阅读说明：本技术 用于扫描空间角度的方法和设备 (Method and apparatus for scanning spatial angles ) 是由 S·博加特舍尔 A·霍莱切克 R·施尼策尔 M·拜尔 R·哈斯 于 2018-05-22 设计创作，主要内容包括：公开了一种用于借助至少两个电磁射束扫描空间角度的方法,其中,产生至少一个电磁射束,接着通过能旋转的反射镜将其沿着水平角度和/或沿着竖直角度转向,将空间角度借助所述至少一个电磁射束扫描和当在一对象上反射之后将至少一个被反射的电磁射束通过可与反射镜同步地沿着水平角度旋转的接收光具接收。此外公开了一种用于执行该方法的激光雷达设备。(A method for scanning a spatial angle by means of at least two electromagnetic beams is disclosed, wherein at least one electromagnetic beam is generated, which is then deflected by a rotatable mirror along a horizontal angle and/or along a vertical angle, the spatial angle is scanned by means of the at least one electromagnetic beam and, after reflection on an object, at least one reflected electromagnetic beam is received by a receiving light fixture which can be rotated along the horizontal angle synchronously with the mirror. A lidar device for carrying out the method is also disclosed.)

1. A method for scanning a spatial angle by means of at least one electromagnetic beam (4, 12) has the following steps;

-generating at least one electromagnetic beam (4),

-steering the at least one electromagnetic beam (4) by means of a rotatable or pivotable mirror (6) along a horizontal angle and/or along a vertical angle,

-scanning the spatial angle by means of the at least one electromagnetic beam (4, 12),

-receiving at least one reflected electromagnetic beam (16) by means of a receiving optical means (18) which can be rotated along said horizontal angle in synchronism with said mirror (6),

it is characterized in that the preparation method is characterized in that,

the scanning takes place by means of at least two electromagnetic beams (4, 12).

2. Method according to claim 1, wherein the at least two electromagnetic beams (4) are generated by at least two beam sources (2) angularly staggered.

3. Method according to claim 1, wherein at least one electromagnetic beam (4) is generated by at least one beam source (2) and the at least one electromagnetic beam (4) is split into at least two electromagnetic beams (12) by a beam splitter (8) followed by the rotatable mirror (6).

4. Method according to one of claims 1 to 3, wherein the at least two generated electromagnetic beams (4) are generated at a distance from one another.

5. Method according to one of claims 1 to 4, wherein the at least two electromagnetic beams (4) generated are generated angularly offset from one another.

6. Method according to one of claims 1 to 5, wherein at least two parallel electromagnetic beams (4, 12) are combined into at least one beam group (20, 22, 24).

7. Method according to one of claims 1 to 6, wherein at least two electromagnetic beams (4, 12) of at least one beam group (20, 22, 24) are generated in such a way that they are oriented parallel to one another.

8. Method according to one of claims 1 to 7, wherein at least two reflected electromagnetic beams (16) received by the receiving optics (18) are conducted onto at least two detector elements (14).

9. Method according to one of claims 1 to 8, wherein at least one detector element (14) is assigned to at least one generated electromagnetic beam (4, 12) or beam group (20, 22, 24) on the basis of a distance or an angular offset.

10. Lidar device (1) for scanning a spatial angle with at least one electromagnetic beam (4, 12) according to a method of any of the preceding claims, having: at least one beam source (2) for generating at least one electromagnetic beam (4); a pivotable mirror (6) for steering the generated at least one electromagnetic beam (4) along a horizontal angle and/or along a vertical angle; and a receiving optic (18) rotatable synchronously with the mirror (6) for receiving at least one electromagnetic beam (16) reflected on an object (17), characterized in that the scanning takes place by means of at least one electromagnetic beam (4) which is divided into at least two sub-beams (12) which are angularly and/or laterally offset.

11. Lidar device according to claim 10, wherein the mirror (6), the receiving fixture (18) and the detector element (14) are rotatable along a vertically extending rotation axis (V) in relation to each other or independently of each other.

12. Lidar device according to claim 10 or 11, wherein the mirror (6) is pivotable orthogonal to a vertical axis of rotation (V).

Technical Field

A method for scanning a spatial angle by means of at least one electromagnetic beam and a lidar device.

Background

Rotating 3D scanners are known which operate on the principle of lidar (Light Detection And Ranging). The laser beam is usually deflected in a meandering manner in this case, so that the spatial angle can be scanned. In addition to the steering along the vertically extending pivot axis, there is an additional steering of the laser beam along the horizontal pivot axis. The laser beam is usually steered linearly so that the entire spatial angle is scanned with a defined resolution. The spacing between the scanning paths of the laser beam is critical in particular. A compromise between the resolution and the scanning frequency of such a device must be reached. In order to compensate for the gaps between the scanning paths of the laser beam and to increase the resolution of the 3D scanner, for example, interleaving methods are known which, like the skipping method, reduce the possible distance between the scanning paths by a plurality of scanning processes or additional scans over the entire spatial angle. But where the scanning frequency is reduced by the number of additional scans.

Disclosure of Invention

The object of the present invention can be seen as providing a lidar device and a method for scanning an area or a spatial angle with an increased resolution while the scanning frequency remains at least constant.

This object is achieved by the subject matter of the independent claims. Advantageous embodiments of the invention are the subject matter of the dependent claims.

According to one aspect of the invention, a method for scanning a spatial angle by means of at least one electromagnetic beam is provided. In a first step, at least one electromagnetic beam is generated and then deflected by a rotatable or pivotable mirror to a horizontal angle and/or a vertical angle. The at least one electromagnetic beam is split by a replication unit, for example a beam splitter, into at least two partial beams having different spatial angles, wherein the scanning of the spatial angles takes place by means of the at least two electromagnetic beams. The at least two electromagnetic beams may be reflected or scattered by an object in space. The at least one reflected electromagnetic beam is received by a receiving optic that is rotatable along a horizontal angle in synchronization with the mirror. The entire pivoting region of the mirror and thus the entire angular region covered by the electromagnetic beam in space can be imaged onto the corresponding detector element.

The measurement rate of the scanner or lidar device, which is the number of measurement points per revolution or per angular range, can thus be doubled at least. The frame rate or the scanning frequency can be kept constant or increased. The at least one electromagnetic beam is preferably generated by a laser or other light source, such as a strongly focused LED. The laser is fixedly or non-rotatably positioned and impinges on the mirror or micromirror in the direction of a vertically extending axis of rotation. This may simplify the thermal attachment of the laser. The horizontal and vertical angles are spread by a spatial angle, which may be conical or pyramidal. The at least two beams can be arranged horizontally next to one another in such a way that at least two scanning paths which can be arranged next to one another are formed by each scanning path. This makes it possible to scan a larger horizontal angle with the scanning frequency remaining constant or to increase the scanning frequency with the horizontal angle remaining constant. An increase in horizontal resolution can be achieved with the horizontal angle and scanning frequency remaining constant. Each scan path comprises a plurality of measurement points or beam pulses which are spaced in time relative to one another. By means of this time interval, each measurement point generated during the evaluation of the measurement points of the received reflections can be unambiguously associated with the generated measurement point. The at least two beams may alternatively be arranged vertically side by side, so that, similar to a horizontal arrangement, the vertical angle, the scanning frequency or the vertical resolution may be increased. Combinations of these characteristics are possible. Alternatively or additionally, a corresponding steering mirror may be used which requires less of the maximum pivoting area possible. This results in a greater design freedom in the design of the mirror or μmirror. Furthermore, stray illumination can be prevented or at least reduced, since the respective beams are imaged onto separate detector elements on the basis of the receiving optics. Since the at least one generated electromagnetic beam is split into at least two sub-beams with different spatial angles, the meeting points of the at least two received beams onto the detector element are also spatially distant from each other. The transitional illumination of one detector element thus does not lead to or only leads to a limited transitional illumination of adjacent detector elements.

According to an embodiment of the method, the at least two electromagnetic beams are generated by at least two beam sources that are angularly offset. In this case, two or more adjacent beam sources, for example lasers, can be arranged side by side and each emit a beam to a mirror. The at least two beam sources can be angularly offset in this case, so that after the deflection process by the mirror, the beams likewise have an angular offset relative to one another. Alternatively, the at least two beam sources may also be oriented parallel to each other and thus produce parallel beams. The angular offset can be achieved by the mirror arching. Furthermore, the angular offset of the at least two beams can be increased or decreased by the mirror camber.

According to a further embodiment of the method, at least one electromagnetic beam is generated by at least one beam source, wherein the at least one electromagnetic beam is split into at least two electromagnetic beams by means of a beam splitter connected downstream of the rotatable mirror. The beam splitter may for example be realized by a plurality of mirrors that are partially transparent for the electromagnetic radiation beam. Depending on the orientation or the angular position of the mirror, the individual beams split off can have an individual angle with respect to one another. The beams may be oriented, for example, parallel to one another or have varying amounts of angular offset relative to one another. Alternatively, the generated radiation beam can also be divided or decomposed into at least two radiation beams by means of prisms, beam splitter cubes or diffractive optical elements, either uniformly or non-uniformly. The beam splitter is preferably arranged in the optical path of the at least one electromagnetic beam.

In a further embodiment of the method, the at least two generated electromagnetic beams are generated spaced apart from each other. The electromagnetic beams thus generated have a defined spacing relative to one another, which is independent of the object or target to be scanned. This may simplify the analysis process of the scanned area.

According to a further embodiment of the method, the at least two electromagnetic beams generated are generated angularly offset from one another. The beams thus generated have an angular offset relative to each other such that the beams are distanced from each other with increasing distance from the at least one beam generator. Thereby scanning a larger angular area.

In a preferred embodiment of the method, at least two parallel electromagnetic beams are combined into a beam group. Thus, all beams of a beam group have the same angle with respect to a common optical axis. The other or further beam sets have different angles. The resulting at least two beams, which are subsequently reflected from the scanned object point, can thus be deflected by the receiving optics in such a way that the beams of a respective beam group impinge on a detector element. This favorably affects eye safety in the near field region. In the near field region, the required light energy is divided into the number of beams contained in the beam set. Since the single beam is no longer used, but rather at least two beams are used for scanning the spatial angle, each beam can be made weaker, so that eye safety can be improved since the beams that may come into contact with the eye are less strongly concentrated or are less strongly present. In the far field, the individual beams of the beam group overlap one another, so that the light energy in the beams impinges in a bundle on the object point. In this case, an increased measuring range can be achieved in terms of eye safety compared to systems based on a single electromagnetic transmission beam.

According to a further embodiment of the method, at least two electromagnetic beams of at least one beam group are generated in a manner oriented parallel to one another. Thus, the beams of a beam group may have the same angle relative to the common optical axis. Other or additional sets of beams may have different angles. A beam set can be realized technically simply by the same angle of all the beams of a beam set.

According to a further embodiment of the method, at least one reflected electromagnetic beam received by the receiving optics is conducted to at least one detector group. Each beam set generated can be assigned a detector set. The receiving optics can divert or guide the reflected beam to a specific detector group depending on the angle or deviation from the optical axis of the receiving optics.

In a further embodiment of the method, at least one detector element is assigned to at least one generated electromagnetic beam or beam group on the basis of the distance or angular offset. The detector elements can be arranged relative to the emission angle or orientation of the generated beam group, so that the reflected beams of the defined beam group can impinge as far as possible on the detector elements provided for this purpose.

According to a further aspect of the invention, a lidar device for scanning a spatial angle with at least one electromagnetic beam according to a method according to an aspect of the invention is provided. The lidar device has at least one beam source for generating at least one electromagnetic beam. The at least one electromagnetic beam generated can be deflected by means of a mirror along a horizontal angle and/or along a vertical angle. The device has a receiving optics that can be rotated synchronously with the mirror for receiving at least one electromagnetic beam reflected on an object, wherein at least two electromagnetic beams are generated.

At least two scan paths arranged side by side can thereby be generated instead of one scan path. Possible gaps between the scanning paths can be reduced in order to increase the resolution of the lidar device, since at least two scanning paths have been generated during the pivoting movement of the mirror. Alternatively, the time for scanning a defined spatial angle or angle can be reduced and thus the scanning frequency increased, depending on the number of beams produced, while the spacing between the scanning paths remains constant. The scanning path can run straight in the vertical or horizontal direction or in a meandering manner.

According to an embodiment of the lidar device, the mirror, the receiving luminaire and the at least one detector element are rotatable, relative to each other or independently, along a vertically extending axis of rotation. Here, the receiving optics can be rotated or pivoted simultaneously with the mirror or with a time delay. The at least one detector element or detector array can be coupled to the receiving means or arranged fixedly or independently of other rotatable components of the device. Preferably, the mirror or micro-mirror, the receiving optics and the at least one detector element perform a uniform movement.

In a preferred embodiment of the laser radar device, the mirror is pivotable orthogonally to the axis of rotation. Such a mirror can be implemented particularly simply technically. In this case, the axis of rotation can advantageously coincide with at least one electromagnetic beam generated by the beam source before the beam is deflected by the mirror. The beam source can thus be embodied fixedly, so that the beam source is subjected to low mechanical stresses during operation of the lidar device. Furthermore, a fixed beam source can be optimally thermally modulated and can be attached to a downstream evaluation unit in a technically simple manner.

Drawings

Preferred embodiments of the invention are explained in detail below on the basis of strongly simplified exemplary diagrams. Shown here are:

figure 1a is a schematic view of a lidar apparatus according to a first embodiment,

fig. 1b is a schematic illustration of a lidar apparatus according to a first embodiment, in which the mirrors are deflected differently,

figure 2 is a schematic diagram of a lidar apparatus according to a second embodiment,

figure 3 is a schematic view of a lidar apparatus according to a third embodiment,

fig. 4 is a schematic diagram of a lidar apparatus according to a fourth embodiment.

In the figures, identical structural elements have identical reference numerals.

Detailed Description

Fig. 1a and 1b show a first exemplary embodiment of a lidar device 1. The laser radar device 1 has a beam source 2, which according to the present embodiment is a laser 2. The laser 2 is arranged fixedly in the device 1 and generates an electromagnetic beam 4. The resulting beam 4 extends vertically from the laser 2 to the mirror 6 and defines a vertical axis of rotation V of the apparatus 1. The mirror 6 is arranged in the device 1 such that the vertical axis of rotation V passes centrally through the mirror 6. The mirror 6 reflects the generated beam 4 and steers the beam 4 into a defined direction. The mirror 6 is mounted rotatably along a pivot axis V and can, for example, be freely rotated or pivoted in any defined region. During the rotation, the mirror 6 performs an uninterrupted movement directed in a direction of rotation. During pivoting, the mirror changes its pivoting or rotational direction when a certain angle, either horizontal or vertical, is reached. During the rotation or pivoting, the mirror 6 continuously deflects the generated beam 4 in accordance with the orientation of the mirror 6. The mirror 6 has an additional horizontal axis of rotation H. Along the horizontal rotation axis H, the mirror 6 performs a pivoting movement in a defined vertical angle. According to this exemplary embodiment, a beam splitter 8 is connected downstream of the mirror 6 in the beam path of the electromagnetic beam 4. The beam splitter 8 may comprise a plurality of partially transmissive mirrors 10 which preferably partially transmit and partially reflect the generated radiation beam 4. Alternatively, the beam splitter 8 may also be a beam splitter prism. The beam splitter 10 is rotatable about a vertical axis of rotation and is connected to the mirror 6, so that the resulting beam 4 is optimally conducted to the beam splitter 8. The partially reflected radiation beam 12 is guided to the partially permeable further mirror 10 and is again partially transmitted and partially reflected there. A plurality of beams 4, 12 can thus be generated. The beams 4, 12 are spaced apart from one another in the vertical orientation of the device 1. The split beam 12 has a different exit angle than the original beam 4 so that a larger vertical angle can be scanned. The vertical and horizontal angles spread out by a spatial angle which may be conical or pyramidal. The resulting beams 4, 12 are operated in a pulsed manner and are deflected in a meandering manner over the entire spatial angle in accordance with the movement of the mirror 6. The lidar device 1 can thus scan the spatial angle by means of the beam 4. Due to the higher number of beams 4, 12 produced, the device 1 has a plurality of detector elements 14, which are matched to the number and orientation of the beams 4, 12. In order to be able to implement the mirror 6 mechanically simply, it can also be rotated along the vertical axis of rotation V in a direction of rotation and be shielded in a defined angular range, so that the beams 4, 12 can leave the device 1 only in a defined horizontal angle. For receiving the beam 16 reflected at the object 17, the device 1 has a receiving device 18 or receiving optics 18, which can also be rotated or pivoted synchronously with the mirror 6, and which focuses and deflects the reflected beam 16 onto the defined detector elements 14. The defined detector elements 14 can thus be assigned to the particular beams 4, 12, 16, so that the entire pivot angle or at least a part of the pivot angle can be imaged on the detector. In fig. 1b, the mirror 6 has a pivoting angle that changes along the horizontal axis of rotation H with respect to fig. 1 a. According to the present embodiment, the beam splitter 8 is implemented statically in terms of vertical orientation. Although the beam splitter 8 can be rotated synchronously with the mirror 6, the partially transmissive mirror 10 is not additionally adjusted according to the exemplary embodiment. But this is technically equally achievable.

Fig. 2 shows a lidar device 1 according to a second embodiment. In contrast to the first exemplary embodiment, laser radar device 1 has a beam splitter 8, which splits and diverts the generated beams 4, 12 in such a way that beams 4, 12 can be combined into three beam groups 20, 22, 24, wherein beams 4, 12 in one beam group 20, 22, 24 run parallel to one another. The beams 4, 12 of the different beam groups 20, 22, 24 have an angular offset relative to one another. According to the present exemplary embodiment, two adjacent beams 4, 12 are combined to form a beam group 20, 22, 24.

Fig. 3 shows a lidar device 1 according to a third embodiment. In contrast to the second exemplary embodiment, in the third exemplary embodiment, instead of the adjacent beams 4, 12 being generated being combined into a respective beam group 20, 22, 24, a plurality of beams 4, 12, which are separated from one another by one or more further beams 12, are combined into a respective beam group.

Fig. 4 shows a lidar device 1 according to a fourth exemplary embodiment. In contrast to the exemplary embodiments shown above, laser radar system 1 does not have beam splitter 8 here. The multiple radiation beams 4 are generated by multiple radiation beam sources 2 or individual lasers 2. These lasers 2 have an angular offset with respect to each other. The lasers 2 are positioned such that all the beams 4 generated meet the mirror 6 at an intersection point with the vertical axis of rotation V. The beams 4 produced likewise have an angular offset which corresponds to the angular offset of the laser 2. The resulting beam 4 is also widened after being deflected by the mirror 6 by the angle defined by the laser 2.