With a sensor device for recording moisture on a window pane with a transmitter and a receiver and an optical unit arranged between the transmitter and the receiver, wherein the optical unit includes an optical input unit facing the transmitter, an optical output unit facing the receiver and a coupling-in and coupling-out region on the side of the window pane, the coupling-in and coupling-out region is optically separated from the optical input unit and the optical output unit such that the electromagnetic waves emitted by the transmitter are refracted. A particularly compact constructional design is achieved thereby.

Provided are methods for acoustic emission based device control. Some methods described also include receiving information associated with a first acoustic emission sensor, a second acoustic emission sensor, and a third acoustic emission sensor is received. In embodiments, the information corresponds to an event. In accordance with the first, second, and third acoustic emission sensor information, the first, second, and third timestamps, and a geometry of the surface, a unit vector is calculated from each acoustic emission sensor in the direction of the event's origin. Parameters are calculated based on the unit vectors. Systems and computer program products are also provided.

A composite pane for separating an interior space from an external environment, includes an inner pane, an outer pane with an inner surface, and an intermediate layer that areally joins the inner surface of the outer pane to an outer surface of the inner pane, a capacitive sensor for detecting moisture having at least one capacitor that is connected to an electronic sensor unit, which is provided for detecting a change in capacitance of the capacitor, wherein the capacitor has at least two electrodes formed from a transparent, electrically conductive coating, which are capacitively coupled.

An illustrative example embodiment of a device for detecting rain or a substance on a windshield includes at least one radiation source, an internal reflection sensor situated to detect at least some of a first portion of the radiation that reflects from the windshield. The internal reflection sensor provides a first output that has a characteristic that differs based on whether at least one raindrop is on the windshield. A scattered reflection sensor is situated to detect at least some of a second portion of the radiation reflecting from rain near the windshield or a substance on the windshield. The scattered reflection sensor provides a second output indicative of an amount of radiation incident on the scattered reflection sensor. A processor is configured to determine a condition of the windshield based on the first output and the second output.

In a driving apparatus (10) in which a position of a rotating shaft (27) of an electric motor (16) in a direction of an axis (B1) is determined, the driving apparatus (10) has: a stopper (77) which determines a position of the rotating shaft (27) in the direction of the axis (B1), and a terminal holder (31) which holds a first terminal for supplying an electric current to the electric motor (16), wherein a layout region of the stopper (77) in the direction of the axis (B1) and a layout region of the terminal holder (31) in the direction of the axis (B1) are overlapped with each other.

In a driving apparatus (10) in which a position of a rotating shaft (27) of an electric motor (16) in a direction of an axis (B1) is determined, the driving apparatus (10) has: a stopper (77) which determines a position of the rotating shaft (27) in the direction of the axis (B1), and a terminal holder (31) which holds a first terminal for supplying an electric current to the electric motor (16), wherein a layout region of the stopper (77) in the direction of the axis (B1) and a layout region of the terminal holder (31) in the direction of the axis (B1) are overlapped with each other.

A method for acquiring road data onboard a vehicle, the road data associated with a segment of road is provided. The method obtains, via vehicle onboard sensors, sensor data associated with current weather conditions, current road conditions, and a physical road state; determines whether the current weather conditions indicate existence of severe weather, whether the current road conditions indicate potential slip, and whether the physical road state indicates one or more road anomalies; generates a road data result, based on existence of severe weather, potential slip, and one or more road anomalies; and transmits the road data result, via a vehicle onboard telematics unit.

A camera module for a vehicle vision system for a vehicle includes a camera fixedly disposed at an exterior portion of a vehicle so as to have a field of view exterior of the vehicle. A transparent cover element includes an at least partial cylindrical element that at least partially surrounds the camera with a portion of the transparent cover element disposed in front of a lens of the camera. At least one wiping element engages an exterior surface of said transparent cover element. The transparent cover element is rotatable relative to the camera about a longitudinal axis of the transparent cover element to move portions of the transparent cover element across the at least one wiping element to clean dirt or contaminants from the transparent cover element.

A method for programming a wiper system for operating a vehicle windscreen wiper where a wiper module on the driver's side is programmed as a master module and a wiper module on the passenger's side is programmed as a slave module. The wiper modules include a reversing motor, a gear, a holder, and a control. A program sequence, vehicle-specific characteristic data and data for the operation of the wiper module as master or slave module are stored in the control. The wiper module on the driver's side is connected via an on-board wiring system interface and a first data communication line with a vehicle control unit. Provision is made that before the activation of the wiper module on the driver's side via the first data communication line in its control the wiper module is defined or respectively pre-programmed neither as master module nor as slave module.

A method for programming a wiper system for operating a vehicle windscreen wiper where a wiper module on the driver's side is programmed as a master module and a wiper module on the passenger's side is programmed as a slave module. The wiper modules include a reversing motor, a gear, a holder, and a control. A program sequence, vehicle-specific characteristic data and data for the operation of the wiper module as master or slave module are stored in the control. The wiper module on the driver's side is connected via an on-board wiring system interface and a first data communication line with a vehicle control unit. Provision is made that before the activation of the wiper module on the driver's side via the first data communication line in its control the wiper module is defined or respectively pre-programmed neither as master module nor as slave module.