RU2672050C1 - Radio pulse train shaper with a large dynamic range - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: invention relates to radio engineering and can be used in bench equipment. Result is achieved due to the fact that the radio pulse train shaper with a large dynamic range contains carrier frequency generator, modulator, attenuator, pulse train envelope shaper and control unit, which are interconnected and made in a certain way.

EFFECT: technical result achieved – expansion of functionality.

6 cl, 2 dwg

Description

The invention relates to radio engineering and can be used in bench equipment for testing devices for processing radar signals.

In bench equipment for testing devices for processing radar signals, it is necessary to generate radio pulses at an intermediate frequency with different values of the amplitude, duration of the front and suppression in a pause without additional modulations and distortions.

In FIG. 2 for explanation, the spectrogram of the radio pulse of the present invention. In the signal spectrum, parasitic spectral components (MSS) are visible that limit the working dynamic range. The maximum value of signal A (minus 26 dBm, where dBm is the absolute power level is expressed in “decibels relative to one milliwatt”), the value B is the spurious spectral components (MSS) expressed in dBm (minus 110 dBm). The dynamic range of the radio pulse is D _pи (D _pи = А-В, in this case about 80 dB). C is the general spectrogram for the sequence of radio pulses. MSS can be interpreted as false targets in the Doppler range.

The dynamic range of the radio pulse, free of spurious components, is a dimensionless quantity equal to the ratio of the power of the useful narrow-band signal to the power of the largest spurious frequency component.

A device is known, “Digital Radar Shaper” (application No. 2015146971/07 for the utility model of the same name according to IPC G01S 13/00 of 02/02/2015), containing an output on which radar signals are simulated.

The disadvantages of the known device is that it generates radar signals with a dynamic range of 65 dB (see the formula of the well-known utility model), for high-quality development of radar receivers requires about 80 dB.

The closest in technical essence to the claimed invention is a device for generating radio pulses (patent No. 174639 for IPC Н03К 3/80 for 2017), containing a serially connected carrier frequency generator (in the known device, a sinusoidal signal source), a modulator (in the known device, a circuit on bipolar transistors) and the output of the sequence of radio pulses of the device, the second input of the modulator being its control input.

A disadvantage of the known device is that it lacks the possibility of forming and changing the length of the envelope of the sequence of radio pulses and pauses between them, as well as the formation of a single radio pulse with the possibility of changing its length. The patent for the device does not disclose the necessary details of the technical implementation of its most important analog key circuit, which provides mainly a large dynamic range of the sequence of radio pulses.

The technical result of the claimed invention is to expand the functionality and development of the prototype by ensuring the formation of the envelope of the sequence of radio pulses and single pulses with a change in their length and a change in the pauses between the radio pulses.

The specified technical result is achieved in that the generator of a sequence of radio pulses (FPR) with a large dynamic range, containing a series-connected carrier frequency generator, a modulator and the output of a sequence of radio pulses FPR, the second input of the modulator being its control input, characterized in that the carrier frequency generator is a series-connected circuit from a reference frequency distribution circuit, a first frequency divider, a frequency-phase detector, a lower filter their frequency and voltage-controlled oscillator, and also contains a second frequency divider and matching load, and the modulator is a series-connected circuit of the first band-pass filter, an analog key through its first signal input, and the second band-pass filter, and also contains a third band-pass filter and two low-pass filters, in addition, the FPF contains an attenuator and an envelope shaper of the sequence of radio pulses as part of the automatic frequency control circuit, two comparison circuits, a start trigger, and a counter Ika (MF), four OR circuits, a trigger for video pulses (Tg VI), in addition, the IDF contains an input, an output, and a group of control inputs. The input of the reference frequency distribution circuit is the input of the FPF, the first output of the voltage-controlled generator through the second frequency divider is connected to the second input of the frequency-phase detector, and its second output is connected to the input of the first band-pass filter, the output of the second band-pass filter through the attenuator is connected to the output of the PDF , the second signal input of the analog switch through the third bandpass filter is connected to the matching load, the output of the first circuit OR is connected to the input of the unit to the zero logical state (zero) Tg VI, the unit input of which is connected to the output of the second OR circuit, the direct output of which is connected through the first low-pass filter to the first control input of the analog key, the second control input of which is connected through the second low-pass filter to the inverse output Tg VI, the output of the third circuit OR is connected to the installation input to zero SC, the counting input of which is connected to the output of the first AND circuit and to the polling inputs of the first and second comparison circuits, the output of the second AND circuit is connected to the first input of the fourth OR circuit, the output of which is connected to the input of the installation to zero start Tg, the direct output of which is connected to the first input of the first circuit And, the second input of which is connected to the output of the frequency control circuit, the input of which is connected to the second output of the reference frequency distribution circuit, the output is "equal to" the first comparison circuit is connected to the first input the second AND circuit and the first input of the first OR circuit, the second input of which is connected to the installation unit in the start unit Tg and the FPF start input, the PDF input of the key signal input selection key is connected to the first input of the second OR circuit, the second input of which dinan with the output “equal” to the second comparison circuit and the first input of the third OR circuit, the second input of which is connected to the third input of the first OR circuit, with the second input of the fourth OR circuit and with the reset input of the PDF, the second input of the second circuit And is connected to the control input "Series / One" DFR, the first group of inputs of the first comparison circuit is the inputs of the "VI length code" FPR, the first group of inputs of the second comparison circuit is the inputs of the "VI code" of the FPR, the group of MF outputs is bitwise connected to the second groups of inputs of the first and second circuits comparisons.

In FIG. 1 and in FIG. 2, respectively, is a block diagram of the inventive device, a shaper of a sequence of radio pulses (PDF) and a spectrogram of a radio pulse obtained with its help.

The FPF contains a carrier (reference) frequency generator 1 with a reference frequency distribution circuit 1.1, a first frequency divider 1.2, a frequency-phase detector 1.3, a low-pass filter 1.4, a voltage controlled oscillator 1.5, a second 1.6 frequency divider and matched load 1.7, a modulator 2 with a first 2.1 and second 2.2 bandpass filters, analog key 2.3, third bandpass filter 2.4, first 2.5 and second 2.6 lowpass filters, attenuator 3, shaper 4 of the envelope of the sequence of radio pulses (sequence of video pulses) with automatic frequency control circuit 4.1, the first comparison circuit (cx cf. 4.2), the trigger 4.3 start, counter (MF) 4.4 length and repetition period of the video pulses (VI), the second comparison circuit 4.5, the first circuit OR 4.6, the second circuit OR 4.7 , trigger 4.8 VI, 3rd circuit OR 4.9, 4th circuit OR 4.10, 1st circuit And 4.11 and 2nd circuit And 4.12, as well as input 5, output 6 and group 7 of the control inputs FPR.

The control unit (CU) 8 FPF is not included in the device and is shown in FIG. 1 for clarification. At the same time, for the simplest manual control, the PDF BU 8 may contain a toggle switch 8.1 for selecting the first or second signal input of the analog key 2.3, the first 8.2 and second 8.3 dial-ups of the duration and period of the video pulses on the switches, respectively, the 8.4 Start button, the 8.5 Series / One toggle switch ”, Button 8.6“ Reset ”.

The elements used in the PDF, with the exception of blocks 1 and 2 (carrier frequency generator and modulator based on analogue key 2.3), are elements of wide application. All the logic of block 4 can be implemented on one FPGA chip with the corresponding connection elements.

As an analogue key 2.3, the domestic key 6400KX014, OKB-Planeta OJSC (www.okbplaneta.ru) is used, and MASWSS0192 from M / A-COM (www.macom.com) with high speed and linearity can be used as an analogue. In this technical implementation, an analog key 6400KX014 is used, which has first and second signal inputs, and control inputs are used as input control outputs. 1 and control 2.

Morion, a high-frequency precision crystal oscillator GK87-TS, is used as a voltage-controlled oscillator 1.5, and a miniature high-frequency low-noise precision crystal oscillator GK219-TS with the highest possible levels of relative spectral density of phase noise can be used as an analog.

A generator of a sequence of radio pulses (FPR) with a large dynamic range, containing serially connected carrier frequency generator 1, a modulator 2 and an output 6 of a sequence of radio pulses FPR, the second input of modulator 2 being its control input, while the carrier frequency generator 1 is a series-connected circuit of a reference frequency distribution circuit 1.1, a first frequency divider 1.2, a frequency-phase detector 1.3, a low-pass filter 1.4 and a voltage controlled oscillator 1.5, and also contains a second frequency divider 1.6 and matching load 1.7, and modulator 2 is a series-connected circuit from the first bandpass filter 2.1, the analog key 2.3 through its first signal input and the second bandpass filter 2.2, and also contains a third bandpass filter 2.4 and two lower filters frequencies 2.5 and 2.6, in addition, the FPF contains an attenuator 3 and an envelope shaper 4 of a sequence of radio pulses as part of a frequency lock 4.1, two comparison circuits 4.2 and 4.5, a start trigger 4.3, a counter (MF) 4.4, four the OR gate 4.6, 4.7, 4.9 and 4.10, the trigger for video pulses (Tg VI) 4.8, in addition, the FPG contains input 5, output 6 and a group of control inputs 7, while the input of the reference frequency distribution circuit 1.1 is input 5 of the FPF, the first output of the generator 1.5 controlled by voltage through a second frequency divider 1.6 is connected to the second input of the frequency-phase detector 1.3, and its second output is connected to the input of the first band-pass filter 2.1, the output of the second band-pass filter 2.2 through the attenuator 3 is connected to the output 6 of the PDF, the second signal input of the analog key 2.3 through third by the gloss filter 2.4 is connected to the matching load 1.7, the output of the first OR OR 4.6 circuit is connected to the input of the unit to the zero logical state (zero) ТГ ВИ 4.8, the unit input of which is connected to the output of the second OR OR 4.7 circuit, whose direct output through the first lower filter of frequencies 2.5 is connected, with the first control input of the analog key 2.3, the second control input of which is connected through the second low-pass filter 2.6 with the inverse output Tg VI 4.8, the output of the third circuit OR 4.9 is connected to the installation input to zero Sch 4.4, the counting input of which is connected with you during the first circuit And 4.11 and with the polling inputs of the first 4.2 and second 4.5 comparison circuits, the output of the second circuit And 4.12 is connected to the first input of the fourth circuit OR 4.10, the output of which is connected to the installation input to zero Tr starting 4.3, the direct output of which is connected to the first input the first AND 4.11 circuit, the second input of which is connected to the output of the frequency lock 4.1, the input of which is connected to the second output of the reference frequency distribution circuit 1.1, the output is "equal" to the first comparison circuit 4.2 is connected to the first input of the second And 4.12 circuit and the first input of the first OR 4.6, the second input of which is connected to the installation input in the unit Tg of start 4.3 and the input 7.4 "Start" of the FPF, the input 7.1 of the PDF of selecting the signal input of the key is connected to the first input of the second OR 4.7 circuit, the second input of which is connected to the output "equal" to the second comparison circuit 4.5 and the first input of the third circuit OR 4.9, the second input of which is connected to the third input of the first circuit 4.6 OR, with the second input of the fourth circuit OR 4.10 and with the input 7.6 "Reset" PDF, the second input of the second circuit AND 4.12 is connected to the input 7.5 of the control "Series / One »DPR, the first group of inputs of the first comparison circuit 4. 2 is the inputs 7.2 of the “ID length code” of the IDF, the first group of inputs of the second comparison circuit 4.5 is the inputs 7.4 of the “ID code of the length of the VI” IDF, the group of outputs SC 4.4 is bitwise connected to the second input groups of the first 4.2 and second 4.5 comparison circuits.

FPR works as follows.

We consider the PDF operation at a really used intermediate frequency of 60 MHz, input 48 a reference signal 48 MHz to synchronize blocks 1 and 4. To compare two signals on a frequency-phase detector, two division schemes are selected, the comparison occurs at 12 MHz.

The reference frequency signal (for example, from a standard master oscillator type GK87-TS, which is not part of the device) through the input 5 of the PDF, the distribution circuit 1.1 and the first frequency divider 1.2 is fed to the first input of the frequency-phase detector 1.3, to the second input of which a signal from the generator 1.5 through the second frequency divider 1.6 (feedback), and from the output of which, where the output voltage is formed, which is determined by the phase difference at its first and second inputs, the signal through the low-pass filter 1.4 acts on the generator 1.5, which synchronizes with the reference frequency.

Then, from the output of the generator 1.5 through the first bandpass filter 2.1, the signal is fed to the first signal input of the analog switch 2.3, from the output of which, when it is open, through the third bandpass filter 2.4 and the resistive attenuator 3 is fed to the output 6 of the DPR. In this case, the analog key 2.3 is opened and closed using its first and second control inputs, respectively, the selection of the signal input and the actual opening / closing of the analog key using block 4.

The reference frequency signal from the distribution circuit 1.1 also goes to the frequency auto-tuning circuit 4.1 and is a clock signal for the entire block 4. Depending on the required operating modes of the analog key 2.3, the duration and period of the radio pulses, the corresponding control commands are set on the group of inputs 7, which are fed to the block 4, on which the corresponding formation of control signals (video pulses, etc.) occurs with an analog key 2.3.

Consider the main modes of operation of the PDF with the simplest manual control from BU 8 (see Fig. 1).

All elements of the FPR memory (VI trigger 4.8, start trigger 4.3 and Sch. 4.4) are set to the log. 0 when the “Reset” button is pressed 8.6. In this case, the considered first signal input of the key is closed.

Preliminarily, in all operating modes, the PDF selects for operation the first (through the first bandpass filter 2.1) or second (through the second bandpass filter 2.2) signal input of the analog key 2.3. Both signal inputs of this analogue key 2.3 work the same way, therefore, its operation is only described below through the first signal input, and the second signal input is closed to the matching load 1.7.

To select the first signal input with the toggle switch 8.1 control unit 8, a voltage of the log level is applied. 1 at the first input of email. 4.7 whereby through the installation input to the log. 1 trigger 4.8 on its direct output is set to a signal log.1, which is fed to the input of email. 2.5, and on the inverse output of trigger 4.8, a log signal is set. 0, which is input to email. 2.6, which opens the key 2.3 (in accordance with the truth table, from the specification for the analog key, the link to the source is given above). In this case, the possibility is obtained through the selected signal input of the key output signal from email. 1.5 apply to output 6 (for example, to the input of the signal processing device under test).

To form a single radio pulse, toggle switch 8.5 of the control unit 8 provides a voltage of level log.1, setting the pulse mode of operation of unit 4. The required length of the radio pulse is set using dial 8.2, setting the appropriate code, from the output of the toggle switch 8.5 the signal log.1 is fed to the first electronic input. 4.12. Then, after pressing the 8.7 “Reset” button, press the 8.4 “Start” button, as a result of which the 4.3 start trigger is set to the “Log. 1 "and using the first cx. And email 4.11 allows the passage of clock pulses from email. 4.1 to the polling inputs of both comparison schemes 4.2 and 4.5 and simultaneously to the counting input of the count. 4.4, providing switching outputs of the counter on a rising edge. Also, the signal from button 8.4 is fed to cx OR 4.7, which sets the level of “Log. one". When the progressive code on the counter 4.4 of the specified code for the length of the radio pulse is reached, the comparison circuit 4.2 generates an “equal” signal, which arrives at cx OR 4.6, setting trigger 4.8 to the state “log. 0 ". At the same time, the signal from cx cp 4.2 arrives at cc And 4.12, the output of which is via email. 4.10 installs email. 4.3 to the log. 0 terminating the operation of block 4. I.e. the envelope of the only radio pulse is provided, which is generated (cut out) from the continuous signal at the input of the analog key 2.3, the gated radio pulse at its output (then transmitted through the filter 2.4 and attenuator 3 to the output 6 of the PDF) in the interval of the open analog key 2.3 with the state “log. 1 ”trigger 4.8 VI.

To form a sequence of radio pulses (series), the toggle switch 8.2 BU 8 supplies the voltage level log. 0, setting the pulse mode of operation of unit 4. The required length of the radio pulses is set using dial 8.3, and the required repetition period is set to BU 8 on set 8.4 and also set the toggle switch 8.6 to “Series” (level “log. 0”). Then, after pressing the reset button 8.7, the start button 8.5 is pressed. Because the pulse duration obviously does not exceed the value of the pulse repetition period, you can use the counter 4.4 as a counter of the pulse length, and as a counter of the repetition period. The process of forming the pulse duration is similar to that described above for the formation of a single radio pulse. The level of "log. 0 ”, coming from the toggle switch 8.6 to cx And 4.12, prohibits the reset of trigger 4.3 when a signal“ equals ”appears at the output of cx cp 4.2. Further, when the code on the counter 4.4 is reached, the preset code for the pulse repetition period, the comparison circuit 4.5 generates an “equal” signal, which arrives at cx OR 4.6, setting trigger 4.8 to the state “log. 1 ”and on cx OR 4.9, which resets counter 4.4. Counter 4.4 starts counting anew from the value “0” and the process of forming the VI repeats. T.O. a series of video pulses with a given duration and repetition period is formed.

Claims (6)

1. A generator of a sequence of radio pulses (FPR) with a large dynamic range, containing serially connected carrier frequency generator, a modulator and an output of a sequence of radio pulses FPR, the second input of the modulator being its control input, characterized in that the carrier frequency generator is a series-connected circuit from the circuit distribution of the reference frequency, the first frequency divider, frequency-phase detector, low-pass filter and voltage-controlled generator, and t It also contains a second frequency divider and matching load, and the modulator is a series-connected circuit of the first band-pass filter, an analog key through its first signal input, and the second band-pass filter, and also contains a third band-pass filter and two low-pass filters, in addition, the DPR contains an attenuator and a shaper of the envelope of a sequence of radio pulses as part of a self-tuning frequency circuit, two comparison circuits, a start trigger, a counter (MF), four OR circuits, a video pulse trigger (T d VI), in addition, the PDF contains an input, output, and a group of control inputs, while the input of the reference frequency distribution circuit is a PDF input, the first output of the voltage-controlled generator through the second frequency divider is connected to the second input of the frequency-phase detector, and its second output connected to the input of the first bandpass filter, the output of the second bandpass filter through the attenuator is connected to the PDF output, the second signal input of the analog key through the third bandpass filter is connected to the matching load, the output of the first circuit OR connected to the input of the unit to the zero logical state (to zero) Tg VI, the unit input of which is connected to the output of the second OR circuit, whose direct output is connected through the first low-pass filter, to the first control input of the analog key, the second control input of which is connected through a second low-pass filter with an inverse output Tg VI, the output of the third OR circuit is connected to the installation input to zero MF, the counting input of which is connected to the output of the first circuit And and to the polling inputs of the first and second comparison circuits, the output of the second circuit And with is single with the first input of the fourth OR circuit, the output of which is connected to the start of the zero Tg start, the direct output of which is connected to the first input of the first AND circuit, the second input of which is connected to the output of the frequency lock circuit, the input of which is connected to the second output of the reference frequency distribution circuit , the output is “equal to” the first comparison circuit connected to the first input of the second AND circuit and the first input of the first OR circuit, the second input of which is connected to the installation input to the start unit Tg and the input of the FPF Start, the PDF input of the signal input select cl cha is connected to the first input of the second OR circuit, the second input of which is connected to the equal to the second comparison circuit and the first input of the third OR circuit, the second input of which is connected to the third input of the first OR circuit, with the second input of the fourth OR circuit and with the input "Reset" FPR, the second input of the second circuit And is connected to the control input "Series / One" FPR, the first group of inputs of the first comparison circuit is the inputs of the "Code length VI" FPR, the first group of inputs of the second comparison circuit is the inputs of the "Code of the period VI" FPR, group of outputs Mid bit connected to the second groups of inputs of the first and second comparison circuits. 2. The shaper of the sequence of radio pulses with a large dynamic range, according to claim 1, characterized in that the shaper of the envelope of the sequence of radio pulses is implemented on a single FPGA chip. 3. The shaper of the sequence of radio pulses with a large dynamic range, according to claim 1, characterized in that the shaper of the envelope of the sequence of radio pulses is implemented on discrete logic elements. 4. The generator of the sequence of radio pulses with a large dynamic range, according to claim 1, characterized in that as an analog key use MASWSS0192 company M / A-COM. 5. A shaper of a sequence of radio pulses with a large dynamic range, according to claim 1, characterized in that a GK219-TS with the maximum possible levels of the relative spectral density of phase noise of the Morion company is used as a controlled voltage generator. 6. Shaper of the sequence of radio pulses with a large dynamic range, according to p. 1, characterized in that to control it using a handheld remote control or personal computer.

Images