WO2023115086A1

WO2023115086A1 - Method for detecting an ambient light condition

Info

Publication number: WO2023115086A1
Application number: PCT/AT2022/060450
Authority: WO
Inventors: Georg BRUNNHOFER; Andreas Klug; Christof LEITGEB
Original assignee: Avl List Gmbh
Priority date: 2021-12-20
Filing date: 2022-12-20
Publication date: 2023-06-29
Also published as: AT525768B1; AT525768A1

Abstract

The invention relates to a method for detecting an ambient light condition in the surroundings of a vehicle, the method comprising the following steps: measuring brightness measurement values of the surroundings of the vehicle using a plurality of, preferably four, photosensors (3) at at least one point in time; calculating at least one measure for the scattering, preferably the standard deviation (s) or the variance, of at least a part of the measurement values of the photosensors (3) at the point in time; detecting an ambient light condition at the point in time on the basis of at least one absolute brightness value base on the brightness measurement values (8a-8d) of the photosensors (3) and the measure.

Description

Method of detecting an ambient light condition

The invention relates to a method for detecting an ambient light condition in the vicinity of a vehicle. US 5,100,000 also relates to a sensor arrangement for mounting on a vehicle and for determining ambient light conditions with a plurality, preferably four, photosensors directed in different directions.

In particular during test drives of vehicles with at least one driver assistance system, it is very important to determine the current ambient light conditions around the vehicle independently of the driver assistance system. Since driver assistance systems usually have a large number of sensors, including optical sensors, the ambient light conditions can be problematic for the function of the driver assistance system. For example, object detection due to backlighting, solar radiation, sudden and strong changes in the level of illumination, for example when entering/exiting tunnel tubes, or constant and rapid changes in light and shadow, for example when driving through forests, can make the measured values of the optical sensors less useful. This can lead to very different data situations in different conditions such as strong sunlight from the front, cloudy sky, driving in a tunnel, etc. During the validation of these driver assistance systems, it is therefore essential that various lighting scenarios are run through and it is also possible to understand when which lighting scenario was present in order to be able to assess the reaction of the driver assistance system and its robustness and subsequently to enable the development of more robust driver assistance systems.

DEO 10 2015 200 583 A1 discloses a method for detecting the ambient light of a vehicle, in which a planar image sensor and a single photocell are provided, and in which the measured values of these components are evaluated and compared in order to check the signals for plausibility. This alone provides insufficient information about the ambient light.

DE 10 2017 000 474 A1 discloses a device for determining the ambient light of a vehicle, with two light sensors being arranged parallel to one another but having different opening angles. In this way, different positions of the sun can be identified. However, the identification of some environmental conditions is still difficult and imprecise.

EP 1 566 654 A2 discloses a sensor unit for a motor vehicle for measuring light with a number of sensor elements. A sensor element is used for this for measuring the light in the direction of travel of the motor vehicle and a sensor element for measuring the light in the vicinity of the motor vehicle.

EP 2 570 964 A2 discloses a method in which an object is illuminated by a headlight of the vehicle and image data from a camera and relative position data from a receiving unit are evaluated together so that the illuminated object can be recognized as self-luminous or as reflective. Again, this gives little information about the ambient light conditions.

US 2014/277939 A1 describes how the current weather and ambient light conditions around the vehicle are determined by recordings by a camera of the vehicle, supported by additional data from GPS, online weather data and the time. The camera is primarily used to check the weather data that is already available and retrieved online. This causes an inexact result. In addition, detection is highly dependent on the quality of the data available online.

A sensor arrangement is presented in US Pat. No. 4,760,772 A, which identifies the position of the sun in relation to the vehicle in order to regulate an air conditioning system accordingly. However, this alone is not sufficient to determine an ambient light condition of the vehicle, since other light sources are not identified. Furthermore, it cannot be determined whether, for example, there is diffuse incidence of light through a cloudy sky.

The object of the invention is therefore to provide a method for detecting ambient light conditions in the vicinity of a vehicle and a sensor arrangement for mounting on a vehicle and for determining ambient light conditions, which enables the ambient light condition to be detected exactly and as independently as possible.

This object is achieved according to the invention in that the method according to the invention comprises the following steps:

measurement of brightness values of the area surrounding the vehicle using a plurality of, preferably four, photo sensors at at least one point in time;

Calculation of at least one measure for the scatter, preferably the standard deviation or the variance, of at least part of the measured values of the photo sensors at the point in time; detecting an ambient light condition at the time based on at least one absolute brightness value based on the brightness readings of the photo sensors and the metric.

The dimension can be calculated, for example, by means of a calculation unit.

The measure therefore indicates how much the measured values of the different photo sensors deviate from each other, i.e. how scattered they are.

Provision can be made for the sensor arrangement to have three photosensors which are directed in different directions. As a result, the exact position of a light source can already be determined by triangulation.

It is also achieved in that the sensor arrangement has a calculation unit connected to the photosensors for calculating at least one measure of the scatter, preferably the standard deviation or the variance, from at least some of the measured brightness values of the photosensors, and that the sensor arrangement has a calculation unit connected to the calculation unit Has a detection unit, which is designed to detect an ambient light condition on the basis of at least one absolute brightness value based on the measured brightness values of the photo sensors and the index.

By including the absolute brightness value and at the same time the measure for the scattering, it is surprisingly possible to determine exactly what lighting conditions the vehicle's sensors are exposed to. If the incidence of light is diffuse, for example when it is very cloudy, the measured values are in a narrow range. On the other hand, when there is strong radiation from a certain side, i.e. when there is strong solar radiation or a strong, artificial, point light source, the brightness value of at least one photo sensor is higher than that of at least a second one. This is due to the different position and possibly also alignment of the photo sensors to the light source. In this way, the current ambient light conditions can also be recognized in real time. Rapid changes in the ambient light conditions are also easily recognizable. The detection of the ambient light condition can also include the identification of one or more light sources and/or the type of these light sources, for example the sun, street lights or vehicle lights of other vehicles.

For improved differentiation of the ambient light conditions and/or identification of a light source, the spectral light components can preferably also be distinguished, preferably between ultraviolet (UV), visible (Vis) and infrared (IR) light components. This allows diffuse Distinguish lighting conditions such as heavy cloud cover from, for example, shady conditions in otherwise sunny conditions.

The recognition unit and the calculation unit can also be implemented together, for example in a common microcontroller or common computer system. In this case, the recognition unit can also be connected directly to the photosensors or can receive measured brightness values of the photosensors in processed or unprocessed form via the calculation unit.

Photo sensors are any type of sensors that can convert the characteristics of light falling on the sensor into a signal that can be processed, preferably an electrical signal. This can be, for example, a simple photodiode, a diode array, a camera, or also large-area photosensitive elements on rigid or flexible carrier materials, structures or mats, so-called large-area (flexible) electronics units. Provision can also be made for a single sensor element, for example a sensor foil, to be provided, with this sensor element having a plurality of measuring areas which supply measured values which are independent of one another. In this case, these measuring ranges correspond to the photo sensors.

The measured brightness value can be the illuminance, measured in lux, and/or the light intensity and/or another physical variable or a combination of these variables that characterizes the light falling on the vehicle from a specific direction.

Several dimension numbers and/or several absolute brightness values can also be calculated and included in different combinations for recognition.

On the one hand, the ambient light conditions can be weather conditions, ie, for example, bright sunshine, cloudy situations during the day, sunrise or sunset, or no solar radiation during the nighttime. On the other hand, the ambient light conditions can also be caused by other factors of the environment or traffic, for example low lighting due to driving in a tunnel, repeated strong changes in the frontal lighting when driving overland at night and oncoming traffic, area-specific illumination by street lighting, etc.

The photo sensors are preferably arranged outside the vehicle and/or are at least directed outwards.

In this case, at least some of the measured brightness values and/or the differences in at least some of the measured brightness values at the point in time can be used as absolute Brightness values are included in the detection of an ambient light condition.

It can preferably be provided that the measure for the scattering is essentially invariant to a rotation of the photo sensors about a vertical axis of the vehicle. Thus, the measure remains essentially unchanged when the vehicle rotates about its vertical axis, even if the sun or another strong light source shines from a certain direction. The exact position of the light source can be calculated from the absolute brightness readings, while the metric can be used to identify other conditions such as cloudiness.

The vertical axis means an axis of the vehicle which runs vertically when the vehicle is level, ie which is essentially transverse to the wheel plane. The wheel plane means a substantially horizontal plane when the vehicle is intended to be lying on a level surface and the wheels are on the same plane, the wheel plane.

Furthermore, it can be provided that the mean value of at least part of the measured values of the photo sensors is calculated and used as an absolute brightness value for detecting an ambient light condition. The measured values from a selection of the photo sensors can be used. Provision can also be made for the measured values of at least one specific wavelength and/or at least one specific wavelength spectrum to be used to calculate the mean value. It can also be advantageous for the measured values from specific points in time to be used to calculate the mean value. The mean value can be calculated easily and quickly and is a good indicator for estimating the absolute overall brightness. It thus enables a subdivision of the ambient light condition on the basis of typical illuminance levels, but also an initial assessment of the type of light source and its current state, e.g. street lighting, the sun on a clear sky and the sun on a cloudy sky.

Provision can also be made for a measured, absolute brightness value measured by a photosensor, preferably the highest brightness value measured at the time, to be used as the absolute brightness value for detecting an ambient light condition. This means that no or only insignificant calculation or filtering of the measured value is necessary for use, which is particularly fast. The highest brightness value measured best reflects the brightness of the strongest light source, allowing it to be accurately identified. It is particularly advantageous if the photo sensors point in different directions. Thus, the measurement of brightness values of the surroundings of the vehicle can be carried out with several photo sensors from several, preferably four, different directions. This causes large differences in the brightness readings when light is emitted from a specific direction, making it easier to identify the ambient light condition. In the case of strong solar radiation or a strong, artificial, point light source, the brightness value of the photosensors directed towards the source is significantly higher than those that are further away or inclined from it. This simplifies the detection of the ambient light condition and in particular the detection and positioning of light sources and leads to higher accuracy. This also applies if it is provided that the photo sensors of the sensor arrangement are at least partially directed in different directions and the further photo sensor is preferably directed in a different direction than the photo sensors. If the additional photosensor is directed in a different direction than the photosensors, the information content is expanded in that information that is not partially redundant is recorded between at least one photosensor and the additional photosensor.

Provision can also be made for the photo sensors to point at least partially, preferably at least predominantly, in the same direction, or for the photo sensors of the sensor arrangement to be directed at least partially, preferably at least predominantly, in different directions. This results in an embodiment that is as flat as possible, which, for example, can also be arranged particularly easily on a vehicle roof. The different irradiation angles of the photosensors by the light sources can be sufficient to generate differences in the measured brightness values, which make it possible to recognize the ambient light condition.

In order to achieve an image of the ambient brightness that is as exact as possible, it can be provided that at least two, preferably four, photosensors are arranged essentially rotationally symmetrically around a vertical axis of the vehicle. Preferably, one photo sensor points in the direction of travel, one against the direction of travel and one photo sensor each to the left and right. The same also applies if the photosensors are arranged in a sensor unit and are preferably arranged essentially rotationally symmetrically about a vertical axis of the sensor unit. In this case, the sensor unit can require a compact form which can be easily mounted on a vehicle, for example on the roof of the vehicle. The sensor unit can also be designed as a sensor housing or can include a sensor housing. In a preferred embodiment, it is provided that a detection unit receives at least the absolute brightness value and the metric, and compares the absolute brightness value and the metric with value ranges of stored, categorized ambient light conditions to identify the ambient light condition. Provision can preferably also be made for the detection unit to select that stored ambient light condition for the point in time whose pre-stored values best match those of the measured ones.

As a rule, at least one value range for the absolute brightness value and one for the standard deviation is stored for each ambient light condition. If both measured values fall within the range, it is recognized that the relevant ambient light condition is present. In this way, the prevailing ambient light condition can be divided into a defined category, for example "strong sunshine" (high mean value with high standard deviation), "shady driving condition" (low mean value with medium-high standard deviation), or "minimal lighting" (very low mean value with low standard deviation). ). In the future, these processes can also be automatically carried out with finer categorization by means of self-learning, self-calibrating and/or self-adapting systems.

In this way, a categorization of the ambient light condition can be carried out very easily and quickly, and each examined point in time can be assigned to a category. This enables simple and quick processing and assessment of a test drive. These stored ambient light conditions can be stored in a database or in a data store, which can be connected to the detection unit.

In order to obtain a more precise result, it can be provided that further measurement data, preferably the time in the area of the vehicle, the position of the vehicle, particularly preferably the GPS position, and/or the location and/or geographic orientation of the vehicle, are used in the detection of the ambient light conditions are taken into account. For this purpose it can be provided that the sensor arrangement has a locating device, preferably a GPS locating device, and/or a clock and/or at least one position sensor or a compass. The other measurement data does not necessarily have to be measured by the vehicle itself. For example, the time can be queried via wireless transmission from a clock that is further away, for example an atomic clock, or can come from GPS data. The position of the vehicle means the inclination along the longitudinal and/or transverse axis of the vehicle, i.e. the pitch or roll angle. The measured values of the photo sensors can be combined with the respective further data. On the one hand, this allows the ambient light conditions to be better determined, for example by including the prevailing time and possibly also the date of the observation in the assessment of the light sources. On the other hand, the detected ambient light condition can also be assigned to a location or a time, thus facilitating further processing or analysis after the journey. Here, too, support can be provided by self-learning systems.

Furthermore, it can be provided that at least one additional photo sensor, which is essentially directed in the direction of travel of the vehicle, measures at least one measured brightness value at the at least one point in time and this measured brightness value is included in the detection of an ambient light condition. This is particularly advantageous for recognizing backlight situations or other lighting situations caused by other road users, since these are particularly difficult for visually-based driver assistance systems to cope with. The same also applies if the sensor arrangement has a further photosensor, which is designed to be attached in the direction of travel of the vehicle. The sensor arrangement can also have a further photosensor, which is designed to be attached in the opposite direction to the direction of travel of the vehicle. It is preferably provided that the further photo sensor is arranged in the area of a photo sensor of the driving assistance system.

In this sense, it is particularly advantageous if the additional photosensor is spaced apart from the sensor unit. For example, the additional photosensor can be arranged in the area of the hood, while the sensor unit can be arranged on the roof of the vehicle. The additional photo sensor can be connected to the other parts of the sensor arrangement by cable or wirelessly, for example by radio, Bluetooth or wireless LAN.

In order to achieve a particularly good result with regard to the backlight situation, it is preferably provided that the further photo sensor is essentially parallel to a vertical axis of the vehicle.

Furthermore, it can be provided that the change in the absolute brightness value and/or the dimension number between a number of points in time is included in the detection of the ambient light condition at a specific point in time. This is particularly useful when the light changes rapidly and these indicate a specific light situation, for example driving into or out of a tunnel in bright sunshine. In order to achieve an even more precise detection of the ambient light condition, it is advantageous if at least one of the photo sensors, preferably all photo sensors, determines measured brightness values for at least two different wavelengths or wavelength ranges of the light and particularly preferably if all photo sensors determine measured brightness values for the same wavelengths or wavelength ranges of the light . In this way, different light sources, which have different characteristic spectra, can be distinguished from one another. In addition, conclusions can be drawn about the cloudiness status, for example, since the sun's spectrum changes due to cloudiness. Furthermore, it is clearly possible to distinguish, for example, shadow situations from general cloud cover. The same also applies if it is provided that measured brightness values for at least two different wavelengths of light can be measured by at least one photosensor, preferably at least all four photosensors.

In this sense, it is particularly advantageous if at least one of the photo sensors, preferably all photo sensors, measures at least one brightness measurement value each in the infrared range, in the ultraviolet range and in the visible light range. As a result, information about the light source or light sources can be recorded in a particularly simple and comprehensive manner and light sources can be differentiated from one another and/or identified, but also the ambient light conditions. The same also applies if it is provided that the photo sensors, preferably at least all four photo sensors, comprise at least one infrared sensor, one ultraviolet sensor and one sensor for visible light.

In a preferred embodiment it can be provided that the relative position of at least one light source, preferably at least the sun, to the vehicle is determined from the measured brightness values of the photo sensors. This can help to identify the lighting situation, since, for example, a low-lying sun provides strong backlight in the direction of travel, while driving in the opposite direction, i.e. away from the sun, puts a different load on the sensors of the driver assistance system.

Provision can preferably be made for the invention to include the calculation of the luminance of at least one light source. This is particularly possible when a large number of photo sensors are available.

The position of the photosensors to those of the sun on the horizon in the part of the world in which the invention is carried out will be ideally adjusted. For example, an arrangement at an angle of approximately 47° is particularly advantageous when used in Central Europe, since as much sunlight as possible falls on the sensors in this way. The same also applies if the sensor unit has at least one main contact surface for resting on the vehicle and at least one photo sensor of the sensor unit points away from the main contact surface and at an angle of between 10° and 70°, particularly preferably between 25° and 55°, very particularly preferably between 40° and 50°.

The horizontal plane is a plane which is horizontal when the vehicle is arranged on a level surface. So it corresponds to or is parallel to the wheel plane of the vehicle and is normal to the vertical axis of the vehicle.

The invention also relates to a vehicle, in particular partially or fully autonomous vehicles, with at least one driver assistance system (ADAS, Advanced Driver Assistance System'), the ADAS having at least one photosensor and the vehicle having a sensor arrangement according to the invention in addition to the ADAS. As a result, the ambient light condition can be recognized easily and quickly while driving the vehicle, preferably a passenger car, at any point in time during the journey. The sensor arrangement or at least the photo sensors are preferably arranged on the roof and/or the hood of the vehicle. Usually the photo sensor of the ADAS is a camera. The term vehicle is to be understood broadly, it can also be a rail vehicle such as a train, a watercraft such as a ship, an aircraft such as a helicopter or airplane, or another vehicle.

It can be provided that the further photo sensor points essentially in the direction of travel of the vehicle and is preferably located in the area of the at least one photo sensor of the ADAS. This enables particularly good detection of light falling on the vehicle from the front.

Furthermore, it can be provided that the measurement of a measured brightness value of the surroundings of the vehicle at the time is provided by a sky light photo sensor, and that the sky light photo sensor is shielded from direct solar radiation. Correspondingly, provision can also be made for the sensor arrangement to have at least one skylight photosensor, which is shielded from direct solar radiation. Such shielding can be achieved, for example, by means of a corresponding cover, or by directing the skylight photosensor in the direction of the underground, with a light-reflecting surface preferably being arranged opposite the skylight photosensor in this case. With such a skylight photosensor, the indirect, diffuse sunlight that has been scattered by the atmosphere, the so-called skylight, can be better determined. This can occur with a clear sky in combination with direct sunshine as well as without direct sunshine, for example when it is cloudy. This makes it easier to distinguish shadow conditions from cloudy skies.

Furthermore, it can be advantageous that at least two photosensors are designed as a common sensor film, which have at least two sensor areas that are preferably directed in different directions. All photo sensors are preferably designed as a common sensor film. Such sensor foils generally have a very large number of individual photosensors, which are usually arranged in a matrix-like manner. This sensor film can be essentially flat, at least in sections, so the photo sensors can be directed in essentially the same direction, at least in sections. An ambient light condition can thus be detected on the basis of the intensity differences of the brightness measurement values of the photo sensors. Provision can also be made for the sensor film to be essentially bent, at least in sections. In other words, it can therefore be provided that the photo sensors of the sensor film are essentially directed in different directions, at least in sections. In this way, a large amount of information can be collected from a wide variety of directions. For example, it can be provided that the sensor film is bent in at least one direction of extension. For example, the sensor film can be made hemispherical. In this way, the positions of light sources can be determined even more precisely. In a flat embodiment of the film in particular, it is advantageous if the sensor film is aligned essentially parallel to a horizontal plane of the vehicle and points away from the vehicle, preferably points upwards, i.e. points away from the base of the vehicle in the intended use position.

The invention is further explained in more detail using non-restrictive embodiments according to the invention. Show it :

1a shows a sensor arrangement according to the invention in a schematic oblique view in one embodiment;

1b shows part of a section through a sensor arrangement according to the embodiment, arranged on a vehicle roof;

FIG. 2 shows part of the sensor unit of the sensor arrangement in FIG. 1 in a plan view; FIG. 3 shows a diagram of the measured brightness values over time during a test drive and the calculated mean values and standard deviations compared to this.

1a shows a sensor arrangement 1 with a sensor unit 2 on which four photosensors 3 are arranged. In this case, two photosensors 3 are opposite each other at a 90° angle to the other two photosensors. The photo sensors are thus arranged in a rotationally symmetrical manner about a vertical axis A of the sensor unit 2 . In this case, the vertical axis A is oriented normal to a main bearing surface 4 of the sensor unit, which is used for attaching the sensor arrangement

1 on the vehicle is used. As a rule, the vertical axis of the vehicle then corresponds to that of the vertical axis A or is at least parallel to it.

The photo sensors 3 are inclined at an angle 5 of 47° in relation to the main bearing surface 4 and point away from the center of the sensor unit 2 . Thus, the photo sensors 3 are all pointing away from each other and in different directions. The sensor arrangement has a cable 6 for the power supply. In an alternative embodiment, the sensor unit 2 can be connected via the cable 6 to a further sensor that is not arranged in the sensor unit 2 . Alternatively or additionally, it can be provided that the sensor unit 2 has an energy store such as a battery, which supplies it with energy.

1b shows a section through the sensor arrangement 1, it being clearly visible that the photosensor 3 is on a sloping side face of the sensor unit

2 is arranged and thus at an angle 5 to a transverse axis of the vertical axis A is. Thus, the photo sensor 3 is oriented to the altitude of the sun in Europe and North America. Depending on the place of use, this angle can be varied.

In Fig. 2 shows a support part 2e of the sensor unit 2, on which the photosensors

3 (not shown in Fig. 2) are arranged. For this purpose, the support part 2e has four receiving surfaces 2a-2d, each of which is pivoted by 90° about the vertical axis A relative to its adjacent receiving surfaces 2a-2d. When light falls on the sensor arrangement from a direction 7, the photosensor 3 on the bearing surface 2b is irradiated the most and will deliver the highest measured brightness value. The photosensor 3 on the supporting surface 2a is irradiated more weakly and those on the supporting surfaces 2c and 2d even weaker. In this way, the direction of the light can be determined from the measured brightness values. The sensor arrangement 1 is preferably mounted on the vehicle in such a way that the photosensor 3 on the contact surface 2a is directed in the direction of travel and that on the contact surface 2c is directed counter to the direction of travel. In FIG. 3, the measured brightness values of the sensor arrangement from the previous figures are shown as illuminance in lux over time in seconds. Below this is the calculated mean value m of all four measured brightness values and the associated standard deviation s around the mean value m, in a separate diagram for a better overview. The photo sensor 2 directed in the direction of travel supplies the measured brightness value 8a, the photo sensor 2 directed to the left supplies the measured brightness value 8b, the photo sensor 2 directed in the opposite direction of travel supplies the measured brightness value 8c, and the photo sensor 2 directed to the right supplies the measured brightness value 8d. In a first driving phase 9a, strong value changes can be seen in the mean value m and in the standard deviation s. This suggests movement in strong sunshine through an area where the sun is consistently obscured by objects such as tall buildings. In a second driving phase 9b, the mean value m and the standard deviation s are very high. This occurs in strong sunshine and clear skies. In a third driving phase 9c, the mean value m and the standard deviation s are minimal. This indicates a tunnel journey, especially in combination with a time when sunshine can be expected. In a fourth driving phase 9d, the mean value m is at a low level and the standard deviation s is also very low. This can be interpreted as driving during the day under very cloudy skies or shadows cast by objects such as houses.

Claims

P A T E N T C A L I M A G A method for detecting an ambient light condition in the vicinity of a vehicle, the method comprising the steps of:

measurement of brightness values of the surroundings of the vehicle with a plurality, preferably four, photo sensors (3) at at least one point in time;

Calculation of at least one measure for the scatter, preferably the standard deviation (s) or the variance, of at least part of the measured values of the photo sensors (3) at the point in time;

Detection of an ambient light condition at the point in time on the basis of at least one absolute brightness value based on the measured brightness values (8a-8d) of the photo sensors (3) and the index. Method according to Claim 1, characterized in that the measure for the scattering is essentially invariant to a rotation of the photo sensors (3) about a vertical axis of the vehicle. Method according to Claim 1 or 2, characterized in that the mean value (m) of at least part of the measured values of the photo sensors (3) is calculated and used as an absolute brightness value for detecting an ambient light condition. Method according to one of Claims 1 to 3, characterized in that a measured, absolute brightness value (8a-8d) of a photo sensor (3), preferably the highest brightness value (8a-8d) measured at the time, is used as the absolute brightness value for detecting a Ambient light condition is used. Method according to one of Claims 1 to 4, characterized in that the photosensors (3) point in different directions. Method according to one of Claims 1 to 5, characterized in that at least two, preferably four, photosensors (3) are arranged essentially rotationally symmetrically around a vertical axis of the vehicle. Method according to one of Claims 1 to 6, characterized in that a categorization unit receives at least the absolute brightness value and the index and, to identify the ambient light condition, compares the absolute brightness value and the index with value ranges of stored, categorized ambient light conditions. Method according to one of Claims 1 to 7, characterized in that further measurement data, preferably the time in the area of the vehicle, the position of the vehicle, particularly preferably the GPS position, and/or the location and/or geographic orientation of the vehicle be included in the detection of the ambient light condition. Method according to one of Claims 1 to 8, characterized in that at least one further photo sensor (3), which is directed essentially in the direction of travel of the vehicle, measures at least one measured brightness value at the at least one point in time and this measured brightness value is included in the detection of an ambient light condition becomes. Method according to claim 9, characterized in that the further photo sensor (3) is essentially parallel to a vertical axis of the vehicle. Method according to one of Claims 1 to 10, characterized in that the change in the absolute brightness value and/or the measure between a number of points in time is included in the detection of the ambient light condition at a specific point in time. Method according to one of Claims 1 to 11, characterized in that at least one of the photo sensors (3), preferably all photo sensors (3), determines measured brightness values for at least two different wavelengths or wavelength ranges of the light and particularly preferably that all photo sensors (3) measured brightness values for the same wavelengths or wavelength ranges of light. Method according to Claim 12, characterized in that at least one of the photo sensors (3), preferably all photo sensors (3), measures at least one brightness measurement value each in the infrared range, in the ultraviolet range and in the visible light range. Method according to one of claims 1 to 13, characterized in that the relative position of at least one light source, preferably at least the sun, to the vehicle is determined from the measured brightness values of the photo sensors (3). Method according to any one of Claims 1 to 14, characterized in that the photosensors (3) are arranged inclined in relation to a horizontal plane of the vehicle and preferably at an angle of between 10° and 70°, more preferably between 25° and 55° entirely are particularly preferably arranged between 40 ° and 50 °. - 16 - Sensor arrangement (1) for mounting on a vehicle and for determining ambient light conditions with several, preferably four, photo sensors (3), characterized in that the sensor arrangement (1) has a calculation unit connected to the photo sensors (3) for calculating at least one Measure for the scatter, preferably the standard deviation (s) or the variance, from at least a portion of the measured brightness values of the photosensors (3), and that the sensor arrangement (1) has a detection unit connected to the calculation unit, which is used to detect an ambient light condition on the basis of at least one absolute brightness value based on the measured brightness values of the photo sensors and the index. Sensor arrangement (1) according to Claim 16, characterized in that the sensor arrangement (1) has a further photosensor which is designed to be attached in the direction of travel of the vehicle. Sensor arrangement (1) according to Claim 16 or 17, characterized in that the photosensors (3) are arranged in a sensor unit (2) and are preferably arranged essentially rotationally symmetrically about a vertical axis (A) of the sensor unit (2). Sensor arrangement (1) according to Claim 18, characterized in that the further photosensor is spaced apart from the sensor unit (2). Sensor arrangement (1) according to one of Claims 16 to 19, characterized in that measured brightness values for at least two different wavelengths of light can be measured by at least one photosensor (3), preferably at least all four photosensors (3). Sensor arrangement (1) according to claim 20, characterized in that the photo sensors (3), preferably at least all four photo sensors (3) comprise at least one infrared sensor, one ultraviolet sensor and one sensor for visible light. Sensor arrangement (1) according to one of Claims 16 to 21, characterized in that the sensor unit (2) has at least one main bearing surface (4) for lying on the vehicle and at least one photosensor (3) in the sensor unit (2) from the main bearing surface (4 ) points away and is at an angle (5) of between 10° and 70°, more preferably between 25° and 55°, most preferably between 40° and 50°. Sensor arrangement (1) according to any one of claims 16 to 22, characterized in that at least two photosensors (3) as a common - 17 -

Sensor film are designed, which have at least two sensor areas, which are preferably directed in different directions.

24. Sensor arrangement (1) according to one of claims 16 to 23, characterized in that the photo sensors (3) are at least partially directed in different directions and the further photo sensor is preferably directed in a different direction than the photo sensors (3).

25. Vehicle with at least one driver assistance system (ADAS, Advanced Driver Assistance System), the ADAS having at least one photo sensor, characterized in that the vehicle has a sensor arrangement (1) according to one of claims 16 to 24 in addition to the ADAS.

26. Vehicle according to claim 25, characterized in that the further photo sensor of the sensor arrangement (1) points essentially in the direction of travel of the vehicle and is preferably in the region of the at least one photo sensor of the ADAS.

2022 12 20

MT