A remotely operated sun visor includes a first rotational mechanism, a second rotational mechanism, a sun visor body, a controller unit, and a power switch. The first rotational mechanism and the second rotational mechanism are perpendicularly positioned of each other in such a way that the first rotational mechanism is internally positioned along the sun visor body and the second rotational mechanism is internally positioned across the sun visor body. The sun visor body being torsionally connected to the first rotational mechanism so that the sun visor body can be rotated up and down, about an automobile windshield. The sun visor is torsionally connected to the second rotational mechanism so that the sun visor body can be rotated from the windshield to the side windows, about an automobile A-pillar. The first rotational mechanism and the second rotational mechanism are electrically connected to the power switch through the controller unit.

A system includes a computer programmed to detect a first and a second object in received image data, determine a mesh of cells on each of the first and second object surface, upon identifying a cell of the mesh on the first object mismatched to a corresponding cell on the second object to refine the mismatched cell to a plurality of cells, wherein identifying the mismatch is based on a at least one of a mismatch in a color, texture, shape, and dimensions, stop refining the cell upon determining that a refinement of the refined cell of the first object results in a refined cell that is matched to a corresponding refined cell of the second object, and output location data of mismatched cells of the first and second objects. A mismatched cell has at least one of a color mismatch, texture mismatch, and shape mismatch.

An adjustable vehicle visor. The adjustable vehicle visor includes a track securable to a vehicle ceiling, wherein an actuator is slidably disposed within the track. A motor is connected to the actuator and can move the actuator along the track when the motor is actuated. An arm having a longitudinal aperture extending between opposing ends thereof is affixed to the actuator along the longitudinal aperture, such that the arm can rotate about the actuator when the motor is actuated. A visor is pivotally affixed to the arm, the visor having a telescopic panel therein that can selectively move between an extended position and a retracted position. A remote device is in wireless communication with the motor, wherein the remote device can transmit a control signal to actuate the motor.

A remotely operated sun visor includes a first rotational mechanism, a second rotational mechanism, a sun visor body, a controller unit, and a power switch. The first rotational mechanism and the second rotational mechanism are perpendicularly positioned of each other in such a way that the first rotational mechanism is internally positioned along the sun visor body and the second rotational mechanism is internally positioned across the sun visor body. The sun visor body being torsionally connected to the first rotational mechanism so that the sun visor body can be rotated up and down, about an automobile windshield. The sun visor is torsionally connected to the second rotational mechanism so that the sun visor body can be rotated from the windshield to the side windows, about an automobile A-pillar. The first rotational mechanism and the second rotational mechanism are electrically connected to the power switch through the controller unit.

A sun visor connector includes: a bracket; an arm portion having an end inserted through the bracket to be rotatably arranged; a housing fixed to the bracket and arranged in a vicinity of the end of the arm portion inserted through the bracket; a pair of connector terminals accommodated in the housing and connected to counterpart terminals; a pair of arm connection parts provided in an elastically deformable manner on the pair of connector terminals and connected by sandwiching the end of the arm portion by a biasing force; and a preliminary displacement portion provided in the housing, abutting on the pair of arm connection parts, and causing the pair of arm connection parts to be arranged in a separated manner by keeping a biasing force against the end of the arm portion.

A connector terminal for a sun visor includes a body portion accommodated in a housing fixed to one side of an attachment member of a bracket, the bracket configured to be attached to the attachment member, a mating connection portion provided on one end of the body portion and connected to a mating terminal arranged on one side of the attachment member, an arm connection portion provided on the other end of the body portion and connected to an end of an arm portion rotatably supporting a sun visor body arranged on the other side of the attachment member, the end being inserted into the bracket, and a fixed portion provided between the mating connection portion and the arm connection portion of the body portion and fixed to the housing.

A sun visor connector includes: a bracket attached to an attachment member; an arm portion rotatably supporting a sun visor main body and having an end inserted through the bracket to be rotatably arranged; a housing fixed to the bracket and arranged in a vicinity of the end of the arm portion inserted through the bracket; a connector terminal accommodated in the housing and connected to a counterpart terminal; an arm connection part provided in an elastically deformable manner on the connector terminal and connected to the end of the arm portion by a biasing force; an engaging portion including a projecting portion provided in the housing and a recessed portion provided in the bracket and engaged with the projecting portion; and a first restricting portion provided in the projecting portion and pressed against and abuts on the recessed portion in a deformation direction of the arm connection part.

A vehicle sun visor has a sun visor body including an electrical component, an arm including a cylindrical-end portion with contact parts of a pair of conductors and rotatably holding the sun visor body, a mounting bracket for mounting the arm to a vehicle, and a connector including a pair of terminals to contact with a corresponding contact part of the pair of conductors. On the upper side and the lower side of the cylindrical-end portion exposed outside an arm-supporting portion of the mounting bracket, a small-diameter cylindrical-end portion and a large-diameter cylindrical-end portion are provided. The small-diameter cylindrical-end portion and the large-diameter cylindrical-end portion are provided with cutouts provided at alternate positions. First arcuate plate shape contact part is arranged on an outer peripheral surface of the small-diameter cylindrical-end portion, and second arcuate plate shape contact part is arranged on an outer peripheral surface of the large-diameter cylindrical-end portion.

A vehicle includes a ceiling structure for a passenger compartment of the vehicle. The ceiling structure has an opening. The vehicle further includes a sunvisor assembly that is mounted to the ceiling structure. The sunvisor assembly has a panel and a swivel rod received by the opening to attach the panel to the ceiling structure. The swivel rod is movable from a first position to a second position upon receiving a predetermined force to the panel. The second position is a position in which the swivel rod is positioned further into the opening of the ceiling structure than when in the first position.

An adjustable vehicle visor. The adjustable vehicle visor includes a track securable to a vehicle ceiling, wherein an actuator is slidably disposed within the track. A motor is connected to the actuator and can move the actuator along the track when the motor is actuated. An arm having a longitudinal aperture extending between opposing ends thereof is affixed to the actuator along the longitudinal aperture, such that the arm can rotate about the actuator when the motor is actuated. A visor is pivotally affixed to the arm, the visor having a telescopic panel therein that can selectively move between an extended position and a retracted position. A remote device is in wireless communication with the motor, wherein the remote device can transmit a control signal to actuate the motor.