RU224777U1 - INVARIANT AMPLITUDE DEMODULATOR WITH TWO REFERENCE SIGNALS - Google Patents

Abstract

The utility model relates to the field of systems, networks and devices of telecommunications and radio engineering and can be used in radio transmitting devices, telecommunication systems and devices that require receiving an amplitude-modulated received signal from a communication channel. The technical result of the utility model is the ability to form information elements from the received amplitude-modulated received signal via a communication channel from the message transmitter to the recipient. A dual-reference invariant amplitude demodulator uses two reference signals and an amplitude-modulated received signal that contains information elements, allowing a greater variety of signals to be used in a communications system, rather than just signals of similar shapes as in the well-known invariant amplitude demodulation. The location line of the ends of the vectors of transmitted signals can occupy an arbitrary position in the coordinate system of the signal space. 2 ill.

Description

The utility model relates to the field of systems, networks and devices of telecommunications and radio engineering and can be used in radio transmitting devices, telecommunication systems and devices that require receiving an amplitude-modulated received signal from a communication channel.

The achieved technical result of the utility model is aimed at the possibility of forming information elements from the received amplitude-modulated received signal via a communication channel from the message transmitter to the recipient.

This is achieved by the fact that the invariant amplitude demodulator uses two reference signals and an amplitude-modulated received signal, which contains information elements, which allows the use of a greater variety of signals in the communication system, and not only signals of a similar shape as in the well-known invariant amplitude demodulation. And in the vector representation, the line of location of the ends of the reference and information signal vectors can occupy an arbitrary position relative to the origin of the signal space coordinate system (Fig. 1).

The utility model proposes a modification of the well-known invariant amplitude demodulation, which takes the values of information elements by the ratio of the lengths of signal vectors lying on the same straight line passing through the origin of the signal space coordinate system [1]. A modification of such demodulation allows the use of signals whose vector ends lie on a straight line, not necessarily passing through the origin of the signal space coordinate system.

Synthesis of invariant amplitude demodulation with two reference signals.

In order to provide greater clarity to the procedure for synthesizing invariant amplitude demodulation with two reference signals, a two-dimensional signal space is used, the coordinate axes of which correspond to some orthonormal basic functions of time, for example, the Kotelnikov functions ϕ ₁ (t) and ϕ ₂ (t), differing in a time shift that provides their orthogonality. In this case, the signals can be represented by two time samples, the values of which specify the coordinates of the ends of the signal vectors in a two-dimensional signal space (Fig. 1).

In fig. 1 on the left shows a straight line occupying a general position and not passing through the origin of the signal space coordinate systems. Points A, B and C define the ends of the three input signal vectors .

As already mentioned [2, 3, 4], the transformation of input signals into output signals is described by an affine group of transformations. In fig. 1 dotted lines display the scheme of affine transformation of the ends of the vectors of input signals into the ends of the vectors of the corresponding output signals . One of the possible forms of writing the affine transformation invariant in the form of a “three-point relationship” in this example has the following form:

It is also possible to write the invariant as follows:

Let us assume that in (1) S ₁ (t) and S ₂ (t) play the role of so-called “reference signals”, and S ₃ (t) - information S ₁ (t). In this case, from (1) one can obtain the first invariant amplitude demodulation algorithm [2, 3]:

,

where ^∧ - sign means an estimate of the accepted value;

- assessment of the value of the received information element;

- estimation of the magnitude of the information signal vector;

- estimation of the magnitude of the vector of the first reference signal;

- estimation of the magnitude of the vector of the second reference signal;

i is the number of the time interval during which the value of the information element J _{i is transmitted.}

From expression (2) we can obtain the second invariant amplitude demodulation algorithm [2, 3, 4]:

Block diagram of an invariant amplitude demodulator with two reference signals.

The block diagram of the demodulator is shown in Fig. 2.

The scheme consists of:

BHIS - information signal storage unit;

BHPOS - storage unit of the first reference signal;

BHVOS - storage unit of the second reference signal;

BVRVOS - block for calculating the difference between reference signal vectors;

BOAIAD - block for determining the invariant amplitude demodulation algorithm;

BVRV - block for calculating the vector difference;

BVVO - error probability calculation block;

BGS and U - group synchronization and control unit;

divider;

demultiplexer.

The operation of the demodulator begins with receiving from the communication channel an estimate of the information signal, an estimate of the first and an estimate of the second reference signals, which are sequentially fed to the input of the demultiplexer. From the input of the demultiplexer, estimates of the information signal, estimates of the first and estimates of the second reference signals are supplied to the inputs of the information signal storage units (BHIS), the first reference signal storage unit (BHROS) and the second reference signal storage unit (BHVOS). Next, estimates of the first and second reference signals are sent to the block for calculating the difference in vectors of the reference signals (BVRVOS) and the block for determining the invariant amplitude demodulation algorithm (BOAIAD). In the BOAIAD, the algorithm is determined by which demodulation will be carried out according to expression (1) or (2). If the 1st demodulation algorithm is selected, then the second reference signal will be sent from the output of the BOAAIA; if the 2nd demodulation algorithm is selected, then the first reference signal will be sent from the output of the BOAAIA.

The selected reference signal from the BOAIAD and the evaluation of the information signal is sent to the vector difference calculation unit (VDC). The result obtained from the BVRV simultaneously with the result from the BVRVOS enters the divider. The resulting quotient from the divisor is sent to the error probability calculation block (EPBO), in which the correctness of the information element is determined and a decision is made to transmit the received information element to the message recipient or to request a repeat from the transmitting part.

When the first estimate of the information signal is received from the BOAIAD, the group synchronization and control block (BGS and U) receives a signal that invariant amplitude demodulation is carried out according to 1 demodulation algorithm. During the reception of information signal estimates from the BVVO, information about each incorrectly received information element is transmitted to the BOAIAD, where incorrectly received information elements are counted and the resulting number of incorrectly received information elements is compared with the threshold value stored in the BOAIAD. When the number of incorrectly received information elements exceeds the threshold value from the BOAIAD in the BGS and U and a signal is sent to the transmitting side that the operation of the invariant amplitude demodulator changes from demodulation algorithm 1 to demodulation algorithm 2 and the counter of incorrectly received information elements is reset. Next, the operation of the invariant amplitude demodulator is carried out according to the 2nd demodulation algorithm, and incorrectly received information elements are counted until the number of these elements exceeds the threshold value stored in the BOAIAD. After exceeding the threshold value of incorrectly received information elements, the BOAIAD sends a signal to the BGS and U and to the transmitting side that the operation of the invariant amplitude demodulator changes from 2 demodulation algorithms to 1 demodulation algorithm and the counter of incorrectly received information elements is reset. The operation of the invariant amplitude demodulator continues until the communication session is completed.

Coordinated operation of all blocks of the invariant amplitude demodulator with two reference signals is ensured by the group synchronization and control block. For clarity, in Fig. 2 from BGS and U to all blocks of the invariant amplitude demodulator with two reference signals, no lines are shown.

Conclusion.

The proposed utility model for an invariant amplitude demodulation communication system with two reference signals is a further generalization of the well-known invariant amplitude demodulation system [1].

The advantage of this utility model is that there is no need to ensure similarity of the shapes of the signals used, as is the case with the prototype. The location line of the ends of the vectors of transmitted signals can occupy an arbitrary position in the coordinate system of the signal space [2, 3, 4].

In addition, when changing the sequence of transmission of reference signals, taking into account the lengths of their vectors, it becomes possible to transmit a sign of positivity or negativity of the values of information elements. For example, a positive sign may be that the first temporal reference signal has a shorter vector length compared to the vector length of the second temporal reference signal. The negativity sign is transmitted in the reverse order of the reference signals.

Thus, the proposed invariant amplitude demodulation with two reference signals makes it possible to double the size of the alphabet of information elements compared to the prototype.

In invariant amplitude demodulation with two reference signals, in contrast to invariant amplitude demodulation, signals are used not of one shape, but of three different shapes - two different reference signals and an information signal, which also differs in shape from the reference ones. This means that to intercept messages transmitted by a two-reference invariant amplitude demodulation communication system, the enemy's task becomes three times more difficult. To calculate the value of the transmitted information element, it needs to detect and estimate the parameters of three previously unknown signals of different shapes, and not one shape, as in the case of a transmission system with invariant amplitude demodulation. Thus, it can be argued that the computational costs of intercepting messages in a communication system with invariant amplitude demodulation with two reference signals are three times higher compared to the prototype system.

Bibliography.

1. Lebedyantsev V.V. Development and research of methods for analysis and synthesis of invariant communication systems. Dissertation for the degree of Doctor of Technical Sciences. Novosibirsk, 1995

2. I.I. Pavlov Evaluation of noise immunity of a communication system with MIAM // Communications Bulletin. - 2020. - No. 5 p. 5.

3. Modified invariant amplitude modulation / B.V. Lebedyantsev, S.S. Abramov, I.I. Pavlov, E.V. Morozov, E.S. Abramova, M.S. Pavlova // T-Comm. Telecommunications and transport.2020. T. 14, No. 6. pp. 13-19.

4. Invariant information transmission systems in radio transmitting devices: textbook / I.I. Pavlov, E.S. Abramova, V.V. Lebedyantsev, M.S. Pavlova, S.S. Abramov, - Novosibirsk Siberian State University of Telecommunications and Informatics, 2019. - 125 p.

Claims (10)

An invariant amplitude demodulator with two reference signals, characterized in that it contains a demultiplexer configured to simultaneously generate, in time, an estimate of the information signal, an estimate of the first and second reference signals received from the communication channel, also consisting of an information signal storage unit (ISU), made with the ability to store the obtained estimate of the information signal from the communication channel, a first reference signal storage unit (FRS), configured to store the obtained estimate of the first reference signal from the communication channel, a second reference signal storage unit (BHROS), configured to store the obtained estimate of the second reference signal from the communication channel, BHPOS and BHVOS are connected to a block for calculating the difference of reference signal vectors (BVRVOS), configured to receive estimates of the first and second reference signal at its inputs, and at the same time BHPOS and BHVOS are connected to a block for determining the invariant amplitude demodulator algorithm (BOAIAD) , made with the ability to determine the algorithm by which demodulation will be carried out, if 1 demodulation algorithm is selected, then the second reference signal will be sent from the output of the BOAAIA, if the 2nd demodulation algorithm is selected, then the first reference signal will be sent from the output of the BOAAIA, the output of the BOAAIA and the output of the BHIS is connected to the block for calculating the vector difference (VVRV) with the possibility of receiving an evaluation of the information signal and estimating the reference signal from the BOAIAD at its inputs, the results obtained from the VVRVOS and VVRV are sent to the divider with the ability to perform mathematical division, the quotient obtained from the divider is supplied to the calculation block probability of error (BEP) with the ability to determine the correctness of the received information element and with the ability to decide whether to transmit the received information element to the recipient of the message or to request a replay from the transmitting part, the BPO has the ability to transmit error information to the BOAIAD when an incorrect received information element is detected, BOAIAD, in in turn, has the ability to count incorrectly received elements and compare them with threshold values; if the threshold value of incorrectly received elements is exceeded, the BOAIAD has the ability to change the demodulation algorithm and the counter of incorrectly received information elements is reset, and the BOAIAD is configured to carry out invariant amplitude demodulation according to 1 demodulation algorithm upon receipt of the first estimate of the information signal, with 1 demodulation algorithm where ∧ - sign means an estimate of the accepted value; - assessment of the value of the received information element; - estimation of the magnitude of the information signal vector; - estimation of the magnitude of the vector of the first reference signal; - estimate of the vector value of the second reference signal, i-number of the time interval during which the value of the information element J _i is transmitted a 2 demodulation algorithm also consisting of a group synchronization and control block with the ability to ensure coordinated operation of all blocks of the invariant amplitude demodulator with two reference signals.

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