RU143080U1 - DIGITAL FORMER OF LINEAR-FREQUENCY-MODULATED RADIO SIGNALS - Google Patents

Abstract

1. A digital shaper of broadband linear-frequency-modulated radio signals, comprising a reference generator, the output of which is connected to the clock inputs of the microcontroller and the direct digital synthesis synthesizer, the information input of which is connected to the first output of the microcontroller, while the first output of the direct digital synthesis synthesizer is connected to the first low-frequency the input of the quadrature modulator, the high-frequency input of which is connected to the output of the master oscillator, and the output of the quadrature modulator is The output of the device is characterized in that a power divider, an inverter of a sinusoidal signal and a controlled key are introduced into it, while the second output of the direct digital synthesis synthesizer is connected to the input of the power divider, the second output of which is connected to the second input of the controlled key, the first input of which is connected to the first output of the power divider through a sinusoidal signal inverter, the third input of the controlled key is connected to the second output of the microcontroller, and the output of the controlled key is connected to the second low-frequency m quadrature modulator input. 2. A digital shaper of broadband linear-frequency-modulated radio signals according to claim 1, characterized in that an integrated phase shifter is used as a sinusoidal signal inverter, which rotates the phase of the input sinusoidal signal by 180 degrees. 3. The digital shaper of broadband linear-frequency-modulated radio signals according to claim 1, characterized in that an analog single-pole switch in two directions or an analog two-way switch is used as a controlled key

Description

The utility model relates to radio engineering and can be used in radar systems with continuous emission of linear-frequency-modulated radio signals, as well as in various measuring instruments.

A prior art broadband linear-frequency-modulated radio signal shaper is known, the basis of which is a direct digital signal synthesis device and a phase-locked loop (Kosov A.S., Zotov V.A. Generator with linear digital frequency tuning of the MM wave band // Materials of the XIX International Crimean Conference “Microwave Technology and Telecommunication Technologies.” - 2009, p. 85). In this shaper, the direct digital synthesis device generates a linear-frequency-modulated radio signal, which is the reference for the phase-locked loop, which plays the role of a frequency multiplier with a high multiplication factor.

The advantage of this shaper is a wide range of possible frequency deviations of linearly-frequency-modulated radio signals, the upper limit of which is determined by the value (0.4 ... 0.45) · f _T · (M / N), where f _T is the clock frequency of the direct digital device synthesis, M is the division ratio of the output frequency of the phase-locked loop, N is the division ratio of the output frequency of the direct digital synthesis device.

The disadvantage of this shaper is the increase in the phase noise level at the output of the phase-locked loop, compared with the noise level at the output of the direct digital synthesis device. In addition, the nonlinear effects of the phase-locked loop cause a violation of the linearity of the frequency tuning of the generated linear-frequency-modulated radio signal.

Closest to the claimed utility model is a shaper of broadband linear-frequency-modulated radio signals, the basis of which is a device for direct digital signal synthesis, a quadrature modulator and a master oscillator of an unmodulated radio signal (Kochemasov V.N., Golubkov A.V., Golubkov V.G. , Cherkashin V.G., Yankovsky E.V. Methods for the formation of ultra-wideband linear-frequency-modulated signals // Materials of the IV all-Russian scientific and technical conference "Omsk Microwave 2012. - 2012, p. 121).

The operation of this device consists in the formation by the device of direct digital synthesis of two quadrature oscillations with a ramp frequency, which are fed to the low-frequency inputs of the quadrature modulator. At the same time, a harmonic oscillation at a frequency f _n from the master oscillator is supplied to the high-frequency input of the quadrature modulator. As a result, a radio signal is generated at the output of the quadrature modulator, the frequency of which varies from f _n to f _n + F _dev . In this case, F _vir ≤ (0.4 ... 0.45) · f _T , where F _vir is the frequency deviation, f _T is the clock frequency of the direct digital signal synthesis device.

The advantage of this device is the high linearity and stability of the frequency change, the ability to tune the carrier frequency of the radio signal by changing the frequency of the master oscillator.

The disadvantage of this device is the inability to form broadband linear-frequency-modulated radio signals with a frequency deviation exceeding the value (0.4 ... 0.45) · f _T.

The problem to which the claimed utility model is directed is to expand the range of frequency deviation values of linearly-frequency-modulated radio signals generated by a broadband linear-frequency-modulated radio signals generator, based on a direct digital signal synthesis synthesizer, quadrature modulator and master oscillator, to values (0.8 ... 0.9) · f _T.

The solution to this problem is achieved due to the fact that the digital shaper of broadband linear-frequency-modulated radio signals contains a reference generator, the output of which is connected to the clock inputs of the microcontroller and the direct digital synthesis synthesizer, the information input of which is connected to the first output of the microcontroller, while the first output of the direct synthesizer digital synthesis is connected to the first low-frequency input of the quadrature modulator, the high-frequency input of which is connected to the output of the master oscillator and, according to the utility model, a power divider, a sinusoidal signal inverter and a controlled key are introduced into it, while the second output of the direct digital synthesis synthesizer is connected to the input of the power divider, the second output of which is connected to the second input of the controlled key, the first input of which is connected to the first output power divider through a sinusoidal signal inverter, the third input of the controlled key is connected to the second output of the microcontroller, and the output of the controlled key is connected to the second low-frequency input square polar modulator.

The solution to this problem is also achieved due to the fact that as an inverter of the sinusoidal signal, an integrated phase shifter is used, which provides a phase rotation of the input sinusoidal signal by 180 degrees.

The solution to this problem is also achieved due to the fact that an analog single-pole switch in two directions or an analog two-channel multiplexer is used as a controlled key.

The technical result of the utility model consists in doubling the frequency deviation of the linearly-frequency-modulated radio signals generated by the broadband linear-frequency-modulated radio signals generator based on a direct digital signal synthesis synthesizer, a quadrature modulator, and a master oscillator.

The operation of the proposed digital shaper broadband linearly-frequency-modulated radio signals, the structural diagram of which is presented in FIG. 1 is explained using the timing diagrams shown in FIG. 2.

The device of FIG. 1 contains a reference generator 1, a direct digital synthesis synthesizer 3, a microcontroller 2, a power divider 4, a sine wave inverter 5, a controlled key 6, a quadrature modulator 7, and a master oscillator 8.

The output of the reference generator 1 is connected to the clock input of the direct digital synthesizer 3 and the input of the microcontroller 2. The first output of the microcontroller is connected to the information input of the direct digital synthesis synthesizer 3, and the second output is connected to the control input of the controlled key 6.

The first output of the direct digital synthesizer 3 is connected to the first low-frequency input of the quadrature modulator 7. The second output of the synthesizer 3 is connected to the input of the power divider 4, the first output of which is connected through the inverter of the sinusoidal signal 5 to the first information input of the controlled key 6.

The second output of the power divider 4 is connected to the second information input of the controlled key 6. The output of the master oscillator 8 is connected to the high-frequency input of the quadrature modulator 7.

The practical implementation of the circuit elements of a digital driver of broadband linear-frequency-modulated radio signals can be carried out on the basis of the widely used electronic components of Analog Devices, STMicroelectronics, Hittite, Mini-Circuits Laboratory, Maxim, Vishay.

The device proposed in this application works as follows. The direct digital synthesis synthesizer 3, based on the information received from the microcontroller 2 (start time, initial and final value of the synthesized frequency, step and time of frequency tuning), generates two quadrature frequency modulated signals u _c (t) and u _s (t) with symmetrical the triangular law of the change in frequency f _dds (t), the deviation F _virgos and the period T _m (Fig. 2a). The reference generator 1 generates a clock signal that provides synchronous operation of the direct digital synthesis synthesizer 3 and the microcontroller 2, which performs the function of controlling the operation of the synthesizer 3 and the controlled key 6.

The in-phase signal u _c (t) is supplied to the first low-frequency input of the quadrature modulator 7, and the quadrature signal u _s (t) is fed to the input of the power divider 4, which distributes the signal power to two outputs. The signal from the first output of the power divider 4 after passing the inverter of the sinusoidal signal 5 is fed to the first analog input of the controlled key 6, the second input of which is fed from the second output of the power divider 4. As a result, two differential signals are formed u _s (t) and -u _s (t), which are supplied to the information inputs of the controlled key 6. The key 6 commutes one of the input signals to the second low-frequency input of the quadrature modulator 7 at time points determined by the control signal u _control (t), p coming from the microcontroller 2 (Fig. 2B):

At the high-frequency input of the quadrature modulator 7 is supplied from the master oscillator 8, a radio signal of frequency f _n .

As a result, the output of the quadrature modulator 7 generates a linear-frequency-modulated radio signal u _LFM (t), described by the expression:

The frequency of the radio signal (2) varies according to the law of the asymmetrical sawtooth function f _o (t) (Fig. 2c), the frequency deviation is equal to twice the deviation 2F _{dev of the} low-frequency modulating signal generated by the direct digital synthesis synthesizer. The period of asymmetric sawtooth modulation of the generated linear frequency-modulated radio signal is equal to the period of symmetric triangular modulation of the modulating signal.

Thus, the claimed device in comparison with the known device (prototype) allows you to double the range of possible values of the frequency deviation of the linearly-frequency-modulated radio signals.

Claims (3)

1. A digital shaper of broadband linear-frequency-modulated radio signals, comprising a reference generator, the output of which is connected to the clock inputs of the microcontroller and the direct digital synthesis synthesizer, the information input of which is connected to the first output of the microcontroller, while the first output of the direct digital synthesis synthesizer is connected to the first low-frequency the input of the quadrature modulator, the high-frequency input of which is connected to the output of the master oscillator, and the output of the quadrature modulator is The output of the device is characterized in that a power divider, an inverter of a sinusoidal signal and a controlled key are introduced into it, while the second output of the direct digital synthesis synthesizer is connected to the input of the power divider, the second output of which is connected to the second input of the controlled key, the first input of which is connected to the first output of the power divider through a sinusoidal signal inverter, the third input of the controlled key is connected to the second output of the microcontroller, and the output of the controlled key is connected to the second low-frequency m quadrature modulator input. 2. A digital shaper of broadband linear-frequency-modulated radio signals according to claim 1, characterized in that an integral phase shifter is used as an inverter of the sinusoidal signal, providing a 180 degree phase rotation of the input sinusoidal signal. 3. The digital shaper of broadband linear-frequency-modulated radio signals according to claim 1, characterized in that the analog key is a two-way analog single-pole key or an analog two-channel multiplexer.