Provided is a vehicle wiper device including (i) a first motor that includes a first output shaft, that rotates the first output shaft to rotate a wiper arm back and forth about a pivot point of the wiper arm, and that causes a wiper blade coupled to a leading end portion of the wiper arm to perform a back and forth wiping operation between an upper return position and a lower return position on a windshield, (ii) a second motor that changes a wiping range on the windshield by the wiper blade, (iii) a rotation angle detector that detects a rotation angle of the first output shaft, and (iv) a controller that controls the second motor according to a rotation angle of the first output shaft detected by the rotation angle detector in a state in which a broad field of view should be secured on a front passenger seat side.

A sensor cleaning system for a vehicle is disclosed that includes a sensor assembly. The sensor assembly may include a fluid-dispensing nozzle for a vehicle sensor, a housing within a body of a vehicle, and a driving member which can move the nozzle between a stowed position within the housing and a deployed position.

The present disclosure relates to apparatus for controlling operation of a vehicle system. The apparatus includes a processor operable in an automatic mode to output a control signal to automate operation of the vehicle system. The processor is configured to receive a measurement signal from a sensor associated with the vehicle system. The processor outputs the control signal in dependence on a comparison of the measurement signal to a control function. A user override of the automated operation of the vehicle system is detected and the processor re-calibrates the control function in dependence on the detected user override. The present disclosure also relates to a vehicle and to a method of controlling operation of a vehicle system.

The present disclosure relates to apparatus for controlling operation of a vehicle system. The apparatus includes a processor operable in an automatic mode to output a control signal to automate operation of the vehicle system. The processor is configured to receive a measurement signal from a sensor associated with the vehicle system. The processor outputs the control signal in dependence on a comparison of the measurement signal to a control function. A user override of the automated operation of the vehicle system is detected and the processor re-calibrates the control function in dependence on the detected user override. The present disclosure also relates to a vehicle and to a method of controlling operation of a vehicle system.

The present invention relates to a total reflection type rain sensor using a mirror, which is attached to a glass of a vehicle to detect raindrops falling onto the glass of the vehicle and outputs a signal capable of controlling speed and cycle of a wiper of the vehicle according to the amount and falling frequency of raindrops detected.

A vehicular vision system includes a driver-side exterior mirror assembly, a passenger-side mirror assembly and an interior mirror assembly. The fields of view of the mirror reflective elements of the exterior mirror assemblies are adjustable by the driver via a respective actuator. The exterior mirror assemblies include respective cameras that each have a respective rearward field of view that supplements the field of view of the mirror reflective element when viewed by the driver of the vehicle. A video display is disposed behind the mirror reflector of an interior mirror reflective element such that displayed video images are viewable through the mirror reflector of the interior mirror reflective element. The video display includes a driver-side display portion and a passenger-side display portion that each display images derived from image data captured by the respective camera while not displaying images derived from image data captured by the other camera.

A vehicle wiper device and vehicle wiper device control method are provided that are capable of changing a position of a wiping range of a wiper arm in a manner that is less distracting.

When a switch for an enlarged wiping operation has been switched ON, a microcomputer 58 performs control to change the position of a wiping range by starting rotation of an output shaft of a second motor 12 in a predetermined direction when a rotation angle of an output shaft of a first motor 11 has reached an angle corresponding to a position within a predetermined range in the vicinity of one out of a upper return position P1P or a lower return position P2P. Accordingly, when a front passenger seat side wiper blade 36 changes direction at either the upper return position P1P or the lower return position P2P, a front passenger seat side wiper arm 35 begins to extend, and the position of a wiping range of the front passenger seat side wiper blade 36 is moved upward on a front passenger seat side.

A vehicle window wiper system includes a wiper arm having a sliding joint operated by a linear actuator which selectively extends and retract the sliding joint. A controller is configured to cause the linear actuator to selectively extend and retract the sliding joint. A wiper arm rotational position provided to the controller determines whether the wiper arm should be in an extended or a retracted position.

A vehicle window wiper system includes a wiper arm having a sliding joint operated by a linear actuator which selectively extends and retract the sliding joint. A controller is configured to cause the linear actuator to selectively extend and retract the sliding joint. A wiper arm rotational position provided to the controller determines whether the wiper arm should be in an extended or a retracted position.

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.