CN1588125A - Method for telemetering precipitation parameter and high frequency Doppler acoustic radar device - Google Patents
Method for telemetering precipitation parameter and high frequency Doppler acoustic radar device Download PDFInfo
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- CN1588125A CN1588125A CN 200410056588 CN200410056588A CN1588125A CN 1588125 A CN1588125 A CN 1588125A CN 200410056588 CN200410056588 CN 200410056588 CN 200410056588 A CN200410056588 A CN 200410056588A CN 1588125 A CN1588125 A CN 1588125A
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Abstract
The invention relates to a method of quantitatively and remotely measuring the particle size distribution, precipitation and other parameters of the precipitation by using high-frequency Doppler sound wave method and a high-frequency Doppler sound radar set for realizing it. The invention uses a radar antenna to transmit high-frequency sound wave pulse at a frequency not lower than 6kHz and uses many microphones to receive the returning signal, controls the transmission of detecting sound wave by PC and DSP circuit, analyzes and processes the received signal to obtain a precipitation power spectrum and an atmospheric disturbance power frequency spectrum, deduces the particle size distribution and other precipitation parameters from the precipitation power spectrum and deduces vertical average wind speed and other atmospheric disturbance parameters from the obtained atmospheric disturbance power frequency spectrum, and thus corrects the effect of the vertical wind to increase the measuring accuracy.
Description
Technical field
The present invention relates to a kind of various atmospheric precipitations of quantitative remote measurement that are used for, like rain the method for size-grade distribution, quantity of precipitation and other precipitation parameters of, snow, hail and mixing phase thereof, and the hf doppler acoustic radar of realizing this method.Hf doppler acoustic radar device of the present invention also can be used for measuring sandstorm.
Background technology
Up to now, measuring the record of precipitation and the accuracy of data all can not meet the demands far away.Though the routine measurement of precipitation size-grade distribution is all extremely important for weather forecast, air pollution analysis forecast etc., the record of conventional precipitation particle size distribution measurement is not arranged as yet so far.
At present, the instrument that can be used for quantitatively surveying the raindrop size-grade distribution comprises Joss-Waldvogel (J-W) disdrometer, optics rain gage (OP) and the small-sized radar Doppler of high-frequency microwave.Preceding two kinds of instruments not only cost an arm and a leg, and not high for climatic condition accuracies of measurement such as heavy rain, heavy rains.This is because their measurement receiving area or measurement reception volume are very little, for the J-W disdrometer, measures receiving area and is about 50cm
2,, measure the reception volume and be about 80cm for a kind of known optics rain gage
3And J-W disdrometer and optics rain gage are subjected to Influences on Wind Velocity very big.In addition, for granule, for example diameter is less than the raindrop of 0.4mm-1.0mm, and for bulky grain, for example diameter has exceeded the measurement range of J-W instrument greater than the raindrop (under the situation of heavy rain) of 5.2-5.75mm.
Microwave radar realizes measuring purpose by measuring the raindrop decline rate.According to the fixed relationship of decline rate and raindrop size, can derive the size of raindrop, thereby obtain size-grade distribution and other precipitation parameters of raindrop.But because the influence of vertical velocity in the atmosphere, microwave radar can only be measured synthetic raindrop decline rate, be the actual decline rate and the vertical velocity sum of raindrop, therefore have only to deduct the raindrop decline rate that vertical velocity just can obtain reality with this synthetic decline rate.If do not utilize vertical velocity to proofread and correct, then measured quantity of precipitation may cause 100% error.And existing microwave radar can only be measured the precipitation power spectrum, and influence that can't measuring vertical wind, thereby cause measuring accuracy lower.And microwave radar can only measure rainfall, and can not mixing mutually at snow, hail and frozen water, the weather condition of precipitation descends accurately to measure.
Present existing low frequency Doppler acoustic radar generally adopts the piezoelectric loudspeaker that sends with the receiving sensor unification,, for example is made up of 37 word sound press electric horns on antenna plate with array format.In this design, owing to needing more than 100 millisecond from the switch transition time that sends to reception, having limited reliable minimum measuring height is about 15-20 rice.The used frequency range of this all-bottom sound radar is that 1000Hz is to 4500Hz, and can not be used for high frequency (more than the 6kHz), this low-frequency sound wave can only be measured the atmospheric disturbance power spectrum, and can not survey the precipitation power spectrum, thereby can only be used to measure altitude wind field, can't quantitative measurment precipitation parameter.
Summary of the invention
Therefore, the technical problem to be solved in the present invention is to provide a kind of method and apparatus, can descend size-grade distribution, quantity of precipitation and other precipitation parameters of remote measurement precipitation in the equal various meteorological conditions of rain, snow, hail and mixing thereof, and can obtain atmospheric disturbance parameters such as average vertical wind speed simultaneously, thereby the error that vertically-supplying air causes is proofreaied and correct, improve measuring accuracy.
Task of the present invention realizes like this: in the method according to the invention, send the high frequency sound wave pulse that frequency is not less than 6kHz by hf doppler acoustic radar antenna at interval vertically upward with certain hour, after delay after a while, receive by precipitation particle and the back scattered acoustic signals of atmospheric disturbance with a plurality of acoustic receiving transducers, the acoustic signals that receives is through amplifying, add and after deliver to sampling of data and processing section, carry out mould/number (A/D) conversion, and resulting digital signal carried out fast Fourier transform (FFT), be transformed to frequency-region signal from time-domain signal, obtain precipitation power spectrum and atmospheric disturbance power spectrum simultaneously, then the precipitation power spectrum and the atmospheric disturbance power spectrum that are obtained are analyzed, derive precipitation size-grade distribution and other precipitation parameters from the precipitation power spectrum, and derive average vertical wind speed and other atmospheric disturbance parameters from resulting atmospheric disturbance power spectrum, utilize average vertical wind speed and/or other atmospheric disturbance parameters that precipitation size-grade distribution and other precipitation parameters are proofreaied and correct, to improve measuring accuracy.
Hf doppler acoustic radar device according to the present invention is made of antenna part and data sampling and processing section, and wherein antenna part comprises the infundibulate emission/receiving hood of opening vertically upward, is used to send and receive the antenna plate of sound wave; On described antenna plate, come transmission frequency to be not less than the high frequency sound wave pulse of 6kHz, receive back scattered acoustic signals with a plurality of sound wave receiving traps with electromagnetic horn; Behind the receiving antenna plate, be provided with pre-amplification circuit, the acoustic signals that is used for collecting amplify, add and; Through amplifying, add and acoustic signals deliver to data sampling and processing section, described data sampling and processing section are to amplifying, add and after signal carry out mould/number conversion, and the digital signal that obtains carried out fast fourier transform, be transformed to frequency-region signal from time-domain signal, obtain precipitation power spectrum and atmospheric disturbance power spectrum simultaneously, and, described data sampling and processing section are analyzed the precipitation power spectrum and the atmospheric disturbance power spectrum that are obtained, derive precipitation size-grade distribution and other precipitation parameters from the precipitation power spectrum, and derive average vertical wind speed and other atmospheric disturbance parameters from resulting atmospheric disturbance power spectrum, utilize average vertical wind speed and/or other atmospheric disturbance parameters that precipitation size-grade distribution and other precipitation parameters are proofreaied and correct.
In acoustic radar device according to the present invention, inwall at infundibulate emission/receiving hood and casing all posts the acoustic foam material, the a plurality of sound wave receiving traps that are used to receive high frequency sound wave preferably adopt microphone, and described each microphone can have the flared skirt that is used to gather sound wave.
According to a preferred embodiment of the present invention, described microphone is installed in the aperture on the described antenna plate, the sonic sensor of microphone an intersegmental distance is arranged in from the opening of aperture to aperture, formed an acoustic wave filter, described spacing is adjusted according to the wavelength of the high frequency sound wave pulse of being sent, / 4th of a high frequency sound wave pulse wavelength that described spacing is about sent receives noise to reduce.
Different with the optics rain gage with the J-W disdrometer, the method according to this invention and device detection volume can reach 6-7m
3, can survey precipitation particle equivalent diameter is the bulky grain that 0.2mm arrives unrestricted size.J-W and OP instrument can not detect meteorologies such as snow, hails, and the present invention can quantitative automatic identification and measured quantity of precipitation and size-grade distribution under the above-mentioned meteorological condition.
Compare with the small-sized radar Doppler of microwave, because strong about 1000 times of the scattering that the scattering ratio microwave that sound wave produces from atmospheric disturbance produces, therefore (frequency is not less than 6kHz to the high frequency acoustic radar, even reach more than the 20kHz) can measure precipitation power spectrum and atmospheric disturbance power spectrum (can derive the average vertical wind speed thus) simultaneously, thereby can proofread and correct the error that vertically-supplying air causes, and microwave radar can't be accomplished this point.In addition, because the specific inductive capacity of water is about 5 times of specific inductive capacity of ice, therefore the electromagnetic wave signal from the ice pellets scattering is far smaller than from the electromagnetic wave signal of water droplet scattering, so just makes microwave radar can not accurately measure snow, hail and frozen water and mixes precipitation mutually.Sound wave decay in water and ice is very little, can ignore, but the decay of high-frequency microwave in ice and water is very big and very inequality, so cause the bigger measuring error of high-frequency microwave radar.But sound wave is identical from the signal intensity of water droplet during with the ice pellets scattering, therefore can improve the accuracy of measurement that frozen water mixes phase precipitation greatly.
This shows, the hf doppler acoustic radar is compared with J-W disdrometer, optics rain gage and other conventional rain gages and high-frequency microwave radar, improved accuracy of measurement greatly, and can and mix meteorological condition such as phase precipitation and descend to measure at snow, hail, and above-mentioned three kinds of routine measurement instruments generally can not quantitative measurment snow, hails and are mixed phase precipitation.
The key distinction of the present invention and existing Doppler's acoustic radar is: acoustic radar device of the present invention is operated in the higher frequency range, for 6kHz arrives 20kHz, perhaps reach 40kHz, this depends on the sensitivity of the reception microphone that is adopted, preferred frequency of operation is 10.3kHz~10.8kHz, therefore can be used for quantitative remote measurement precipitation parameter.The method according to this invention and device not only can be measured the precipitation power spectrum, can also obtain the atmospheric disturbance power spectrum simultaneously, and in view of the above the precipitation size-grade distribution, quantity of precipitation and other precipitation parameters that obtain be proofreaied and correct.After frequency of operation surpassed 20kHz, device of the present invention can not exert an influence to people's ear hearing.
An Important Thought of the present invention also is, except the sound wave of antenna send and receiving sensor element, prime amplifier, be used to drive electromagnetic horn power amplifier etc. must be with the hardware realization, other functions of whole acoustic radar device, as sound wave pulse generator, superheterodyne receiver, low pass and bandpass filter, acoustic radar operation controller and real-time digital signal processing functions such as (as FFT), all can realize by software.For example can adopt the DSP circuit board that is built in the PC, combine, realize above-mentioned functions by programming with PC.Whole like this data processing and recording process are all real-time, online to carry out (on-line), and whole instrument can be moved automatically, need not to be kept an eye on and operated by personnel.Realization of the present invention simultaneously is very convenient, has reduced equipment cost.
Utilize the method according to this invention and device can remedy the existing blank of measuring the routine techniques of various precipitation size-grade distribution, improve the degree of accuracy that measures rainfall, particularly, remedied simultaneously and can not measure the blank that snow, hail and frozen water mix phase precipitation in the routine techniques automatically in the rain heavily degree of accuracy of measurement, heavy rain of strong wind, storm wind condition.
The present invention also can be used as the sound wave spectrum analyser; When using low-frequency antenna plate (1500Hz is to 4500Hz) instead, can be used for measuring altitude wind field (being lower than 500 meters to 1000 meters).Because the high frequency acoustic radar can be measured the atmospheric disturbance Doppler frequency spectrum simultaneously, thereby can derive radially wind speed, therefore also can be used for the real-time wind speed shear in airport and monitor.Also extend to the instrument that is used for the quantitative measurment sandstorm in addition.
Description of drawings
Explain the present invention by means of the embodiment shown in the accompanying drawing below.As shown in the figure:
Fig. 1 has schematically illustrated the theory diagram according to acoustic radar device of the present invention;
Fig. 2 shows according to electromagnetic horn of the present invention and the cut-open view that receives the arrangement of microphone on antenna plate;
Fig. 3 shows according to electromagnetic horn of the present invention and the front view that receives the arrangement of microphone on antenna plate;
Fig. 4 shows the enlarged diagram according to acoustic wave filter of the present invention;
Fig. 5 shows first kind of embodiment according to acoustic radar device of the present invention;
Fig. 6 shows second kind of embodiment according to acoustic radar device of the present invention.
Embodiment
Fig. 1 has schematically illustrated the theory diagram according to hf doppler acoustic radar device of the present invention.Mainly comprise antenna part 1 and data sampling and processing section 3 at hf doppler acoustic radar device according to the present invention.Antenna part 1 is used for launching high frequency sound wave vertically upward at interval with certain hour, and receives back scattered acoustic signals.Antenna part 1 also comprises a pre-amplification circuit 2, be used for to the signal that each sonic sensor receives carry out preposition amplification and add and, this pre-amplification circuit is that those skilled in the art use always.Through amplification and add and after signal be sent to data sampling and processing section 3, in data sampling and processing section 3, carry out conversion, processing and analysis, data sampling and processing section 3 also can be set and control the operational factor of acoustic radar simultaneously.
Below the simple measuring process of describing the acoustic radar device: at first from the acoustic radar antenna with certain hour at interval (for example per second) send a sound wave pulse vertically upward, the width of pulse for example is 50ms, after after a while, after for example passing through the delay of 10ms, begin to receive the scattered signal that causes from various precipitation particles and atmospheric disturbance, the continuous analog signal in time that receives is added through preposition amplification back (its enlargement factor is preferably 60-70dB), resulting signal is delivered to data sampling and processing section again, carry out the A/D conversion, by analog signal conversion continuous in time is digital signal sequences, pass through fast Fourier transform (FFT) then, calculate precipitation (rain, snow, hail or mix phase precipitation) power spectrum in frequency domain, can derive the parameter of precipitation size-grade distribution and other precipitation thus, also obtained the atmospheric disturbance power spectrum simultaneously, derive vertical mean wind speed and other atmospheric disturbance parameters thus, thereby the influence to vertically-supplying air is proofreaied and correct, to improve the measuring accuracy of precipitation parameter.
Atmospheric disturbance scattered signal (Bu Lake scattering) is proportional to f
1/3(wherein f is a frequency of sound wave), and the scattered signal of precipitation (Rayleigh scattering) is proportional to f
4Therefore, conventional all-bottom sound radar (1000-4500Hz) though detectable atmospheric disturbance, from the scattered signal of precipitation particle too a little less than, promptly use the sound wave of 4500Hz also can only detect the frequency spectrum of heavy rain.Experiment showed, that to have only frequency to reach the precipitation Doppler frequency spectrum that about 6000Hz detects when above just enough big, have practical value.In order to survey the scattered signal of precipitation with high frequency sound wave, preferably select suitable microphone for use.
For example frequency of sound wave is when the 10kHz left and right sides, and sensitivity of microphone available in the commerce is higher, and characteristic is smooth, can reach optimum detection effect, even very little particle is that raindrop or the ice slag of 0.2mm also can be detected as diameter.Can obtain the commercial ultrasonic sensor of 40kHz in the market, but the atmospheric disturbance that the acoustic radar of 40kHz obtains spectrum is too small.The characteristic of present commercial microphone is best about 10kHz.
Data sampling among Fig. 1 and processing section 3 preferably are made up of a PC and a DSP circuit as workstation.According to the present invention, except the sound wave of antenna sends and receiving sensor element, prime amplifier, power amplifier etc. must be with the hardware realizations, the operation of other acoustic radar devices and operation control, transmission, received signal processing capacity etc. can all be realized by software (subroutine).The running parameter of acoustic radar, as frequency of sound wave, sound wave pulse width and send repetition frequency, the frequency spectrum of sound wave averaging time, show the time interval of quantity of precipitation and vertical velocity etc., can on PC, set by software.In addition, the parameter that other relevant datas are handled comprises sample frequency multiple (4 times or 8 times), and the method for spectral smoothing and level and smooth number of times etc. also can be set by software.Sound wave pulse generator, superheterodyne receiver, low pass and bandpass filter, real time digital signal are handled functions such as (FFT, power spectrum calculating etc.) and acoustic radar operation controller and can be realized by programming in DSP and PC.The present invention can realize full machine robotization and unattended like this, and the work of instrument is more reliable, and does not need substantially to safeguard simultaneously-measured precision and accuracy height.DSP and PC also can all be integrated in the casing of acoustic radar device, thereby reduce equipment volume, and prevent external disturbance.
Have multiple integrated DSP chip to use at present, these dsp chips have pipeline organization, and computing function is powerful, is very suitable for the FFT computing.The DSP circuit also includes ingredients such as A/D, D/A translation interface, storer except that dsp chip, whole DSP circuit can be designed as the form of plug-in card, is built in the PC.Can certainly adopt other microprocessor to realize the function of DSP, perhaps only realize all data processing functions, but the arithmetic speed of DSP be very fast, be convenient to realize real-time, online measurement with PC.
Wherein DSP programmes with corresponding assembly language, and can use various program languages as the PC of workstation, waits and programmes as C++, Visual Basic.
Fig. 2 and Fig. 3 show structure and design according to antenna plate 4 of the present invention with longitudinal sectional view and front view respectively.Antenna plate 4 for example can be made by plank or aluminium sheet, can be designed as rectangle, and its size for example is 40cm * 40cm, perhaps also can be designed as circle, and its diameter for example is 40cm.The thickness of antenna plate 4 for example is 15mm.Certainly, the size of antenna plate 4 can design according to practical situations, and in pre-amplification circuit 2 is arranged on the casing of high frequency acoustic radar device.
On antenna plate 4 as shown in Figures 2 and 3, the device that is used to send the test high frequency sound wave be used to receive the sensor branch that returns sound wave and be arranged: a powerful electromagnetic horn 5 is arranged on the central authorities of antenna plate 4, is used to send high frequency sound wave; The microphone 6 that receives skirts with a plurality of band loudspeaker is centered around electromagnetic horn 5 arranged around that send sound wave as acoustic receiving transducer (for example being 20 to 26 microphones).
According to a preferred embodiment of the present invention, as shown in Figure 2, each microphone receiving sensor element 7 is positioned at an aperture 8 on the antenna plate, and the diameter of aperture for example is 9.8mm.Fig. 4 is the zoomed-in view of microphone preferred structure among Fig. 2.Have one intersegmentally apart from l the microphone receiving sensor element 7 in from the opening part of described aperture 8 to aperture, as the wavelength of establishing sound wave is λ, and then this intersegmentally preferably is about λ/4 apart from l, has formed an acoustic wave filter.For example, when the centre frequency of electromagnetic horn 5 emission sound waves was 10kHz, described spacing l was about 7.8mm, and the quality factor q of the bandpass filter of formation is about 10, and its bandwidth is about 1kHz, thereby has reduced interference of noise to received signal effectively.
Fig. 5 shows a kind of embodiment according to hf doppler acoustic radar device of the present invention.As we can see from the figure, in casing 9 outer setting of described device the one infundibulate emission/receiving hood 10 of opening is vertically upward arranged, its xsect can be rectangle or circle, and its cross-sectional area reduces from top to bottom gradually.This emission/receiving hood 10 can be wooden, also can be made by aluminium or plastics etc., and the inclination angle between its side and the ground normal for example is 15 °~18 °, makes that entering lural sound wave can fully be gathered by antenna plate 4.The inwall that is preferably in infundibulate emission/receiving hood 10 posts the acoustic foam material, to remove interference noise.The size of infundibulate emission/receiving hood 10 also can design according to actual needs, and the big more sensitivity of then measuring of its size is high more.
In order to change the direction of propagation of sound wave, can launch in infundibulate/reflecting plate 11 is set between receiving hood 10 and the antenna plate 4.As shown in Figure 4, reflecting plate 11 is arranged on the below of infundibulate emission/receiving hood 10, and the inclination angle between it and the ground is 45 °, and antenna plate 4 is provided with perpendicular to ground.
Fig. 6 shows another embodiment, wherein be provided with two reflecting plates 11 and 12, wherein first reflecting plate 11 is arranged on the below of infundibulate emission/receiving hood 10, and the inclination angle between the ground is 45 °, angle between second reflecting plate 12 and first reflecting plate 11 is 90 °, and antenna plate 4 is parallel to ground and is provided with, and is positioned at the top of second reflecting plate 12.Adopting the advantage of two reflecting plates is to avoid water droplet to be splashed on the antenna plate through reflection fully, thereby has reduced the possibility that breaks down.
Reflecting plate can be made by corrosion resistant plate, and its surface smoothing helps reflective sound wave.The thickness of reflecting plate is more preferably greater than 0.5mm, and heating defrost device can be equipped with in its back side, is used for removing under the weather conditions of cold snowflake and ice crystal attached to the reflecting plate surface.But in the embodiment that adopts two reflecting plates, second reflecting plate 12 just do not need such heating defrost device has been set overleaf, because snowflake and ice crystal can not fallen on second reflecting plate 12 substantially.
The present invention is not limited to the foregoing description, and those skilled in the art can make various changes within the scope of the invention.
In addition, because basic identical with the measuring principle of precipitation parameters such as rain, snow, be that the sand and dust particle is littler, so the method according to this invention and device also can be diverted to the measurement to the sandstorm meteorologic parameter to the measurement of sandstorm.
Claims (20)
1. the size-grade distribution of a quantitative remote measurement precipitation, the method of quantity of precipitation and other precipitation parameters, it is characterized in that, send the high frequency sound wave pulse that frequency is not less than 6kHz by hf doppler acoustic radar antenna at interval vertically upward with certain hour, after delay after a while, receive by precipitation particle and the back scattered acoustic signals of atmospheric disturbance with a plurality of acoustic receiving transducers, the acoustic signals that receives is through amplifying, add and after deliver to sampling of data and processing section, carry out mould/number conversion, and resulting digital signal carried out fast fourier transform, be transformed to frequency-region signal from time-domain signal, obtain precipitation power spectrum and atmospheric disturbance power spectrum simultaneously, then the precipitation power spectrum and the atmospheric disturbance power spectrum that are obtained are analyzed, derive precipitation size-grade distribution and other precipitation parameters from the precipitation power spectrum, and derive average vertical wind speed and other atmospheric disturbance parameters from resulting atmospheric disturbance power spectrum, utilize average vertical wind speed and other atmospheric disturbance parameters that precipitation size-grade distribution and other precipitation parameters are proofreaied and correct, to improve measuring accuracy.
2. the method for claim 1 is characterized in that, described a plurality of acoustic receiving transducers are microphones.
3. method as claimed in claim 2, it is characterized in that, microphone is installed in the aperture on the antenna plate, the sonic sensor of microphone an intersegmental distance is arranged in from the opening of aperture to aperture, thereby formed an acoustic wave filter, wavelength according to the high frequency sound wave pulse of being sent is adjusted described spacing, and making described spacing is 1/4th of the high frequency sound wave pulse wavelength that sent, receives noise to reduce.
4. the method for claim 1, it is characterized in that, described data sampling and processing section are made of a computing machine and a high-speed data treating apparatus as workstation, wherein mould/number conversion and fast fourier transform are finished by described high-speed data treating apparatus, and the analysis that the frequency spectrum that is obtained carries out is finished by described computing machine.
5. method as claimed in claim 4 is characterized in that, described high-speed data treating apparatus is the DSP circuit.
6. as each described method in the claim 1 to 5, it is characterized in that the processing and the analysis of data in data sampling and processing section of the generation of sound wave pulse and superheterodyne reception, signal all can be by software automatically, realize in real time.
7. hf doppler acoustic radar device that is used for size-grade distribution, quantity of precipitation and other precipitation parameters of quantitative remote measurement precipitation, it is characterized in that, described acoustic radar device is made of antenna part and data sampling and processing section, wherein antenna part comprises the infundibulate emission/receiving hood of opening vertically upward, is used to send and receive the antenna plate of sound wave; On described antenna plate, come transmission frequency to be not less than the high frequency sound wave pulse of 6kHz, receive back scattered acoustic signals with a plurality of sound wave receiving traps with electromagnetic horn; Behind the receiving antenna plate, be provided with pre-amplification circuit, the acoustic signals that is used for collecting amplify, add and; Through amplifying, add and acoustic signals deliver to data sampling and processing section, described data sampling and processing section are to amplifying, add and after signal carry out mould/number conversion, and the digital signal that obtains carried out fast fourier transform, be transformed to frequency-region signal from time-domain signal, obtain precipitation power spectrum and atmospheric disturbance power spectrum simultaneously, and, described data sampling and processing section are analyzed the precipitation power spectrum and the atmospheric disturbance power spectrum that are obtained, derive precipitation size-grade distribution and other precipitation parameters from the precipitation power spectrum, and derive average vertical wind speed and other atmospheric disturbance parameters from resulting atmospheric disturbance power spectrum, utilize average vertical wind speed and other atmospheric disturbance parameters that precipitation size-grade distribution and other precipitation parameters are proofreaied and correct.
8. hf doppler acoustic radar device as claimed in claim 7 is characterized in that described a plurality of acoustic receiving transducers are microphones.
9. hf doppler acoustic radar device as claimed in claim 8, it is characterized in that, described microphone is installed in the aperture on the described antenna plate, the sonic sensor of microphone an intersegmental distance is arranged in from the opening of aperture to aperture, formed an acoustic wave filter, described spacing is adjusted according to the wavelength of the high frequency sound wave pulse of being sent, and the length that makes described spacing is 1/4th of the high frequency sound wave pulse wavelength that sent, receives noise to reduce.
10. hf doppler acoustic radar device as claimed in claim 8 is characterized in that, the electromagnetic horn that is used to launch the high frequency sound wave pulse is positioned at the central authorities of described antenna plate, a plurality of microphones that are used to receive sound wave be arranged in described electromagnetic horn around.
11. hf doppler acoustic radar device as claimed in claim 7, it is characterized in that, described data sampling and processing section are made of a computing machine and a high-speed data treating apparatus as workstation, wherein mould/number conversion and fast fourier transform are finished by described high-speed data treating apparatus, and the analysis that the frequency spectrum that is obtained carries out is finished by described computing machine.
12. hf doppler acoustic radar device as claimed in claim 11 is characterized in that described high-speed data treating apparatus is the DSP circuit.
13. hf doppler acoustic radar device as claimed in claim 12 is characterized in that the DSP circuit is designed to plug-in card, is built in the described computing machine.
14., it is characterized in that described data sampling and processing section can be built in the casing of described hf doppler acoustic radar device as each described hf doppler acoustic radar device in the claim 7 to 13.
15. hf doppler acoustic radar device as claimed in claim 7 is characterized in that, is provided with a reflecting plate below infundibulate emission/receiving hood, the inclination angle between it and the ground is 45 °, and antenna plate is provided with perpendicular to ground.
16. hf doppler acoustic radar device as claimed in claim 15 is characterized in that, heating defrost device is housed at the back side of described reflecting plate.
17. hf doppler acoustic radar device as claimed in claim 7, it is characterized in that, be provided with two reflecting plates, wherein first reflecting plate is arranged on infundibulate emission/receiving hood below, and the inclination angle between the ground is 45 °, angle between second reflecting plate and first reflecting plate is 90 °, and antenna plate is parallel to ground and is provided with, and is positioned at the top of second reflecting plate.
18. hf doppler acoustic radar device as claimed in claim 17 is characterized in that, heating defrost device is housed at the back side of described first reflecting plate.
19. hf doppler acoustic radar device as claimed in claim 7 is characterized in that, the processing and the analysis of data in data sampling and processing section of the generation of sound wave pulse and superheterodyne reception, signal all can be by software automatically, realize in real time.
20. as each described hf doppler acoustic radar device application in the meteorologic parameter of quantitative measurment sandstorm in the claim 7 to 19.
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CN101258420B (en) * | 2005-06-20 | 2012-07-04 | 温德比克私人有限公司 | Sodar sounding of the lower atmosphere |
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CN106680820A (en) * | 2017-01-22 | 2017-05-17 | 张子良 | Novel parabolic antenna, acoustic radar system for detecting water vapor transfer channel and rainfall predicting method |
CN108474867A (en) * | 2015-12-18 | 2018-08-31 | 釜庆大学校产学协力团 | High resolution precipitation amount data recovery system and its method |
CN112255155A (en) * | 2020-10-28 | 2021-01-22 | 浙江大学 | Rotation measurement system and method for two-dimensional distribution of particle concentration and particle size |
CN112611921A (en) * | 2020-12-09 | 2021-04-06 | 上海无线电设备研究所 | Atmospheric sound field simulation device and electromagnetic scattering characteristic test method thereof |
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2004
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Cited By (7)
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CN101258420B (en) * | 2005-06-20 | 2012-07-04 | 温德比克私人有限公司 | Sodar sounding of the lower atmosphere |
CN101715502B (en) * | 2007-06-01 | 2012-07-04 | 涅磐公司 | Housings for phased array monostatic sodar systems |
CN108474867A (en) * | 2015-12-18 | 2018-08-31 | 釜庆大学校产学协力团 | High resolution precipitation amount data recovery system and its method |
CN106680820A (en) * | 2017-01-22 | 2017-05-17 | 张子良 | Novel parabolic antenna, acoustic radar system for detecting water vapor transfer channel and rainfall predicting method |
CN113366344A (en) * | 2018-11-06 | 2021-09-07 | 安德思托利公司 | Rain sensor |
CN112255155A (en) * | 2020-10-28 | 2021-01-22 | 浙江大学 | Rotation measurement system and method for two-dimensional distribution of particle concentration and particle size |
CN112611921A (en) * | 2020-12-09 | 2021-04-06 | 上海无线电设备研究所 | Atmospheric sound field simulation device and electromagnetic scattering characteristic test method thereof |
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