RU2702750C1 - Method of generating hybrid phase-shift keyed signals by successive concatenation of radio pulses - Google Patents

Abstract

FIELD: radio equipment.

SUBSTANCE: invention relates to radio engineering and can be used in information transmission systems. In the method of generating hybrid phase-shift keyed signals (HPKS) by serial concatenation of radio pulses from a digital sequence, a control pulse sequence is generated in accordance with a predetermined rate of manipulation. Then, manipulating radio pulses are generated on the basis of harmonic oscillation and Gauss wavelet of the first order, which in accordance with digital sequence are supplied to the key device, at the output of which the resulting HPKS is obtained.

EFFECT: technical result is possibility of formation of hybrid phase-shift keyed signals without nonlinear multiplication operations, which simplifies technical implementation of devices based on it.

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Description

The invention relates to the field of radio engineering, and can be used in information transmission systems by means of phase-shift keyed signals (PMS).

A known method of generating signals with a constant envelope and m-ary phase-shift keying (Banquet V.L., Dorofeev V.M.Digital methods in satellite communications. - M .: Radio and communications, 1988., S. 36, 37 Fig. 2.1 , but).

The technical essence of the known method lies in the fact that using the switch, two streams of even and odd binary symbols, respectively, are formed from the digital information stream of symbols. Then, each of these streams is subjected to digital-to-analog conversion (DAC), and then multiplying (using balanced modulators) with the corresponding quadrature components of the carrier (subcarrier) oscillation. The multiplication results are summarized using an adder, the output of which receive a phase-shift signal (PMS).

The disadvantage of this method is the implementation of non-linear multiplication procedures that complicate the practical implementation of devices based on it.

A known method of generating signals with a constant envelope and m-ary phase shift keying (Banquet V.L., Dorofeev V.M.Digital methods in satellite communications. - M .: Radio and communications, 1988., p. 83, Fig. 3.3) consisting in the following: a digital sequence associated with information symbols is divided into two digital information sequences, each of the obtained DAC sequences is subjected to a corresponding digital-to-analog converter. Multiply one of the received signals with the in-phase component of the carrier (subcarrier) oscillation, and the other with the quadrature component of the carrier (subcarrier) oscillation. Adding the results of multiplication in the adder, the FMS is obtained at the output of the adder.

The disadvantage of this method is the implementation of non-linear multiplication procedures that complicate the practical implementation of devices based on it.

Closest in technical essence to the claimed invention is the "Method of generating a phase-shifted signal with a constant envelope" (Patent RU 2264044 IPC H04L 27/20 (200.01) publ. 10.11.2005, bull. No. 31).

The essence of the prototype method is that the digital sequence of information zeros and ones associated with information symbols is divided into two digital information sequences, the DAC of the two sequences obtained is carried out, one of the received signals with the in-phase component of the carrier / subcarrier oscillation is multiplied, and the other with the quadrature component of the carrier / subcarrier oscillation, and the received signals are summarized. Before dividing into two digital sequences, the digital sequence associated with information symbols is converted into the original information digital chaotic sequence by manipulating the control parameter of the generating recursive algorithm with information symbols; separation to obtain two digital information chaotic sequences is performed by quadrature conversion of the original information digital chaotic sequence.

The disadvantage of the prototype method is the limitation of its scope, which does not allow it to form hybrid phase-shift signals (HFS) based on it, consisting of fragments of radio signals of various functional bases, as well as the use of non-linear multiplication procedures and various transformations that complicate the technical implementation devices based on it.

The objective of the invention is to provide a method that expands the scope of its application, and allows you to form a HFS.

The technical result of the proposed method is the formation of HFS without non-linear operations of multiplication, which allows to simplify the technical implementation of devices based on it.

In the claimed method, the technical result is achieved by the fact that oscillations are generated from the digital sequence of information zeros and ones, which are summed up, while a control pulse sequence (UIP) is formed from the digital sequence of information zeros and ones, and the duration of each of the pulses of the generated UIP are and correspond to a predetermined speed of HFS manipulation, then manipulating radio pulses are formed to manipulate information zeros and ones, and in the quality of the radio pulses is chosen to be harmonic oscillation for the duration of one period and the first order Gaussian wavelet, while the amplitude value of the first order Gaussian wavelet is reduced to the level of the amplitude of the harmonic oscillation, and the duration of the harmonic oscillation period and the duration of the first order Gaussian wavelet defined as manipulating radio pulses are selected equal to the pulse durations of the formed UIP, the resulting HFS is formed by means of a serial concat nation of manipulating radio pulses using a key device with two inputs (KUDV), for which manipulating radio pulses are fed to KUDV, the inputs of which are switched under the influence of the generated SPS, while the first input of KUDV is supplied with a radio pulse generated from harmonic oscillation for a period of one period, and the second input - a radio pulse is generated, formed from a first-order Gaussian wavelet, the generated radio pulses are fed to the inputs of the KUDV in such a way that their phases in the resulting HFS are opposites to each other, in this case, if a radio pulse is used to manipulate the information zero, formed from harmonic oscillations for a duration of one period, then a radio pulse formed from a first-order Gaussian wavelet is used to manipulate an information unit, and, conversely, if the manipulation speed changes, the durations are changed of each of the pulses of the generated UIP, and, accordingly, the duration of the period of harmonic oscillation and the duration of the Gaussian wavelet of the first order, is determined s as manipulating radio pulses, and at the output of the KUDV, the resulting HFS obtained by successive concatenation of radio pulses is obtained.

The hybridity of the resulting signal consists in the use of fragments of radio signals from various functional bases for its formation. In the inventive method, a hybrid signal is formed from the basis of harmonic functions and from the basis of wavelet functions.

The claimed technical solution is illustrated by drawings, where

in FIG. 1 shows time plots explaining the sequence and nature of the HFS formation procedures by sequentially concatenating preformed radio pulses corresponding to information values of zeros and ones;

in FIG. 2 shows the radio pulses used for the formation of HFS: U (t) - formed from harmonic oscillations; Z (t) - formed on the basis of a first-order Gaussian wavelet without additional procedures to reduce its amplitude value (level) to the level of the amplitude of the radio pulse U (t); S (t) - formed on the basis of a Gaussian wavelet of the first order using additional procedures to reduce its amplitude value (level) to the level of the amplitude of the radio pulse U (t).

Implementation of the proposed method for the formation of HFS through the sequential concatenation of radio pulses involves the following operations.

1. An impulse sequence is formed from a digital sequence of information zeros and ones.

In this case, the duration of a single pulse transmission determines the transmission rate.

In general, the sequence can be any:

zero corresponds to an impulse of positive polarity, and to unity - negative;

zero corresponds to an impulse of negative polarity, and to unity - positive, etc.

2. Form manipulating radio pulses to manipulate information zeros and ones. The harmonic oscillation for the duration of one period and the Gaussian wavelet of the first order are chosen as radio pulses.

3. The amplitude value of the Gaussian wavelet of the first order is reduced to the level of the amplitude value of the harmonic oscillation.

It is possible to decrease the amplitude value, for example, by using an attenuator. The implementation of these procedures can reduce the peak factor of the resulting HFS.

As an example in FIG. 2 shows the radio pulses: U (t) - formed from harmonic oscillation; Z (t) - formed on the basis of a first-order Gaussian wavelet without additional procedures to reduce its amplitude value (level) to the level of the amplitude of the radio pulse U (t); S (t) - formed on the basis of a Gaussian wavelet of the first order using additional procedures to reduce its amplitude value (level) to the level of the amplitude of the radio pulse U (t).

4. The duration of the period of harmonic oscillation and the duration of the Gaussian wavelet of the first order, defined as manipulating radio pulses, is chosen equal to the pulse durations of the generated UIP.

The implementation of these procedures provides clock synchronization of the resulting HFS at the reception. As an example, FIG. 1c shows the radio pulses U (t), and FIG. 1d shows the radio pulses S (t).

5. The desired HFS is formed by sequential concatenation of manipulating radio pulses based on CUDW. Why manipulating radio pulses served on KUDV, the inputs of which are switched under the influence of the generated TPS. A radio pulse generated from harmonic oscillation U (t) for a duration of one period is supplied to the first input of the KUDV, and a radio pulse generated from the first-order Gaussian wavelet S (t) is supplied to the second input of the KUDV.

6. The generated radio pulses are fed to the KUDV inputs in such a way that their phases in the resulting HFS are opposite to each other. If a radio pulse formed from harmonic oscillation for a duration of one period is used to manipulate informational zero, then a radio pulse generated from a first-order Gaussian wavelet is used to manipulate an information unit, and vice versa.

The implementation of these procedures provides phase differences, on the basis of which at the reception they decide on the transmitted information symbol.

7. To change the speed of manipulation, the durations of each of the pulses of the generated UIP are changed, and, accordingly, the duration of the period of harmonic oscillations and the duration of the first-order Gaussian wavelet are defined as manipulating radio pulses.

8. The resulting HFS, formed by sequentially concatenating the radio pulses, is obtained at the output of the KUDV.

The concatenation process itself is implemented through a key scheme. As an example, in FIG. 1d shows the principle of HFS formation by sequentially concatenating radio pulses connected via a key.

Thus, in the inventive method, when it is implemented due to the sequential concatenation of radio pulses, formed from harmonic oscillations for a period of one period and from a first order Gaussian wavelet connected via a key, they provide the formation of a HFS without non-linear multiplication operations, which leads to the achievement of the goal of the claimed technical result .

Claims (1)

A method of generating hybrid phase-shifted signals by sequentially concatenating radio pulses, which consists in generating oscillations from a digital sequence of information zeros and ones, characterized in that a control pulse sequence is formed from a digital sequence of information zeros and units, and the duration of each of the pulses generated control pulse sequence are equal to each other and correspond previously for at the manipulation speed of the hybrid phase-manipulated signals, then manipulating radio pulses are formed to manipulate information zeros and ones, and harmonic oscillations for the duration of one period and a first-order Gaussian wavelet are selected as radio pulses, while the amplitude of the first-order Gaussian wavelet is reduced to the level of the harmonic amplitude oscillations, the duration of the period of harmonic oscillations and the duration of the first-order Gaussian wavelet defined in among the manipulating radio pulses, they are chosen equal to the pulse durations of the generated control pulse sequence, the resulting hybrid phase-manipulated signals are formed by sequentially concatenating the manipulating radio pulses using a key device with two inputs, for which the manipulating radio pulses are fed to a key device with two inputs, the inputs of which are switched under the influence of the generated control pulse sequence, while on n the first input of the key device with two inputs serves the radio pulse generated from harmonic oscillation for a duration of one period, and the second input serves the radio pulse generated from the first order Gaussian wavelet, the generated radio pulses are fed to the inputs of the key device with two inputs so that their phases in the resulting hybrid phase-shifted signals were opposite to each other, while if a radio pulse formed from harmonics is used to manipulate informational zero If the oscillation fluctuates over the duration of one period, then a radio pulse generated from a first-order Gaussian wavelet is used to manipulate the information unit, and vice versa, if the manipulation speed changes, the duration of each of the pulses of the generated control pulse sequence is changed, and accordingly, the duration of the harmonic oscillation period and the duration of the Gaussian wavelet first order, defined as manipulating radio pulses, and at the output of the key device with two input they receive the resulting hybrid phase-shift signals generated by the sequential concatenation of the radio pulses.

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