CN214895782U - High-resolution laser radar - Google Patents

Abstract

The utility model discloses a high resolution laser radar, laser radar includes laser emission unit, collimation unit, beam split unit, digital micromirror device, focus unit and detector unit and constitutes. Wherein the laser emitting unit is used for emitting a pulse laser beam; the collimation unit is used for collimating the pulse laser beam and reducing the divergence angle; the light splitting unit is used for reflecting the pulse laser beam to the digital micromirror device; the digital micromirror device can be used as a blazed grating and is used for emitting the pulse laser beams in diffraction orders of-2, -1, 0, 1 and 2 respectively, each pulse laser beam can generate five diffraction pulse laser beams in a time-sharing manner, and the resolution of the laser radar can be improved; the focusing unit is used for focusing the echo light beam transmitted by the light splitting unit to the detector. The utility model provides a simple structure, low-cost high resolution laser radar.

Description

High-resolution laser radar

Technical Field

The utility model relates to a laser radar technical field, concretely relates to high resolution laser radar of simple structure, low cost.

Background

With the continuous development of automatic driving technology in recent years, the laser radar has been developed greatly as a core component of an automatic driving system, the measuring range of the laser radar can reach hundreds of meters, the measuring precision can reach millimeter level, and the laser radar has the advantages of high response speed, strong anti-interference capability and the like. Therefore, the laser radar also has wide application prospect in other fields such as unmanned aerial vehicles, security protection, topographic mapping and the like.

The laser scanning assembly is an important component of a laser radar system, and the mechanical laser radar uses a mechanical laser scanning device such as a rotating polygonal prism to change the emitting direction of laser light to realize large-angle scanning, but due to the influences of the size, weight, cost, power consumption and the like, the mechanical rotating laser scanning mode is gradually replaced. Micro-electro-mechanical systems (MEMS) have the advantages of small volume, low weight, low power consumption and the like, are widely applied and developed in laser radar systems, and a typical MEMS device is a two-dimensional resonance type vibrating mirror. However, the scanning technique of the hybrid solid-state lidar based on the two-dimensional resonant mode galvanometer has high cost and limited scanning field of view, and is difficult to combine large scanning field of view and high scanning frequency. The reason is that the deflection angle of the two-dimensional galvanometer is contradictory to the working frequency thereof, and the resonant frequency of the two-dimensional galvanometer can only be reduced when the deflection angle of the galvanometer is required to be increased, so that the processing technology of the resonant galvanometer which needs to obtain the deflection angle in a large range and the working frequency is extremely high in requirement and the manufacturing cost is difficult to control.

SUMMERY OF THE UTILITY MODEL

The utility model provides a high resolution laser radar design scheme with simple structure and low cost for avoiding the defects of the prior laser scanning technology.

In order to realize the purpose, the utility model discloses a technical scheme be:

the laser radar comprises a laser emission unit, a collimation unit, a light splitting unit, a digital micro-mirror device, a focusing unit and a detector unit.

The laser emission unit is used for emitting a pulse laser beam with nanosecond pulse width;

the collimation unit is used for collimating the laser beam and reducing the divergence angle;

the light splitting unit is used for reflecting the laser beam to the digital micromirror device and transmitting the laser echo beam to the detector unit; the digital micromirror device can be used as a diffraction grating and is used for emitting laser beams in different diffraction orders;

the focusing unit is used for focusing the laser echo beam transmitted by the light splitting unit to the detector.

If the number of the laser emission units is N, the number of the collimation units is N; each laser beam is incident on the surface of the digital micro-mirror device to generate 5 diffracted light beams in a time-sharing manner, wherein the 5 diffracted light beams are respectively-2-level, -1-level, 0-level, 1-level and 2-level diffracted light beams, and then the N lasers can generate 5N diffracted light beams in a time-sharing manner.

The digital micromirror device comprises a set of micromirror arrays, each micromirror being rotatable + -θThe switch has two states, and the switching time of the switch state is microsecond. In the process of switching state transition of the micro-mirror, nanosecond-level pulse laser beams are used for irradiating the micro-mirror, and the micro-mirror array can be used as a programmable blazed grating. Incident laser when the inclination angle of the micromirror in the switching process is a blaze angleThe optical beam may be diffracted into a specific diffraction order among-2, 1, 0, 1, 2 orders with a diffraction efficiency close to 100%.

When the number of the lasers is 1, the incident angle of the lasers, which is reflected by the light splitting unit and then is incident to the surface of the digital micromirror device, isαThe incident angle is the angle between the laser beam and the perpendicular line of the reflective surface of the digital micromirror device. When the number of lasers is increased, the incidence angle of each laser beam needs to be atαAnd adjusting within +/-2 degrees on the basis.

The high-resolution laser radar can realize higher emergent beam density by increasing the number N of the laser emitting units, and further can realize the improvement of the resolution of the laser radar at lower cost.

Compared with the prior art, the utility model discloses beneficial effect embodies:

1. the digital micro-mirror device is used as a laser scanning device, each beam of nanosecond pulse laser is incident on the surface of the digital micro-mirror device to generate 5 beams of diffracted light in a time-sharing manner, and the requirements of large scanning angle and high resolution are met at the same time with lower cost;

2. the higher density of the emergent light beams can be realized by increasing the number N of the laser emitting units, so that the resolution of the laser radar is improved at lower cost;

3. based on a common light path measurement principle, only one polarization unit and one detection unit are used, and the measurement of a trigger signal and a detection signal is realized by changing the polarization states of a measuring beam and an echo beam, so that the volume of the laser radar is effectively reduced, and the high-resolution laser radar with a simple and compact structure is realized.

Drawings

Fig. 1 is a schematic diagram of a laser radar according to the present invention;

fig. 2 is a schematic diagram of a control system of a laser radar shown in the present invention.

Detailed Description

In order to make the above objects, features and advantages of the present invention more intuitive and understandable, embodiments of the present invention will be described in detail below with reference to the accompanying drawings. It should be noted that, the technical solution provided in the embodiments of the present application is described in detail with five transmitting units as a basis, and in specific implementation, the number of the transmitting units may be modified according to the required actual field angle and resolution to achieve different levels of requirements. Thus, modifications may occur to those skilled in the art within the scope of the claims and the described embodiments do not represent the only embodiments of the invention.

The embodiment of the laser radar technical solution of the present invention is shown in fig. 1, and comprises a laser emitting unit 10, a collimating unit 11, a light splitting unit 14, a digital micromirror device 15, a focusing unit 13, and a detector unit 12. The laser emitting unit 10 is used for emitting a pulse laser beam with nanosecond pulse width; the collimation unit 11 is used for collimating the laser beam and reducing the divergence angle; the light splitting unit 14 is used for reflecting the laser beam to the digital micromirror device and transmitting the laser echo beam to the detector unit; the digital micromirror device 15 can be used as a diffraction grating for emitting laser beams in different diffraction orders; the focusing unit 13 is used for focusing the laser echo beam transmitted through the light splitting unit to the detector.

Fig. 1 is the utility model discloses a laser radar system principle schematic diagram, after laser emission unit 10 launches the infrared laser beam of pulse that the pulsewidth is less than 10 nanoseconds, shoot into beam splitting unit 14 behind the laser beam collimation by collimation unit 11. The light splitting unit 14 includes a polarization light splitting prism and a quarter wave plate, the polarization light splitting prism is used for reflecting the pulse laser beam, then the pulse laser beam firstly passes through the quarter wave plate and enters the digital micromirror device 15, the laser beam is reflected by the measured object, then returns along the original path, and then passes through the quarter wave plate for the second time, the polarization state of the laser beam is changed, the reflected S light is changed into the transmitted P light, and at this time, the reflected S light can pass through the light splitting unit 14 and then is focused on the detection center of the detector unit 14 by the focusing unit 13. The digital micromirror device 14 is used for emitting each laser beam reflected by the light splitting unit 14 in a specific diffraction order among-2, -1, 0, 1, 2 orders.

The digital micromirror device consists of a group of micromirror arrays, each micromirror can rotate +/-12 degrees along the diagonal to realize two states of switching, and the switching time of the states of the switching is microsecond. Therefore, when the micro mirror array is irradiated by a pulse laser beam with the pulse width less than 10ns in the switching state conversion process, the micro mirror array can be used as a programmable blazed grating. In the process of switching state conversion of the micro-mirror, a pulse laser beam is injected when the inclination angle of the micro-mirror is a blazed angle, the pulse laser beam can be diffracted into 5 different diffraction orders of-2 order, -1 order, 0 order, 1 order and 2 order according to requirements, the rotation angle of the micro-mirror array corresponding to each diffraction order is-10.3 degrees, -5.8 degrees, 0 degrees, +4.9 degrees and +12 degrees, and the diffraction efficiency can approach 100 percent. Each laser beam can produce five diffraction laser beam, to the utility model discloses a laser radar system, 5 transmitting element can produce 25 laser beam in timesharing.

When the number of the emission units is 1, the incidence angle of the emission units to the surface of the digital micromirror device after being reflected by the light splitting unit is 30°The incident angle is the angle between the laser beam and the perpendicular line of the reflective surface of the digital micromirror device. When the number of the emitting units is increased, the incidence angle of each laser beam needs to be adjusted within +/-2 degrees on the basis of 30 degrees. Lidar resolution may be increased with the increase of transmit units. When the number of the emitting units is 3, the incident angle of each laser beam is adjusted to 29.3 °, 30.0 ° and 30.7 °, respectively, and a resolution of 3.2 ° can be achieved within a 48 ° field angle. When the number of the emitting units is 5, the incident angle of each laser beam is adjusted to 29.2 °, 29.6 °, 30.0 °, 30.4 ° and 30.8 °, respectively, and a resolution of 2.1 ° can be achieved within a 48 ° field angle.

Fig. 2 is a schematic diagram of a lidar control system according to the present invention, which includes a microprocessor 20, a laser 21, a digital micromirror device 22, a synchronous controller 23, a timing module 24, a signal processing circuit 25, and an APD detector 26. The microprocessor controls 20 the synchronous controller 23 to drive five lasers ABCDE in a time-sharing manner, each laser generates five times of pulse laser beams in the process of one switching state conversion of the digital micromirror device, and the deflection angle of the micromirror array in the digital micromirror device corresponding to each pulse laser beam is a diffraction angle, so that each laser generates five times of high-efficiency pulse diffraction laser beams, the scanning frequency and the resolution of the laser radar can be improved along with the increase of the lasers, and the high resolution and the high scanning frequency of the laser radar are realized at the same time. The synchronous controller needs to be calibrated by experiment to meet the timing precision of the laser radar system. The switching state transition motion process of the digital micromirror device is non-linear and the non-linear error can be minimized using non-linear fitting. The timing module of the system realizes high-precision timing by using a TDC-GP22 chip, a pulse laser beam reflected by a measured object is collected by an APD detector, and a pulse electric signal generated by processing circuits such as trans-resistance amplification, voltage comparison and the like through a signal processing circuit is input to the timing module to be used as a trigger signal for finishing single-point measurement of the laser radar. The whole laser radar system has simple structure and lower cost and can simultaneously realize high resolution and high scanning frequency.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in the embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (5)

1. A high resolution lidar characterized by: the laser radar comprises a laser emission unit, a collimation unit, a light splitting unit, a digital micromirror device, a focusing unit and a detector unit, wherein the laser emission unit is used for emitting a pulse laser beam with nanosecond pulse width; the collimation unit is used for collimating the laser beam and reducing the divergence angle; the light splitting unit is used for reflecting the laser beam to the digital micromirror device and transmitting the laser echo beam to the detector unit; the digital micromirror device can be used as a diffraction grating and is used for emitting laser beams in different diffraction orders; the focusing unit is used for focusing the laser echo beam transmitted by the light splitting unit to the detector.

2. A high resolution lidar according to claim 1, wherein: if the number of the laser emission units is N, the number of the collimation units is N; each laser beam is incident on the surface of the digital micro-mirror device to generate 5 diffracted light beams in a time-sharing manner, wherein the 5 diffracted light beams are respectively-2-level, -1-level, 0-level, 1-level and 2-level diffracted light beams, and then the N lasers can generate 5N diffracted light beams in a time-sharing manner.

3. A high resolution lidar according to claim 1 or 2, wherein: the digital micromirror device is composed of a group of micromirror arrays, each micromirror rotates +/-theta along a rotating shaft of the micromirror to realize two states of switching, the switching state conversion time is microsecond, nanosecond-level pulse laser beams are used for irradiating the micromirrors during the switching state conversion process of the micromirrors, the micromirror arrays are used as programmable blazed gratings, incident laser beams are diffracted into corresponding diffraction orders among-2-level, -1-level, 0-level, 1-level and 2-level when the inclination angle of the micromirrors during the switching state conversion process is a blazed angle, and the diffraction efficiency is close to 100%.

4. A high resolution lidar according to claim 1, 2 or 3, wherein: when the number of the emission units is 1, the incidence angle of the emission units, reflected by the light splitting unit and incident to the surface of the digital micromirror device, is alpha, and the incidence angle is the included angle between a laser beam and a vertical line of a reflection surface of the digital micromirror device; when the number of the emitting units is increased, the incidence angle of each laser beam needs to be adjusted within +/-2 degrees on the basis of alpha.

5. A high resolution lidar according to claim 1, wherein: according to the high-resolution laser radar, the number N of the laser emitting units is increased, so that higher emergent beam density is realized, and the resolution of the laser radar can be improved at lower cost.

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