The present invention is intended to encourage a driver to visually recognize a direction from the side and rear of a vehicle and requiring visual recognition by the driver at a complicated intersection. A side and rear reflection controller of the present invention includes: a geometry recognition unit that recognizes the geometry of an intersection having same direction entry lanes; a position recognition unit that recognizes the position of the own vehicle relative to the intersection; a visibility direction setting unit that sets a part from the side and rear of the own vehicle as a recommended visibility direction on the basis of the position of the own vehicle relative to the intersection and the same direction entry lanes; and a control unit that controls the side and rear reflection display device so as to present an image in the recommended visibility direction to the driver.

An image display control device displays, on a monitor, images of the periphery of a vehicle that are captured by a left camera and a right camera installed in the vehicle. The device includes: a vehicle detection unit which detects another vehicle from the images captured by the left camera and the right camera; an enlargement unit which, when the other vehicle is detected by the vehicle detection unit, subjects the images captured by the left camera and the right camera to enlargement processing on the basis of a delay time the images take to be displayed on the monitor; and an output unit which outputs the images subjected to the enlargement processing by the enlargement unit to the monitor.

A support assembly for a mirror head includes a support arm defining a longitudinal axis. A top slot wall and a bottom slot wall of the support arm extend at least partly along the longitudinal axis and at least partly define a slot therebetween. The top slot wall defines an opening therethrough. A ramp extends from the bottom slot wall towards the top slot wall adjacent to the opening. The support assembly further includes inboard and outboard trunnions that are adapted to be at least partly and movably received in the slot. A carriage is coupled to the outboard trunnion and the mirror head. A support brace is rotationally coupled to the inboard and outboard trunnions. The outboard trunnion selectively travels on the ramp and through the opening to allow the support brace to be inclined obliquely relative to the longitudinal axis and the carriage to be rotated.

An exterior mirror assembly for a vehicle includes an arm having a proximal end coupled with a vehicle door and a distal end. A mirror assembly is coupled to the arm. The mirror assembly includes an electro-optic element. The mirror assembly is rotatable about the distal end between first and second positions. An imager is disposed proximate to the distal end and configured to capture image data within a blind spot zone of said vehicle

The present invention provides an inner rear-view device for a vehicle that includes a stay, a pivot, a bracket, a housing, a knob, a rear-view unit, a switching mechanism, a fixed engagement section, an elastically-engaged section, an elastically-deformed section, and a suppressing section. The inner rear-view device for the vehicle can adjust angles of a screen and the like and prevent movement of a knob at the time of angle adjustment of the screen and the like even when pivot torque is increased by a magnitude that corresponds to an increase in masses of the housing and the like.

Systems and methods to improve safety and more efficient Advanced Driver Assistance Systems (ADAS) and autonomous vehicle (AV) systems for vehicular operation through the application of multiple thermal sensors arranged in systems where the resolution, Field Of View (FOV), and aiming angle of individual sensors are varied. In particular two configurations are discussed in detail, a three-sensor arrangement for forward and forward off angle data acquisition, and a two or three sensor arrangement for blind spot and pinch point awareness for towing applications. In some forward-looking three-sensor embodiments, the center sensor may provide a high-quality narrow field of view of radiometric data for use with tracking algorithms to identify pedestrian and large animal targets for long range driver identification. The side sensors may provide radiometric data for peripheral vision on short/medium range approaching targets for situational awareness at crosswalks and turning corners.

In general, techniques are described by which a computing system dynamically and automatically adjusts an orientation of one or more mirrors of a vehicle. A computing system includes at least one processor and memory. The memory includes instructions that, when executed, cause the at least one processor to determine a current orientation of a mirror of a vehicle and determine a preferred orientation of the mirror based upon a set of data points. Execution of the instructions also causes the at least one processor to output a command to adjust the mirror to the preferred orientation in response to determining the current orientation is not the preferred orientation.

An interior rearview mirror assembly includes a mounting structure configured for mounting at an interior portion of a vehicle. A distal end portion of the mounting arm is at an angle relative to a proximal end portion of the mounting arm at the interior portion of the vehicle. An attaching element is fixedly disposed at the distal end portion. A mirror housing includes an aperture, and the mounting arm of the mounting structure passes through the aperture without making contact with the mirror housing. A reflective element is attached at an attachment plate disposed within the mirror housing. A motorized actuator is mounted at the attachment plate at the reflective element or at the attaching element at the distal end portion of the mounting arm. The motorized actuator is electrically operable to adjust the reflective element and the mirror housing together and in tandem relative to the mounting structure.

A mirror assembly includes a housing. The assembly additionally includes a reflective body secured to the housing and having a rigid portion and a flexible portion. The assembly also includes an actuator operably coupled to the flexible portion. The actuator is configured to move the flexible portion between a first curvature relative to the rigid portion and a second curvature relative to the rigid portion. The assembly further includes a controller in communication with the actuator. The controller is configured to, in response to an operating condition being satisfied, control the actuator to move the flexible portion from the first curvature to the second curvature.

A vehicle, system and method of adjusting a mirror of a vehicle. A system for adjusting a mirror of a vehicle is disclosed. The system includes a calibration a calibration marker disposed on the vehicle, a camera, a motor and a processor. The calibration marker forms a calibration image onto a face of an occupant of the vehicle via reflection through the mirror. The camera obtains a camera image including the calibration image and the face of the occupant. The processor determines from the camera image an initial location of the calibration image at the face, determines a calibrated setting of the mirror that places the calibration image at a calibration location, and operates the motor to adjust the mirror to the calibrated setting.