The present disclosure provides a casing and a lens and relates to the technical field of optical equipment. The casing includes an outer casing provided with an accommodating hole and an inner casing accommodated in the outer casing and provided with a mounting hole. The outer casing is made of metal material, and a hardness of the inner casing is lower than a hardness of the outer casing, thereby the outer casing can meet the metal shape requirements of the lens. The relatively soft inner casing can solve the problem that a metal material cannot be tightly fitted with the lens group. The casing not only has advantages of metal profiles, but also can take a fitting structure with stacked outer diameters and a bumpy ridge fitting structure into account due to providing the relatively soft inner casing inside, which is more beneficial for lenses with high performance requirements.

Embodiments of the disclosure include a suspension assembly having a support member, a moving member movably coupled to the support member, and shape metal alloy wires coupled between the support and moving members by attachment structures. According to various embodiments, the attachment structures include at least one of: an adhesive disposed proximate to a side of the attachment structures and between the attachment structures.

A lens apparatus includes a lens unit and a fixed member engaged with the lens unit. A position of the lens unit relative to the fixed member is adjustable in an optical axis direction by rotating the lens unit relative to the fixed member about an optical axis. The lens unit includes a holding member configured to hold the lens and engaged with the fixed member, and a press member engaged with the holding member and configured to press the lens against the holding member in the optical axis direction. The holding member includes an engagement portion engageable with a tool configured to rotate the lens unit about the optical axis relative to the fixed member. The press member includes a hole portion penetrating in the optical axis direction. The hole portion enables the tool to be engaged with the engagement portion through the hole portion.

An imaging lens assembly includes a dual molded optical element, a plurality of imaging lens elements and a light blocking element. The dual molded optical element has an object-side surface and an image-side surface and includes a light transmitting portion and a light absorbing portion. The light transmitting portion includes an optical effective section. The light absorbing portion is located on at least one of the object-side surface and the image-side surface of the dual molded optical element, and a plastic material of the light absorbing portion and a plastic material of the light transmitting portion are different colors. The imaging lens elements are disposed in the inner space of the imaging lens assembly. The light blocking element is disposed adjacent to the light transmitting portion of the dual molded optical element.

A lens unit includes: a resin lens including a flange forming an outer peripheral portion of the resin lens and a fitting portion having a diameter smaller than a diameter of the outer peripheral portion of the flange; a lens barrel including a lens housing chamber and an abutting surface, the lens housing chamber housing the resin lens with the fitting portion facing the abutting surface; and a pressing member pressing the resin lens against the abutting surface along an optical axis of the resin lens. The fitting portion being fit into the lens housing chamber over an entire circumference of the fitting portion with clearance between the entire circumference and the lens housing chamber to position the resin lens in a direction perpendicular to the optical axis of the resin lens.

An assembly method of a SMA assembly, includes disposing a lens holder unit on a SMA unit, the lens holder unit being provided with a first spring, a lens holder and a coil that are mounted on the first spring, with the first spring pressed against a mounting surface of the SMA unit; and bonding the first spring of the lens holder unit with the mounting surface of the SMA unit. The assembly process is simplified, the coating and soldering space become big to facilitate the bonding process, and the joining force between the SMA unit and the lens holder unit is enhanced.

A lens barrel includes a lens drive ring actuated to drive a lens group along an optical axis, a driving direction detector detecting a driving direction of the lens drive ring, an actuator actuating the lens drive ring, a power transmission mechanism transmitting a driving force of the actuator to the lens drive ring, a manual operation member to manually move the lens drive ring, and a lens-driving controller controlling the actuator to drive the lens drive ring to move the movable lens group. When the lens drive ring is driven, the lens-driving controller controls a driving output of the actuator according to whether or not a first driving direction of the lens drive ring detected immediately before the lens drive ring is driven and a currently-detected second driving direction of the lens drive ring are mutually identical.

Various embodiments include perimeter sheet spring suspension arrangements for cameras. A perimeter sheet spring suspension arrangement may be used to suspend a moveable platform of the camera from a base structure of the camera, and allow a lens group of the camera to move laterally. According to some embodiments, the perimeter sheet spring suspension arrangement may include one or more tabs that may be used as bumpers that cushion lateral movement of the moveable platform.

Optical assemblies may include a projector assembly, a waveguide, and a mounting mechanism. The projector assembly may be configured for generating an image, and the waveguide may be configured for transmitting the image to a location in front of a user's eye. The mounting mechanism may removably couple the waveguide to an underlying frame. The mounting mechanism may include a detachable coupling, at least one flexure secured to a peripheral edge of the waveguide, and at least one flexure support coupled to the at least one flexure. The flexure support may be removably secured to the detachable coupling by a removable retainer. Various other related systems, methods, and devices are also disclosed.

An optical element driving mechanism is provided, including a fixed portion, a movable portion, a driving assembly, and a stopping assembly. The movable portion is movably connected to the fixed portion, wherein the movable portion is used for connecting to an optical element having a main axis. The driving assembly is disposed on the fixed portion or the movable portion, and the driving assembly is used for driving the movable portion to move relative to the fixed portion. The stopping assembly is connected to the movable portion and the fixed portion.