KR102041133B1 - A thirty two-channel ridar - Google Patents

Abstract

The present invention simplifies the optical path by using a reflective optical system having a simple structure, and fires a parallel light source of 32 lines of different channels in the form of pulses to acquire the reflected beams with four light receiving sensors, so that the object can be accurately identified. The channel-type lidar, the 32-channel type lidar according to the present invention, the first laser diode 110, the first parabolic reflector 120, the first arm line beam switching unit 130, the first light receiving unit ( 140, the first light receiving sensor 101, the second laser diode 150, the second parabolic reflector 160, the second arm line beam switching unit 170, the second light receiving unit 180, and the second light receiving sensor The unit 106, the first rotation driver 190, the third laser diode, the third parabolic reflector, the third arm line beam switching unit, the third light receiving unit, the third light receiving sensor unit, the fourth laser diode, and the fourth parabolic reflector And a fourth arm line beam switching unit, a fourth light receiving unit, a fourth light receiving sensor unit, and a second rotation driving unit.

Description

32-channel rider {A THIRTY TWO-CHANNEL RIDAR}

The present invention relates to a 32-channel lidar, and more specifically, to simplify the optical path by using a reflective optical system with a simple structure, four beams reflected by firing parallel light sources of 32 lines of different channels in the form of pulses. The present invention relates to a 32-channel lidar capable of accurately identifying an object obtained by a light receiving sensor.

In general, in order to transmit the beam far, the diverging beam must be converted into a parallel light source, and the existing parallel light source implementing optical system constituting the lidar is mostly a refractive optical system (lens using method). The smaller the curvature of the lens, the larger the spherical aberration, and the farther the transmission distance, the greater the spread of the beam, making it unsuitable for long distance sensing light sources.

In addition, when the lens aperture is increased to increase the amount of incident light, spherical aberration occurs at the edge of the lens, so that even if a large number of light beams reach the lens, the light receiving sensor may not be focused, multifocal, or has a large depth of focus. There is a problem of low efficiency.

The technical problem to be solved by the present invention is to simplify the optical path by using a reflection optical system of a simple structure, while firing the beam reflected by four parallel light sources of 32 lines of different channels in the form of pulses to obtain an object It is to provide a 32-channel type lidar that can be accurately identified.

The 32-channel lidar according to the present invention for solving the above technical problem, the first laser diode for emitting a fusiform beam to the lower side; A first parabolic reflector installed below the first laser diode and configured to convert a beam emitted by the first laser diode into parallel light and irradiate it forward; A first arm line beam switching unit rotatably installed in front of the first parabolic reflector and converting parallel light irradiated by the first parabolic reflector into an eight-line laser beam while rotating at a constant speed; Is installed below the first arm line beam switching unit, the beam reflected by the object in front of the laser beam irradiated by the first arm line beam switching unit for each reflection surface of the first arm line beam switching unit A first light receiver to receive light; A first light receiving sensor unit installed in parallel with the first laser diode and sensing a distance to the object by using a beam transmitted by the first light receiving unit; A second laser diode disposed below the first laser diode and emitting a fusiform beam upward; A second parabolic reflector disposed above the second laser diode and configured to convert a beam emitted by the second laser diode into parallel light and irradiate it forward; A second arm line beam switching unit rotatably installed in front of the second parabolic reflector and converting parallel light irradiated by the second parabolic reflector into an eight-line laser beam while rotating at a constant speed; Is installed below the second arm line beam switching unit, the beam reflected by an object in front of the laser beam irradiated by the second arm line beam switching unit for each reflective surface of the second arm line beam switching unit A second light receiver to receive light; A second light receiving sensor unit installed in parallel with the second laser diode and sensing a distance to the object by using a beam transmitted by the second light receiving unit; A first rotation driver installed between the first and second arm line beam switching units and simultaneously rotating the first arm line beam switching unit and the second arm line beam switching unit; A third laser diode installed in a direction facing the first laser diode and emitting a fusiform beam downward; A third parabolic reflector installed below the third laser diode and converting a beam emitted by the third laser diode into parallel light to irradiate the light forward; A third arm line beam switching unit rotatably installed in front of the third parabolic reflector and converting parallel light irradiated by the third parabolic reflector into an eight-line laser beam while rotating at a constant speed; Is installed below the third arm line beam switching unit, the beam reflected by an object in front of the laser beam irradiated by the third arm line beam switching unit for each reflective surface of the third arm line beam switching unit A third light receiver configured to receive light; A third light receiving sensor unit installed in parallel with the third laser diode and detecting a distance to the object by using a beam transmitted by the third light receiving unit; A fourth laser diode disposed below the third laser diode and emitting a fusiform beam upward; A fourth parabolic reflector disposed above the fourth laser diode and configured to convert a beam emitted by the fourth laser diode into parallel light and irradiate it forward; A fourth arm line beam switching unit rotatably installed in front of the fourth parabolic reflector and converting parallel light irradiated by the fourth parabolic reflector into an eight-line laser beam while rotating at a constant speed; It is installed below the fourth arm line beam switching unit, the beam reflected by an object existing in front of the laser beam irradiated by the fourth arm line beam switching unit for each reflective surface of the fourth arm line beam switching unit A fourth light receiver configured to receive light; A fourth light receiving sensor unit installed in parallel with the fourth laser diode and detecting a distance to the object by using a beam transmitted by the fourth light receiving unit; And a second rotation driver installed between the third and fourth eighth line beam switching units and simultaneously rotating the third eighth line beam switching unit and the fourth eighth line beam switching unit.

In the 32-channel lidar according to the present invention, the first and third laser diodes and the second and fourth laser diodes are preferably installed to emit beams in a direction facing each other.

In addition, in the present invention, the first arm line beam switching unit is provided in front of the first parabolic reflector such that eight reflecting surfaces form a regular octagon, each reflecting surface is installed at a different angle by the first parabolic reflector A first eight surface reflector for converting the irradiated parallel light into an eight-line laser beam; It is installed penetrating through the center of the first eight-sided reflector portion, and rotates together with the first eight-sided reflector portion by the rotational power of the rotary drive unit to sequentially receive parallel light irradiated by the first parabolic reflector with the eight reflective surfaces. It is preferable to include; a first rotating shaft that reflects.

In addition, in the present invention, the first light receiving unit is provided under the first eight reflecting mirror portion so that the same number of reflecting surfaces as the first eight reflecting mirror portion to form a regular octagon, and irradiated by each reflecting surface of the first eight reflecting mirror portion A first light receiving arm reflector for receiving a laser beam reflected by an object in front of the laser beam; A second rotating shaft installed through the center of the first light receiving reflecting mirror portion and coupled with the first rotating shaft to rotate together with the first rotating shaft to rotate the eight reflecting surfaces in the same manner as the reflecting surface of the eight reflecting mirror portion; ; And a first light receiving lens disposed in front of the first light receiving arm surface reflector and configured to collect a laser beam reflected by each of the reflecting surfaces of the first light receiving arm surface reflector.

In addition, in the present invention, the first light receiving sensor unit may include: a first light receiving sensor installed side by side with the first laser diode at the first laser diode side; And a first light receiving beam reflecting unit disposed in front of the first light receiving lens and reflecting a beam collected by the first light receiving lens toward the first light receiving sensor.

According to the 32-channel lidar according to the present invention, a simple optical reflection system is used to simplify the optical path and increase efficiency, while obtaining a reflected beam by emitting thousands of times a parallel light source per second to identify an object. It is also very high and extends the detection angle up to 360 degrees depending on the optics configuration.

In addition, the 32-channel lidar according to the present invention is provided with four light-receiving sensors, but also capable of sensing the 32-channel laser beam irradiated in different directions, thus making it easy to manufacture and having a very low manufacturing cost.

1 is a perspective view showing the structure of a 32-channel lidar according to an embodiment of the present invention.
2 is a plan view showing the structure of a 32-channel lidar according to an embodiment of the present invention.
3 is a side view illustrating a structure and an optical path of a 32 channel lidar according to an embodiment of the present invention.

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

The 32-channel lidar 1 according to the present embodiment includes a first laser diode 110, a first parabolic reflector 120, a first arm line beam switching unit 130, a first light receiving unit 140, and a first The light receiving sensor unit 101, the second laser diode 150, the second parabolic reflector 160, the second arm line beam switching unit 170, the second light receiving unit 180, and the second light receiving sensor unit 106. , A first rotary driver 190, a third laser diode (not shown), a third parabolic reflector (not shown), a third arm line beam shifter (not shown), and a third light receiver (not shown) Not shown), a third light receiving sensor (not shown), a fourth laser diode (not shown), a fourth parabolic reflector (not shown), and a fourth arm line beam switching unit (not shown) May be configured to include a fourth light receiving unit (not shown), a fourth light receiving sensor unit (not shown), and a second rotation driver (not shown).

First, as shown in FIGS. 1 to 3, the first laser diode 110 is a component that emits a fusiform beam downward in a pulse form. The first laser diode 110 may be replaced with another component capable of oscillating a laser having excellent straightness. In the present embodiment, the first laser diode 110 may use a laser diode that emits a laser beam having a wavelength of 905 nm, which is an invisible light region.

Next, as illustrated in FIGS. 1 and 2, the first parabolic reflector 120 is installed below the first laser diode 120, and parallels beams emitted by the first laser diode 110. It is a component that converts light and irradiates it forward. In this embodiment, the reflective surface of the parabolic reflector 120 has a parabolic reflective surface suitable for this, and preferably made of a material or mirror treatment or a thin film coating having a reflectance close to 100%.

Next, as shown in FIGS. 1 and 2, the first arm line beam switching unit 130 is installed in front of the first parabolic reflector 120, and the first parabolic reflector 120 is disposed on the first parabolic reflector 120. It converts the parallel light irradiated into the 8-line laser beam. That is, the laser beam incident on one line by the first arm line beam switching unit 130 is divided into laser beams having a plurality of lines, thereby enabling the function of a 32-channel lidar.

To this end, in the present exemplary embodiment, the first arm line beam switching unit 130 may be configured as a first arm surface reflector 132 and a first rotation shaft 134 as shown in FIGS. 1 and 2. . First, the first arm surface reflector 132 has a structure in which eight reflective surfaces are formed to have a regular octagon. In this case, the eight reflective surfaces are installed to have different angles with respect to the vertical surface, and the eight reflective surfaces installed to have different angles reflect the laser beams incident in the same direction in different directions. In particular, when the eight reflective surfaces are rotated by the first rotation shaft 134, the eight reflective surfaces are irradiated in a predetermined direction to scan the laser beam reflected and irradiated by the rotation of the reflective surface.

In this embodiment, since eight reflective surfaces are provided, eight reflective surfaces are installed to form a regular octagon, as shown in FIG. 3, and each reflective surface 132 is 0, 1, 2, 3, It may be installed in an inclined state to have an angle of 4, 5, 6, 7 degrees. Eight reflective surfaces installed to have different angles rotate and reflect one laser beam into eight line beams in the form of drawing eight lines while rotating.

Next, the first rotating shaft 134 is installed through the central axis of the first arm surface reflector 132 and rotates together with the first arm surface reflector 132 so that the eight reflecting surfaces are the first parabola. The first arm surface reflector 132 is rotated to sequentially reflect parallel light emitted by the reflector 120. That is, all of the reflecting surfaces installed on the first arm surface reflector 132 by the first rotation shaft 134 sequentially irradiate the laser beam irradiated by the first parabolic reflector 120 by its installation angle. The first arm surface reflector 132 is rotated at a constant rotational speed so as to irradiate different arm line beams.

Next, as shown in FIGS. 1 and 2, the first light receiving unit 140 is installed below the first arm line beam switching unit 130 and irradiated by the first arm line beam switching unit 130. It is a component that receives a beam reflected by an object existing in front of the laser beam. That is, the first light receiving unit 140 splits the beams reflected by the object in front of the laser beams, which are divided into eight line beams by the first eight-surface reflector 132, and receives the light by dividing each line beam. It is a component.

To this end, in the present exemplary embodiment, the first light receiving unit 140 is specifically illustrated in FIGS. 1 and 2, and the first light receiving slope reflector 141, the second rotating shaft (not shown), and the first light receiving unit are illustrated. It can be configured to include a lens 143.

First, as shown in FIG. 1, the first light receiving arm reflector 141 has the same number of reflecting surfaces as the first armar reflector 132 at the lower side of the first arm reflector 132. It is installed to form an octagon, and receives a laser beam reflected by an object in front of the laser beam irradiated by each reflecting surface of the first arm surface reflector 132 and reflects toward the first light receiving lens 143. Component.

In this case, the number of reflecting surfaces provided on the first light receiving reflector 141 is not only equal to the number of reflecting surfaces of the first reflecting reflector 132, but also the installation position thereof is completely the same. Therefore, the light receiving reflection surface installed at the same position receives the laser beam emitted by the light reflection reflection surface installed at the same position, and is separately detected.

Next, the second axis of rotation is installed through the center of the first light receiving arm surface reflector 141, and rotates together with the first light receiving arm surface reflector 141, such that the eight reflecting surfaces are formed by the second rotation axis. The first light receiving arm surface reflector 141 is rotated to be rotated in the same manner as the reflecting surface of the first arm reflector 132. That is, the second rotation shaft may be substantially connected to the first rotation shaft and integrally formed or replaced by the first rotation shaft.

Next, as illustrated in FIGS. 1 and 2, the first light receiving lens 143 is installed in front of the first light receiving reflector 141 for light receiving, and the first light receiving reflector 141 of the first light receiving reflector 141. The laser beam reflected by each reflective surface is a component that focuses the light receiving sensor 144. Accordingly, the first light receiving lens 143 has an optical structure capable of receiving and condensing all the laser beams incident from the first light receiving arm surface reflector 141. For example, as illustrated in FIGS. 1 and 2. Likewise, it may have a rectangular lens shape.

Next, the light receiving sensor unit 101 is installed in parallel with the laser diode 110, and is a component that senses the distance to the object by using a beam transmitted by the light receiving unit 140. That is, the light receiving sensor 101 calculates the distance to the front object by analyzing a time difference between the beam divergence point by the laser diode 110 and the light reception point by the light reception sensor 102. To this end, in the present embodiment, the light receiving sensor unit 101 may specifically include a light receiving sensor 102 and a light receiving beam reflecting unit 103. First, as shown in FIGS. 1 and 3, the light receiving sensor 102 is installed adjacent to the laser diode 110 and is installed side by side in the same direction as the laser diode 110. The light receiving sensor 102 may employ a general light receiving sensor.

The light receiving beam reflecting unit 103 is installed in front of the light receiving lens 143 to reflect the beam incident from the light receiving lens 143 toward the light receiving sensor 102. In this embodiment, the light receiving sensor 102 is installed in the vicinity of the laser diode to compact the equipment, and the light path of the light receiving beam is changed by using the light receiving beam reflector 103.

Meanwhile, in the present exemplary embodiment, the second laser diode 150, the second parabolic reflector 160, the second arm line beam switching unit 170, the second light receiving unit 180, and the second light receiving sensor unit 106 are illustrated in FIG. As shown in 1 to 3, the first laser diode 110, the first parabolic reflector 120, the first parline beam switching unit 130, the first light receiving unit 140, and the first light receiving sensor unit ( 101) is installed in the vertical symmetry, since the configuration and operation is substantially the same, repeated description thereof will be omitted.

Next, the rotation driving unit 190 is installed between the first and second arm line beam switching units 130 and 170 and is a component for rotating both at the same time. Therefore, the rotation driving unit 190 may be formed of a general motor, and is connected to the first, second, third and fourth rotation shafts to rotate all of them at the same speed.

Thus, the first arm line beam switching unit 130 disposed above and the second arm line beam switching unit 170 disposed below by the first rotation driving unit 190 are rotated simultaneously, so that the 16-channel laser is overall. The beam is irradiated to complete the 16-channel lidar.

Meanwhile, in the 32-channel lidar 1 according to the present exemplary embodiment, the first and second eighth-line beam switching units 130 and 170 may be arranged side by side with the first and second eighth-line beam switching units. An in-beam switching unit (not shown) is provided. And third and fourth laser diodes (not shown in the figure) and third and fourth parabolic reflectors (not shown in the figure) that irradiate the beams to the third and fourth eight-beam beam switching units. 2, the same function as the two-armed beam switching unit 130 or 170. Of course, the third and fourth light receiving units (not shown in the drawing) and the third and fourth light receiving sensors (not shown in the drawing) also include the first and second light receiving units 140 and 180 and the first and second light receiving sensor units 101 and 106. And perform substantially the same function.

Therefore, the 16-channel laser beam switching unit disposed at the upper side and the fourth arm-line beam switching unit disposed at the upper side by one second rotation driving unit (not shown in the drawing) are rotated at the same time, thereby irradiating 16 laser beams as a whole. The 16-channel lidar is completed, and the 32-channel lidar is finally completed by combining with the 16 channels completed by the first and second arm-line beam switching units 130 and 170.

1: 32-channel lidar according to an embodiment of the present invention
110: first laser diode 120: first parabolic reflector
130: first arm line beam switching unit 140: first light receiving unit
150: second laser diode 160: second parabolic reflector
170: second arm line beam switching unit 180: second light receiving unit
101: first light receiving sensor unit 106: second light receiving sensor unit
190: first rotational drive

Claims (5)

A first laser diode emitting a fusiform beam downward;
A first parabolic reflector installed below the first laser diode and configured to convert a beam emitted by the first laser diode into parallel light and irradiate it forward;
A first arm line beam switching unit rotatably installed in front of the first parabolic reflector and converting parallel light irradiated by the first parabolic reflector into an eight-line laser beam while rotating at a constant speed;
Is installed below the first arm line beam switching unit, the beam reflected by the object in front of the laser beam irradiated by the first arm line beam switching unit for each reflection surface of the first arm line beam switching unit A first light receiver to receive light;
A first light receiving sensor unit installed in parallel with the first laser diode and sensing a distance to the object by using a beam transmitted by the first light receiving unit;
A second laser diode disposed below the first laser diode and emitting a fusiform beam upward;
A second parabolic reflector disposed above the second laser diode and configured to convert a beam emitted by the second laser diode into parallel light and irradiate it forward;
A second arm line beam switching unit rotatably installed in front of the second parabolic reflector and converting parallel light irradiated by the second parabolic reflector into an eight-line laser beam while rotating at a constant speed;
Is installed below the second arm line beam switching unit, the beam reflected by an object in front of the laser beam irradiated by the second arm line beam switching unit for each reflective surface of the second arm line beam switching unit A second light receiver to receive light;
A second light receiving sensor unit installed in parallel with the second laser diode and sensing a distance to the object by using a beam transmitted by the second light receiving unit;
A first rotation driver installed between the first and second arm line beam switching units and simultaneously rotating the first arm line beam switching unit and the second arm line beam switching unit;
A third laser diode installed in a direction facing the first laser diode and emitting a fusiform beam downward;
A third parabolic reflector installed below the third laser diode and converting a beam emitted by the third laser diode into parallel light to irradiate the light forward;
A third arm line beam switching unit rotatably installed in front of the third parabolic reflector and converting parallel light irradiated by the third parabolic reflector into an eight-line laser beam while rotating at a constant speed;
Is installed below the third arm line beam switching unit, the beam reflected by an object in front of the laser beam irradiated by the third arm line beam switching unit for each reflective surface of the third arm line beam switching unit A third light receiver configured to receive light;
A third light receiving sensor unit installed in parallel with the third laser diode and detecting a distance to the object by using a beam transmitted by the third light receiving unit;
A fourth laser diode disposed below the third laser diode and emitting a fusiform beam upward;
A fourth parabolic reflector disposed above the fourth laser diode and configured to convert a beam emitted by the fourth laser diode into parallel light and irradiate it forward;
A fourth arm line beam switching unit rotatably installed in front of the fourth parabolic reflector and converting parallel light irradiated by the fourth parabolic reflector into an eight-line laser beam while rotating at a constant speed;
The fourth arm line beam switching unit is installed below the fourth arm line beam switching unit, the beam reflected by the object existing in front of the laser beam irradiated by the fourth arm line beam switching unit for each reflective surface A fourth light receiving unit for receiving light;
A fourth light receiving sensor unit installed in parallel with the fourth laser diode and detecting a distance to the object by using a beam transmitted by the fourth light receiving unit;
And a second rotation driver installed between the third and fourth eighth-line beam switching units and simultaneously rotating the third eighth-line beam switching unit and the fourth eighth-line beam switching unit. The method of claim 1,
The first and third laser diodes and the second and fourth laser diodes are 32 channel type lasers, which are installed to emit beams in a direction facing each other. The method of claim 1, wherein the first arm line beam switching unit,
Eight reflective surfaces are formed in an octagonal shape in front of the first parabolic reflector, and each reflective surface is installed at different angles to convert parallel light emitted by the first parabolic reflector into an eight-line laser beam. 1 octahedral reflector;
It is installed penetrating through the center of the first eight-sided reflector portion, and rotates together with the first eight-sided reflector portion by the rotational power of the rotary drive unit to sequentially receive parallel light irradiated by the first parabolic reflector with the eight reflective surfaces. It is a 32-channel li characterized in that it includes; a first rotation axis reflecting to. The method of claim 3, wherein the first light receiving unit,
The same number of reflecting surfaces as the first eight-surface reflector are formed in an octagonal shape on the lower side of the first eight-surface reflector, and reflected by an object in front of the laser beam irradiated by each reflecting surface of the first eight-face reflector. A first light receiving arm reflector for receiving a laser beam;
A second rotating shaft installed through the center of the first light receiving reflecting mirror portion and coupled with the first rotating shaft to rotate together with the first rotating shaft to rotate the eight reflecting surfaces in the same manner as the reflecting surface of the eight reflecting mirror portion; ;
And a first light receiving lens installed in front of the first light receiving arm surface reflector and configured to focus a laser beam reflected by each reflecting surface of the first light receiving arm surface reflector. . The method of claim 4, wherein the first light receiving sensor unit,
A first light receiving sensor disposed at a side of the first laser diode in parallel with the first laser diode;
And a first light receiving beam reflector disposed in front of the first light receiving lens and reflecting a beam collected by the first light receiving lens toward the first light receiving sensor.

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