RU2730422C1 - Method of spatial coding and transmission of digital information - Google Patents

Abstract

FIELD: wireless communication equipment.SUBSTANCE: invention relates to wireless communication systems. Method comprises arbitrarily dividing antenna unit of N antennas into m independent sectors, each of which contains n=N/m antennas, where m≥2. Antennas are configured to independently connect to a digital information source. At that, sequence of connection of each of n antennas inside each of independent sectors m depending on the digital code at the output of the control unit in each sector is provided both in ascending order of their numbers inside this sector – in clockwise direction, and in decreasing order – in a counterclockwise direction. This allows obtaining (2)different combinations of connected sectors and simultaneously rotation direction of polarization vector – clockwise or counterclockwise in each sector.EFFECT: technical result consists in improvement of noise immunity and speed of digital information transmission.1 cl, 2 dwg

Description

The invention relates to wireless communication systems, in particular to digital communication technology, and can be used to transmit discrete information over communication channels using multi-antenna systems.

There are many known methods of physical coding of digital information. Currently, the most effective is multiposition carrier keying, which exists in two main types: phase PSK and quadrature amplitude QAM.

As an informative parameter, you can use not only the amplitude, frequency or phase of the carrier, but also the polarization of the radio wave. Known methods of polarization modulation (manipulation) of a signal are based on the fact that, depending on the value of the useful signal, one of two or two parameters is modulated simultaneously: ϕ is the angle of ellipticity or θ is the angle of spatial orientation of the polarization ellipse. Devices implementing these methods are described in a number of sources, in particular, see K.G. Gusev, A.D. Filatov, A.P. Sopolev. Polarization modulation. - M .: Soviet radio, 1974, p. 63-161.

The disadvantage of these devices is that they are quite complex in implementation and cannot provide multi-position modulation for sufficiently large values of m of multi-position manipulation.

The closest in technical essence is the method adopted as a prototype for encoding and transmitting digital information, which consists in the fact that digital signals are successively emitted through an antenna unit containing N antennas radially located in one plane, which have different radiation polarizations, and when emitted, each digital signals are directed to a specific antenna having a certain angle of inclination to the horizon, and therefore a certain polarization (see RF patent No. 2704742, IPC Н03М 13/00, publ. 2019).

The disadvantage of this method is the relative complexity of its technical implementation, as well as insufficient transmission rate for small values of the positional index m and low noise immunity for large values of m.

The technical problem to be solved by the invention is to increase the noise immunity and the speed of digital information transmission.

The solution to this technical problem is achieved by the fact that in the method of coding digital information, which consists in the fact that digital signals are emitted in the form of radio waves through an antenna unit containing N radially located antennas in one plane, which have different radiation polarizations, for which the antennas are located in one vertical planes and are oriented at different angles to the horizon, and when emitted, each of the digital signals is directed to a certain antenna having a certain angle of inclination to the horizon, and therefore a certain polarization, characterized in that the antenna unit of N antennas is conventionally divided into m independent sectors, each of which contains n = N / m antennas, where m ≥ 2, and the antennas of each of the sectors separately or several sectors simultaneously with the help of the control unit, which receives signals from the digital information source, are made with the possibility of independent connection to the digital information source , while the sequence The connectivity of each of the n antennas inside each of the independent sectors m, depending on the digital code at the output of the control unit in each sector, is provided both in ascending order of their numbers within this sector - clockwise, and in descending order - counterclockwise, allowing receive (2 ² ) ^m different combinations of connected sectors and simultaneously the direction of rotation of the polarization vector - clockwise or counterclockwise in each sector, while each of these combinations according to the adopted matrix is correlated with a certain decimal number from the set (2 ² ) ^m , providing their one-to-one correspondence with the decimal number to be transmitted over the radio channel at a given time.

The solution of the technical problem posed becomes possible due to the fact that to transmit various values of binary codes appearing at the output of a digital information source, different combinations of m sectors of the antenna unit are connected (activated, activated) to it (their number can be from 1 to m) and At the same time, for different combinations, different antenna connection sequences are used within the sectors involved - either in ascending order or in descending order of antenna numbers, i.e. different directions of rotation of the polarization vector of the radio signal. This improves the speed and noise immunity of radio traffic.

The method of encoding digital information is illustrated by drawings, where

in fig. 1. the principle of spatial discrete-polarization coding of digital information for the number of sectors m = 4 is presented, taken as an example;

in fig. 2. shows a block diagram of a device that implements the proposed method.

The following designations are adopted in the drawings:

N is the number of antennas in the antenna unit;

m ₁ , m ₂ , m ₃ , m ₄ - numbers of sectors of the antenna unit;

1 ₁ , 2 ₂ , ... n ₁ - numbers of antennas of 1 sector;

1 ₂ , 2 ₂ , ... n ₂ - numbers of sector 2 antennas;

1 ₃ , 2 ₃ , ... n ₃ - numbers of the antennas of the 3rd sector;

1 ₄ , 2 ₄ , ... n ₄ - numbers of sector 4 antennas;

"+/-" α _m1 ... a _m4 - angles of rotation of the polarization vector of the radio signal - clockwise and counterclockwise, respectively, associated with the position in space of each n antenna within each of the m (m = 4) sectors of the antenna unit.

The method of spatial coding of digital information during wireless transmission of information consists in the fact that digital signals are emitted in the form of radio waves through an antenna unit, which contains antennas radially located in one plane, the number of which is N. Antennas have different radiation polarizations, while the antennas are located in one vertical plane and oriented at different angles to the horizon. In the process of radiation, each of the digital signals is directed to a specific antenna, which has a certain angle of inclination to the horizon, and therefore, a certain polarization.

Digital signals are emitted in the form of radio waves through the antenna unit, which contains antennas radially located in one plane, the number of which is N. The antennas have different radiation polarizations. In this case, the antennas are placed in the same vertical plane and oriented at different angles to the horizon. In the process of radiation, each of the digital signals is directed to a specific antenna, which has a certain angle of inclination to the horizon, and therefore, a certain polarization.

For spatial coding of digital information, an antenna unit containing N antennas radially located in one plane is conventionally divided into m independent sectors. With a uniform distribution of antennas, each of the sectors contains n = N / m antennas, where m ≥ 2. Using the control unit, each of the indicated sectors, separately, in this case, connects one of m sectors, and several sectors for m ≥ 2 can simultaneously connect to a source of digital information. In this case, within each sector, the sequence of connection to the digital information source of each of the n antennas can be performed in two directions: as in the order of increasing their numbers within the given sector, i.e. clockwise and in descending order, i.e. counterclockwise, thus ensuring the rotation of the polarization vector clockwise or counterclockwise.

This solution allows, in turn, to form a number of different options, otherwise - combinations, to connect to the control unit as a certain number of sectors of the antenna unit from 1 to m, and at the same time ensure the choice of one of two sequences, otherwise - the directions of antenna connection within these sectors: in ascending antenna numbers from 1 to n or in descending order of their numbers - from n to 1, i.e. in the opposite direction. All such connections, as is known from mathematics, can be made up (2 ² ) ^m variants.

Further, using the appropriate dependencies, which can be presented in the form of tables, formulas, matrices, etc., each of the possible options for connecting the currently selected sectors and, accordingly, the direction of connecting antennas within the selected sectors is correlated with a certain decimal number subject to transmission over the radio channel at a given time.

To calculate the number of possible combinations for the specified method of coding digital information, you should use the principles of Boolean algebra (see Boolean algebras. Vladimirov DA, 1969, M: Nauka, 319 s). It is known that any function f (x ₁ , x _m ) is called a Boolean function of m variables (arguments), and each of its arguments x _i can take one of two values 0 or 1. Then the set Pm of all Boolean functions (the number of options) from m variables is defined as Pm = (2 ² ) ^m . In the proposed method, as an argument x _i , which, according to the above formula, takes one of the two values "0" or "1", one of the directions of rotation of the polarization vector (antenna connection sequence) is selected within any of the m sectors into which it is "divided" antenna unit.

The use of the proposed method avoids rather complex devices that provide multi-position manipulation (demodulation) of the carrier during wireless transmission of digital information, but comes down to the use of electronic switches and discrete automation elements, which simplifies the circuitry of channel-forming devices and processing of digital signals during radio exchange.

A device that implements the proposed method comprises an antenna unit 1 of a transmitter, a control unit 2 of a transmitter, a source of digital information 3, an antenna control unit 4 of a receiver, a receiver 6 of information.

The method of spatial coding and transmission of digital information is implemented in the device as follows.

Digital information from the source 3 of digital information in the form of a binary digital sequence corresponding to a certain decimal number is supplied to the control unit 2 of the transmitter. The control unit 2 of the transmitter, analyzing the received binary sequence, according to the correspondence matrix determines which of the sectors m, as well as in which sequence of the antenna n within these sectors m should be connected (activated) to transmit this binary sequence, i.e. given decimal number.

Further, in accordance with the algorithm laid down in its operation, unit 2 launches the devices included in its composition, which connect, in other words, activate the antennas of one or another, in other cases, certain sectors of the antenna unit 1 of the transmitter, while ensuring the proper sequence of connecting the antennas n _i inside sectors m _i - clockwise or counterclockwise. The simultaneous connection of sectors with different numbers and their different number, as well as the choice of a different sequence of antenna connection, otherwise the directions of rotation of the polarization vector inside the sectors m to be activated allows you to create a certain number of combinations corresponding to one or another decimal number to be transmitted at a given time through the communication channel.

Reception and processing of information is similar, but in reverse order. The signal in the form of a radio wave arrives at the antenna unit 4 of the receiver, then enters the control unit 5 of the receiver, in which its logical processing takes place, and then to the receiver 6 of digital information.

The number of sectors m can be 2 or more, i.e. m ≥ 2. Technically, this means that logical "0" and "1" correspond to an ascending or descending sequence of connection numbers of pre-numbered antennas within a sector. In this case, the number of combinations that can be formed by choosing certain sectors of the antenna unit 1 in various combinations, as well as varying the direction "+/-" a _n1 ... a _n4 of the polarization vector rotation within each of the selected sectors, is determined by the above known formula Boolean algebra.

Thus, it is possible to provide a one-to-one correspondence between each option for connecting the source 3 of digital information to the antenna unit 1, obtained from combinations of two parameters, namely, "Number and number of activated sectors" and "Direction of rotation of the polarization vector inside the activated sectors" and some decimal number to be transmitted over the radio channel. It is not difficult to see that already with 4 sectors, i.e. with m = 4, the number of numbers that can be transmitted is 256. And with m = 6, their number is 1024. Achieving such coding efficiency with acceptable noise immunity for traditional QAM technologies is not a simple or trivial task.

This does not require an absolutely accurate identification of each of the digital signals arriving at the receiver antennas, which is currently the determining criterion for all known methods of digital radio exchange. A significant advantage of the proposed method is precisely the fact that the receiver only needs to recognize during the clock period only the numbers of activated sectors, as well as the direction of rotation of the polarization vector within these sectors, in other words, to determine which sectors are activated in a given clock period, as well as the sequence of connecting the antennas inside them. Under conditions of intense interference, the solution of such a problem is technically simpler in comparison with the task of accurately separating each of the digital pulses against the background of noise, and, therefore, more reliable.

It should be emphasized that since the number of antennas making it possible to determine the direction of rotation of the polarization vector in each of the sectors m is several, namely n ≥ 2, it can be argued that this process is sufficiently reliably reserved, and, therefore, the direction of rotation of the polarization vector can be established with a high degree of reliability.

The spatial position of the activated sectors is also identified quite simply, since the determining parameter here is precisely the polarization of the electromagnetic wave - a parameter that, as is known, with other things being equal, is least susceptible to natural as well as intentional interference.

Taking into account the fact that there are only 2 directions of rotation of the polarization vector, and the number of sectors m of the antenna unit is unlikely to exceed m = 5, which corresponds to 1024 combinations, and at m = 6 it is already 4096 combinations, respectively, the technical solution of this problem for the current level of development circuitry, as well as signal processing algorithms, cannot cause fundamental difficulties.

Thus, in the proposed method, the algorithm for identifying the received signals and reliable reception of digital information does not include reliable reception of each of the transmitted digital signals individually, as is done in all known methods, but such macroparameters as "direction of rotation of the polarization vector" and " antenna unit sector (s) number (s) ". This makes it possible to significantly reduce the influence, and, taking into account the dynamically changing signal polarization, to practically abstract from concepts such as the effect of interference on the useful signal, and also to consider in a different way the influence of such a fundamental parameter as the signal-to-noise ratio on the stability of radio traffic. It is the proposed method of coding and transmission of digital information, which allows, when transmitting digital information, to operate with such integral parameters as the spatial position of the radiation sectors, as well as the direction of rotation of the polarization vector inside them, as well as the technical implementation of the transmission and reception of a radio signal based on them, allows a fundamentally new level to solve the issues of increasing noise immunity and speed of radio exchange when transmitting digital information.

Thus, the invention makes it possible, in comparison with the prototype, to increase the noise immunity and the transmission rate of digital information.

Claims (1)

A method for spatial coding and transmission of digital information, which consists in the fact that digital signals are emitted in the form of radio waves through an antenna unit containing N antennas radially located in one plane, which have different radiation polarizations, for which the antennas are located in the same vertical plane and oriented under different angles to the horizon, and when emitted, each of the digital signals is directed to a certain antenna having a certain angle of inclination to the horizon, and therefore a certain polarization, characterized in that the antenna unit of N antennas is conventionally divided into m independent sectors, each of which contains n = N / m antennas, where m≥2, and the antennas of each of the sectors separately or several sectors simultaneously using the control unit, which receives signals from the digital information source, are made with the possibility of independent connection to the digital information source, while the connection sequence each of n antennas inside each of the independent sectors m, depending on the digital code at the output of the control unit in each sector, is provided both in ascending order of their numbers within this sector - clockwise, and in descending order - counterclockwise, making it possible to obtain (2 ² ) ^m different combinations of connected sectors and simultaneously the direction of rotation of the polarization vector - clockwise or counterclockwise in each sector, while each of these combinations, according to the adopted matrix, is correlated with a certain decimal number from the set (2 ² ) ^m , ensuring their one-to-one correspondence with this decimal number to be transmitted over the radio channel at a given time.

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