The invention relates to a motor vehicle instrument cluster, comprising a digital display screen which is intended to be hidden from the vehicle passengers and capable of displaying a source image containing a multitude of indicator modules for the driver of the vehicle, and a panel (20) located below the digital display screen, at least the main central (20A) and upper (20B) portions of said panel being opaque and reflective, the panel (20) being inclined relative to the display screen so as to reflect the source image towards the driver so that the latter perceives, in his/her field of vision, a virtual image located in front of the panel (20), characterized in that the lateral (20C) and lower (20D) portions of the panel (20) are transparent.

An optical imaging lens including an optical lens assembly with an optical axis, a lens barrel and a conductive element is disclosed. The optical lens assembly includes a plurality of lenses. The lens barrel includes an inner wall surface and a heating film, wherein the inner wall surface surrounds the optical axis and is made of electrical insulating material, and the heating film is formed on the inner wall surface. The optical lens assembly is disposed in the lens barrel in order from an object side to an image side. An edge of at least one lens of the optical lens assembly contacts the heating film. The conductive element is extended along the inner wall surface of the lens barrel, and is electrically connected to the heating film. One terminal of the conductive element is connected to an external power supply.

The invention concerns a vehicle camera system (2), comprising a camera (8) comprising a camera lens (80), a movable shutter (10) for protecting the camera lens when the camera is not used, and an integrated lens cleaning mechanism, comprising at least one cleaning liquid nozzle (12) that is part of the shutter (10). The integrated lens cleaning mechanism further includes a collector (14) for collecting used cleaning liquid dripping off the camera lens (80).

The present disclosure provides a lens module including a lens assembly and a lens holder; the lens assembly including a lens barrel and an optical assembly accommodated in the lens barrel; the lens holder including an accommodation portion having an accommodation space; the lens assembly being at least partially accommodated in the accommodation space; the lens holder having a support portion that extends into the accommodation space in a direction of an optical axis of the optical assembly and is disposed on an image side of the lens barrel; the lens module further including a sealing ring disposed on the support portion; and the lens barrel pressing the sealing ring to the support portion to achieve sealing between the lens barrel and the accommodation portion. The present disclosure prevents contaminants such as particles and liquid from entering the lens barrel to contaminate the optical assembly and the optical filter.

A object detection apparatus may include: an object detection sensor having a cover for protecting the object detection sensor from foreign matter, and configured to sense a target object by transmitting a scan signal to the target object and receiving a sensing signal reflected from the target object; a protection film part including a protection film disposed on an outer surface of the cover to prevent contamination of the cover by foreign matter; and a control unit configured to replace the protection film disposed on the outer surface of the cover through a winding operation for the protection film part when a protection film replacement condition is satisfied due to contamination of the protection film, in order to prevent a reduction in sensing performance of the object detection sensor due to contamination by foreign matter.

This disclosure relates to the minimally invasive medical technical field, and specifically, to a device of anti-fogging endoscope system including a beam of a near-infrared light for anti-fogging, which is coupled into an endoscope imaging optical channel in combination coaxially and is transmitted to the front optical window sheet, the visible light passes through the front optical window sheet, and the near-infrared light is absorbed by the absorption characteristics of the front optical window sheet to raise the temperature of the front optical window sheet. The device is also provided with a cut filter for eliminating the impact on image quality caused by the near-infrared stray light, so that the illumination light source of the prior-art endoscope is not necessary to be changed. It is suitable to integrate the coaxial coupling module with a camera handle or adapter and is more convenient to operate the device.

A sensor lens cleaning system for a cylindrical sensor having a sensor lens surface includes an extended member having a first end coupled to the cylindrical sensor and a second end opposite the first end, a nozzle coupled to the second end of the extended member, an actuator coupled to the extended member and configured to control the extended member, and a controller in electronic communication with the actuator and configured to communicate an actuator control signal to the actuator. The nozzle generates an air stream directed at the sensor lens surface.

An apparatus includes a mass detection circuit coupled to a surface covered with a plurality of electrodes. The mass detection circuit is configured to detect a mass of a first droplet present on the surface. The apparatus further includes a transducer circuit coupled to a transducer, which is coupled to the surface and form a lens unit. The transducer circuit configured to excite a first vibration of the surface at a resonant frequency to form a high displacement region on the surface. The apparatus also includes a voltage excitation circuit coupled to the plurality of electrodes. In response to the detection of the mass of the first droplet, the voltage excitation circuit is configured to apply a sequence of differential voltages on one or more consecutive electrodes which moves the first droplet to the high displacement region.

A heating device includes a housing, a primary induction coil, a controller circuit, and a secondary induction coil. The housing is configured to retain a camera lens. The primary induction coil is positioned proximate the housing and configured to generate a magnetic field in response to receiving electrical power from a power supply. The controller circuit is in electrical contact with the primary induction coil and is configured to control the electrical power delivered to the primary induction coil. The secondary induction coil overlays the primary induction coil and is configured to receive the magnetic field from the primary induction coil and generate heat. The secondary induction coil heats the camera lens when the primary induction coil receives the electrical power.

This technology relates to system for clearing a sensor cover. The system may include a sprayer, a support, and a positioning device. The sprayer may be mounted to the support and direct a flow of fluid to the sensor cover. The positioning device may be configured to adjust the position of the sprayer on the support. The system may include a nozzle and the nozzle may be positioned to direct the flow of fluid to an area of the sensor cover. The system may include additional sprayers.