A vibrator includes an electromechanical transducer which is a piezoelectric ceramic made of sodium-potassium niobate metal oxides and whose temperature characteristics of a relative permittivity is 500 [ppm/° C.] or less in absolute value in a temperature range from −40° C. to 170° C., wherein excitation of the electromechanical transducer produces a vibration wave. Another vibrator includes an electromechanical transducer which is a piezoelectric ceramic made of sodium-potassium niobate metal oxides and whose temperature characteristics of a relative permittivity is 390 [ppm/° C.] or less in absolute value in a temperature range from 0° C. to 60° C., wherein excitation of the electromechanical transducer produces a vibration wave.

This application provides a lens module. The lens module includes a first lens module and a second lens module, and the first lens module and the second lens module are arranged along an optical axis. The first lens module is configured to implement a long focal length, and the second lens module is configured to implement focusing. During specific disposition, the first lens module includes a first lens, and a light incident side surface of the first lens includes a light transmission region and a first reflection region; a light outgoing side surface of the first lens includes a second reflection region and a light outgoing region; and the first reflection region and the second reflection region are configured to refract light incident into the first lens. The second lens module includes at least one second lens, and the at least one second lens is a focusing lens.

A defrosting lens includes a lens barrel having an opening toward an object side, a first lens disposed in the lens barrel and located at the opening, and a heating member. The heating member is for providing a heat source and is disposed between an inner wall of the lens barrel and the first lens. The heating member is arranged along a peripheral edge of the first lens. By raising a temperature of the first lens through the heat source supplied by the heating member, frost formed on the first lens could be removed, thereby a definition of an image captured by the defrosting lens could be effectively improved, and the defrosting lens could be applied in various environments without being limited by the change of climate temperature difference.

The present disclosure relates integrated chip structure including a MEMS actuator. The MEMS actuator includes an anchor having a first plurality of branches extending outward from a central region of the anchor. The first plurality of branches respectively include a first plurality of fingers. A proof mass surrounds the anchor and includes a second plurality of branches extending inward from an interior sidewall of the proof mass. The second plurality of branches respectively include a second plurality of fingers interleaved with the first plurality of fingers as viewed in a top-view. One or more curved cantilevers are coupled between the proof mass and a frame wrapping around the proof mass. The one or more curved cantilevers have curved outer surfaces having one or more inflection points as viewed in the top-view.

An integrated image sensor and lens assembly may include a lens barrel, a collet, and a lens mount. The lens barrel may be coupled to the collet which is coupled to the lens mount. The lens barrel and the collet may each include a fastening structure reciprocal to each other. Alternatively, the collet and the lens mount may each include a fastening structure reciprocal to each other. The optical distance between the set of lenses and the image sensor may be tuned such that the focal plane of the lenses coincides with the image plane. The fastening structures allow the lens barrel to be adjusted relative to the lens mount in order to shift the focal plane in a direction along the optical axis to compensate for focal shifts occurring during assembly/cure and/or temperature cycling.

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.

Systems and techniques are provided for meta-lens cameras. For example, an apparatus can include a first substrate including a first aperture and a second substrate including a first meta-lens. The first substrate and the second substrate are mechanically coupled such that at least a first portion of the first aperture is disposed over at least a second portion of the first meta-lens.

A light direction adjustment mechanism and an imaging device that enables size reduction are provided. The adjustment mechanism includes a first optical element (201), a second optical element (202) having a same optical axis as that of the first optical element (201), and a rotation mechanism (63). The rotation mechanism (63) allows the first optical element (201) to rotate while the rotation mechanism (63) changes a rotation angle of the first optical element (201) relative to the second optical element (202) when the first optical element (201) is rotated about the optical axis in a first direction. The rotation mechanism (63) allows the first optical element (201) to rotate while the rotation mechanism (63) does not change the rotation angle of the first optical element (201) relative to the second optical element (202) when the first optical element (201) is rotated about the optical axis in a second direction.

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 lens barrel has at least one movable lens group that can move in one direction and the other direction along the optical axis, the lens barrel comprising: a movable lens frame; a voice coil motor for driving a movable lens group and the movable lens frame along the optical axis; and a stopper mechanism brought into contact with the movable lens frame. The stopper mechanism includes a stopper member that moves between a retracted position where the stopper member does not touch the movable lens frame when the voice coil motor is energized, and an abutting position where the stopper member is brought into contact with the movable lens frame when the voice coil motor is not energized.