RU2725130C2 - Method for wireless transmission and reception of data - Google Patents

Abstract

FIELD: communication equipment.

SUBSTANCE: method for wireless transmission and reception of data involves transmitting a data stream from a transmitting device to a receiving device using antenna units consisting of each of a plurality of N antennas, mutually oriented in space, using a given matrix for controlling transmission and reception of data. Signals from the transmitting device are transmitted to the logic device, provided with a certain coding feature corresponding to the number of the antenna N, and then transmitted to the electronic switch, which in accordance with assigned codes sequentially distributes signals on each of N antennas of antenna unit of transmitting device, wherein each of the N antennae is placed in a vertical plane normal to the radiation direction such that two antennae are arranged in each polarization plane, wherein the adjacent antennae are oriented at an angle α between their longitudinal axes with the possibility of transmitting and receiving data by forming a plurality of communication channels with different polarization of the radio signal.

EFFECT: technical result consists in improvement of carrying capacity of multi-antenna systems and expansion of their technological resources as technology of spatial coding of information due to formation of a multipolarized data stream.

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Description

The invention relates to communication technology and can be used to increase the stability of radio exchange between stationary or mobile radio engineering objects.

A known method of transmitting a correction code in a wireless communication system, according to which the base station generates a correction code sequence for each of the multiple antennas and transmits a correction code sequence to the user equipment for each antenna. The location of the frequency subcarrier to which each sequence of the correction code is mapped is determined based on the frequency reuse factor [see RF patent No. 2487477, IPC Н04В 7/06, publ. 2013].

The disadvantage of this method is that the radio exchange occurs using radio waves of a single (vertical) polarization.

There is also known a method of using multi-antenna systems, adopted as a prototype, when the transmitter station receives channel information for at least one subcarrier, which is a subset of the many subcarriers used for data transmission. The transmitter station receives at least one transmission control matrix for at least one subcarrier from the channel information and determines a transmission control matrix for each of the plurality of subcarriers. The transmitter station performs transmission control or beam control for each of the plurality of subcarriers using the transmission control matrix for such a subcarrier [see RF patent No. 2404511 IPC Н04В 7/06, publ. 2010].

The disadvantage of this method is that the radio exchange occurs with the use of antennas of a single (vertical) polarization, which, as you know, is used by most radio transmitters, which creates difficulties in radio frequency planning.

The technical problem to which the invention is directed is to increase the throughput of multi-antenna systems, expand their technological resources as a technology for spatial coding of information by forming a multipolarized data stream and to save a frequency resource.

The solution of the technical problem is achieved by the fact that in the method of wireless transmission and reception of data, which consists in transmitting a data stream from a transmitting device to a receiving device using antenna units, each consisting of many N antennas, mutually oriented in space, using a given control matrix according to the invention, data from a transmitting device is sequentially supplied according to a data transmission control matrix to each of the N antennas of the antenna unit of the transmitting device, while each of the N antennas is arranged in a vertical plane normal to the radiation direction, and adjacent antennas are oriented under angle α between their longitudinal axes with the possibility of transmitting and receiving data due to the formation of many communication channels with different polarization of the radio signal.

The solution of this problem is also directed by the fact that the angle α between the longitudinal axes of the antennas is calculated by the formula α = 360 ° / N.

The solution of this technical problem becomes possible due to the fact that the antenna devices of the transmitting and receiving devices are made in the form of a multi-antenna design, the longitudinal axes of which are located radially in the same plane and at given angles to each other. This allows various fragments of the signal to be emitted using radio waves having different polarizations. In the general case, the angles between the antennas may be different.

The method is illustrated in FIG. 1 is a diagram showing radio transmitting and receiving devices 1 and 2, respectively, logic devices 3 and 4, electronic switches 5 and 6 and a plurality of antennas 7 in each of the antenna units of transmitting and receiving devices 1 and 2, respectively.

The following letter designations are shown in the diagram: RTU ₁ and RTU _{2 —} transmitting and receiving radio devices, LU ₁ and LU ₂ — logical devices and K1 and K2 — switches corresponding to transmitting and receiving radio devices RTU1 and RTU2, and also shown as an example the case of using antennas with the number N = 8 with their uniform distribution around the circle, when the angle α between their longitudinal axes is α = 45 °.

In the drawing, a two-way arrow denotes a two-way communication between radio engineering devices and their components.

The method of wireless transmission and reception of data involves two-way radio exchange and consists in transmitting a data stream from a transmitting device RTU1 to a receiving RTU2 using antenna units, each of which consists of many antennas, number N. The transmission and reception of data is carried out using radio signals using a control matrix identical for the reception and transmission specified by the logic devices LU1 and LU2.

In this case, the data from the transmitting device RTU1 according to the data transfer control matrix is supplied sequentially to each of the N antennas of the antenna unit of the transmitting device RTU1 using the switch K1.

To do this, each of the N antennas of the transmitting and receiving devices RTU1 and RTU2 is oriented in space, located in a vertical plane normal to the direction of radiation, providing the ability to transmit and receive radio signals due to the formation of communication channels with different polarization of radio waves, and adjacent antennas are oriented at an angle α between their longitudinal axes.

With the orientation of N antennas in each of the antenna blocks of the transmitting and receiving devices RTU1 and RTU2 in the particular case, the angle α between the longitudinal axes of the antennas is calculated by the formula α = 360 ° / N.

Since it is assumed two-way equal radio exchange, the number N of antennas 7 in the antenna devices of the transmitting and receiving devices 1 and 2 must match. Before the start of the radio exchange session for the transmitting and receiving devices 1 and 2, a single scenario (control matrix) of the radio exchange is established, i.e. a sequence of antennas 7 (their numbers) through which the radiating antenna system of the transmitting device 1 will emit a particular fragment of the data stream. A similar approach to the designation of a radio exchange scheme (only in the frequency domain) is known and used, in particular, in the FHSS technology (an example of its application is Bluetooth technology). This allows you to increase the signal-to-noise ratio at the input of the receiving device 2.

The signals with individual polarization, having spread in space, fall on the antenna unit of the receiving device 2, where, using a given mathematical algorithm, they are processed to identify the signal and are arranged in a sequence of pulses in strict accordance with the order of their radiation by the transmitting device 1.

The signals from the transmitting device 1, arriving at the logical device 3, are supplied with the last defined coding feature (code) corresponding to the antenna number 7 - "N ₁ ", through which this particular signal is subsequently radiated into space. From the output of the logical device 3, the signals provided with codes are fed to an electronic switch 5, which, in accordance with the assigned codes (and therefore the antenna numbers), sequentially distributes the signals to each of the N antennas 7 of the transmitting device 1.

Since the antennas 7, located in the same plane, are located relative to each other at a certain angle α, the polarizations of the radio waves emitted by them will also differ from each other, namely, by this angle α. In the particular case at α = 360 ° / N, i.e. with a uniform distribution of antennas 7, the radio exchange system according to the proposed method becomes more resistant to random changes in the relative position of the blocks of antennas 7 of the transmitting and receiving devices 1 and 2.

Having spread in space, radio waves reach the antennas 7 of the receiving device 2 - the subscriber. Switch 6, whose operation is synchronized with the operation of switch 5, sequentially "polls" antennas 7, sending signals to the logic device 4 of the receiving device 2. The latter, using the codes of the received signals, restores the original sequence of transmitted data and transmits them for further use.

The proposed method is a variation of the method of spatial coding of signals (an example is MIMO technology). It is known that the transmission of information using radio waves, it is necessary to modulate one of the 3 (or several at the same time) basic parameters of an electromagnetic wave: amplitude, frequency or phase. It is also known that electromagnetic waves (EMW) are characterized by one more parameter - polarization and can differ from each other by the angle of polarization. Most modern radio devices operate using vertical polarization of the wave, some of them horizontal (for example, terrestrial television systems), and some circular (for example, space communications). These technologies are widely used in modern radio engineering. The use of a particular type of polarization is dictated by the conditions for the propagation of radio waves and the technological features of a particular radio engineering system. At the same time, regardless of the polarization, all modern radio engineering systems use one of the above types of modulation — amplitude, frequency, or phase — to transmit information.

The proposed method allows you to use the 4th parameter of the electromagnetic wave, namely the polarization, and it is precisely as an informative parameter. The method allows, in addition, to select (depending on the state of the radio channel) the most preferred polarization of the radiation of radio waves under the given conditions. Methods using EMW polarization as an encoding feature, as well as optimizing the angle of polarization of radio waves depending on radio conditions, are currently unknown. The application of the proposed method allows the use of similar systems in conjunction with the known narrowband and broadband systems simultaneously. Radio communication can occur in the same frequency range, "on top" of existing systems, which can significantly save the frequency resource - one of the most important resources of radio systems, thereby expanding the capabilities of radio communications, significantly reducing the cost of traffic.

In contrast to the known methods of transmitting and receiving radio signals and extracting information in an information system, in the proposed method, radio exchange can be carried out simultaneously with other radio devices operating in the same frequency range, thereby expanding the technological resource of the multi-antenna system without creating practically interference to them. This makes it possible to increase the efficiency of the use of the frequency resource of the radio channel by increasing the throughput of the multi-antenna system, as well as increasing the noise immunity of radio systems, and improving the quality of the received signal in radio channels.

In general, the method is a variation of the spatial coding method of the signal, which allows to increase the throughput of the radio channel for multi-antenna systems, expand their functionality and increase their reliability.

Thus, the invention allows to increase the throughput of multi-antenna systems, to expand their technological resource, as the technology of spatial coding of information due to the formation of a multipolarized data stream, allows you to save the frequency resource of radio systems.

Claims (2)

1. The method of wireless transmission and reception of data, which consists in transmitting a data stream from a transmitting device to a receiving device using antenna units, each consisting of a plurality of N antennas, mutually oriented in space, using a given control matrix of transmitting and receiving data, characterized in that the signals from the transmitting device arrive at the logical device, are supplied with a certain coding attribute corresponding to the antenna number N, and then are sent to the electronic switch, which, in accordance with the assigned codes, sequentially distributes the signals to each of the N antennas of the antenna unit of the transmitting device, each of N antennas are placed in a vertical plane normal to the direction of radiation in such a way that two antennas are placed in each polarization plane, and adjacent antennas are oriented at an angle α between their longitudinal axes with the possibility of transmitting and receiving data by forming the many communication channels with different polarization of the radio signal. 2. The method according to p. 1, characterized in that the angle α between the longitudinal axes of the antennas is calculated by the formula α = 360 / N.

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