KR20200000284A - Multi Scanner - Google Patents

Abstract

An object of the present invention is to implement a dual scanning for scanning the laser beam in two directions inclined toward the horizontal direction and the ground, but without the need for additional mechanical device structure of the rotating reflector that can be miniaturized optical system and lidar optical system structure using the same I would like to present.
The scanning apparatus for a lidar of the present invention is composed of a multi-scanner having a double reflector for sending a laser beam in a plurality of directions, and the double reflector implements different angles with respect to a rotation axis of a rotating device such as a motor. Can be scanned at different angles.

Description

Multi Scanner

The present invention relates to an optical structure of a scanning lidar, and more particularly, to an optical system capable of implementing double scanning for scanning a laser beam in multiple directions, for example, in two directions inclined horizontally and to the ground. It relates to a multi-scanner structure provided.

The lidar is an electro-optic sensor that measures the time when the laser beam reaches the object and is reflected back to obtain the distance information of the object, and is a device capable of constructing 3D spatial information about the surrounding features. The lidar device is composed of a laser, a detector, a transmission and reception optical system, and a scanning device. A scanning device is generally an optical element positioned on a transmission / reception path of a laser beam. The scanning device is configured in such a way that a reflector is coupled to a rotating means such as a motor, so that its shape and characteristics are determined according to the optical basic structure. Therefore, the scanning method must be carefully determined in order to increase the light efficiency, miniaturization, and reliability of the lidar light fixture.

In the case of mechanical scanning lidar, the lidar structure must be designed according to whether the transmitting and receiving unit shares the optical path or is separated. In addition, in some cases, there is a need to configure a scanning device having a plurality of reflective surfaces in order to achieve the purpose of multi-scanning, or a means for actively adjusting the angle of the scanner reflective surface may be introduced.

Particularly, in the case of a vehicle lidar, a structure for securing alignment and simplifying assembly and miniaturization of a vehicle and securing operation reliability are pursued.

Korean Patent Laid-Open Publication No. 10-2018-0032709 also proposes a scanning lidar incorporating a rotating reflection mirror in a lidar optical system for miniaturization and stability. This configuration scans the beam over a wide range, but it is difficult to simultaneously detect the road plane other than the front of the vehicle.

An object of the present invention is to implement a dual scanning for scanning the laser beam in a plurality of directions, for example, two directions inclined toward the horizontal direction and the ground, but without the need for additional mechanical device structure of the rotating reflector that can be miniaturized optical system And it is to present the structure of the lidar optical system using the same.

The scanning device for a lidar of the present invention comprises a double reflector for sending a laser beam in a plurality of directions, and the double reflector implements different angles with respect to a rotation axis of a rotating device such as a motor to direct the laser beam to different angles. You can scan.

In the above, one of the two reflecting surfaces of the double reflector directs the laser beam in the horizontal direction for the purpose of detecting the front object and the other reflecting surface is in the close distance in the horizontal direction for the purpose of detecting the low height object. It is configured to have an angle for sending the laser beam in a downward direction.

In the above, since each detection distance by the reflector configured to detect the two directions is different from each other, in order to ensure the maximum area of the detection surface for the horizontal direction, the two reflecting surfaces may be formed of a rotating axis and an asymmetrical structure and centered on the rotating axis In consideration of the rotational inertia may be formed to have a different area.

In the above, by applying a double reflector can be configured as a multiple reflector to send a laser beam in more directions as needed.

In addition, in the case of introducing a means for actively adjusting the scanner reflecting surface, as a means to be proposed in the present invention to apply a method that allows the scanner structure to have the necessary hinge structure and to be able to switch to the required angle by using a magnetic force Can be.

Meanwhile, another object of the present invention is to provide a plurality of scanning structures in which multiple transmissions are implemented by separating the transmission beams in different directions and reflecting them on a scanner having a single reflective surface. In this case, a plurality of detection angles are provided, and a detector module structure in which one or more detectors for detecting them simultaneously are arranged in multiple structures and additionally a lens or a curved reflector is arranged to collect the detection light at one point.

That is, the present invention,

As a beam scanner,

A first reflective surface for traveling forward the beam emitted from the light source;

A second reflecting surface which is inclined at an angle different from the first reflecting surface to advance the beam emitted from the light source in a direction capable of scanning near distance from a path by the first reflecting surface;

A body including the first reflecting surface and the second reflecting surface and having a rotation axis connected thereto; And

It includes; a rotating shaft connected to the body,

The rotation axis is rotated to provide a multi-beam scanner, characterized in that the sensing of the far object in the front and at the same time can detect a short distance object below.

The multi-beam scanner of claim 1, further comprising one or more reflecting surfaces inclined at different angles from the first reflecting surface and the second reflecting surface to advance the beam in a direction different from the horizontal direction. do.

In the above, the inclination angle of the first reflective surface provides a multi-beam scanner, characterized in that the beam advances in the horizontal direction and is formed in a larger area than the second reflective surface.

In the above, the position of the rotation axis connected to the body of the multi-beam scanner is determined in consideration of the rotational inertia exerted according to the shape of each reflective surface, characterized in that it is set at a point asymmetrical away from the center of the body It provides a multi-beam scanner.

In addition, the present invention,

A multi-beam scanner for multiplexing and scanning the path of the beam emitted from the light source,

A reflector reflecting the beam;

A hinge structure installed on a rear surface of the reflector;

A permanent magnet installed on a rear surface of the reflector to change the inclination angle of the reflector;

An electromagnet for generating a magnetic force together with the permanent magnet to vary the inclination angle of the reflector;

A scanner rotating shaft having one side connected to the hinge structure and the other side connected to the motor;

A motor connected to the scanner axis of rotation to provide rotational power of the reflector; And

And a stage disposed on the motor, wherein the electromagnet is installed, and an opening for connecting the scanner rotational shaft and the motor is formed.

By driving the electromagnet to exert a magnetic force on the permanent magnet to move the hinge structure to change the inclination angle of the reflector,

It provides a multi-beam scanner, characterized in that for driving the motor to vary the azimuth angle of the reflector by the rotation of the scanner axis of rotation to scan the beam multiple by the reflecting surface operation of the reflector.

In the above, the permanent magnet provides a multi-beam scanner, characterized in that configured in a curved shape.

In addition, the present invention,

A multi-beam scanner for multiplexing and scanning the path of the beam emitted from the light source,

A beam splitter for reflecting a portion of the beam emitted from the light source at the first reflecting surface, transmitting the remaining beam, and reflecting at the first reflecting surface;

A reflector for reflecting the beams reflected by the beam splitter in a dual path and advancing the beams forward; And

It includes a driving unit for rotating the reflector; provides a multi-beam scanner, characterized in that for scanning the beam transmitted from one light source in a multi-path.

A light receiving module in which a beam propagated from a reflective surface of the multi-beam scanner is disposed on a path of a beam reflected by an object,

A beam focusing optical system for focusing the beam;

A plurality of detectors for receiving beams focused by the beam focusing optical system;

And a light path guiding optical system for guiding the paths of the beams to the detectors so that the beams are focused by the optical system, and the beams focused on different paths can be received by the detector, respectively. To provide.

The beam scanner and the light receiving module of the present invention can be applied to a lidar, and according to such a lidar, the optical system and the lidar including the same can be miniaturized without requiring additional apparatus and machinery while implementing double scanning or multiple scanning. At the same time, it can detect near distance and at the same time.

Another multiple scanning structure of the present invention has a plurality of detection angles to more accurately detect the surrounding environment.

In addition, when the means for actively adjusting the scanner reflecting surface is introduced, it is not necessary to divide the scanner reflecting surface, so that the light receiving area by the scanner reflecting surface can be maximized, resulting in a further miniaturization of the system. In other words, even in the case of actively adjusting the scanner reflecting surface, the present invention suggests a structure that can be simply implemented while minimizing additional mechanisms, which is also suitable for a small low-cost multi-scanning lidar structure.

In addition, the lidar of the present invention has a small number of parts, the alignment can be stabilized, and the assembly to the vehicle body is relatively easy, thereby providing market competitiveness.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic diagram illustrating the range of scanning when a dual scanner lidar is mounted in the present invention.
2 is a schematic diagram of a dual scanner;
3 is a schematic diagram of an asymmetric dual scanner.
4 is a block diagram showing a lidar configuration including a dual scanner.
5 is a perspective view of the dual scanner;
Figure 6 is a cross-sectional view showing a scanner structure having a hinge structure and the scanner structure and the means for adjusting the angle.
7 is a schematic diagram illustrating a method of adjusting the angle of the scanner structure of FIG. 6.
8 is a plan view showing a semi-circular permanent magnet shape.
9 is a conceptual diagram of a transmission beam splitter;
10 is a block diagram of a light receiving module including a dual structure detector.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a schematic diagram illustrating the range of scanning when a dual scanner lidar is mounted in the present invention. By including a double scanner in one lidar, as shown in FIG. In other words, it shows a lidar mounting that can monitor a short distance (including the floor of a road) within a few meters almost simultaneously while monitoring a long distance of about 100m in front. Such lidar includes a dual scanner as shown in FIG.

That is, the double scanner 100 includes two reflective surfaces 110 and 120 having different inclination angles. The first reflective surface 110 and the second reflective surface 120, which are mirrors around the rotation axis 130, are disposed to face each other. The inclination angle formed with the vertical plane of the first reflective surface 110 is 45 degrees, and the laser beam traverses the path in the horizontal direction by the first reflective surface 110 to serve as a front monitoring, and the vertical surface of the second reflective surface 120 is The angle of inclination with is less than 45 degrees and steeper. Accordingly, the laser beam travels downward by the second reflecting surface 120 to monitor small obstacles such as pedestrians or speed bumps and curbs at a distance closer to the vehicle. The dual scanner 100 is rotated by connecting a rotating shaft to a driving means such as a motor to sufficiently secure the left and right ranges of forward and downward sensing.

4 is a block diagram showing a lidar configuration including the dual scanner of FIG.

The light source 10 includes a laser diode (LD), and adjusts the path of the beam emitted from the light source 10 through the reflector 20 to face the dual scanner 100. The first reflecting surface 110 and the second reflecting surface 120 of the double scanner 100 alternately reflect the laser beam by the motor at the lower end thereof to proceed forward and downward, and below the object in front of and downward. The reflected beam reflected from the object is incident on the first reflecting surface 110 or the second reflecting surface 120 of the double scanner and reflected to the detector 40. It is preferable to arrange the light receiving lens 30 for converging the beams in front of the detector 40. The detector 40 is disposed with a light receiving element. Further, an optical element (for example, a lens) for collimation may be disposed between the light source 10 and the reflector 20.

The difference in the inclined plane inclination of the dual scanner naturally causes the area of the first reflecting plane 110 to be configured to be larger than the area of the second reflecting plane, so that the wide reflecting plane for the horizontal beam that monitors a longer distance is Increases the probability of detection to increase the reliability.

The lidar configuration as described above has a small number of parts, but can monitor both the front and the bottom and the long distance and short distance, the alignment of the dual scanner 100 is easy, stable, and excellent in reliability.

5 is a perspective view showing the actual shape of the dual scanner of FIG. For better understanding, the dual perspective scanner shows the geometry coupled to the rotating motor. Reflective surfaces are multiplely supported from the inside for stability of double scanner operation.

In order to further widen the area of the first reflective surface 100 of the double scanner 100, the extension surface 115 further extending above the interface with the second reflective surface 120 is shown. That is, the two reflectors can be designed to have different areas so that the reflector for the horizontal direction detection of the two reflectors can have a different area, in which case the two reflectors with respect to the rotation axis in consideration of the center of the rotational inertia force Is placed asymmetrically.

The double scanner 100 is basically formed on both sides with a reflective surface based on a columnar body, and gives a reflective performance by a reflective coating. The inclination angle of both sides is formed differently, and has a hole for assembly at the bottom. As described above, since the double scanner 100 has a two-shaped reflective surface based on a body, the operation is very stable and easy to align compared to an optical system composed of a general planar mirror.

In order to enlarge the area of the first reflecting surface 110, the extension surface 115 and the body portion extending upwardly on both sides of the first reflecting surface 110 do not increase the overall volume and weight of the double scanner. It also increases the reliability of the lidar sensor.

3 is a schematic diagram showing a reflection result of a laser beam by a dual scanner.

As described above, since the area of the first reflecting surface 110 and the area of the second reflecting surface 120 are larger, the two reflecting surfaces are asymmetrically disposed with respect to the rotation axis 130 in consideration of the center of the rotational inertia force. That is, the rotation shaft 130 is positioned away from the border point of the first reflecting surface 110 and the second reflecting surface 120 toward the first reflecting surface 110. Transparency is shown in a more understandable position and shape of the rotation axis.

In the above, it is advantageous that the first reflecting surface and the second reflecting surface can be further reduced in volume by adjoining each other. However, it may be formed at a distance by slightly deforming it without adjoining each other, in which case the position of the rotation axis is set in consideration of the center of the rotational inertia force.

On the other hand, the dual beam scanner can be transformed into a multi-scanner by forming a mirror surface in more than one side as needed. For example, a multi-scanner having a three-mirror can be configured by further configuring a third reflecting surface which sends the beam slightly upward or downwardly at a different angle from the second reflecting surface beside the first reflecting surface for forward illumination. In addition, it can be extended to be configured as a slope mirror.

In this way, one lidar having a double scanner capable of simultaneously monitoring the long distance ahead and the short distance below can be realized.

Meanwhile, the multi-scanner 200 may be configured as a single reflective surface, but means for actively adjusting the angle of the reflective surface may be provided. That is, to adjust the angle of the reflective surface, an appropriate hinge structure 220 may be installed on the rear surface of the reflective surface, and magnetic force may be used as a means for changing the angle of the reflective surface (see FIG. 6). The hinge structure 220 is connected to the scanner axis of rotation 230, the scanner axis of rotation can be rotated by the motor 250 so that the entire reflection surface can be rotated 360 degrees along the azimuth. The stage 240 placed on the rotating shaft of the motor serves as a stage of the entire scanner module, and has an opening for connecting the scanner rotating shaft and the motor. The inclination angle of the reflective surface (the altitude of the upper surface of the reflective surface) is changed by the hinge operation of the hinge structure. It is arranged to control the inclination angle of the reflecting surface by magnetic force.

In the above, since the scanner 200 rotates, the permanent magnet attached to the scanner mechanism is preferably formed in a curved shape such as a semicircle (see FIG. 8), and the electromagnet module for generating a magnetic force does not rotate the motor fixture. Install in-stage. When changing the inclination angle, the reflector can be pulled out or pushed out by the magnetic force applied to the electromagnet (see Fig. 7), and the permanent magnet structure installed in a semicircle while the scanner rotates can exert a constant force, resulting in the The angle of reflection can be freely controlled as desired for both altitude and azimuth.

9 and 10 show the transmission beam separation and the dual detector structure. A beam splitting device is manufactured to separate the transmission beam, and the reflectance of the partial reflecting surface is adjusted according to the detection distance, so that the output of the transmission beam is properly distributed. In FIG. 9, the transmitted beam emitted from the light source LD is reflected by the front side of the beam splitter having an inclination angle to change its path toward one point (first point) of the scanner reflector and the other output passes through the front side of the beam splitter. It is reflected from the reflective surface on the back and proceeds to the other place (second point) of the scanner reflector. Accordingly, the transmission beam emitted from one light source is directed toward the front of the scanner, but travels differently from each other, thereby scanning a wider front area with one scanner. In the case of FIG. 9, it is possible to simultaneously scan the front that is horizontal from the scanner and the front that is lower than the horizontal, that is, the far distance of the front of the scanner and the near distance of the front of the scanner.

In addition, the light receiving module for receiving the beams reflected by the target object by the beam scanned by the scanner may be configured as shown in FIG.

That is, one or more detectors for detecting light returning to each target and returning to multiple channels need to be provided. The light returned from the optically different detection directions travels in the direction of the rotational direction with respect to the center point according to the rotation of the scanner except the optical axis center direction, so that a corresponding circular or semicircular detector structure may be considered. Since the configuration is technically difficult to implement practically, it is necessary to arrange a convex lens or a curved (annular in the case of FIG. 10) reflector to send a rotating reception light to one place. As a result, the detector may be arranged in a multi-structure or a dual structure and may be configured as shown in FIG. 10.

That is, an optical system such as a reflector or a lens, which may include reflected light incident on different paths by the beam focusing lens and may be sent to the detector, may be arranged so that the beam is received at the detector corresponding to each path. In the above, the detectors are illustrated as two detectors, but more can be arranged.

Such a scanner configuration is easy to install with a small number of parts while increasing the scanning range.

The rights of the present invention are not limited to the embodiments described above, but are defined by the claims, and those skilled in the art can make various modifications and adaptations within the scope of the claims. It is self-evident.

Light source 10, reflector 20, light receiving lens 30, detector 40, double scanner 100, first reflecting surface 110, second reflecting surface 120, axis of rotation 130, extending surface 115, permanent magnet 205, electromagnet 210, hinge structure 220, scanner axis of rotation 230, stage 240, motor 250

Claims (8)

As a beam scanner,
A first reflective surface for traveling forward the beam emitted from the light source;
A second reflecting surface that is inclined at a different angle from the first reflecting surface to advance the beam emitted from the light source in a direction capable of scanning near distance from a path by the first reflecting surface;
A body including the first reflecting surface and the second reflecting surface and having a rotation axis connected thereto; And
It includes; a rotating shaft connected to the body,
The rotating beam is rotated to detect a far object in front of the multi-beam scanner, it characterized in that it can detect a short distance object below. The multi-beam scanner of claim 1, further comprising at least one reflecting surface inclined at a different angle from the first reflecting surface and the second reflecting surface to propagate the beam in a direction different from the horizontal direction. . The multi-beam scanner according to claim 1, wherein the inclination angle of the first reflecting surface advances the beam in a horizontal direction and is formed with a larger area than the second reflecting surface. According to any one of claims 1 to 3, wherein the position of the rotation axis connected to the body of the multi-beam scanner is determined in consideration of the rotational inertia exerted according to the shape of each reflecting surface, A multi-beam scanner, characterized in that it is set at an asymmetric point. A multi-beam scanner for multiplexing and scanning the path of the beam emitted from the light source,
A reflector reflecting the beam;
A hinge structure installed on a rear surface of the reflector;
A permanent magnet installed on a rear surface of the reflector to change the inclination angle of the reflector;
An electromagnet for generating a magnetic force together with the permanent magnet to vary the inclination angle of the reflector;
A scanner rotating shaft having one side connected to the hinge structure and the other side connected to the motor;
A motor connected to the scanner axis of rotation to provide rotational power of the reflector; And
And a stage disposed on the motor, wherein the electromagnet is installed, and an opening for connecting the scanner rotational shaft and the motor is formed.
By driving the electromagnet to exert a magnetic force on the permanent magnet to move the hinge structure to change the inclination angle of the reflector,
And multi-scanning the beam by the reflecting surface motion of the reflector by varying the azimuth angle of the reflector by driving the motor to rotate the scanner axis of rotation. The multi-beam scanner according to claim 5, wherein the permanent magnet is curved. A multi-beam scanner for multiplexing and scanning the path of the beam emitted from the light source,
A beam splitter for reflecting a portion of the beam emitted from the light source at the first reflecting surface, transmitting the remaining beam, and reflecting at the first reflecting surface;
A reflector for reflecting the beams reflected by the beam splitter in a dual path and advancing the beams forward; And
And a driving unit to rotate the reflector, wherein the multi-beam scanner scans the beam transmitted from one light source as a multi-path. A light receiving module in which a beam propagated from the reflective surface of the multi-beam scanner of claim 1, 5 or 7 is disposed on a path of a beam reflected by an object.
A beam focusing optical system for focusing the beam;
A plurality of detectors for receiving beams focused by the beam focusing optical system;
And a light path guiding optical system for guiding the paths of the beams to the detectors so that the beams are focused by the optical system, and the beams focused on different paths can be received by the detector, respectively. .

Images