RU165173U1 - DEVICE FOR FORMING SIGNALS WITH FOUR-POSITION SQUARE MANIPULATION - Google Patents

Abstract

1. A signal conditioning apparatus with four-position quadrature keying (CCM), comprising a frequency divider (10), the output of which is connected to the second input (11.2) of the synchronizer (11), to the second input (7.2) of the balanced modulator (BM) (7) and to 90 ° phase shifter input (6), the output of which is connected to the second input (8.2) of the BM (8) and to the second input (12.2) of the synchronizer (12), to the first input (12.1) of which the output of the second information pulse source (2) is connected , the output of the synchronizer (12) is connected to the second input (4.2) of the phase manipulator (4), to the first input (4.1) of which the phase shifter output is connected at 90 ° (5), and the output of the phase manipulator (4) is connected to the first input (8.1) of the BM (8), the output of which is connected to the second input (9.2) of the adder (9), to the first input (11.1) of the synchronizer (11) the output source of the first information pulse (1) is connected, and the output of the synchronizer (11) is connected to the second input (3.2) of the phase manipulator (3), the output of which is connected to the input (7.1) of the BM (7), the output which is connected to the first input (9.1) of the adder (9), the output of which is the output of the device, characterized in that in the device the commutator (16), the unit for multiplying the amplitude by the value (14), the unit for dividing the amplitude by the value (15), specifying the generator ЗГ (13), the first output (13.1) of which is connected to the input of the multiplication unit (14), the output of which is connected to the first input (16.1) of the switch (16), the second output (13.2) of the ЗГ (13) is connected to the input of the division unit (15), the output of which is connected to the second input (16.2) of the switch (16), to the third input (16.3) of which the source output of the first information pulse (1) is connected, and the second source output is connected to the fourth input (16.4) of the switch (16) and the data pulse (2), the switch output (16) connected to the first input (3.1) of the phase manipulator (3), to the input

Description

The technical solution relates to telecommunications, namely to digital radio communications, and can be used in information transmission systems using signals with quadrature keying.

The device described in ed. St. USSR 692109, class H04L 27/20, 1979 (a method of generating signals with quadrature phase modulation, called the authors of the signals of double phase telegraphy), which consists in the fact that the manipulating sequence of binary video signals from the message source (1) is supplied to the phase manipulator (3), from the message source ( 2) is fed to the delay unit (9), and then to the phase manipulator (4).

The carrier harmonic oscillation is supplied to the phase manipulator (3) and through the phase shifter (5) to the phase manipulator (4) with a shift of 90 °. Phase manipulators (3) and (4) form binary-manipulated radio signals with cosine and sine filling and a rectangular envelope.

The generated sequences of binary-manipulated radio signals are fed to the first inputs of balanced modulators (BM) (7) and (8), the other inputs of which receive a simulating harmonic signal with a frequency equal to half the symbol repetition rate, and the instantaneous value is zero at the beginning and end of the symbols arriving at the phase manipulators (3) and (4), while the modulating signal is fed directly to the BM (8), and to the BM (7) through the phase shifter (10) with a shift of 90 °. From the outputs of the BM (7) and (8), two sequences of phase-shifted signals arrive at the inputs of the adder (6). The output of the adder (6) is the output of the device.

The known device allows you to generate signals with quadrature phase modulation (CPM), the phase of which is continuous at the boundaries of the symbols, and the envelope is constant. The result is a reduction in the level of out-of-band emissions during transmission of the generated radio signals with a high transmitter efficiency.

A disadvantage of the known device for generating signals with CPM is the high level of out-of-band emissions during transmission of the generated radio signals, due to the presence of gaps in the first derivative of the generated signals at the borders.

Closest to the claimed is the device described in patent No. 2205518, IPC 7 H04L 27/20, 2003 (a method of generating signals with quadrature phase modulation), which consists in the fact that the carrier harmonic oscillation is split into in-phase and quadrature oscillations shifted by one relative to the other in phase by 90 °, using the phase shifter (5). The phase-in-phase and quadrature harmonic signals shifted relative to each other by 90 ° in phase with the help of a frequency divider (10) are (4k + 1) times, where k is an integer, and a phase shifter (6).

The manipulating sequences of binary video signals received from two message sources are shifted by half the symbol duration one relative to the other so that the phases of the in-phase and quadrature harmonic signals coincide with the phases of the in-phase and quadrature oscillations at the beginning and end of each symbol, respectively, using synchronizers (11) and (12 )

Manipulating in-phase and quadrature oscillations in phase by 180 ° are shifted from one another by half the symbol duration by manipulating sequences of binary video signals using phase manipulators (3) and (4).

Balanced modulation of the in-phase and quadrature binary-manipulated oscillations is performed, phase-shifted by 90 ° in phase and in-phase harmonic signals, with a frequency equal to half the symbol repetition rate, so that the envelopes of the obtained oscillations are equal to zero at the beginning and end of each symbol using BM (7) and (8).

Summarize the received vibrations using the adder (9).

The disadvantage of the prototype device is the relatively low noise immunity of the generated signal.

The purpose of the claimed technical solution is a device for generating four-position quadrature keying (ChKM) signals with an increased noise immunity.

The goal is achieved by increasing the average Euclidean distance between the points of the signal constellation. In addition, each point of the formed signal constellation has different values of the in-phase and quadrature components. Thanks to the new combination of these features, an increase in the noise immunity of the generated FMC signals is provided.

The inventive device is illustrated by drawings:

FIG. 1 - a device for generating ChKM signals;

FIG. 2 - temporary diagrams explaining the sequence of operations performed when generating the FMC signals;

FIG. 3 - synchronizer (11).

The claimed device shown in FIG. 1 consists of: a master generator ЗГ (13) whose first output (13.1) is connected to the input of the multiplication unit (14), the output of which is connected to the first input (16.1) of the switch (16). The second output (13.2) of the ЗГ (13) is connected to the input of the division unit (15), the output of which is connected to the second input (16.2) of the switch (16). The output of the switch (16) is connected to the first input (3.1) of the phase manipulator (3), to the first input (4.1) of the phase manipulator (4) through the phase shifter (5) and to the input of the frequency divider (10). The output of the frequency divider (10) is connected to the second input (11.2) of the synchronizer (11), to the second input (7.2) of the BM (7) and to the input of the phase shifter (6), the output of which is connected to the second input (12.2) of the synchronizer (12) and to the second input (8.2) BM (8). The output of the first message source (1) is connected simultaneously to the third input (16.3) of the switch (16) and to the first input (11.1) of the synchronizer (11) whose output is connected to the second input (3.2) of the phase manipulator (3). The output of the phase manipulator (3) is connected to the first input (7.1) of the BM (7) whose output is connected to the first input (9.1) of the adder (9). The output of the second message source (2) is connected to the fourth input (16.4) of the switch (16) and to the first input (12.1) of the synchronizer (12) whose output is connected to the second input (4.2) of the phase manipulator (4). The output of the phase manipulator (4) is connected to the first input (8.1) of the BM (8) whose output is connected to the second input (9.2) of the adder (9). The output of the adder (9) is the output of the device.

ZG (13) is designed to generate a cosine-shaped reference voltage. As a ZG, a scheme of a bridge cosine-wave signal generator (Wines generator) can be used (see. I got I. Operational amplifiers. - M, Mir, 1982. - P. 200-201, Fig. 6.27).

(первый коэффициент трансформации). В качестве блока умножения может быть использована схема операционного усилителя патент №2070768 от 20.12.1996 г.The multiplication unit (14) is designed to increase the voltage of the reference oscillation in

(first transformation ratio). As a multiplication unit, the circuit of the operational amplifier of the patent No. 2070768 of December 20, 1996 can be used.

(второй коэффициент трансформации). В качестве блока деления может быть использован электронный аттенюатор патент №2425440 от 27.07.2011 г.The division unit (15) is designed to reduce the voltage of the reference oscillation in

(second transformation ratio). The electronic attenuator patent No. 2425440 of July 27, 2011 can be used as a division block.

The switch (16) is designed to switch off the increased or decreased voltage of the reference oscillation, depending on the information values of the signals coming from the first and second message sources. As a switch, a bi-directional switch controlled by the XOR logic element with two digital inputs can be used.

The frequency divider (10) divides the frequency of the reference oscillation (4k + 1) times, where k is an integer. The implementation of the frequency divider is known and described in RF patent No. 2266609.

Phase shifters (5), (6) are designed to shift the phase of the reference oscillation by 90 °. The implementation of the phase shifter is known (see. I got I. Operational amplifiers - M., Mir, 1982 - S. 196, Fig. 6.20).

Phase manipulators (3), (4) manipulate in-phase and quadrature oscillations in phase by 180 °. Their implementation is known and described in the patent of the Russian Federation No. 2379797 from 01.20.2010

Balanced modulators (7), (8) perform balanced modulation of in-phase and quadrature binary-manipulated oscillations, 90 ° shifted from one another in phase. The implementation of balanced modulators is known and described in patent SU 372640 of 05.21.1973.

The adder (9) is designed to add balance-modulated in-phase and quadrature components. As an adder (9), a summing amplifier circuit was used (see. I got I. Operational amplifiers. - M.: Mir, 1982. - P. 184-185, Fig. 6.7).

Synchronizers (11), (12) are designed to synchronize the phases of the in-phase and quadrature harmonic signals with the phases of the information signals coming from the first and second message sources, respectively, so that their phases coincide at the beginning and end of each symbol.

The synchronizer (11) consists of a pulse phase detector (IPD) (11.1.1), a controlled delay line (ULZ) (11.1.2), and an amplitude limiter (11.1.3). The input of the amplitude limiter (11.1.3) is the input (11.2) of the synchronizer (11), and the output is connected to the second input of the IFD (11.1.1), the first input of which is the input (11.1) of the synchronizer (11). The output of the IFD (11.1.1) is connected to the first input of the ULZ (11.1.2), the second input of which is connected to the input (11.1). The output of the ULZ (11.1.2) is the output of the synchronizer (11).

IFD (11.1.1) is designed to compare the phases of the vibrations arriving at its inputs and the formation of the control voltage by the results of the comparison. The implementation of IFD is known and described in patent No. 2012992 of 05.15.1994.

ULZ (11.1.2) is designed to delay information pulses for a time corresponding to the control voltage. The implementation of the ULZ is known and described in patent No. 2024185 of November 30, 1994.

The amplitude limiter (11.1.3) is designed to convert a harmonic signal into a pulse sequence. As an amplitude limiter, it is possible to use a two-sided limiter, the implementation of which is known and described in “200 Selected Electronics Circuits” by Mathew Mandle Editorial Board on Computer Science and Electronics, Russian translation, Mir, 1985, 1980 - p. 128.

The synchronizer device (12) is identical to the synchronizer device (11).

The claimed device for generating ChKM signals works as follows. The two initial information bit sequences come from the outputs of the first (1) and second (2) message sources simultaneously to the inputs of the first (11) and second (12) synchronizers, respectively, and to the third (16.3) and fourth (16.4) control inputs of the switch (16 )

Upon receipt of the third (16.3) control input of the switch (16) from the output of the first (1) source of messages of a single informational pulse (AI), and the fourth (16.4) control input of the switch (16) from the output of the first (2) source of messages of a single AI the reference oscillation coming from the second output (13.2) of the exhaust gas (13) to the input of the division unit (15), in which its amplitude is divided by K ₂ , and then received at the controlled input (16.2) of the switch (16) it is switched on its output (Fig . 2a) from the output of which it enters the frequency divider (10) in which that the reference oscillation is divided into 4k + 1 (where k - integer). From the output of the frequency divider (10), the low-frequency cosine oscillation goes to the second (11.2) input of the synchronizer (11) in which it is synchronized with the unit AI coming to its first (11.1) input from the output of the first message source (1), so that their phases coincided at the beginning and end of the AI. Then, the synchronized single AI (Fig. 2d) from the output of the synchronizer (11) goes to the second (3.2) input of the phase manipulator (3), the first (3.1) input of which from the output of the switch (16) receives a weakened cosine reference oscillation (Fig. 2a ) The phase manipulator (3) will change the phase of the weakened cosine reference oscillation by 180 °. The resulting quadrature component (CS) (Fig. 2e) comes from the output of the manipulator (3) to the first (7.1) input of the BM (7) to the second (7.2) input of which the low-frequency cosine oscillation enters from the output of the frequency divider (10). BM (7) performs the balanced modulation of the CS according to the law of low-frequency cosine oscillation. The balanced-modulated CS (Fig. 2g) from the output of the balanced modulator (7) is fed to the first (9.1) input of the adder (9).

At the same time, from the output of the frequency divider (10), the low-frequency cosine oscillation goes to the input of the phase shifter (6) which shifts its phase by 90 °, from its output the low-frequency sinusoidal wave goes to the second (12.2) input of the synchronizer (12) in which it synchronizes with received at its first (12.1) input from the output of the second message source (2) as a single AI, so that their phases coincide at the beginning and end of the AI. Then, the synchronized single AI (Fig. 2b) from the output of the synchronizer (12) goes to the second (4.2) input of the phase manipulator (4), the first (4.1) input of which from the output of the switch (16) receives 90 ° shifted in phase in the phase shifter (5) attenuated cosine support oscillation (Fig. 2a). The phase manipulator (4) changes the phase of the weakened sinusoidal reference oscillation by 180 °. The in-phase component (SS) formed as a result of this (Fig. 2c) comes from the output of the manipulator (4) to the first (8.1) input of the BM (8) to the second (8.2) input of which the low-frequency sinusoidal oscillation comes from the output of the phase shifter (6). BM (8) performs balanced modulation of the SS according to the law of low-frequency sinusoidal oscillation. The balanced-modulated SS (Fig. 2e) from the output of the BM (8) is fed to the second (9.2) input of the adder (9). In the adder, the CS and SS are added, as a result of which the resulting oscillation is formed at the output of the adder (Fig. 2c) corresponding to the point of the signal constellation.

Upon receipt of the third (16.3) control input of the switch (16) from the output of the first (1) source of messages of zero AI, and the fourth (16.4) of the control input of the switch (16) from the output of the first (2) source of messages of zero AI , as in the case when a single AI arrives at the third (16.3) control input of the switch (16) from the output of the first (1) message source, and the fourth (16.4) control input of the switch (16) comes from the output of the first (2) message source single AI, except that phase manipulation Torr (3) does not change the phase of the attenuated cosine reference oscillation 180 °, and the phase manipulator (4) also does not change the phase of the attenuated sine wave reference oscillation 180 °.

Upon receipt of the third (16.3) control input of the switch (16) from the output of the first (1) source of messages of zero AI, and the fourth (16.4) of the control input of the switch (16) from the output of the first (2) source of messages of a single AI, the reference oscillation coming from the first output (13.1) of the SG (13) to the input of the multiplication unit (14), in which its amplitude is multiplied by K ₁ , and then received at the controlled input (16.1) of the switch (16) is switched to its output (Fig. 2a), from the output of which it enters the frequency divider (10) in which the frequency of the reference oscillation d divisible by 4k + 1 (where k - integer). From the output of the frequency divider (10), the low-frequency cosine oscillation goes to the second (11.2) input of the synchronizer (11) in which it is synchronized with the zero AI arriving at its first (11.1) input from the output of the first message source (1), so that their phases coincided at the beginning and end of the AI. Then, the synchronized zero AI (Fig. 2d) from the output of the synchronizer (11) goes to the second (3.2) input of the phase manipulator (3), the first (3.1) input of which from the output of the switch (16) receives the amplified cosine reference oscillation (Fig. 2a ) The phase manipulator (3) will not change the phase of the amplified cosine reference oscillation by 180 °. The CS formed as a result of this (Fig. 2e) comes from the output of the phase manipulator (3) to the first (7.1) input of the BM (7) to the second (7.2) input of which the low-frequency cosine oscillation enters from the output of the frequency divider (10). BM (7) performs the balanced modulation of the CS according to the law of low-frequency cosine oscillation. The balanced-modulated CS (Fig. 2g) from the output of the balanced modulator (7) is fed to the first (9.1) input of the adder (9).

At the same time, from the output of the frequency divider (10), the low-frequency cosine oscillation goes to the input of the phase shifter (6) which shifts its phase by 90 °, from its output the low-frequency sinusoidal wave goes to the second (12.2) input of the synchronizer (12) in which it synchronizes with received at its first (12.1) input from the output of the second message source (2) as a single AI, so that their phases coincide at the beginning and end of the AI. Then, the synchronized single AI (Fig. 2b) from the output of the synchronizer (12) goes to the second (4.2) input of the phase manipulator (4), the first (4.1) input of which from the output of the switch (16) receives 90 ° shifted in phase in the phase shifter (5) enhanced cosine support oscillation. The phase manipulator (4) changes the phase of the amplified sinusoidal reference oscillation by 180 °. The SS formed as a result of this (Fig. 2c) comes from the output of the phase manipulator (4) to the first (8.1) BM input (8) to the second (8.2) input of which a low-frequency sinusoidal oscillation comes from the output of the phase shifter (6). BM (8) performs balanced modulation of the SS according to the law of low-frequency sinusoidal oscillation. The balanced-modulated SS (Fig. 2e) from the output of the balanced modulator (8) goes to the second (9.2) input of the adder (9). In the adder, the CS and SS are added, as a result of which the resulting oscillation is formed at the output of the adder (Fig. 2c) corresponding to the point of the signal constellation.

Upon receipt of the third (16.3) control input of the switch (16) from the output of the first (1) message source of a single AI, and the fourth (16.4) control input of the switch (16) from the output of the first (2) message source of a zero AI, the device works in a similar way , as in the case when the third (16.3) control input of the switch (16) from the output of the first (1) message source receives a zero AI, and the fourth (16.4) control input of the switch (16) from the output of the first (2) message source single AI, except that phase Yator (3) modifies the amplified cosine phase reference oscillation 180 °, and the phase manipulator (4) does not change fazuusilennogo sinusoidal reference oscillation 180 °.

The synchronizer (11) operates as follows. The low-frequency cosine oscillation supplied to the second input (11.2) of the synchronizer (11) is fed to the input of the amplitude limiter (11.1.3), which converts it into pulsed oscillation. From the outputs of the amplitude limiter (11.1.3), the pulse oscillation is fed to the second input of the IFD (11.1.1) in which it is compared in phase with the AI received at its first input from the first input (11.1) of the synchronizer (11). As a result of the comparison, the control voltage is generated at the output of the IFD (11.1.1), which is supplied to the control input of the ULZ (11.1.2), to the controlled input of which the AI arrives. ULZ (11.1.2) delays the incoming AI for a time interval corresponding to the control voltage. The time-delayed AI from the output of the ULZ (11.1.2) is sent to the output of the synchronizer (11).

Synchronizer (12) works just like synchronizer (11).

The switch (16) operates as follows. Upon receipt of a single AI at its third input (16.3), and a zero AI at the fourth input (16.4) or a zero AI at the third input (16.3), and a reinforced reference is switched to the output of the switch (16) wobble from its first entrance (16.1). When a single AI arrives at its third input (16.3), and a single AI arrives at the fourth input (16.4) or a zero AI at the third input (16.3), and a zero AI at the fourth input (16.4), the attenuated output of the switch (16) reference oscillation from its second input (16.2).

The result of the operation of the claimed device is the generation of CCM signals shown in FIG. 2a. Due to the achieved result, each point of the signal structure is determined by different and non-repeating values of the in-phase and quadrature components. In addition, the average Euclidean distance between the points of the signal constellation increases. This leads to an increase in the noise immunity of the formation of FMC signals in comparison with the prototype device.

Claims (2)

1. A signal conditioning apparatus with four-position quadrature keying (CCM), comprising a frequency divider (10), the output of which is connected to the second input (11.2) of the synchronizer (11), to the second input (7.2) of the balanced modulator (BM) (7) and to 90 ° phase shifter input (6), the output of which is connected to the second input (8.2) of the BM (8) and to the second input (12.2) of the synchronizer (12), to the first input (12.1) of which the output of the second information pulse source (2) is connected , the output of the synchronizer (12) is connected to the second input (4.2) of the phase manipulator (4), to the first input (4.1) of which the phase shifter output is connected at 90 ° (5), and the output of the phase manipulator (4) is connected to the first input (8.1) of the BM (8), the output of which is connected to the second input (9.2) of the adder (9), to the first input (11.1) of the synchronizer (11) the output source of the first information pulse (1) is connected, and the output of the synchronizer (11) is connected to the second input (3.2) of the phase manipulator (3), the output of which is connected to the input (7.1) of the BM (7), the output which is connected to the first input (9.1) of the adder (9), the output of which is the output of the device, characterized in that in the device the commutator (16), the unit for multiplying the amplitude by the value

(14), the unit for dividing the amplitude by

(15), the master generator of the exhaust gas (13), the first output (13.1) of which is connected to the input of the multiplication unit (14), the output of which is connected to the first input (16.1) of the switch (16), the second output (13.2) of the exhaust gas (13) is connected to the input of the division unit (15), the output of which is connected to the second input (16.2) of the switch (16), to the third input (16.3) of which the output of the source of the first information pulse (1) is connected, and to the fourth input (16.4) of the switch (16) the output of the second source of the information pulse (2) is connected, the output of the switch (16) is connected to the first input (3.1) of the phase manipulator (3), to the input of the phase shifter (5) and to the input of the frequency divider (10). 2. ChKM signal generation device according to claim 1, characterized in that the synchronizer (11) consists of a pulse phase detector (IFD) (11.1.1), a controlled delay line (ULZ) (11.1.2), and an amplitude limiter (11.1. 3), the input of which is the input (11.2) of the synchronizer (11), and the output is connected to the second input of the IFD (11.1.1), the first input of which is the input (11.1) of the synchronizer (11), the output of the IFD (11.1.1) is connected to the first input of the ULZ (11.1.2), the second input of which is connected to the input (11.1), and the output to the output of the synchronizer (11).

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