power level correction by the detected sensitivity to interference, P correction, by apparent packet error rate (PER) and set Ptransmit, according to P baseline, Pmargin and P correction. The disadvantage of this method is that the threshold power value is not determined by the minimum value from the lower threshold information transfer rates in user agreements.

Also known is a method and device for high-speed and low-speed communication via satellites in low and medium orbits. In the method of multi-station communication via satellites, according to which, at subscriber stations, high-speed and low-speed information is modulated by various, but phased between, pseudorandom codes modulating carriers, the radiation of the received information packets with preambles to the relay satellites on which they are received, estimates the mismatches delay codes and carrier frequencies, memorizing these discrepancies and the information part of the packets, and then form new packets and reradiation along with the synchronization signal to the corresponding subscriber stations and neighboring relay satellites, on which the received information is allocated, and according to the received mismatches, they carry out automatic tuning of their own transmitters with automatic tuning, provide bandwidth control for individual channels of high-speed (low-speed) transmission, varying the parameters of the code and time seals provide synchronization of receivers and transmitters with automatic tuning at subscriber stations and neighboring satellites Kakh-transponders on low-speed transmission lines also provide the ability to transmit high-speed (low-speed) information through optional transparent transponders installed on board (RU No. 2133555, 07.20.1999). The disadvantage is that this method is not applicable for satellites operating in geostationary orbits. The closest is a method for distributing the power of airborne transmitters between signals of a multi-beam satellite system for access to information resources [1]. In it, with given information about the number of rays, the requested information transfer rates, the total power of the airborne transmitters, the parameters of the spectral density of the noise power, normalized to the attenuation coefficient, the width of the working frequency bands, the interference coefficients between signals, the signal powers are determined.

The disadvantages of this method include the fact that the method does not solve the problem of power distribution of airborne transmitters between signals of a multi-beam satellite system of access to information resources while limiting the lower thresholds of information transfer rates in user agreements.

The technical result of the invention is the distribution of power of airborne transmitters between signals in the direct channels of a satellite system for accessing information resources with repeated use of frequency bands with restrictions on lower thresholds for information transfer rates in user agreements. The power distribution of airborne transmitters allows different users to receive an information resource at different speeds depending on their needs.

To achieve a technical result, a method for distributing power of airborne transmitters between signals of a multi-beam satellite system for accessing information resources is proposed, in which the search for optimal signal powers is performed using the dynamic power distribution algorithm.

A method for distributing power of airborne transmitters between signals of a multi-beam satellite system for accessing information resources is carried out according to the following operations.

1. Obtaining information about the number of rays, the requested information transfer rates, the total power of the airborne transmitters, the parameters of the spectral density of the noise power, normalized to the attenuation coefficient, the width of the working frequency bands, the interference factors between signals.

2. Obtaining values of lower thresholds for information transfer rates in user agreements.

3. Determination of the required information transfer rates.

4. Determination of the minimum signal power values sufficient to provide the required information transfer rates.

5. Determination of the excess of the value of the total power of airborne transmitters over the sum of the minimum values of signal powers sufficient to provide the required information transfer rates. If the excess is not 0 go to step 7.

6. The output of the signal power values for further processing.

If the excess of the total power values of the airborne transmitters over the sum of the minimum signal power values is not equal to 0, then perform:

7. Determination of signal power values.

8. Definition of additional restrictions or their absence. To determine the absence of additional restrictions, go to paragraph 6. When determining the limitations of paragraph 8, do the following:

9. Determination of signal power values with additional restrictions, go to step 8. And this is done repeatedly until the absence of additional restrictions under paragraph 8 is obtained.

A method for distributing power of airborne transmitters between signals of a multi-beam satellite system for accessing information resources (Fig. 1) comprises:

- block 1 data input;

- block 2 input lower thresholds for information transfer rates in user agreements;

- block 3 determine the required transmission rates of information;

- block 4 determine the minimum required signal strengths;

- block 5 determining the adequacy of the total power of airborne transmitters;

- block 6 output signal power;

- block 7 determine the power of the signals;

- block 8 determining additional restrictions;

- block 9 determine the power of the signals with additional restrictions.

The data input unit 1 receives information about the number of rays, the requested information transfer rates, the total power of the airborne transmitters, the parameters of the noise power spectral density normalized to the attenuation coefficient, the width of the working frequency bands, the interference factors between signals, where

- N is the number of rays;

- D _{i the} requested transmission rate of information in the i-th subscriber;

- P _tot - total power of airborne transmitters;

- γN ₀ - parameter of the spectral density of the noise power, normalized to the attenuation coefficient;

- W is the width of the working frequency band;

- h _ij is the interference factor between signals.

The input unit 2 of the lower thresholds for information transfer rates in user agreements receives the values of the lower thresholds for information transfer rates in user agreements, where

- D _i ^min - lower threshold information transfer rate in user agreements of the i-th subscriber.

Block 3 determining the required information transfer rates determines the required information transfer rates from at least the requested and lower threshold

where D _i ^* is the required information rate of the i-th subscriber.

Block 4 determining the minimum required signal powers determines the minimum values of signal powers (P _i ^* ), sufficient to provide the required information rates,

Block 5 determining the sufficiency of the total power of airborne transmitters determines the sufficiency of the total power of the transmitters to provide the required information rates.

Here U is the sign value of the defining function sgn. If U is 1, then this means that the total power of the transmitters is enough to provide the required information transfer rates. If U is -1, then this means that the total power of the transmitters is not enough to provide subscribers with the required transmission speed. Therefore, if U is 0, then the total power of the airborne transmitters is only enough to provide the required information transfer rates.

Via the power output unit 6, the signal power values are transmitted for further processing.

Block 7 determine the power of the signals determines the optimal values of the power of the signals according to a given criterion.

We obtain the optimal values of the signal powers (P _i ) according to (4)

where the criterion is given as (5)

and the information rate provided is expressed as

Block 8 determining additional restrictions checks whether the provided data rates corresponding to certain values of signal powers, the condition

and determines additional restrictions or their absence. If there are provided information transfer rates that do not satisfy the condition in block 8, then they are stored as C ^* (P _i ), and their number as m.

Block 9 determining the signal powers with additional restrictions determines the optimal values of the signal powers according to a given criterion with additional restrictions on C ^* (P _i )

where the variable n is initially zero.

The proposed method is as follows.

Information about the number of rays, the requested information transfer rates, the total power of the airborne transmitters, the parameters of the spectral density of the noise power, normalized to the attenuation coefficient, the widths of the working frequency bands, and the interference coefficients between the signals are sent to input data block 1.

The lower threshold values of information transfer rates in user agreements are received at block 2 for inputting lower thresholds for information transfer rates in user agreements.

Based on the received values of the lower threshold information rates in user agreements and the requested information rates, the required information rates are determined in block 3 for determining the required information rates.

Based on certain values of the required information transfer rates and the received information about the parameters of the noise power spectral density normalized to the attenuation coefficient, the width of the working frequency bands, the interference coefficients between the signals, the minimum signal powers sufficient to provide the required information transmission rates in the determination unit 4 are determined minimum required signal powers.

In block 5 determining the sufficiency of the total power of airborne transmitters compares the sum of the minimum values of the signal powers sufficient to provide the required information transfer rates, and the total power of the airborne transmitters. If the sum of the minimum values of the signal powers is equal to the total power of the airborne transmitters, then the minimum values of the signal powers sufficient to provide the required information rates are output from the signal power output unit 6 for further processing. If the corresponding sum is not equal to the total power of the airborne transmitters, then the optimal values of the signal powers in block 7 determine the power of the signals.

Information transfer rates corresponding to certain signal power values are checked in block 8 for determining additional restrictions. If all these information transfer rates satisfy the condition in block 8, then certain signal powers are output from the signal power output unit 6 for further processing.

At information transfer rates that do not satisfy the condition in block 8, additional restrictions are formed on their basis. After that, the signal powers are determined under additional restrictions in block 9 for determining the signal powers under additional restrictions, and the information transfer rates corresponding to these powers are also checked in block 8.

The operations in blocks 8 and 9 continue until all information transfer rates satisfy the condition in block 8.

Thus, we obtain the power distribution of airborne transmitters between signals in the direct channels of a multi-beam satellite system for accessing information resources with repeated use of frequency bands.

Achievable technical result of the proposed method for distributing the power of airborne transmitters between signals in the direct channels of a multi-beam satellite system of access to information resources is to obtain this distribution with restrictions on the lower thresholds of information transfer rates in user agreements. In addition, the proposed method makes it possible to optimally distribute the power of airborne transmitters under restrictions on the lower thresholds of information transfer rates in user agreements, if the total power of airborne transmitters is insufficient to provide the required information transfer rates.

Bibliography

1. Heng Wang, Aijun Liu, Xiaofei Pan, Jiong Li, Optimization of Power Allocation for a Multibeam Satellite Communication System with Interbeam Interference, - Journal of Applied Mathematics - Volume 2014 (2014), Article ID 469437, 8 pages.

Claims (1)

A method for distributing the power of airborne transmitters between signals of a multi-beam satellite system of access to information resources, which consists in the fact that information is received on the data input unit about the number of beams, the requested information transfer rates, the total power of the airborne transmitters, the noise spectral density parameters normalized to the attenuation coefficient , the width of the working frequency bands, the interference coefficients between the signals, after which the values of the signal powers in the power determination unit are determined the rest of the signals, after which the signal power values are transmitted to the signal power output unit, characterized in that after the information is received in the data input unit, the values of the lower thresholds of information transfer rates in user agreements are received in the input unit of the lower thresholds of information transfer speeds in user agreements, after which the values of the required information transfer rates are determined in the unit for determining the required information transmission rates, after which the minimum power values are determined the rest of the signals sufficient to provide the required information transfer rates in the block for determining the minimum required signal powers, after which the excess of the total power values of the airborne transmitters over the sum of the minimum signal powers sufficient to provide the required information rates in the block for determining the sufficiency of the total power of the airborne is determined transmitters, after which the excess of the total power value of the airborne transmitters over the sum of the minimum values is compared signal strengths with zero, after which, when the excess is equal to zero, the minimum signal powers are transmitted that are sufficient to provide the required transmission rates to the signal power output unit, and if the excess is not equal to zero, the signal powers in the power determination unit are determined signals, after which additional restrictions or their absence are determined in the block for determining additional restrictions, after which, when determining the absence of additional restrictions, the values are transmitted signal powers to the signal power output unit, while determining one or more additional restrictions, the signal power values are determined with additional restrictions in the signal power determination unit with additional restrictions, after which additional restrictions or their absence in the additional restrictions determination unit and the subsequent determination of values are determined signal powers with additional restrictions in the unit for determining signal powers with additional ogre changes, and so on, until the absence of additional restrictions in the additional restrictions determination unit is determined, after which the signal power values are transmitted to the signal power output unit, and then the power values are transmitted to the power distribution device on board the satellite for subsequent power distribution between the signals.

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