A system includes a computer including a processor and a memory, the memory storing instructions executable by the processor to actuate a windshield wiper on a vehicle, collect amplitude data and frequency data from a sound of the windshield wiper, and, upon determining that the amplitude data meets a first predetermined threshold and the frequency data meets a second predetermined threshold, actuate a vehicle component to move the vehicle to a specified location.

The invention relates to a wiper device comprising at least one wiper drive (10) which is provided for driving a wiper arm (12) over a wiping region (14) of a vehicle window (16) in a direction-changing manner and comprising at least one control and/or regulating unit (18) which is provided for actuating the at least one wiper drive (10) in order to move the wiper arm (12) between a first wiping region boundary (20) and a second wiping region boundary (22). The wiper device comprises at least one interface (24) which is provided for establishing communication between the control and/or regulating unit (18) and an external end user unit (26), wherein the external end user unit (26) is provided at least for adjusting the first wiping region boundary (20).

The invention relates to a wiper device comprising at least one wiper drive (10) which is provided for driving a wiper arm (12) over a wiping region (14) of a vehicle window (16) in a direction-changing manner and comprising at least one control and/or regulating unit (18) which is provided for actuating the at least one wiper drive (10) in order to move the wiper arm (12) between a first wiping region boundary (20) and a second wiping region boundary (22). The wiper device comprises at least one interface (24) which is provided for establishing communication between the control and/or regulating unit (18) and an external end user unit (26), wherein the external end user unit (26) is provided at least for adjusting the first wiping region boundary (20).

An electric motor includes: brushes (31) that are brought into sliding contact with a commutator of an armature that is fixed to a rotation shaft and feeds electric power; a brush holder stay (33) that supports the brushes (31) via brush holders (41); noise prevention elements (110) that are electrically connected to the brushes (31); and terminals (130) and jump wires (141) that electrically connect between the brush holders (41) and the noise prevention elements (110), wherein first connection portions, which connect between the noise prevention elements (110) and the terminals (130), and second connection portions, which connect between the terminals (130) and the jump wires (141), are both disposed only on a first surface (S1) of the brush holder stay (33).

An electric motor includes: brushes (31) that are brought into sliding contact with a commutator of an armature that is fixed to a rotation shaft and feeds electric power; a brush holder stay (33) that supports the brushes (31) via brush holders (41); noise prevention elements (110) that are electrically connected to the brushes (31); and terminals (130) and jump wires (141) that electrically connect between the brush holders (41) and the noise prevention elements (110), wherein first connection portions, which connect between the noise prevention elements (110) and the terminals (130), and second connection portions, which connect between the terminals (130) and the jump wires (141), are both disposed only on a first surface (S1) of the brush holder stay (33).

A pop-up external lens washing system has an extendable aiming fixture configured to aim a lens cleaning spray at an external lens which is exposed to the elements and apt to become soiled with debris. The extendable nozzle assembly is configured to be aimed toward the external lens by the extended aiming fixture during the washing operation only and has at least one laterally offset washing nozzle projecting from the aiming fixture to a spray washing fluid toward the external lens surface, spraying at a shallow, glancing spray aiming angle to impinge upon and wash the lens external surface.

A self-centering wiper system for an optical device having an optical device body defined by an outer surface with an annular-shaped cross-section disposed along an axis includes an annular-shaped bellows. The bellows is configured to fit externally and concentrically with respect to the outer surface of the optical device body. The bellows has at least one bladder configured to accept a pressurized fluid to thereby extend the annular-shaped bellows along the axis. The wiper system also includes an annular-shaped wiper element fixed to the annular-shaped bellows and configured to wipe contaminants off the outer surface of the optical device body as the at least one bladder accepts the pressurized fluid and the annular-shaped bellows expands along the axis. An optical device having such a self-centering wiper system is also disclosed.

A system includes a first computer including a processor and a memory. The memory stores instructions executable by the processor to receive a message from a second computer indicating one of a cleaning command specifying a sensor and a precipitation condition. If the message does not indicate a precipitation condition, the instructions include instructions to actuate a reservoir pump to clean the sensor specified in the cleaning command. If the message does indicate the precipitation condition, the instructions further include instructions to actuate a windshield wiper.

A pedestrian protecting device according to one aspect of the present invention includes: a right air bag device including a right air bag configured to be deployed at a right region of the windshield; and a left air bag device including a left air bag configured to be deployed at a left region of the windshield. A wiper device includes a right wiper and a left wiper including a turning fulcrum located closer to a middle portion of a vehicle than a turning fulcrum of the right wiper. The right and left air bags and include respective tip end portions that vertically overlap each other at the middle portion of the vehicle. The right air bag of the air bag device is deployed before the left air bag of the air bag device is deployed.

A fog detecting system for a vehicle includes a camera disposed at a vehicle and having a field of view forward of the vehicle, and a non-imaging sensor disposed at the vehicle and having a field of sensing forward of the vehicle. The camera captures image data and the non-imaging sensor captures sensor data. A control includes at least one data processor operable to process image data captured by the camera and sensor data captured by the non-imaging sensor. The control, responsive to processing of image data captured by the camera and processing of sensor data captured by the non-imaging sensor, determines presence of fog ahead of the vehicle and in the field of view of the camera and in the field of sensing of the non-imaging sensor.