An optical rain sensor including a plurality of light detecting elements and a plurality of peripheral light emitting elements disposed on a printed circuit board (PCB) and surrounding a central light emitting element disposed on the PCB, wherein, in a first mode of operation, the central light emitting element is configured to emit light beams toward the plurality of light detecting elements, and wherein, in a second mode of operation, each of the peripheral light emitting elements is configured to emit light beams toward the plurality of light detecting elements.

An electro-optical assembly, in particular a sensor assembly for detecting ambient light, includes a reflection surface, a lens body and an electro-optical component, in particular a light receiver. The component includes a depression having a main lens section, in particular a diverging lens section with a concave interior wall, and a converging lens section with a convex interior wall. The interior wall of the converging lens section is formed in such a way that the rays of the ray path which travel through the converging lens section to the electro-optical component hit the reflection surface in such way that the angle of incidence at the reflection surface is larger or the same as the critical angle of the total internal reflection at the reflection surface. In another aspect a method for detecting ambient light is described.

A raindrop detection device includes: a front monitoring camera for photographing a front of a vehicle through a windshield of the vehicle; a raindrop detection camera for photographing a raindrop adhering to the windshield; and an electronic control unit disposed away from the windshield, the front monitoring camera, and the raindrop detection camera, performing an image processing on an image data of a front image from the front monitoring camera, and performing an image processing on an image data of a windshield image from the raindrop detection camera.

An outside viewing device for a vehicle, having a camera that is housed in a casing having a frontal wall through which there passes an imaging window, and an internal partition which is parallel to the frontal wall and through which there passes an opening next to the imaging window. In addition, two peripheral wiper seals, disposed at the periphery of the window and the opening, delimit a guide in which a transparent screen slides, in a sealed manner, between at least two imaging positions, in each of which different surface portions of the screen are positioned next to the imaging window. Finally, a device for moving the screen is designed to slide the latter between its different positions.

In certain example embodiments, moisture sensors, defoggers, etc., and/or related methods, are provided. More particularly, certain example embodiments relate to moisture sensors and/or defoggers that may be used in various applications such as, for example, refrigerator/freezer merchandisers, vehicle windows, building windows, etc. When condensation or moisture is detected, an appropriate action may be taken (e.g., actuating windshield wipers, turning on a defroster, triggering the heating of a merchandiser door or window, etc.). Bayesian approaches optionally may be implemented in certain example embodiments in an attempt to improve moisture detection accuracy. For instance, models of various types of disturbances may be developed and, based on live data and a priori information known about the model, a probability of the model being accurate is calculated. If a threshold value is met, the model may be considered a match and, optionally, a corresponding appropriate action may be taken.

A vehicle and a method for controlling a body thereof are provided. The vehicle may include a processor, and non-transitory memory storing instructions executed by the processor. The processor may be configured to determine a first operation mode of a convenience device based on external environment information obtained by a sensor device when converting to an autonomous driving state; determine a second operation mode of the convenience device based on an input of a convenience device manipulator; compare the first operation mode with the second operation mode; and control the convenience device in the first operation mode or the second operation mode based on a comparison result.

In certain example embodiments, moisture sensors, defoggers, etc., and/or related methods, are provided. More particularly, certain example embodiments relate to moisture sensors and/or defoggers that may be used in various applications such as, for example, refrigerator/freezer merchandisers, vehicle windows, building windows, etc. When condensation or moisture is detected, an appropriate action may be taken (e.g., actuating windshield wipers, turning on a defroster, triggering the heating of a merchandiser door or window, etc.). Bayesian approaches optionally may be implemented in certain example embodiments in an attempt to improve moisture detection accuracy. For instance, models of various types of disturbances may be developed and, based on live data and a priori information known about the model, a probability of the model being accurate is calculated. If a threshold value is met, the model may be considered a match and, optionally, a corresponding appropriate action may be taken.

A vehicle and a method for controlling a body thereof are provided. The vehicle may include a processor, and non-transitory memory storing instructions executed by the processor. The processor may be configured to determine a first operation mode of a convenience device based on external environment information obtained by a sensor device when converting to an autonomous driving state; determine a second operation mode of the convenience device based on an input of a convenience device manipulator; compare the first operation mode with the second operation mode; and control the convenience device in the first operation mode or the second operation mode based on a comparison result.

In certain example embodiments, moisture sensors, defoggers, etc., and/or related methods, are provided, More particularly, certain example embodiments relate to moisture sensors and/or defoggers that may be used in various applications such as, for example, refrigerator/freezer merchandisers, vehicle windows, building windows, etc. When condensation or moisture is detected, an appropriate action may be taken (e.g., actuating windshield wipers, turning on a defroster, triggering the heating of a merchandiser door or window, etc.). Bayesian approaches optionally, may be implemented in certain example embodiments in an attempt to improve moisture detection accuracy. For instance, models of various types of disturbances may be developed and, based on live data and a priori information known about the model, a probability of the model being accurate is calculated. If a threshold value is met, the model may be considered a match and, optionally, a corresponding appropriate action may be taken.

An outside viewing device for a vehicle, having a camera that is housed in a casing having a frontal wall through which there passes an imaging window, and an internal partition which is parallel to the frontal wall and through which there passes an opening next to the imaging window. In addition, two peripheral wiper seals, disposed at the periphery of the window and the opening, delimit a guide in which a transparent screen slides, in a sealed manner, between at least two imaging positions, in each of which different surface portions of the screen are positioned next to the imaging window. Finally, a device for moving the screen is designed to slide the latter between its different positions.