RU2075832C1 - Method for three-dimensional distributed reception of signal which is transmitted through multiple-beam channel and device which implements said method - Google Patents

Abstract

FIELD: radio engineering, communication devices. SUBSTANCE: method involves putting receiving antenna elements along straight line which is directed towards signal source and optical addition of distribution signals so that each distribution signal is calculated as coherent addition of signal from first receiving antenna which is used as reference to signals of other receiving antennas. Said receiving antennas are spaced by distance which is multiple of wave length and is greater than it. Corresponding device has N receiving antennas 1, N-1 coherent addition units 2, majority weight adder 3 and additional coherent addition unit 4. EFFECT: increased functional capabilities. 2 cl, 2 dwg

Description

 The invention relates to radio engineering, in particular to radio communication technology, and can be used in decameter (DCM) communication systems.

 In decameter radio lines, when receiving discrete information (DI) under conditions of interference fading of signals caused by the multipath of the medium of propagation of radio waves, a lone reception cannot sufficiently provide noise immunity.

A well-known method that provides increased noise immunity, is the diversity reception on parallel channels with subsequent coherent or discrete addition of the received CI [1]
A known method of diversity reception using a negative correlation of fading signals in parallel channels [2]
This method is based on a radio wave propagation model in which a negative correlation of fading in spatially separated reception points is possible, and assumes the presence of a radiation source, for example, a radio transmitter with a single vertical vibrator, a propagation medium in which there is a single wave arrival path to the direct reception point ("terrestrial wave "), and the other with reflection from a vertical plane, for example, from the ionospheric layer, and at least two radiation detectors, for example, in the form of a vertical vibrator 's antennas spaced at a distance of about several wavelengths. The occurrence of negatively correlated signal fading in the receiving elements depends on a number of parameters: the distance of the path, the height of the reflecting layer, the spatial separation between the receiving antennas.

 When organizing radio communications in the DCM range on routes with a length of 500 km or more, the “earth wave” is practically absent. At the same time, experimental data are known that indicate that several rays of the signal (at least two) reflected from different layers of the ionosphere arrive at the receiving point [3] In the case of multipath, in particular two-beam, propagation of radio waves along paths with a length of 500 km and more, it is possible to create conditions for the occurrence of a negative correlation of signal fading.

 This spatial diversity method does not use the negative reception correlation capability of blocking the signals, since immediately the addition of all signals from the diversity receiver elements is applied in a coherent or incoherent manner.

 A known method of diversity receiving a signal from a radiation source [4] is selected as a prototype and consists of placing three receiving elements on a straight line oriented to the radiation source at a distance greater than the wavelength and a multiple of it from each other and the subsequent optimal addition of diversity signals, and each of the diversity signals is formed as a result of coherent addition of signals from the middle receiving antenna element with each of the extreme receiving antenna elements.

 The disadvantage of this method is the inability to use the negative correlation of signal fading in the diversity branches to the full.

 A device for multi-channel coherent combining of diversity signals [4] The device contains spatially separated antenna elements, a combining device (coherator), a decision circuit, as well as a main selection filter, a normalizing amplifier, an adjustable amplifier and a control device containing a decision circuit, a meter in each receiving channel VIP module: averager and a functional converter connected to a weighting standardization scheme.

 The disadvantage of this device is that all reception channels are involved in coherent addition, the signals in which can be significantly attenuated due to fading in the communication channel.

 A spatial diversity device [5] is also known as a prototype. This device contains three antenna receiving elements located on a straight line oriented to the radiation source, at a distance from each other greater than the wavelength and a multiple of it, two coherent addition units, the inputs of which are connected to the middle and the corresponding extreme receiving antenna element, and the outputs are connected to the block of optimal addition. In this device, the distance between the pairs of receiving elements is fixed and only two pairs are used.

 The possibility of using a negative correlation of signal fading in the diversity branches is extremely limited.

 The invention provides increased noise immunity of the reception of discrete information in the radio lines of the DCM range.

 This is achieved by the fact that the method of spatial diversity reception using a negative correlation of fading signals in the reception channels is based on a two-beam model of propagation of radio waves in the DCM range. This model assumes the presence of a radiation source, for example, a radio transmitter with a single vertical vibrator, a propagation medium in which the wave travels to the receiving point in two ways, reflected from different height layers of the ionosphere, and at least two radiation receivers, for example, in the form of vertical vibrator antennas spaced in space at a distance of several wavelengths.

 The problem is also solved by the fact that an additional block of coherent addition is introduced into the device that implements the claimed method, the inputs of which are connected to the outputs of the receiving antenna elements, and the output to the additional input of the optimal addition block, made in the form of a majority weighting summation block, and other inputs of the blocks coherent addition connected to the output of the first receiving antenna element.

 The use of a negative correlation of signal fading allows for multiple spatially spaced reception, among the diversity branches of which there are most likely negatively correlated ones, which ensures an increase in the noise immunity of receiving discrete information in DCM radio lines.

 The claimed method of spatial diversity reception includes the transmission of waves through a multipath channel and their reception with the separation of the receiving elements in space at a distance of the order of several wavelengths. Reception is carried out on several receiving elements mounted on a straight line oriented to the radiation source, at a distance from each other greater than the wavelength and a multiple thereof, with the subsequent optimal addition of diversity signals, each diversity signal being formed as a result of coherent addition of the signal of one receiving element, which is a reference one, with a signal from each of the remaining antenna receiving elements. In FIG. Figure 1 shows a probable model of two-wave propagation of radio waves; in FIG. 2 is a structural electrical diagram of a device that implements the claimed method.

 The spatial diversity device comprises N spatially diverse receiving antenna elements 1, N-1 of coherent addition blocks 2, a majority weight summation block 3 and an additional coherent addition block 4.

 The first inputs of all blocks of coherent addition 2 are connected to the first receiving antenna element 1,1, the second inputs are connected to the corresponding antenna elements 1,2-1. All antenna elements are also connected to the inputs of the additional coherent addition unit 4. The outputs of the coherent addition 2 blocks and the additional coherent addition 4 are connected to the inputs of the majority weighting summation block 3, the output of which is the output of the device.

 The blocks of coherent addition 4 and coherent addition 2 are designed to operate at an intermediate frequency and contain controlled phase shifters and a control circuit. They can be implemented similarly to the coherent signal addition unit used in the commercially available multi-channel RADRA R-692 multi-channel radio receiver.

 The majority weighting block 3 operates according to the principle described in the book of L. M. Fink [6] A more specific description is given in the article by G. A. Zhukov [7] The block diagram contains a synchronization device and a signal comparison device that evaluates short blocks of information, for example, 8-10 characters long at a speed of 500 bps; such a block length corresponds to the period of quasi-stationarity of the DCM channel. Based on the evaluation results, for example, according to the maximum number of correctly received discrete information signs, a decision is made on assigning a receiving channel of weight 0 or 1.

 The device operates as follows. In accordance with the model of propagation of radio waves (Fig. 1) in the antenna elements 1 and I and II, spaced apart by a distance Δ, each beam of a two-beam electromagnetic field induces a voltage Ui.

Коэффициент корреляции между напряжениями, индуцированными в антенных элементах I и II, определяется по формуле:

где

K отношение амплитуд второго и первого луча;
Φ разность фаз между напряжениями, индуцированными двумя лучами в антенном элементе; черта над символом означает усреднение по ансамблю v.The phase difference between these voltages is determined as:

The correlation coefficient between the voltages induced in the antenna elements I and II is determined by the formula:

Where

K is the ratio of the amplitudes of the second and first ray;
Φ the phase difference between the voltages induced by two beams in the antenna element; the bar above the symbol means averaging over the ensemble v.

RE in expression (2) changes its value from +1 to -1 depending on the value of D with fixed steel parameters (path length D, height of ionospheric layers H ₁ and H ₂ , operating wavelength l). In N spatially separated antenna elements installed on the same straight line with the distance between elements D with a probability of 100% there are also elements for which the correlation coefficient relative to the first element is negative.

 The signals received by the antenna elements are fed to two-channel blocks of coherent addition. When adding signals in diversity channels with a negative correlation coefficient, the probability of an error in receiving a CI element is 1.5-2 orders of magnitude less than in channels with a positive correlation coefficient. After addition in the blocks of coherent addition 2 and demodulation, the DI arrives at the inputs of the majority weighting summation block 3. Here, the reception channels are selected according to the number of correctly received elements (or signs) of the DI. Moreover, channels with the number of errors exceeding a certain predetermined threshold receive a weight of 0 and the signals received through them do not participate in further processes. The signals in the channels with the number of errors not exceeding the threshold are subjected to discrete majority addition in block 3.

 At the same time, there is a coherent addition of signals of all the receiving elements in an additional coherent addition unit 4. The need for this type of addition is due to the fact that in a real situation when communicating in the DCM range, the presence of a two-beam wave propagation model, although likely, is not necessary. In other conditions, coherent multichannel addition may be more effective than pairwise. The choice of the addition method, more effective in a coherent situation, is carried out by the majority weighting unit 3.

 The proposed method and device that implements it, allows you to determine channels with a negative correlation of fading (by the minimum probability of errors) and to provide increased gains in the probability of errors.

Claims (2)

 1. The method of spatial diversity receiving a signal from a radiation source transmitted over a multipath channel, comprising placing the receiving antenna elements on a straight line oriented to the radiation source, at a distance from each other greater than the wavelength and its multiple, and the subsequent optimal addition of diversity signals, each of the diversity signals is formed as a result of coherent addition of the signal from one receiving antenna element, which is the reference, with the signal of each of the other antenna receiving x elements, characterized in that the reference receiving antenna element is a first receiving antenna element.  2. The device is a spatial diversity of the reception of a signal from a radiation source transmitted over a multipath channel, containing N receiving antenna elements located on a straight line oriented to the radiation source, at a distance from each other greater than the wavelength or multiple of it, N-1 blocks of coherent addition , one of the inputs of the i-th block of coherent addition, where i = 1,2, N-1, is connected to the output of the j-th receiving antenna element, where j = 2,3, N, the block of optimal addition, the inputs of which are connected to the outputs coherent addition blocks, the moves of which are connected to the outputs of coherent addition units, characterized in that an additional coherent addition unit is introduced into it, the inputs of which are connected to the outputs of the receiving antenna elements, and the output to the additional input of the optimal addition unit, made in the form of a majority weighting summation block, and other inputs coherent addition units are connected to the output of the first receiving antenna element.

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