SU1462508A1 - Device for shaping frequency-manipulated signals - Google Patents

Abstract

The invention relates to radio technology and can be used in time-frequency telemechanical systems. The purpose of the invention is to improve the accuracy of the formation of frequency-manipulated signals. The device contains a power supply unit 1, a setup unit 2 to zero, a synthesizer 3 frequency grids, phase shifters 4 and 5, a switch 6, a transmitting filter 7, triggers 8 and 9, integrators 10, 11 and 12, each of which consists of a driver 13 rectangular pulses and integrated circuits 14, sampling and storage units 15, 16, 17 and 18, reference voltage sources 19 and 20, comparison units 21 and 22, and keys 23 and 24. The goal is achieved by reducing intersymbol interference . 1 il.

Description

The invention relates to radio engineering and can be used in time-frequency telemechanics systems.

The purpose of the invention is to increase the accuracy of formation by reducing intersymbol interference.

The drawing shows a structural electrical diagram of the device.

A device for generating frequency-manipulated signals comprises a power unit 1, a unit 2; null, synthesizer 3 of the frequency grid, first and second phase rotators 4 and 5, switch 6, transmitting filter 7, first and second triggers 8 and 9, first, second and third integrators 10.-12, each of which consists of a former 13 rectangular pulses and an integrating chain 14, the first, second, third and fourth blocks 15-18 sampling and storage, the first and second sources of reference voltage 19 and 20, the first and second comparison blocks 21 and 22, the first and second keys 23 and 24.

The device operates as follows.

When you turn on the power supply unit 1, • it turns on. Unit 2 is set to zero, ίThe signal from the output of unit 2 sets I to the initial state of the first, second and third integrators 10-12, the first and second triggers 8 and 9, the first, second and? ' swarm, the third and fourth blocks 15-18 sampling and storage and includes a synthesizer 3 frequency grid. ·

From the first and second outputs of synthesizer 3, the signals of the working frequency ^and fj are supplied respectively to the inputs of the first and second phase shifters 4 and 5, and through them respectively to the first and second inputs of switch 6 and to the first and second integrators 10 and 11. In the formers 13 of all integrators. 10-12, rectangular pulses are formed, the duration of which is equal to the period of repetition of high-frequency pulses at their inputs and then with the help of integrating circuits 14 is converted into amplitude.

From the outputs of the first and second integrators 10 and 11, the signals are respectively supplied to the inputs of the first and third blocks 15 and 17, which sample the signal if there is a corresponding key 23 and 24 on the leading edge of the pulse at their control input. The signal amplitude at the output of the first, second, and third integrators 10-12 at the time of sampling determines the phase disagreement between the high-frequency signal supplied to the transmitting filter 7 and the input signal of the first and second phase shifters 4 and 5. At each moment of time, the first and The second blocks 15 and 16 are in storage mode, and the third and fourth blocks 17 and 18 are in standby mode.

When a manipulation signal is supplied to the control input of the first key 23, the latter opens when the voltage amplitude at the output of the third integrator 12 is equal to the installation voltage of the first reference voltage source 19. The signal from the output of the first key 23 is supplied to the first and second blocks 15 and 16 and to the first and second triggers 8 and 9.

The leading edge of the pulses, the first and second blocks 15 and 16, select the signal coming from the first integrator 10 and from the second source of reference voltage 20 .. The setting value is proportional to the initial phase of the sinusoidal signal of ₂ RF signals with frequency f ₂ and is selected from the absence condition the free component of the transition process when the frequency is turned on.

The signal from the output of the first block 15 enters the second control input of the first phase shifter 4, while adjusting the phase of the signal f, о in the range from 0 to. -360 depending on the level of the sampling signal, and the reference voltage proportional to ψ ₂ , from the input of the second sampling and storage unit 16, is supplied to the first control input of the first phase shifter 4, adjusting the phase in accordance with the setting.

At the same time, the signal from the output of the first key 23 causes the first trigger 8 to be turned on and the second trigger to be turned off 9. The signal from the output of the first trigger 8 is fed to the control input of the switch 6, at the output of which the RF transmission is changed. In this case, the first and second blocks 15 and 16 provide 'storage of the signal at the time of formation of the HF sprinkle f ₂ . Output signal

Ί462508 from switch 6 enters the transmit filter 7.

In the next step, when the manipulating signal arrives at the control input of the second switch 24, the latter opens when the phase of the RF signal t _z arriving at the transmitting filter 7 is equal to the setting of the second source 20. The setting value is selected from the condition that there is no free transient component when the frequency is turned off f ₂ .

The signal from the output of the second key 24 is fed to the third and fourth blocks 15 and 18 and to the first and second triggers 8 and 9. The leading edge of the pulse of the third and fourth blocks 17 and 18 of the sampling and storage sample the signal coming from the second integrator 20 11 and a first voltage reference source 19.

The setpoint value is proportional to the initial phase of the signal f _< and is selected from the condition of the absence of a free 'component of the Transient process when the frequency f, <is turned on. The signal from the output of the third block 17 is fed to the first control input of the second 30 phase shifter 5, while adjusting the phase of the HF signal from 0 to -360 °, and the signal from the output of the fourth block 18 of sampling and storage is fed to the second input 35 of the second phase shifter 5, adjusting the phase in accordance with the setting of the first source 19 of the reference voltage.

Claims (1)

Claim A device for generating frequency-manipulated signals containing a power supply connected in series, a zero-setting unit and a frequency grid synthesizer, the outputs of which are connected to the signal inputs of the first phase shifter, the control inputs of which are connected to the outputs of the first and second sampling and storage units, and the second phase shifter, the control inputs of which are connected to the outputs of the third and fourth blocks of sampling and storage, and the outputs of the first and second phase shifters are connected respectively to the input of the first an integrator, the output of which is connected to the signal input of the first block of sampling and storage, to the first signal input of the switch. RA, to the input of the second integrator, the output of which is connected to the signal input of the third sampling and storage unit, and to the second signal input of the switch, the control inputs and output of which are connected respectively to the outputs of the first and second triggers and to the input of the third integrator, which is connected to the input of the transmitter filter, the output of which is the output of the device, while the control inputs of the first and second sampling and storage units are connected to the first installation inputs of the first and second triggers, the second and third the input inputs of which are connected respectively to the second output of the zeroing unit and to the control inputs of the third and fourth sampling and storage units, characterized in that, in order to increase the accuracy of formation by reducing intersymbol interference, two keys, two comparison units and two reference sources are introduced voltage, the outputs of which are connected respectively to the first input of the first comparison unit, the output of which is connected to the signal input of the first key, and to the first input of the second comparison unit, the output of which is connected is connected with the signal input of the second key, the output of which and the output of the first key are connected respectively to the control inputs of the fourth and second sampling and storage units, the signal inputs of which are connected respectively to the outputs of the first and second sources of reference voltage, and the output of the third integrator is connected to the second inputs of the comparison blocks , and the control inputs of the keys are the control inputs of the device.