RU2128847C1 - Device determining atmospheric conditions - Google Patents

Abstract

FIELD: radar meteorology. SUBSTANCE: device determining atmospheric conditions has synchronizer, transmitter with start-up unit, circulator and antenna with control unit connected in series and to output of circulator, receiver, gating unit, analog-to-digital converter, unit computing coefficient of autocorrelation of time sequence of received reflected radar signals, unit of threshold selection by value of coefficient of autocorrelation, information display unit coupled with second input to output of unit computing coefficient of autocorrelation coupled in its turn to storage and control unit connected to antenna which output is running out to circulator. Synchronizer is connected with its output to gating unit which makes it possible to realize needed technical characteristics of device. EFFECT: possibility of detection of gas impurities. 1 dwg

Description

 The invention relates to radar meteorology and can be used to determine the presence in the atmosphere of contaminants, both chemical and radioactive, including gas.

 A device for determining the state of the atmosphere, in particular for measuring rain intensity, comprising a series-connected transmitter and an antenna switch (circulator), an antenna, a standard signal generator, a series-connected receiver, a strobing unit, a peak detector (analog-to-digital converter), an integrator, a calculator , a mechanical polarizer in the form of a rotating section of a circular waveguide with a built-in quarter-wave phase plate, and a serially connected unit is controlled polarization and actuator, see ed. testimonial. USSR N 1128211, class G 01 S 13/95, publ. 1984 year

 This device allows you to detect various meteo targets, but with its help it is impossible to determine the presence of radioactive and chemical impurities in the atmosphere.

 A known device for determining the state of the atmosphere, comprising a series-connected transmitter with a start-up unit, a circulator and an antenna with a control unit, a standard signal generator, a series-connected receiver, a gating unit, an analog-to-digital converter, an integrator and a computer, a polarizer, a polarizer control unit connected to it as well as a unit for presenting information - a monitor, the first input of the receiver is connected to the second output of the circulator, the output of the standard signal generator is connected to the second input of the receiver; the device has a synchronization block, one output of which is connected to the second input of the gating block, and the third output is connected to the input of the transmitter launch block, see RF patent N 2054695, cl. G 01 S 13/95 dated 11/26/93

 This device is taken as a prototype of the present invention. It provides a quantitative assessment of the degree of pollution of a certain volume of the atmosphere. However, it should be noted that the device effectively detects only such impurities in the atmosphere, in particular radioactive, which have a reflectivity that differs sharply from the reflectivity of a clean atmosphere and natural hydrometeors (rain, snow, hail, etc.). At the same time, it does not solve the problem of effective detection of substances whose reflectivity differs little from the reflectivity of a pure atmosphere and natural hydrometeors. Such substances include, for example, gases transported through trunk pipelines, gasoline vapors and other light oil fractions.

 The present invention is based on the solution of the problem of creating a device for determining the state of the atmosphere for the presence of contaminants in it, which ensures the detection in the atmosphere of substances whose reflectivity differs little from the reflectivity of a clean atmosphere and natural hydrometeors, such as gases transported via main pipelines, vapors petroleum products, etc.

 According to the invention, this problem is solved due to the fact that in the device for determining the state of the atmosphere, comprising a series-connected transmitter with a start-up unit, a circulator and an antenna with a control unit, a series-connected receiver, gates, an analog-to-digital converter, as well as an information presentation unit, an input the receiver is connected to the second output of the circulator, an additional synchronization unit is introduced, a unit for calculating the autocorrelation coefficient of the time sequence of the received reflected x signals, equipped with a memory unit, and a threshold signal selection unit according to the value of the autocorrelation coefficient, while the first output of the synchronization unit is connected to the transmitter start unit, the second output of the synchronization unit is connected to the second input of the gating unit, the input of the autocorrelation coefficient calculation unit is connected to the analog output a digital converter, the second input of this unit is connected to the second output of the antenna control unit, the first output of the autocorrelation coefficient calculation unit is connected to input b flash memory, the output of which is connected to a third input of the calculation of the autocorrelation coefficient, the second output of which is connected to the input of block threshold selection signals, the output of which is connected to a first input of the presenting information, and the third output calculating autocorrelation coefficient block is connected to the second input information presentation unit.

 The applicant is not aware of any sources of information containing information about a technical solution that is identical to the features given in the characterizing part of the claims. This determines, in the applicant's opinion, whether the invention meets the criterion of “novelty”.

 The primary (technical) effect of the claimed device, achieved through the implementation of its differences (in combination with the characteristics indicated in the restrictive part of the claims), consists in the possibility of detecting gas impurities in the atmosphere, the reflectivity of which differs little from the reflectivity of a pure atmosphere and natural hydrometeors. In the process of mixing gas impurities under conditions of natural atmospheric turbulence, a multitude of elementary reflectors are formed in the cloud, distributed randomly in space at a distance from each other equal to about 0.5 wavelength of the radar. With the mutual movement of these reflectors, fluctuations of the total radar signal reflected from the observed zone occur. The fluctuation velocities in the presence of gas impurities in the atmosphere are much higher than the fluctuation velocities in the presence of ordinary hydrometeors or a clean atmosphere. Quantitatively, these speeds are estimated by determining the autocorrelation coefficient of the time sequence of the received reflected radar signals. Moreover, the higher the fluctuation rate, the lower the autocorrelation coefficient, the boundary value of which is set in the threshold selection block.

 Thus, the basis of this invention is a new principle for the detection of gas impurities in the atmosphere.

 These circumstances determine, in our opinion, the compliance of the claimed technical solution with the criterion of "inventive step".

 The invention is illustrated in the drawing, which shows a block diagram of a device.

 The device comprises a transmitter 1 having a trigger unit 2. The output of the transmitter 1 is connected to the first input of the circulator 3, connected by the first output to the first input of the transceiver antenna 4. The output of the antenna 4 is connected to the second input of the circulator 3. The antenna 4 is provided with a control unit 5. The angular position of the antenna 4 is set by an electric signal supplied to its drive (not shown separately in the drawing) from the first output of unit 5. The second output of the circulator 3 is connected to the input of the receiver 6. The output of the receiver 6 is connected to the first input of the gating unit 7, the output of which is connected to the input of the analog-to-digital converter 8. The device comprises a synchronization unit 9, the first output of which is connected to the input of the transmitter start unit 2. The second output of block 9 is connected to the second input of the gating block 7.

 The output of the analog-to-digital converter 8 is connected to the first input of the unit 10 for calculating the autocorrelation coefficient of the time sequence of the received reflected radar signals, the second input of which is connected to the second output of the antenna control unit 5. Block 10 is equipped with a memory block 11, the input of which is connected to the first output of block 10, and the output is connected to the third input of block 10. The second output of block 10 is connected to the input of threshold selection block 12, the output of which is connected to the first input of information presentation block 13, the second input which is connected to the third input of block 10.

 In a specific example implementation of the invention, blocks 10, 11 and 12 are elements of a personal computer, and block 13 is a monitor.

 The device operates as follows. The electrical signal from the first output of synchronization unit 9 is fed to transmitter start-up unit 2. The high-frequency sounding signal from the output of transmitter 1 is fed to the first input of circulator 3 and from the first output of circulator 3 is fed to the first input of antenna 4. The angular position of the antenna is set by the electrical signal received from the first output of the antenna control unit 5. Antenna 4 emits radar pulses into the studied area of the atmosphere. The signals reflected from this zone are received by the antenna 4 and fed to the second input of the circulator 3 and from the second output of the circulator 3 to the input of the receiver 6. From the output of the receiver 6, the received and amplified signal is fed to the first input of the gating unit 7. At the second input of the gating unit 7 with some delay, a signal is supplied from the second output of the synchronization unit 9. This ensures selection of the range of signals reflected from the observed portion of the atmosphere. From the output of the gating unit 7, the selected signals are fed to the input of an analog-to-digital converter 8, from the output of which the signals are digitally fed to the first input of the unit 10 for calculating the autocorrelation coefficient of the time sequence of the received reflected radar signals (range-selected and digitized). The operation of calculating the autocorrelation coefficient is as follows. The entire sequence of signals from the first output of block 10 is fed to the input of block 11 of the memory. The signals delayed in block 11 at various time intervals are fed to the third input of the autocorrelation coefficient calculation unit 10. The digital signal generated in this block, which is proportional to the autocorrelation coefficient of the time sequence of radar signals reflected from the sensed region of the atmosphere, is supplied from the second output of the autocorrelation coefficient calculation unit 10 to the input of the threshold selection block 12. The signals corresponding to a sufficiently small value of the autocorrelation coefficient, specified by the threshold value in the threshold selection block 12, pass to the output of this block and go to the first input of the information presentation block 13. The signals observed using the information presentation unit 13 are mapped to the spatial position of the antenna 4 by applying an electric signal from the antenna control unit 5 to the second input of the autocorrelation coefficient calculation unit 10. From the third output of this block, digital signals corresponding to the angular position of the antenna at the moments of calculation of the values of the autocorrelation coefficient of the signals reflected from the probed portion of the atmosphere are fed to the second input of the information representation block 13.

 To carry out the selection of impurities contained in the atmosphere (methane, propane, butane, etc.), the device is calibrated. Preliminarily experimentally determine the values of the autocorrelation coefficients of radar signals from atmospheric zones that are remote at various distances from the device. Moreover, at given distances, each gas is separately released into the atmosphere at a given speed or a mixture of several gases in a certain proportion. In a specific example of the implementation of the device, such calibration was carried out using graduated valves included in the design of gas pipelines and gas pumping stations. The obtained calibration curve is entered into the unit 10 of the calculator of the autocorrelation coefficient, the output signals of which, adjusted for the range, provide information on the composition of the gas emission and its intensity on the screen of the unit 13 for the presentation of information. In a specific example, indication using pseudo colors is applied.

The implementation of the device is carried out using a well-known element base. The error in determining the rate of exit of gases into the atmosphere at distances up to 10 km is 3% with an average exit velocity of about 2 m ³ / min and 30% with an exit velocity of less than 0.05 m ³ / min.

Claims (1)

 A device for determining the state of the atmosphere, comprising a series-connected transmitter with a start-up unit, a circulator and an antenna with a control unit, a series-connected receiver, a gating unit, an analog-to-digital converter, as well as an information presentation unit, the input of the receiver connected to the second output of the circulator, characterized in that a synchronization unit, an autocorrelation coefficient calculation unit of a time sequence of received reflected signals, provided with a memory unit, and a pore block are introduced selection of signals by the value of the autocorrelation coefficient, while the first output of the synchronization block is connected to the transmitter start block, the second output of the synchronization block is connected to the second input of the gating block, the first input of the autocorrelation coefficient calculation block is connected to the output of the analog-to-digital converter, the second input of this block is connected with the second output of the antenna control unit, the first output of the autocorrelation coefficient calculation unit is connected to the input of the memory unit, the output of which is connected to the third m input of the autocorrelation coefficient calculation unit, the second output of which is connected to the input of the threshold signal selection block, the output of which is connected to the first input of the information representation unit, and the third output of the autocorrelation coefficient calculation unit is connected to the second input of the information presentation unit.