DE102014214710A1 - Rain detection device - Google Patents

Abstract

A rain detection device (200) for a vehicle (700) is presented, comprising a camera (101), a light source (102) for emitting a light cone for rain detection and a light guide (201) with a coupling side (302) having a first surface (304) and an exit side (303) having a second surface (305). The optical fiber coupling side (302) is optically coupled to the light source (102) and the optical fiber (201) is configured to redirect and constrict the light cone of the light source.

Description

Technical area

The present invention relates to rain detection in vehicles. More particularly, the present invention relates to a rain detecting apparatus for a vehicle and a vehicle.

Initial situation of the invention

Nowadays, vehicles may include rain detection functionality for automatically turning on and off the wipers and for controlling the frequency of the wipers. There are different ways of measuring rainfall intensity. One way to measure rainfall intensity is to measure reflections of a light beam on the windshield of the vehicle. For example, there are systems for rain detection in vehicles that are configured to interact with a front-facing camera of the vehicle.

WO 2012/092911 A1 describes a rain detection device comprising a camera and a lighting source.

Summary of the invention

An object of the invention is to provide a more effective and reliable rain detection device.

This object and other objects are achieved by the subject matter of the independent claims. Further embodiments and advantages are set forth in the respective dependent claims.

A rain detecting device for a vehicle is presented, wherein the rain detecting device comprises a camera, a light source for emitting a light cone for rain detection, and a light guide having a coupling side with a first surface and an exit side with a second surface. The coupling side of the light guide is optically coupled to the light source. In addition, the light guide is configured for diverting and narrowing the light cone of the light source.

It should be noted that the present invention may also relate to a vehicle including a rain detection device and the method described in connection with the present invention.

By providing such a rain detecting device comprising a light guide, it is possible to ensure that less light of the light source is lost. In other words, the light from the light source can be used more effectively for rain detection.

A first advantage of the present invention is that the optical fiber can change the emitting direction so as to change from a straight upward direction to an inclined direction toward the windscreen with a narrower cone. In this way it ensures that a much larger proportion of the light emitted by the light source can be used for rain detection, which makes the arrangement more effective. In addition, a second advantage of the light guide is that the light guide can produce a much more uniform illuminated area on the windshield as compared to a light source without a light guide. A third advantage of the present invention is that the rain detection area on the windshield or window can be made larger, because the exit area of the lightguide can be increased in comparison to the exit area of the light source.

The light guide is to be understood as a device for diverting and narrowing the light cone of the light source. The light guide may be embodied, for example, as a solid plastic molded solid structure. In other words, the light guide may comprise a prismatic shape. The coupling side of the light guide may be configured to be optically coupled to the light source. The term "optically coupled" is to be understood as meaning that a greater part of the light cone of the light source is transmitted to the light guide and guided by the light guide. The exit side of the light guide may be configured to emit the redirected and constricted light cone. By redirecting the light cone, the direction of the peak intensity of the light cone is changeable. The light cone is, in other words, tilted by the light guide. The narrowing of the light cone may include reducing the aperture angle of the light cone from the light guide.

The rain detection device may be an independent system of the vehicle. In addition, the rain detection system can also be integrated in a driver assistance system or be part of a driver assistance system of the vehicle. For example, the camera can be used by the driver assistance system for recording driver assistance images. Thus, an existing driver assistance system having a camera is expandable by the rain detection capability. Additionally, the camera may be configured to record reflections of the redirected light cone on a windshield or window of the vehicle. The present invention can thus also be an extension kit for a Driver assistance system for extending an existing driver assistance system to affect rain detection capabilities. The vehicle may be a passenger car, a truck, a motorcycle, or any other vehicle having a windshield or window where rain detection capabilities are relevant. As already mentioned, the camera can be part of a driver assistance system. For driver assistance applications, the focus of the camera may be set to infinity or near infinity. The camera may be installed inside the vehicle and / or directed towards a windshield or window of the vehicle. The camera is, for example, a digital camera with a CMOS chip. The light source may be implemented as an incandescent or light emitting diode and controlled by the rain detection device. The rain detecting device including the camera may be installed, for example, in a device located between the windshield and the vehicle interior mirror so that the driver's visual field is not restricted.

For example, a raindrop or other form of precipitate may cause a change in the reflection of the light cone on the outside of the windshield or window of the vehicle. This reflection will be referred to below as the second reflection. A change in the second reflection can thus be a sign of rain. In addition, the rain detection device may also detect another form of precipitation, which makes the device more effective.

The cone of light of the light source is conceivable as a cone in the broader sense, d. h., The cone of light must not be an exact cone, but merely describes the spatial emission characteristics of the light source. In other words, the light cone is conceivable as a radiation pattern of the light source emitted along one direction. In addition, the cone of light may have a peak intensity along one direction. Furthermore, the light cone can also be described with regard to an opening angle. The aperture angle is, for example, conceivable as an angle of the light cone in which the light cone has half the intensity with respect to the peak intensity of the light cone. In other words, the opening angle may correspond to half the width of the light cone.

According to an embodiment of the invention, the light guide comprises a fresnel-like lens which is arranged on the coupling side of the light guide.

By means of the Fresnel or fresnel-like lens, the coupling side of the light guide can focus the light cone of the light source. Thus, it is possible to ensure that a larger proportion of the light of the light source is subjected to total reflection in the light guide and emitted through the exit side of the light guide. In other words, it is possible for the light guide to lose less light. In this way, a greater proportion of the light from the light source can be used for rain detection, which leads to a more sensitive and / or more accurate rain detection.

According to a further embodiment, the exit side of the light guide is configured for the light scattering.

Therefore, the light guide can emit a cone of light with a continuous and homogeneous intensity. In this way, the light cone for rain detection can be improved. In addition, a higher uniformity illuminated area on the windshield or the window of the vehicle can be realized.

According to a further embodiment, the second surface of the exit side comprises microstructures for the light scattering.

By means of the microstructures, a large illumination area on the second surface of the exit side of the light guide can be effected. In this way, the light guide can illuminate a larger area on the windshield or the window of the vehicle, which can lead to a larger rain detection area.

According to a further exemplary embodiment of the invention, the light guide comprises a reflection side with a third surface for reflecting internal reflections of the light cone emitted by the light source. In addition, the first surface of the coupling side and the third surface of the reflection side enclose an angle whose size is between 45 degrees and 75 degrees. The angle is preferably 60 degrees.

Both the first surface and the third surface may be planar or nearly planar surfaces. In this embodiment, the first surface and the second surface may be arranged so as not to be parallel to each other. The angle included by the first surface and the second surface is conceivable as the angle by which the second surface is inclined with respect to the first surface.

According to a further embodiment, the second surface of the exit side is larger than a light emitting surface of the light source.

In other words, the exit side of the light guide can have a larger surface area than the light source. That way, in the Compared to rain detection devices without optical fiber, the rain detection area on the windshield or the window of the vehicle enlarged.

According to a further embodiment, the light source is a light emitting diode.

The light source is, for example, a TOPLED SMD component.

According to a further embodiment, the light guide is made of transparent plastic, polycarbonate.

The use of polycarbonate may be advantageous because polycarbonate has been tested in the automotive industry and is readily moldable in an injection molding process.

According to a further embodiment, the length of the light guide is between 2 cm and 6 cm and its width between 0.5 cm and 1.5 cm. Preferably, its length is between 3 cm and 4 cm and its width between 0.6 cm and 0.8 cm.

In this way, the light guide is feasible together with the rain detection device and the camera in a device which is located behind the interior mirror of the car and does not restrict the driver's field of view.

According to a further embodiment, a peak intensity of the light cone emitted by the light source in the absence of the light guide runs along a vertical direction.

In other words, the light source may be configured to emit light with a cone of light having a peak intensity along a vertical direction. The vertical direction is related to 1 explained. Thus, the optical fiber can be configured to incline the peak intensity to change from a vertical direction to a tilted direction. The angle between the vertical direction and the inclined direction is, for example, in the range between 40 degrees and 70 degrees.

In accordance with another embodiment, a vehicle is provided that includes a windshield or window and a rain detection device described in connection with the present invention. The light source, the light pipe and the camera are arranged and configured such that the light cone emitted by the light guide is redirected to an area of the windshield or the window of the vehicle.

The camera may be configured to record the first reflection and the second reflection of the redirected light cone. In addition, the light source, the light guide and the camera may be configured such that the first and second reflections are separable from each other. For example, there may be a distance between the first and second reflections so that the camera can distinguish between the first and second reflections. By analyzing the first and second reflections, rain or other forms of precipitate are detectable by the rain detection device.

According to a further embodiment, the rain detection device also comprises a processing unit. The light source, the light pipe and the camera are arranged and configured such that a first reflection of the light cone is reflected from an inside of the windshield or the window to the camera. In addition, the light source, the light pipe and the camera are arranged and configured such that a second reflection of the light cone is reflected from an outside of the windshield or the window to the camera. The processing unit is configured to detect rain based on a change in the second reflection of the light cone recorded by the camera.

For example, a raindrop or other form of precipitate may cause a change in the reflection of the light cone on the outside of the windshield or window, i. h., the second reflection. A change in the second reflection can thus be a sign of rain. In addition, the rain detection device may also detect another form of precipitation, which makes the device more effective.

In another embodiment, the processing unit is configured to calibrate the rain detection device based on the first reflection of the light cone.

For example, the first reflection is not significantly affected by the presence or absence of rain. Therefore, the first reflection is usable for calibrating the rain detection system.

According to a further embodiment, the rain detection device also comprises a housing and a printed circuit board arranged in the housing. The light source is arranged on the circuit board of the rain detection device and the light guide is embedded in an opening of the housing.

In this way it is possible to provide a compact rain detection device. In addition, the opening in the housing and the light guide may be arranged so that light is emitted only through the light guide. In this way, no stray light is generated. In addition, the housing can protect the circuit board and / or the light source from dust and moisture and improve the electromagnetic compatibility (EMC).

According to a further embodiment, the camera is part of a driver assistance system of the vehicle. In addition, the camera is also configured to record a driver assistance picture. In addition, the light source, the light pipe and the camera are configured such that reflections of the light cone on the windshield or the window and the driver assistance image do not overlap.

This is to be understood in that the reflections of the light cone on the windshield and the driver assistance functionality do not overlap in time. In other words, the rain detection functionality and the driver assistance functionality of the camera are executable in different time frames. This is achievable by such timing of the camera and the light source that frames in which the light source is turned on and the rain detection is active do not coincide with frames in which the driver assistance function is performed. In this way the camera can be used for driver assistance and for rain detection. To generate driver assistance images, the focal point of the camera may be set to infinity or near infinity. As a result, driver assistance images can be captured as images that are used or processed to generate driver assistance data.

In addition, a method for rain detection for a vehicle is presented. The method includes the steps of emitting a cone of light through a light source inside the vehicle and redirecting the cone of light to an area of a windshield or window of the vehicle through a light pipe and narrowing the light cone through the light pipe. In addition, the method includes the step of recording an image of the area of the windshield or the window with a camera for rain detection.

This method can be carried out, for example, by a rain detection device described in connection with the present invention. Features and advantages described with respect to the rain detection device and / or the vehicle may also apply to the method. The steps of the method are executable in the order shown. In addition, the steps of the method are executable in a different order or in parallel with each other.

An essential point of the invention is therefore to be seen in that the light guide changes the emission direction of the light source so that is changed from an upward direction to an inclined direction with a narrower cone. In addition, it can be ensured that a larger proportion of the light emitted by the light source can be used for rain detection, which makes the arrangement more effective. Furthermore, compared to light sources without a light guide, a much higher uniformity illuminated area on the windshield or window of the light guide can be generated. In addition, the rain detection area on the windshield or the window is increased, since the exit area of the light guide is increased compared to the exit area of the light source.

One skilled in the art will infer from the above and following description that, unless otherwise specified, in addition to any combination of features associated with an item type, any combination of features pertaining to different item types is also disclosed as having this application is to be considered.

The aspects described above as well as further aspects, features and advantages of the invention are also to be taken from the exemplary embodiments which are described below with reference to the attached drawings.

Brief description of the drawings

1 shows a rain detection device without optical fiber according to an embodiment of the invention.

2 shows a rain detection device according to an embodiment of the invention.

3 shows a light guide according to an embodiment of the invention.

4 shows a side view of a light guide according to an embodiment of the invention.

5 shows a provided on the coupling side of a light guide fresnelartige structure according to an embodiment of the invention.

6A and 6B show different views of a light guide according to an embodiment of the invention.

7 shows a vehicle with a rain detection device according to an embodiment of the invention.

8th shows a flowchart for a method according to an embodiment of the invention.

It should be noted that the figures are drawn schematically and not to scale. None of the reference signs in the claims is to be construed as limiting the scope of the claims.

Detailed description of exemplary embodiments

1 shows a rain detection device 100 according to an embodiment of the invention without optical fibers to explain and show the effect of the light guide of the present invention. The rain detection device 100 may be installed in a vehicle and may be part of a driver assistance system of the vehicle.

The rain detection device 100 includes a camera 101 and a light source 102 and is shown without a light guide. The camera 101 is a front-facing camera that is installed in a vehicle and on a windshield 106 of the vehicle is directed. The light source 102 and the camera 101 are with a printed circuit board 113 the rain detection device 100 connected. In addition, the circuit board 113 in a housing 114 integrated to protect against dust and moisture and to improve electromagnetic compatibility. The housing 114 has an opening 115 , The light source is for emitting the light cone 103 through the opening 115 configured. There is also a processing unit 116 for rain detection connected to the circuit board.

The light source 102 is for sending out a light cone 103 configured to have a peak intensity along a vertical direction 105 and an opening angle 104 Has. The windshield 106 becomes, for example, with the light source 102 with an emission pattern and with a cone of light 103 illuminated with a half width of 60 degrees, with half the width of the opening angle 104 corresponds to the light cone. It should be noted that for the description of the present invention, the light cone 103 is the light cone that is generated in the absence of a light guide. A share 109 of light is used for rain detection. In the absence of the light guide is the proportion 109 not equal to the peak intensity 105 of the light cone 103 , The amount 109 the light gets on the inner surface 107 and the outer surface 108 the windshield 106 of the vehicle. In this way, a first reflection 110 and a second reflection 111 of the light cone 103 generated. It also becomes a passage component 112 of the light cone 103 through the windshield 106 pass through. The camera 101 is for detecting the first and second reflections 110 and 111 configured. The camera 101 is for registering the reflections 110 and 111 of the light cone 103 on the right part of the picture surface of the camera 101 configured. This part is used for rain detection. Raindrops on the windshield 106 produce changes in the outer second reflection 111 what through the camera 101 and / or the processing unit 116 is detected. The camera 101 and / or the processing unit 116 can assume that the inner first reflection 110 is essentially constant and can be the first reflection 110 for the calibration of the rain detection device 100 or as a reference for calculating the change of the second reflection 111 use.

2 shows a rain detection device 200 according to an embodiment. The rain detection device 200 from 2 corresponds for example to the rain detection device 100 from 1 , wherein additionally an optical fiber 201 is available. Like the rain detection device 100 from 1 includes the rain detection device 200 from 2 a camera 101 , a light source 102 and a processing unit 116 that with a circuit board 113 connected in a housing 114 that has an opening 115 has, is integrated. The camera 101 is installed in a vehicle and on the windshield 106 that is an inside 107 and an outside 108 has, addressed.

In contrast to the rain detection device 100 from 1 is a light guide 201 at least partially into the opening 115 embedded in the housing. In addition, the light guide 201 visually to the light source 102 coupled, ie, the light cone of the light source is through the light guide 201 directed. In this way, the light cone of the light source of the light guide 201 diverted and narrowed. The light guide 201 can also have other forms, such. B. the in 4 shown shape. It can be seen that the light cone 202 from 2 opposite the cone of light 103 from 1 inclined and narrowed. The angle 203 is, in other words, smaller than the angle 104 , In addition, the peak intensity 204 of the light cone 202 in a line with the share 109 of the light cone 202 which is reflected on the windshield for rain detection. In this way, a greater part of the light cone is directed to a rain detection area on the windshield. The right angle for the redirected cone of light 202 can depend on the relative angle between the windshield 106 and the camera 101 depend. Accordingly, first and second reflections 110 and 111 as well as a passage component 112 generated.

3 shows an isometric drawing of a light guide 201 according to an embodiment. It can be seen that the light guide 201 is a solid state structure with a prism-like shape. The light guide 201 includes a coupling page 302 for coupling to a light source and an exit side 303 for sending the redirected light cone. The coupling side 302 includes a first surface 304 and the exit side 303 includes a second surface 305 wherein the first and second surfaces 304 and 305 are inclined with respect to each other. The length 306 of the light guide is between 3 cm and 4 cm and the width 307 of the light guide is about 0.7 cm. The coupling side 302 may comprise a structure for more effectively coupling the light of the light source, for example a Fresnel lens. The second surface 305 the exit side 303 For example, a structure for scattering the redirected light cone and producing a light cone having a continuous and homogeneous intensity, for example, microstructures 310 , include. This results in a large illumination area on the light guide exit surface. Therefore, the optical fiber can illuminate a large area on the windshield or the window of the vehicle, resulting in a larger rain detection area. The 5 . 6A and 6B show special structures on the coupling side 302 ,

4 shows a side view of a light guide 201 and a light source 102 according to an embodiment of the invention. The light source 102 is realized as a SMD LED with a flat light emitting area. According to this embodiment, the light guide comprises 201 a coupling page 401 and an exit side 402 which are arranged so that they are perpendicular to each other. In addition, the light guide includes 201 a reflection page 403 at an angle of about 60 degrees to the coupling side 401 runs. The light source 102 is located below the coupling side 401 of the light guide 201 and is optically to the light guide 201 coupled. It is further shown that two different light beams 404 and 405 of the light cone from the light source 102 to be sent out. The light beam 404 is in the light guide 201 passed and due to the small angle of scatter to the coupling side 403 a total reflection in the light guide 201 subjected. Subsequently, the internal reflection of the light beam 404 through the exit side 402 sent out what the light beam 406 results. The light beam 405 becomes on the surface of the exit side 402 and on the surface of the reflection side 403 subjected to two consecutive total reflections before passing through the exit side 402 is sent out what the light beam 407 results.

5 shows a part of a arranged on the coupling side of the light guide fresnel-like lens structure 501 according to an embodiment of the invention. A side view shows the dimensions and angles for a number of V-shaped groove structures provided along the side of the coupling surface. These V-shaped groove structures provide the functionality of expanding the light beam in random directions, resulting in scattering of the light emitted by the light source. This prevents the occurrence of a hot spot on the exit side of the light guide. For example, the angle of the V-shaped groove structure is 105 degrees, and the distance between two adjacent V-shaped groove structures is 0.3 mm, for example.

6A shows a front view of a light guide 201 with light sources 102 . 601 and 602 and 6B shows a side view according to an embodiment of the invention. The light guide 201 includes a coupling page 302 and an exit side 303 with a sloped surface, as seen from the side view 6B is apparent. The light guide 201 includes spherical cavities 603 . 604 and 605 that are above the light sources 102 . 601 and 602 located to the light output of the light sources 102 . 601 and 602 to fit in this case in a dome-shaped lens housing. In this way, a larger part of the light sources 102 . 601 and 602 emitted light in the light guide 201 transfer.

7 shows a vehicle 700 according to an embodiment of the invention with a windshield 106 and a rain detection device 200 , for example, between the windshield 106 and the interior mirror 701 of the vehicle. The rain detection device includes the features described in connection with the present invention.

8th shows a flowchart for a method according to an embodiment of the invention. The method comprises the step S1 of emitting a light cone through a light source inside the vehicle. In addition, the step S2 of redirecting the light cone to a portion of a windshield or a window of the vehicle is performed by a light guide. In addition, the step S3, which includes narrowing the cone of light through the light guide, and step S4, which includes recording an image of the area of the windshield or window with a camera for rain detection, are included in the method.

In the claims, the word "comprising" does not exclude other elements or steps and the indefinite article "a / a / a / a / a "does not exclude a majority. It should be noted that features described with reference to an embodiment may also be combined with other features of other embodiments. The mere fact that certain measures are listed in dependent claims and / or exemplary embodiments differing from one another does not indicate that a combination of these measures can not be used to advantage. The reference signs in the claims are not intended to limit the scope of the claims.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2012/092911 A1 [0003]

Claims (15)

Rain detection device ( 200 ) for a vehicle ( 700 ), the rain detection device comprising: a camera ( 101 ), a light source ( 102 ) for emitting a light cone for rain detection, a light guide ( 201 ) with a coupling side ( 302 ) with a first surface ( 304 ) and an exit side ( 303 ) with a second surface ( 305 ), the coupling side ( 302 ) of the optical fiber optically to the light source ( 102 ) and wherein the optical fiber ( 201 ) is configured for diverting and narrowing the light cone of the light source. Rain detection device ( 200 ) according to claim 1, wherein the light guide ( 201 ) a fresnel-like lens ( 500 ), which at the coupling side ( 302 ) of the light guide is arranged. Rain detection device ( 200 ) according to claim 1 or 2, wherein the exit side ( 303 ) of the light guide ( 201 ) is configured for the light scattering. Rain detection device according to claim 3, wherein the second surface ( 305 ) the exit side ( 303 ) Microstructures ( 310 ) for light scattering. Rain detection device ( 200 ) according to one of the preceding claims, wherein the light guide ( 201 ) further comprises: a reflection side ( 403 ) with a third surface for reflecting internal reflections of the light source ( 102 ) emitted light cone, wherein the first surface ( 304 ) of the coupling side ( 302 ) and the third surface of the reflection side ( 403 ) include an angle whose size is between 45 degrees and 75 degrees, the angle being preferably 60 degrees. Rain detection device ( 200 ) according to one of the preceding claims, wherein the second surface ( 305 ) of the exit side is greater than a light emitting surface of the light source ( 102 ). Rain detection device ( 200 ) according to one of the preceding claims, wherein the light guide ( 201 ) is made of transparent plastic, preferably polycarbonate. Rain detection device ( 200 ) according to one of the preceding claims, wherein the length ( 306 ) of the light guide ( 201 ) between 2 cm and 6 cm and its width ( 307 ) is between 0.5 cm and 1.5 cm, preferably its length is between 3 cm and 4 cm and its width between 0.6 cm and 0.8 cm. Rain detection device ( 200 ) according to one of the preceding claims, wherein a peak intensity of the in the absence of the optical fiber ( 201 ) from the light source ( 102 ) emitted light cone ( 103 ) along a vertical direction ( 105 ) runs. Vehicle ( 700 ) comprising: a windshield or a window ( 106 ), a rain detection device ( 200 ) according to one of the preceding claims, wherein the light source ( 102 ), the light guide ( 201 ) and the camera ( 101 ) are arranged and configured such that the light cone emitted by the light source ( 202 ) narrowed by the light guide and to an area of the windshield or the window ( 106 ) of the vehicle is diverted. Vehicle ( 700 ) according to claim 10, wherein the rain detection device further comprises a processing unit ( 116 ), wherein the light source ( 102 ), the light guide ( 201 ) and the camera ( 101 ) are arranged and configured such that a first reflection ( 110 ) of the light cone from an inner side ( 107 ) of the windshield or window is reflected to the camera, and wherein the light source ( 102 ), the light guide ( 201 ) and the camera ( 101 ) are arranged and configured such that a second reflection ( 111 ) of the light cone from an outside ( 108 ) of the windshield or window is reflected to the camera, and wherein the processing unit is configured to detect rain based on a change in the camera (s). 101 ) recorded second reflection ( 111 ) of the light cone ( 202 ). Vehicle ( 700 ) according to claim 11, wherein the processing unit for calibrating the rain detection device on the basis of the first reflection ( 110 ) of the light cone ( 202 ) is configured. Vehicle ( 700 ) according to one of claims 10 to 12, wherein the rain detection device ( 200 ) further comprises: a housing ( 114 ), one in the housing ( 114 ) arranged circuit board ( 113 ), the light source ( 102 ) is arranged on the circuit board of the rain detection device and wherein the optical fiber ( 201 ) in an opening ( 115 ) of the housing is embedded. Vehicle ( 700 ) according to one of claims 10 to 13, with the camera ( 101 ) Is part of a driver assistance system of the vehicle, the camera ( 101 ) is further configured to record a driver assistance image, and wherein the light source ( 102 ), the light guide ( 201 ) and the camera ( 101 ) are configured such that reflections of the light cone ( 202 ) on the windscreen or the window ( 106 ) and the driver assistance screen do not overlap. A method of rain detection for a vehicle, the method comprising the steps of: Emitting a cone of light through a light source inside the vehicle (S1), Redirecting the light cone to a portion of a windshield or window of the vehicle through a light guide (S2), Narrows the light cone through the light guide (S3) and Recording an image of the area of the windshield or the window with a camera for rain detection (S4).

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