RU2611587C1 - Base station for remote probing of atmosphere - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: invention relates to radio engineering and radio electronics, is intended for remote sounding of the atmosphere and can be used in radar ranging, navigation and communication. Achieved technical result - possibility of obtaining amplitude-frequency and distance-frequency characteristics (AFC and DFC) of radio lines on routes with different length and orientation, as well as measuring doppler frequency shift of reflected radio signal. Said result is achieved due to the fact, that base station for remote sounding of the atmosphere consists of transmitting and receiving parts, provided that transmitting part includes dual receiver of GLONASS/GPS navigation signals, synchronometer, digital computational synthesizer, broadband power amplifier, antenna-feeder device, while receiving part includes antenna-feeder device, high frequency amplifier, analogue-to-digital converter, digital heterodyne, digital computational synthesizer, synchronometer, dual receiver of GLONASS/GPS navigation signals, computer, monitor.

EFFECT: listed devices are made and connected with each other in particular manner.

1 cl, 3 dwg

Description

The invention relates to radio engineering and radio electronics, is intended for remote sensing of the atmosphere and can be used in radar, navigation and communication.

A known ionosonic direction finder (prototype) containing two radio receivers (RPU) with a common local oscillator, which is a chirp generator, GPS receiver with antenna, time synchronization unit, splitter, antenna switch, reference generator, first RPU, second RPU, two-channel ADC , multithreaded computer [1].

With all the advantages of the known ionosonde direction finder, it does not allow measurements of the Doppler frequency shift of the reflected signal in the linear frequency modulation (LFM) mode.

A positive technical result - the ability to obtain amplitude-frequency and distance-frequency characteristics (AFC and DFC) of radio lines on tracks of various lengths and orientations, as well as to measure the Doppler frequency shift of the reflected radio signal - is achieved due to the fact that the base station of remote sensing of the atmosphere, consisting of transmitting and receiving parts; the transmitting part contains a two-system receiver of navigation signals GLONASS / GPS with an antenna; broadband power amplifier, antenna-feeder device; the receiving part contains an antenna-feeder device; an analog-to-digital converter (two-channel ADC), a two-system receiver for GLONASS / GPS navigation signals, and the new thing is that two synchronometers (in the transmitter and receiver), two digital computer synthesizers, a digital local oscillator, a computer and a monitor are introduced; the transmitting part of the base station of the atmospheric remote sensing contains a synchronously connected synchronometer, a digital computer synthesizer, a power amplifier, an antenna-feeder device; the receiving part contains a series-connected antenna-feeder device, a high-frequency amplifier, an analog-to-digital converter, a digital local oscillator, the output of which is connected via a LAN port to a computer; GLONASS / GPS two-system receiver of navigation signals, the output of which is connected to the reference input of the synchronometer; the outputs of the synchronometer are connected to the corresponding inputs of the digital computational synthesizer; the quadrature outputs of the digital computing synthesizer I and Q are connected to the inputs of the digital local oscillator; A computer is connected via a USB port to a digital computer synthesizer; the monitor is connected to the computer output.

The base station for remote sensing of the atmosphere (Fig. 1) consists of a transmitting and receiving parts.

The transmitting part contains a two-system receiver of navigation signals GLONASS / GPS 1; synchronometer 2; digital computer synthesizer 3; broadband power amplifier 4; antenna feeder device 5.

The receiving part contains an antenna-feeder device 6; high frequency amplifier 7; analog-to-digital converter (two-channel ADC) 8; digital local oscillator DDC 9; digital computer synthesizer 10; synchronometer 11; GLONASS / GPS 12 dual-system receiver of navigation signals; A computer 13; monitor 14.

The transmitting part of the base station of the DZ atmosphere contains a two-system receiver of navigation signals GLONASS / GPS 1, which is connected to the reference input of the synchronometer 2, the output of which is connected to the clock input of the DAC; series-connected digital computer synthesizer 3, power amplifier 4; antenna feeder device 5.

The receiving part of the base station DZ atmosphere contains a series-connected antenna-feeder device 6; high frequency amplifier 7; analog-to-digital converter 8; a digital local oscillator DDC 9, the output of which through a LAN port is connected to a computer 13; GLONASS / GPS 12 dual-system navigation signal receiver, the output of which is connected to the reference input of the synchronometer 11; the outputs of the synchronometer are connected to the corresponding inputs of the digital computational synthesizer; the quadrature outputs of the digital computing synthesizer I and Q are connected to the inputs of the digital local oscillator 9, which converts the high frequency into an intermediate one; A computer 13 through a USB port controls the operating modes of the digital computer synthesizer 10; the monitor 14 is connected to the output of the computer 13.

The base station remote sensing of the atmosphere operates as follows.

Synchronometer 2 generates a “sinusoidal” signal of the reference frequency, which is fed to the clock input of the digital computational synthesizer 3, and also synchronometer 2 generates a start pulse for DAC 3. To increase the accuracy of maintaining the frequency in synchronometer 2 and to link the start pulse to accurate time signals, a two-system navigation receiver is used GLONASS / GPS signals 1.

The signal from the output of the DAC 3 is fed to a power amplifier 4 and is transmitted through the antenna-feeder device 5 to the Earth’s atmosphere.

The receiving part of the base station remote sensing of the atmosphere works as follows.

Antenna-feeder device 6 receives the reflected signal, which is input to the high-frequency amplifier 7, and then is converted by analog-to-digital conversion into ADC 8. The signal from the output of ADC 8 is fed to digital local oscillator 9, the second and third inputs of which receive quadrature signals from DAC output 10.

The synchronometer 11 generates a reference frequency signal for the DAC 10, as well as the start pulse of the DAC 10. To increase the accuracy of the frequency of the synchronometer 11, a two-system GLONASS / GPS 12 navigation signal receiver is used, the output of which is connected to the reference input of the synchronometer 11.

The intermediate frequency signal from the output of the digital local oscillator DDC 9 through the LAN port is fed to the input of the computer 13, which performs digital processing of the received signal using specialized software. The monitor 14 is connected to a computer 13 and is used to display the frequency response, frequency response and sonograms of the Doppler frequency shift of the reflected signal. Using a computer 13 through the USB port, you can set the operating modes of the digital computing synthesizer 10.

As a digital computational synthesizer, either a DAC of frequency-modulated signals [2] or a synthesizer with a V-shaped law of frequency modulation [3] is used.

The first of these synthesizers generates a sawtooth LFM signal, which is used to construct the frequency response and frequency response; the second is an FM signal with a V-shaped law of frequency modulation and is used to build Doppler sonograms.

Two operating modes of the base station are possible.

Firstly, this is the construction mode of the frequency response and frequency response of the radio line.

The transmitter’s operating schedule is preliminarily compiled, where the synchronization time, the initial radiation frequency, the rate of change of the transmitter frequency, the launch minute, and the duration of the frequency response and frequency response are indicated.

The base station transmitter emits a reference LFM signal lasting 1 second (this is the synchronization mode). At the receiving end of the radio link, by changing the delay of the start time Δt of the DAC, they achieve the appearance of a harmonic tone signal; in this case, the reflected signal falls into the passband of the receiver.

After synchronization of the equipment, remote sensing of the Earth's atmosphere is performed (the frequency of the transmitter changes according to a sawtooth law, as shown in Fig. 2).

The computer at the receiving end of the radio line performs preliminary information processing. The amplitude of the envelope varies over time, but the construction of the frequency response corresponds to a certain frequency of the probing signal

Where U (f) - frequency response of the radio line;

Δt is the delay in starting the DAC receiver;

ƒ 'is the rate of change of frequency.

The frequency response is constructed as follows.

Using a software FFT (fast Fourier transform), the spectrum of the received signal is calculated; then the spectrogram is cut in time at a certain level of comparing. Further, these sections are recorded at different points in time, thereby building the frequency response:

where t _gr (F) is the group delay time;

t _n (ƒ) is the nth signal mode.

Secondly, this is the mode of building sonograms.

The transmitter emits an FM signal with a V-shaped modulation law (see Fig. 3). The FM signal consists of two phases T _1/2 , first the frequency of the transmitted signal increases, and then decreases. In this case, with a positive phase of frequency change, the received signal is described by the formula

In the negative phase

F _CR - the frequency of the received signal;

F _Doppler - Doppler frequency.

Thus, the accuracy of this method is 2 times higher compared to the known methods for constructing sonograms at fixed frequencies.

The receiving part performs FFT conversion and a sonogram is built with a certain level of comparing depending on the frequency of the reflected signal, (see formula (2)).

Therefore, the base station for remote sensing of the atmosphere allows you to build the frequency response and frequency response of radio lines, and can also be used to build Doppler sonograms.

Literature

1. Patent No. 2399062 of the Russian Federation. IPC G01S 1/08. Ionospheric probe-direction finder / Vertogradov G.G., Uryadov V.P., Vertogradov V.G., Kurbatko SV. Claim 07/15/2009. Publ. 09/10/2010. Bull. Number 25. - 16 p. (prototype).

2. Patent No. 2204197 of the Russian Federation. IPC H03L 7/18. Digital synthesizer of frequency-modulated signals / Ryabov KV., Ryabov V.I. Claim 03/13/2001. Publ. 05/10/2003. Bull. No. 13.- 4 p.

3. Patent No. 2407144 of the Russian Federation. IPC H03L 7/18. A synthesizer with a V-shaped law of frequency modulation / Ryabov KV., Dedov AN, Yuryev IM. Claim 06/22/2009. Publ. 12/20/2010. Bull. Number 35. - 4 p.

Claims (1)

Base station for remote sensing of the atmosphere, consisting of transmitting and receiving parts; the transmitting part contains a two-system receiver of navigation signals GLONASS / GPS with an antenna; broadband power amplifier, antenna-feeder device; the receiving part contains an antenna-feeder device; analog-to-digital converter (two-channel ADC), two-system receiver of GLONASS / GPS navigation signals, characterized in that two synchronometers (in the transmitter and receiver), two digital computer synthesizers, a digital local oscillator, a computer and a monitor are introduced; the transmitting part of the base station of the atmospheric remote sensing contains a synchronously connected synchronometer, a digital computer synthesizer, a power amplifier, an antenna-feeder device; the receiving part contains a series-connected antenna-feeder device, a high-frequency amplifier, an analog-to-digital converter, a digital local oscillator, the output of which is connected via a LAN port to a computer; GLONASS / GPS two-system receiver of navigation signals, the output of which is connected to the reference input of the synchronometer; the outputs of the synchronometer are connected to the corresponding inputs of the digital computational synthesizer; the quadrature outputs of the digital computing synthesizer I and Q are connected to the inputs of the digital local oscillator; A computer is connected via a USB port to a digital computer synthesizer; the monitor is connected to the computer output.

Images