KR20130037428A - Doppler lidar apparatus and method for operating doppler lidar apparatus - Google Patents

Abstract

PURPOSE: A Doppler lidar apparatus is provided to use the laser, which is transmitted and received by relating with the atmosphere, through an etalon with different permeability for each wavelength, thereby easily measuring the wind field property. CONSTITUTION: A Doppler lidar apparatus(100) comprises an etalon(105) transmitting the laser launched from a laser part(101), a transceiver(107) irradiating the penetrated laser to object materials and receives a backscatter signal backscattered from the object material; and a processor(115) for measuring the wind field property using a first scattering signal penetrating the etalon among the backscatter signal. [Reference numerals] (101) Laser part; (103) Beam expansion unit; (105) Etalon; (107) Transceiver; (109) First beam division part; (111) Second beam division part; (113) Wavelength end; (115) Processor;

Description

DOPPLER LIDAR APPARATUS AND METHOD FOR OPERATING DOPPLER LIDAR APPARATUS

Embodiments of the present invention relate to a technique for measuring wind field characteristics using a laser transmitted and received via etalon.

The Doppler lidar system irradiates a laser into the atmosphere and receives signals backscattered by various air molecules or aerosols in the atmosphere, and measures the velocity of air or small particles. In general, the laser used in the Doppler lidar apparatus is an injection seed laser, and the wavelength stability of the laser is very important enough to influence the performance of the entire system. That is, when the wavelength of the laser is changed, a problem occurs because the degree of wavelength shift of scattered Doppler wavelength shifted light is unknown.

In addition, the wavelength of the scattering signal can be measured only when the wavelengths of the etalon and the laser, which are reception devices, are simultaneously controlled by one controller. Here, the etalon is mainly composed of two mirrors with air spaced Etalon, and the temperature of the air and the two mirror intervals constituting the etalon must be precisely controlled in real time.

As a result, the Doppler lidar apparatus is not easy to manufacture and is expensive.

Therefore, there is a need for a technology capable of easily measuring wind field characteristics using a general low cost laser.

An object of the present invention is to easily measure wind field characteristics using a laser transmitted and received in association with the atmosphere through an etalon having a different transmittance depending on the wavelength.

The Doppler lidar apparatus for achieving the above object is irradiated with a laser beam unit for emitting a laser, the etalon for transmitting the laser beam, and the laser transmitted through the etalon to the target object, and backscattered from the target object. And a transmitter / receiver configured to receive the backscattered signal and a first field scattered signal that passes through the etalon among the backscattered signals.

The Doppler lidar device may further include a first beam splitter configured to transmit the emitted laser to the etalon and reflect the first scattered signal to the processor.

The Doppler lidar device may further include a wave plate for rotating the polarization direction of at least one of the laser transmitted through the etalon or the backscattered signal.

The Doppler lidar apparatus may further include a second beam splitter configured to transmit a first scattered signal among the backscattered signals to the etalon, and reflect a second scattered signal from the backscattered signals to the processor. Can be.

The processor may measure the wind field characteristic by further considering the second scattering signal together with the first scattering signal.

The Doppler lidar device may further include a beam enlargement unit for relatively reducing the divergence angle with respect to the emitted laser.

A method of operating a Doppler lidar device for achieving the above object comprises the steps of: firing a laser at the laser portion in the Doppler lidar device; transmitting the emitted laser at the etalon in the doppler lidar device; In the doppler lidar device, the transmitting and receiving unit, irradiating the laser transmitted through the etalon to a target object, receiving a backscattered signal backscattered from the target object, and in the processor in the doppler lidar device, And measuring wind field characteristics by using a first scattering signal passing through the etalon among the backscattering signals.

According to an embodiment of the present invention, by measuring the wind field characteristics through an etalon having a different transmittance depending on the wavelength, and using a laser transmitted and received in association with the atmosphere, precise wavelength control of the laser is not necessary, thereby providing a general low cost. Wind field characteristics can be easily measured using a laser.

According to an embodiment of the present invention, as the time difference of irradiating the laser and receiving the backscattered signal backscattered is short (for example, several tens of microseconds), the temperature change (or external change) of the etalon during the time is Since there is little change in the optical transmittance due to this, temperature correction of etalon due to temperature change is unnecessary as in a typical Doppler lidar apparatus.

1 is a view showing the configuration of a Doppler lidar apparatus according to an embodiment of the present invention.
2 is a view showing a specific example of the Doppler lidar apparatus according to an embodiment of the present invention.
3 is a diagram showing the permeability to etalon in the Doppler lidar apparatus according to an embodiment of the present invention.
4 is a diagram illustrating the transmittance according to the wavelength shift of the laser.
5 is a flowchart illustrating a method of operating a Doppler lidar device according to an embodiment of the present invention.

Hereinafter, a Doppler lidar device and a method of operating the Doppler lidar device according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing the configuration of a Doppler lidar apparatus according to an embodiment of the present invention.

Referring to FIG. 1, the Doppler lidar apparatus 100 according to an embodiment of the present invention includes a laser unit 101, a beam expanding unit 103, an etalon 105, a transceiver unit 107, and a first beam component. An installment unit 109, a second beam splitting unit 111, a wave plate 113, and a processor 115 are included.

The laser unit 101 generates and fires a laser.

The beam expanding unit 103 may relatively reduce the divergence angle of the emitted laser.

The etalon 105 transmits the laser beam that has passed through the beam enlarger 103. In addition, the etalon 105 may transmit some of the backscattered signal that is backscattered after being irradiated to the object (eg, the atmosphere) through the transceiver 107.

Here, the etalon 105 may have a different transmittance according to the wavelength of the laser or a part of the backscattered signal (eg, the first scattered signal).

The transceiver 107 irradiates the laser beam transmitted through the etalon 105 to the object, receives the backscattered signal backscattered from the object, and receives the second beam splitter 111 through the wave plate 113. To pass. In this case, the transceiver 107 may emit, for example, a laser having a wavelength of at least one of 1064 nm, 532 nm, or 355 nm into the atmosphere.

The first beam splitter 109 is, for example, a polarization beam splitter that transmits the laser beam emitted from the laser unit 101 to the etalon 105, and transmits the etalon 105 of the backscattered signal from the transceiver 107. ) May be reflected to the first scattering signal and transmitted to the processor 115.

The second beam splitter 111 may be, for example, a beam splitter that is emitted from the laser unit 101 to transmit most of the laser beams passing through the etalon 105. In addition, the second beam splitter 111 transmits the first scattered signal among the backscattered signals from the transceiver 107 to the etalon 105 and reflects the second scattered signal from the backscattered signal to the processor ( 115).

The wave plate 113 may rotate a polarization direction with respect to the laser transmitted through the etalon 105 or the backscattered signal. Here, the wave plate 113 is, for example, a quarter wave plate, it is possible to rotate the polarization direction of the light passing through twice '90 degrees'. That is, the wavelength plate 113 is rotated 45 degrees before being irradiated to the target object, the laser passing through the wavelength plate 113 is scattered back from the target object is rotated 45 degrees again, the polarization direction of the received backscattered signal As a result, the polarization direction of the laser emitted from the laser unit 101 can be rotated 90 degrees.

The processor 115 measures wind field characteristics (eg, wind field distribution) using the first scattering signal passing through the etalon 105 among the backscattering signals. In addition, the processor 115 may further measure the wind field characteristics by further considering the second scattering signal together with the first scattering signal. Here, the first and second scattering signals may include, for example, signals for external environmental changes such as changes in aerosols in the atmosphere, changes in energy of lasers, changes in permeation of etalon, and the like. In addition, the first scattering signal may further include a signal for the Doppler effect of the particles or air molecules.

That is, the processor 115 may divide the second scattering signal into the first scattering signal, remove the signal for the external environment change, and acquire only the signal for the Doppler effect.

The Doppler lidar apparatus according to an embodiment of the present invention changes the temperature of the etalon during the time period as the time difference of irradiating the laser and receiving the backscattered signal backscattered is short (for example, several tens of microseconds). Since there is almost no change in the optical transmittance due to external change, it is unnecessary to correct the temperature of the etalon due to the temperature change as in the general Doppler lidar apparatus.

2 is a view showing a specific example of the Doppler lidar apparatus according to an embodiment of the present invention.

Referring to FIG. 2, the Doppler lidar apparatus 200 includes a laser unit 201, a beam expander 203, a half wave plate 205, a polarization beam splitter 207, an etalon 209, and a beam splitter. 211, a quarter wave plate 213, a transceiver 220, a first signal processor 230, a second signal processor 240, and a terminal 250.

The laser unit 201 generates and fires a laser.

The beam expander 203 serves to relatively reduce the divergence angle of the emitted laser. The beam expander 203 reduces the divergence angle of the laser, which is a problem that occurs when the divergence angle is relatively large, that is, when the light of the laser irradiated to the atmosphere 215 is spread too much, the field of view of the receiving optical system. ), And the large FOV of the receiving optical system can solve the problem of shortening the measurement distance by increasing the atmospheric background signal.

In addition, by reducing the divergence angle of the laser, the beam expander 203 may solve the problem of changing transmission characteristics when passing through the etalon 209 when the divergence angle is relatively large.

The half wave plate 205 adjusts the direction of the laser beam passing through the beam expander 211 to transmit the linearly polarized laser to the polarization beam splitter 207.

The polarization beam splitter 207 transmits most of the linearly polarized laser.

The etalon 209 reflects most of the laser beam that has passed through the polarization beam splitter 207, so that the laser passes through the polarization beam splitter 207 and proceeds toward the laser unit 201. Accordingly, the Doppler lidar device 200 is a protective optical system (not shown) that protects the laser unit 201 from being impacted by the laser reflected from the etalon 209 and re-entered into the laser unit 201. ) May be further included. Most of the laser beam passing through the etalon 209 passes through the beam splitter 211 and passes through the quarter wave plate 213.

The beam splitter 211 may be designed to transmit most (eg, 90% or more) of the laser.

The quarter wave plate 213 serves to change the polarization of the laser from linear polarization to rotation polarization.

The transceiver 220 includes a first lens 221 or a mirror having a curvature, and a second lens 225 or a mirror having a curvature, and the laser polarized by the quarter wave plate 213 to the first, By transmitting or reflecting through the two lenses 221 and 225, the thickness of the laser can be increased again and irradiated into the atmosphere 215. At this time, as the thickness of the laser increases, the divergence angle of the laser decreases.

The transceiver 220 further includes a hole 223 positioned between the first lens 221 and the second lens 225, and passes the laser to be irradiated through the hole 223 so that the laser is irradiated with respect to the laser to be irradiated. It is possible to reduce the divergence characteristic and to more certainly ensure the parallel characteristic. In addition, the transceiver 220 may pass backscattered light backscattered back in the opposite direction irradiated by the laser among small dust or light scattered by air molecules in the atmosphere 215 to the hole 223 again. . Here, the light scattered by the air molecules or backscattered by the spherical particles, according to Mie or Rayleigh scattering theory, the majority of the light is maintained without changing its polarization characteristics.

That is, the light whose polarization characteristics are maintained is collected by the second lens 225 and collected into small holes, and the light changed into parallel light again by the holes 223 and the first lens 221 is a quarter wave plate. Passing 213 can be linearly polarized light again. The polarization direction of the linearly polarized light differs by 90 degrees from that direction when irradiated into the atmosphere.

The beam splitter 211 reflects about 10% of the light of the wavelength at which the 90-degree phase change occurs, transmits the light to the second signal processor 240, and transmits the remaining 90%. At this time, the transmitted light is transmitted to the etalon 209 to be transmitted again.

The second signal processor 240 includes a lens 241, an optical sensor 243, and an ADC 245.

The lens 241 collects 10% of the reflected light.

The optical sensor 243 converts the collected Lidar signal into an electrical signal.

An ADC (Analogue Digital Convertor) 245 converts an electrical signal into a digital signal and transmits it to the terminal 250 as a second scattered signal.

Etalon 209 can transmit only a very narrow region wavelength due to its characteristics. Accordingly, when there is no movement of air molecules or small dust, that is, scattering material, that is, zero speed or no speed in the direction irradiated by the laser, the wavelength of the backscattered light is the original wavelength, that is, the first etalon 209. May be the same wavelengths as when transmitting.

Here, if the particle moves in the direction in which the laser is irradiated, the backscattered wavelengths may consist of wavelengths with slightly longer wavelengths, and the particles or air molecules may be opposite to the direction in which the laser is irradiated, i. When moving in the direction, the wavelength distribution consists of wavelengths whose wavelength is shorter than the first.

That is, the light transmitted by 90% in the beam splitter 211 passes through the etalon 209 and has different transmission characteristics according to the Doppler wavelength shift characteristics of the wavelengths. If the speed of the scattering material is zero, then the transmission characteristic of the scattered light is the same wavelength distribution as the wavelength characteristic of the transmitted light of the etalon 209 when it is first irradiated from the laser to the atmosphere, and these wavelengths are the original wavelength of the etalon. It has the same distribution characteristic as the permeation characteristic, the permeability has a maximum value, and again, the majority passes through the etalon 209. If scattering is caused by moving particles or air molecules, the wavelength distribution of the scattered light is changed as shown in the figure, and thus does not coincide with the transmission wavelength characteristic graph of the etalon 209, resulting in total transmittance. Will fall. That is, light has different transmission characteristics according to the direction and size of the scattering material movement.

Since the light transmitted through the etalon 209 has a 90 degree polarization direction different from when the polarization direction is first irradiated to the atmosphere, the polarization beam splitter 207 transmits most of the laser beam irradiated into the atmosphere. Most of the back scattered from the laser passing through the etalon 209 is reflected, and is transmitted to the first signal processor 230.

The first signal processor 230 includes a lens 231, an optical sensor 233, and an ADC 235.

The lens 231 receives the scattered Lidar signal via the polarization beam splitter 207 and condenses the received Lidar signal.

The optical sensor 233 converts the collected Lidar signal into an electrical signal.

The ADC 235 converts an electrical signal into a digital signal and transmits the electrical signal to the terminal 250 as a first scattering signal.

The terminal 250 may be, for example, a computer, and includes a signal for a change in external environment such as aerosol change in the atmosphere, a change in energy of a laser, a change in permeability of an etalon, and a signal for a Doppler effect of particles or air molecules. 1 Wind field characteristics can be measured using a scattering signal. In addition, the terminal 250 may more easily measure wind field characteristics by using a second scattering signal including a signal for a change in an external environment along with the first scattering signal.

In addition, the Doppler lidar apparatus 200 may determine the velocity distribution of the wind field by measuring the intensity of the wind and measuring the intensity of the surrounding wind field with respect to other places around it. That is, the Doppler lidar apparatus 200 keeps the irradiation direction of the laser constant, obtains the absolute value of the wind intensity at each point in the direction in which the laser is irradiated, and then irradiates the laser irradiation direction using the scanning device. By changing the direction, the absolute value of the wind field is found again around the initial position, and when applied to the three-dimensional space in this way, the three-dimensional wind field distribution can be known. In addition, when the Doppler lidar apparatus 200 knows the direction of the wind only at any one location, the direction of the wind field at all points can be known by the continuous chracteristics.

FIG. 3 is a diagram showing the transmittance of the etalon in the Doppler lidar apparatus according to an embodiment of the present invention, Figure 4 is a diagram showing the transmittance according to the wavelength shift of the laser.

3 and 4, the transmittance for etalon may be, for example, about 100% or 50% depending on the wavelength.

Here, the wavelength range free wavelength (300-2, Free Spectral Range) to the point where the transmittance is 100% is determined by the refractive index and the thickness of the etalon, and the half-wavelength thickness 300 of the wavelength at which the transmittance is 50%. -1, FWHM: Full Width Half Maximun (FWHM) is related to the reflectivity, the flatness, and the slope of the two faces constituting the etalon.

Doppler lidar devices may use, for example, 1064 nm, 532 nm or 355 nm lasers. Specifically, the Doppler lidar device uses a laser of 355 nm if it wants to acquire a wind field in the air layer where there is little dust, whereas a laser of 1064 nm is used in a dusty area and a 532 nm laser in a normal atmosphere. Can be used.

In case of using a laser of 532 nm, the Doppler lidar device selects the half wavelength (300-1) and the free wavelength (300-2) of the etalon in consideration of the maximum wind speed and precision to be measured. Can be. Here, the free wavelength 300-2 is related to the maximum measurement speed, and the half-wavelength thickness 300-1 is related to the minimum wind field size that the Doppler lidar apparatus can measure.

 On the other hand, the half-wavelength thickness becomes wider when the flatness of the etalon becomes poor or the reflectivity is low, and when the half-wavelength thickness increases, the minimum wind speed that can be measured increases, so the reflectivity and the flatness should be properly controlled. The maximum value of the wind field to be measured is preferably designed such that 50 m / sec or more can be measured in consideration of the speed of the wind field at a typhoon or a high altitude.

Therefore, the thickness of the etalon may be selected based on the wavelength shift calculation and the free wavelength range calculation by the Doppler wind field.

When the transmittance for the etalon is determined by the free wavelength range and the half-wavelength thickness, light such as laser or sunlight having a wide wavelength range has a wavelength of 50 transmittance for each wavelength corresponding to the free wavelength range. That is, most of the light is reflected, but a wavelength having a transmittance of 50 exists for each free wavelength range. If the white light or the laser is transmitted twice, the transmitted light is equivalent to multiplying the first transmitted light 300 twice. However, when the first transmitted light has a wavelength shift as a whole (302, 303), the amount of light to be transmitted twice is significantly reduced compared to the amount of light where no wavelength shift occurs. That is, the amount obtained by multiplying the transmittance graph 300 and the wavelength distributions 302 and 303 becomes a transmitted value, and the value is less than the product of the transmittance graph 300 and the wavelength distribution 301 corresponding to the case where there is no wavelength shift. Value, which depends on the degree of wavelength shift. As a result, since the value of the transmittance varies with the wavelength shift, the Doppler lidar apparatus can determine the degree of wavelength shift by the intensity of the Lidar signal.

5 is a flowchart illustrating a method of operating a Doppler lidar device according to an embodiment of the present invention.

Referring to FIG. 5, in step 501, the Doppler lidar device generates and fires a laser. In this case, the Doppler lidar apparatus may relatively reduce the divergence angle of the laser beam emitted by using the beam enlarger.

In addition, the Doppler lidar device may transmit a laser having a reduced divergence angle through a first beam splitter (eg, a polarizing beam splitter) and then transmit the laser to the etalon.

In step 503, the Doppler lidar device transmits the emitted laser through the etalon.

The Doppler lidar device transmits most of the laser passing through the etalon through the second beam splitter (e.g., beam splitter), and through the wave plate (e. Can be rotated.

In step 505, the Doppler lidar apparatus irradiates the laser (the laser of which the polarization direction is rotated) transmitted through the etalon to the object, and receives the backscattered signal backscattered from the object. In this case, the Doppler lidar apparatus may emit, for example, a laser having a wavelength of at least one of 1064 nm, 532 nm, or 355 nm into the atmosphere.

In addition, the Doppler lidar device may rotate the polarization direction with respect to the backscattered signal through the wave plate.

In operation 507, the Doppler rider apparatus transmits a first scattering signal of the backscattering signal to an etalon through a second beam splitter, and reflects a second scattering signal of the backscattering signal to a processor. have.

In operation 509, the Doppler lidar device transmits the first scattering signal transmitted through the second beam splitter among the backscattering signals through the etalon. In this case, the etalon may have different transmittances depending on the wavelength of the laser or the first scattering signal.

In operation 511, the Doppler lidar apparatus may reflect the first scattered signal transmitted through the etalon to the processor through the first beam splitter.

In operation 513, the Doppler lidar apparatus measures wind field characteristics (eg, wind field distribution) using the first scattering signal or the second scattering signal. Here, the first and second scattering signals may include, for example, signals for external environmental changes such as changes in aerosols in the atmosphere, changes in energy of lasers, changes in permeation of etalon, and the like. In addition, the first scattering signal may further include a signal for the Doppler effect of the particles or air molecules.

That is, the Doppler rider device may check the external environment change or the Doppler effect by using the first scattering signal or the second scattering signal.

The present invention measures the wind field characteristics by using a laser transmitted / received in association with the atmosphere through an etalon having a different transmittance depending on the wavelength, and thus does not require accurate wavelength control of the laser. Intestinal properties can be easily measured.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the claims.

100: Doppler lidar apparatus 101: laser unit
103: beam enlarger 105: etalon
107: transceiver unit 109: first beam splitter
111: second beam splitting portion 113: wave plate
115: processor

Claims (14)

Etalon for transmitting the laser emitted from the laser unit;
A transmitting / receiving unit which irradiates the transmitted laser beam to a target object and receives a backscattered signal backscattered from the target object; And
A processor for measuring wind field characteristics by using a first scattering signal passing through the etalon among the backscattering signals.
Doppler lidar device comprising a. The method of claim 1,
The etalon,
A doppler device having a different transmittance according to the wavelength of the laser or the first scattering signal. The method of claim 1,
A first beam splitter configured to transmit the laser to the etalon and reflect the first scattered signal to the processor
Further comprising, a Doppler lidar device. The method of claim 1,
Wave plate for rotating the polarization direction for at least one of the laser or the backscattered signal
Doppler lidar device further comprising. The method of claim 1,
A second beam splitter configured to transmit a first scattered signal among the backscattered signals to the etalon, and reflect the second scattered signals among the backscattered signals to the processor;
Further comprising, a Doppler lidar device. The method of claim 5,
The processor comprising:
A Doppler lidar device for measuring the wind field characteristics by further considering the second scattering signal together with the first scattering signal. The method of claim 1,
Beam enlargement unit for relatively reducing the divergence angle for the laser
Further comprising, a Doppler lidar device. In the operating method of the Doppler lidar device,
Firing a laser in the laser portion of the Doppler lidar device;
At the etalon in the Doppler lidar device, transmitting the fired laser;
Irradiating a laser beam passing through the etalon to a target object and receiving a backscattered signal backscattered from the target object by a transceiver in the Doppler lidar device; And
Measuring wind field characteristics by using a first scattering signal passing through the etalon among the backscattering signals in a processor in the Doppler lidar apparatus
Method of operation of the Doppler lidar device comprising a. 9. The method of claim 8,
The etalon,
A method of operating a Doppler device in which transmittance is different depending on the wavelength of the laser or the first scattering signal. 9. The method of claim 8,
At a first beamsplitter in the Doppler lidar device, transmitting the laser to the etalon; And
In the first beam splitter, reflecting the first scattered signal and transmitting the reflected signal to the processor
Further comprising, the operation method of the Doppler lidar device. 9. The method of claim 8,
Rotating a polarization direction for at least one of the laser or the backscattered signal at a wavelength plate in the Doppler lidar device
Further comprising, the method of operation of the Doppler lidar device. 9. The method of claim 8,
Transmitting a first scattered signal of the backscattered signal to the etalon at a second beam splitter in the Doppler lidar device; And
Reflecting, by the second beam splitter, a second scattered signal of the backscattered signal to the processor;
Further comprising, the operation method of the Doppler lidar device. The method of claim 12,
Measuring the wind field characteristics,
Measuring the wind field characteristic by further considering the second scattering signal together with the first scattering signal
Including, the method of operation of the Doppler lidar device. 9. The method of claim 8,
At the beam magnifier in the Doppler lidar device, relatively reducing the divergence angle for the emitted laser.
Further comprising, the operation method of the Doppler lidar device.

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