DE102019216813A1 - Sending unit for LIDAR devices with near-field beams and far-field beams - Google Patents

Abstract

Disclosed is a transmission unit, in particular for a LIDAR device, having at least one radiation source for generating electromagnetic rays, wherein the rays generated by the radiation source can be split into two radiation components, with a first radiation component of the radiation generated by the at least one radiation source passing through one of the A lens array downstream of the radiation source can be focused into far-field rays for scanning a far field of a scanning area and a second beam component can be used as near-field rays for scanning a near-field of a scanning area. A LIDAR device is also disclosed.

Description

The invention relates to a transmission unit, in particular for a LIDAR device, with at least one radiation source for generating electromagnetic radiation.

State of the art

Automated vehicles and driving functions are becoming increasingly important in public road traffic. For the technical implementation of such vehicles and driving functions, sensors such as camera sensors, radar sensors and LIDAR sensors are necessary.

LIDAR sensors generate electromagnetic beams, for example laser beams, and use these beams to scan a scanning area. Based on a time-of-flight analysis, distances between the LIDAR sensor and objects in the scanning area can be determined.

Preferably, LIDAR sensors must be able to scan as large a scanning area as possible in order to implement automated driving functions. For example, horizontal scanning angles of 360 °, vertical scanning angles of 20 ° and scanning ranges of up to 200 m are desirable. In previous solutions to these requirements, several different LIDAR sensors are used. In particular, special LIDAR sensors are used for scanning a near field of the scanning area and for scanning a far field of the scanning area.

However, as the number of LIDAR sensors increases, so do the costs for the technical implementation of the automated driving functions.

Disclosure of the invention

The object on which the invention is based can be seen in proposing a transmission unit and a LIDAR device which enable a far field and a near field to be scanned at the same time.

This object is achieved by means of the respective subject matter of the independent claims. Advantageous refinements of the invention are the subject matter of the respective dependent subclaims.

According to one aspect of the invention, a transmission unit, in particular for a LIDAR device, is provided. The transmission unit has at least one radiation source for generating electromagnetic radiation. The beams generated by the radiation source can be split or divided into two beam components.

The at least one radiation source or the entire transmission unit can be designed to be immovable, rotatable or pivotable.

The beams generated by the at least one radiation source are preferably near-field beams for scanning a near-field of a scanning area. In particular, the generated near-field beams can be diffuse or divergent and thus be suitable for scanning short distances or the near-field.

According to the invention, a first radiation component of the near-field rays generated by the at least one radiation source can be focused into far-field rays for scanning a far field of the scanning area by a lens array connected downstream of the radiation source. The remaining beam components or the second beam component can be emitted into the scanning area in the form of near-field beams.

The lens array can collimate part of the generated near-field rays and thus shape them for scanning large distances, such as 100 m to 250 m. As a result, the far-field rays can be designed as individual bundles of rays, which are emitted into the scanning area at the same time or parallel to the near-field rays.

The transmission unit allows a LIDAR device to be used for several applications at the same time. For example, such a LIDAR device can be used both for automated driving functions on a motorway and during a traffic jam. Applications with required measurements from long distances and applications with required measurements from short distances can thus be made possible by a single transmission unit.

The near-field rays can be divergent or diffuse and the far-field rays can be collimated or at least less divergent than the near-field rays.

A receiving unit of the LIDAR device can have a detector or a detector array, which can technically take both applications into account. The reflected and / or backscattered rays from the scanning area can be assigned to the corresponding near-field rays or far-field rays, for example by means of intensity patterns.

The transmission unit according to the invention can save costs and provide a high dynamic range for a LIDAR device. Furthermore, the transmission unit has a high degree of modularity, since the lens array is exchanged directly influences the properties of the far-field rays and the corresponding scanning area.

According to an exemplary embodiment, the near-field rays can be collimated in regions by the lens array to form a pattern of far-field rays, the far-field rays being spaced apart from one another by uniform or non-uniform spacings transverse to a direction of propagation of the far-field rays. By means of this measure, a scanning pattern can be created for the far field of the scanning area. The far-field rays here have gaps to one another. The collimated far-field beams can scan greater distances and can thus be used to detect objects that are far away. The divergent near-field rays lose their signal strength with the distance to the power of four. In contrast, the collimated far-field rays lose their signal strength with the distance squared.

Furthermore, the area of the detector exposed by the far-field rays can be designed to be smaller, as a result of which lower background noise and thus a better signal-to-noise ratio compared to the near-field rays can be achieved.

According to a further embodiment, the distances between the far field beams can be compensated for by operating vibrations and / or by rotating movements of the transmitting unit. The resulting distances between the collimated far-field rays result in gaps in the scanning of the scanning area. No information about the environment can therefore be determined from the gaps. In order to obtain this missing information, a movement of the transmission unit can be initiated, which leads to the gaps in the scanning area also being exposed.

For example, the resulting gaps in an automotive application can be compensated for or at least reduced by vibrations of the vehicle during operation.

Alternatively or additionally, an intended movement of the transmitting unit can be used to exclude gaps in the scanning area and thus to carry out a complete scan of the scanning area. The respective pivoting steps or rotation steps can be smaller than or equal to the distances between the respective far field beams in the horizontal or vertical direction.

According to a further exemplary embodiment, the at least one radiation source is designed as an extensive array with a large number of emitters. The LIDAR device can preferably have an array of emitters in the transmitting unit and a detector array in the receiving unit. The emitters can be designed, for example, as so-called VCSELs or surface emitters. Some of the emitters are used to generate divergent beams for scanning the far field of the scanning area. The near-field rays can have no or only slight distances from one another in the vertical and horizontal directions. Another part of the emitter can project the generated rays onto lenses of the lens array, whereby the respective rays are focused or collimated and thus formed into far-field rays.

Due to the divergent rays or near-field rays, which are emitted without gaps, the near field of the scanning area can be scanned particularly thoroughly.

According to a further embodiment, the emitters can be controlled jointly or independently of one another in order to emit near-field rays. In the case of emitters that can be controlled simultaneously or jointly, a technically particularly simple driver electronics can be used. By means of separately controllable emitters, a dynamic adaptation of the exposure can be realized, which is particularly advantageous with regard to eye safety.

According to a further exemplary embodiment, the lens array has a multiplicity of lenses which collimate part of the near-field rays generated, the lenses being distributed uniformly, unevenly or randomly on the lens array. The lenses can be shaped as microlenses or as macrolenses. The spacing and arrangement of the lenses can be targeted, planned or random. For example, the arrangement of the lenses on the lens array can be adapted to positions of defined emitters. In the case of lenses arranged at random, cost-intensive alignment of the lenses with respect to the at least one radiation source can be dispensed with. If, on the other hand, the lenses are aligned with the emitters, a particularly efficient collimation of the rays in the far field can be carried out.

Alternatively or additionally, the after-field rays generated can be divided into two or more sections. One or more sections are used to emit the near-field rays and one or more sections are used to collimate the near-field rays and generate far-field rays.

When generating far-field beams and near-field beams, additional optics or optical elements can be used for beam shaping.

According to a further embodiment, the lenses of the lens array have a size adapted to the emitters of the at least one radiation source or a size smaller than the emitters. This measure enables targeted distances to be generated around the far-field rays. Depending on the shape and size of the lenses, the horizontal and vertical distance between the far-field rays can be filled by near-field rays or designed without further rays.

The generated far-field beams and the near-field beams here form a generated scanning pattern for the simultaneous scanning of the scanning area in several distance planes.

According to a further alternative aspect of the invention, a transmission unit, in particular for a LIDAR device, is provided. The LIDAR device has at least one radiation source for generating electromagnetic radiation, which radiation source is designed to be immovable, rotatable or pivotable. According to the invention, the at least one radiation source is coupled in a radiation-conducting manner to an optical phased array. In particular, the radiation source can generate far-field rays for scanning a far field and near-field rays for scanning a near field of a scanning region via the optical phased array.

In this way, a LIDAR device can be provided with a dynamic setting of the generated far-field rays and near-field rays. In particular, a situation-dependent adaptation of the scanning pattern can be realized, which is formed from the far-field rays and the near-field rays.

According to one embodiment, the optical phased array has a multiplicity of emitter antennas, the phase relationships between the emitter antennas being configured to be static or adjustable. A technically particularly simple optical phased array, which can generate a constant scanning pattern, can be implemented by means of fixed phase relationships of the emitter antennas. Adapting or changing the scanning pattern of the near-field beams and the far-field beams can be advantageous for dynamic applications. The far field rays can be formed, for example, by constructive interference in the scanning pattern.

According to a further aspect of the invention, a LIDAR device for scanning scan areas is provided. The LIDAR device has a transmitting unit according to the invention and a receiving unit. The transmission unit of the LIDAR device has at least one radiation source for generating rays. The receiving unit has at least one detector for detecting rays.

The receiving unit can have receiving optics for receiving the beams backscattered and / or reflected from the scanning area, which optics then focus the received beams onto the at least one detector. The detector can be positioned in a focal plane of the receiving optics.

The at least one detector of the receiving unit can be designed, for example, as a CCD sensor, CMOS sensor, APD array, SPAD array and the like.

The detector can preferably have a relatively large area in order to undertake an optimal differentiation between the received near-field rays and the received far-field rays.

The at least one detector or the receiving unit can be calibrated after the LIDAR device has been manufactured. For this purpose, a white wall can be exposed to light by the transmitting unit and the corresponding intensity patterns received by the detector can be evaluated.

In particular, detector pixels with a high determined intensity can be allocated for receiving rays from far-field rays and the remaining detector pixels for receiving rays resulting from near-field rays. A technically particularly simple calibration of the receiving unit can thus be carried out.

Another advantage of the LIDAR device is the possibility of a modular structure. Properties of the LIDAR device, such as, for example, resolution, scanning angles in the vertical and horizontal directions, distribution of the far-field rays and the like, can be technically changed by exchanging the lens array and optional lenses or optics. The LIDAR device can thus be adapted to changing customer requirements in a cost-effective manner.

The LIDAR device can be designed as a flash LIDAR or a solid-state LIDAR without moving components. Alternatively, the LIDAR device or parts of the LIDAR device can be designed to be rotatable or pivotable along at least one axis of rotation. In addition, the lidar device can optionally be a micro-scanner or a macro-scanner.

• 1 eine schematische Darstellung einer LIDAR-Vorrichtung gemäß einer Ausführungsform,
• 2 eine Darstellung eines Abtastmusters,
• 3-7 schematische Darstellungen von Linsenarrays und
• 8 eine schematische Darstellung einer Sendeeinheit gemäß einer weiteren Ausführungsform.

In the following, preferred are based on greatly simplified schematic representations Embodiments of the invention explained in more detail. Show here

• 1 a schematic representation of a LIDAR device according to an embodiment,
• 2 a representation of a scanning pattern,
• 3-7 schematic representations of lens arrays and
• 8th a schematic representation of a transmission unit according to a further embodiment.

The 1 shows a schematic representation of a LIDAR device 1 according to one embodiment. The LIDAR device 1 has a transmitter unit 2 and a receiving unit 4th on.

The transmitter unit 2 has a radiation source 6th on what a variety of emitters 8th includes. The emitter 8th are designed as surface emitters and are used, for example, to generate rays 9 in the infrared wavelength range.

The generated rays 9 are called near-field rays 9 designed and have diffuse or divergent radiation characteristics. The near field rays 9 are set up to scan a near field AN of a scanning area A.

Part of the near field rays 9 is through one of the radiation source 6th downstream lens array 10 collimated. The lens array 10 thus generated from a part of the near-field rays 9 collimated far-field rays 11 . The far field rays 11 are set up to scan a far field AF of the scanning area A.

For example, the near-field rays 9 for scanning a distance of up to 50 meters and the far field rays 11 can be used to scan a distance range between 50 and 150 meters.

The receiving unit 4th has a receiving optics 12th on. The receiving optics 12th can be reflected and / or backscattered rays from the scanning area A. 13th received and on a detector 14th focus.

The detector 14th is designed as an extensive detector and is, for example, a CCD detector. Based on an intensity pattern generated by the far field rays 11 and the near field rays 9 is generated, the reflected and / or backscattered beams from the scanning area A 13th to the respective rays 9 , 11 be assigned.

The 2 shows an illustration of a scan pattern 16 . The scan pattern 16 is caused by the near field rays 9 and the far field rays 11 educated. The near field rays 9 are diffuse and penetrate all areas around the far-field rays 11 .

The far field rays 11 are spaced from one another by horizontal distances x and vertical distances z. In the illustrated embodiment, the far field rays are 11 spaced from each other at equal distances x, z.

In the 3 to 7th are schematic representations of lens arrays 10 shown. The lens array 10 has a variety of lenses 18th on. The lenses 18th can be designed as microlenses or as macrolenses and can use the near-field rays 9 to far-field rays 11 focus.

The 3 shows a lens array 10 with evenly distributed lenses 18th . The lenses 18th are to an arrangement of emitters 8th aligned.

The 4th and 5 show further lens arrays 10 with unevenly or irregularly arranged lenses 18th . In particular, the lenses 18th be randomly distributed.

The 6th shows a lens array 10 according to a further embodiment, in which the lenses 18th to an arrangement of the emitters 8th the radiation source 6th are aligned. For every emitter 8th is a lens 18th intended. The lenses 18th have a reduced diameter, thereby reducing the near-field rays 9 in areas to far-field rays 11 be bundled. This creates gaps or distances x, z in the scanning pattern 16 , which by the near-field rays 9 fill out.

In the 7th is another lens array 10 shown. The lens array 10 is divided into two parts. Through a first part 20th of the lens array 10 can the near-field rays 9 pass unhindered. In a second part 22nd of the lens array 10 are the lenses 18th arranged through which the near-field rays 9 to far-field rays 11 be focused. In contrast to the embodiments already shown, is on each part 20th , 22nd of the lens array 10 one lens each 24 for shaping the near-field rays 9 before hitting the lens array 10 arranged.

The 8th shows a schematic representation of a transmission unit 2 according to a further embodiment. In contrast to the in 1 sender unit shown 2 , becomes the scan pattern 16 here by an optical phased array 26th generated.

The radiation source 6th is here with the optical phased array 26th coupled. The optical phased array 26th has a variety of emitter antennas 28 on which for setting phase relationships and for generating the scanning pattern 16 are set up.

In particular, the optical phased array 26th dynamic control of the emitter antennas 28 have through which the scanning pattern 16 can be varied or customized.

Claims (10)

Sending unit (2), in particular for a LIDAR device (1), having at least one radiation source (6) for generating electromagnetic rays, wherein the rays (9) generated by the radiation source (6) can be split into two radiation components, characterized in that, that a first portion of the rays (9) generated by the at least one radiation source (6) can be focused through a lens array (10) downstream of the radiation source (6) to form far-field rays (11) for scanning a far field (AF) of a scanning area (A) and a second beam component can be used as near-field beams (9) for scanning a near-field (AN) of a scanning area (A). Sending unit after Claim 1 , wherein the near-field rays (9) can be collimated in areas by the lens array (10) to form a scanning pattern (16) of far-field rays (11), the far-field rays (11) through uniform or non-uniform distances (x, z) transversely to a direction of propagation of the far-field rays (11) are spaced from each other. Sending unit after Claim 2 , wherein the distances (x, z) between the far field beams (11) can be compensated for by operating vibrations and / or by rotary movements of the transmitter unit (2). Sending unit after one of the Claims 1 to 3 , wherein the at least one radiation source (6) is designed as an extensive array with a plurality of emitters (8). Sending unit after Claim 4 , the emitters (8) being controllable jointly or independently of one another to emit near-field beams (9). Sending unit after one of the Claims 1 to 5 wherein the lens array (10) has a plurality of lenses (18) which collimate part of the generated near-field rays (9), the lenses (18) being distributed uniformly, unevenly or randomly on the lens array (10). Sending unit after one of the Claims 1 to 6th wherein the lenses (18) of the lens array (10) have a size adapted to the emitter (8) of the at least one radiation source (6) or a size smaller than the emitter (8). Transmitter unit (2), in particular for a LIDAR device (1), having at least one radiation source (6) for generating electromagnetic radiation, which is designed to be immobile, rotatable or pivotable, the at least one radiation source (6) having an optical phased Array (26) is coupled in a radiation-conducting manner and far-field rays (11) for scanning a far field (AF) and near-field rays (9) for scanning a near field (AN) of a scanning area (A) can be generated via the optical phased array (26). Sending unit after Claim 8 wherein the optical phased array (26) has a plurality of emitter antennas (28), the phase relationships between the emitter antennas (28) being configured to be static or adjustable. LIDAR device (1) for scanning scanning areas (A), having a transmitting unit (2) according to one of the preceding claims.

Images