A camera module includes a metal yoke, a holder, a plastic barrel, a plurality of plastic lens elements and a plurality of metal conducting elements. The holder is connected to the metal yoke for forming an inner space. The plastic barrel is movably disposed in the inner space and includes at least one buffering part. The plastic lens elements are disposed in the plastic barrel. The metal conducting elements are at least one leaf spring and a wire element, wherein the metal conducting elements are connected to the plastic barrel. Before the at least one buffering part contacts a contacting part of the at least one leaf spring, there is a gap distance between the at least one buffering part and the contacting part of the at least one leaf spring.

A lens accessory (1) is detachably attached to a lens barrel (2), and includes a first holder (104) and a second holder (105) for holding the lens barrel, an operation member (102) that moves at least one holder of the first holder and the second holder between a first position and a second position, and a biasing mechanism (110) that applies a biasing force to the at least one holder so as to hold the lens barrel, the biasing mechanism includes a first biasing member and a moving member that moves the at least one holder from the first position to the second position according to an operation of the operation member via the first biasing member, and when the at least one holder contacts the lens barrel, the first biasing member is displaced by the moving member.

The optical driver apparatus is detachably attachable to an optical apparatus. The optical apparatus includes a lens operation member operable manually, and a locking mechanism switchable between a locking state of restraining motion of the lens operation member and an unlocking state of releasing the restraint. The optical driver apparatus includes a driver operation member, an actuator configured to move the lens operation member, and a controller configured to control the actuator. The controller is configured to drive the actuator in response to an operation of the driver operation member when the locking mechanism is in the unlocking state and to control the actuator, when the locking mechanism is in the locking state, so as to provide one of a state of not driving the actuator in response to the operation of the driver operation member and a state of performing a warning operation.

An accessory apparatus attached to an interchangeable lens attached to a camera body can switch between a first accessory power mode and a second accessory power mode consuming less power than the first accessory power mode. The power state of the accessory apparatus is set based on information regarding the power mode of the camera body and the power mode of the interchangeable lens.

An optical system is provided. The optical system includes a first optical module, a second optical module and a third optical module. The first optical module is configured to connect at least one first optical member. The second optical module is configured to connect at least one second optical member. The third optical module is configured to connect a third optical member, wherein the third optical module is located between the first optical module and the second optical module.

The present disclosure provides an optical element driving mechanism, which includes a movable part, a fixed assembly, and a driving assembly. The movable part is configured to be connected to an optical element. The fixed assembly has a first opening, and the movable part is movable relative to the fixed assembly along a first axis. The driving assembly is configured to drive the movable part to move between a first position and a second position relative to the fixed assembly, so that the optical element selectively overlaps the first opening.

A camera module that does not make a rasping noise even when being subjected to a vibration by a source of vibration is provided. A hall element that detects a displacement of an imaging lens (1) is disposed therein. In the case where the hall element detects a displacement of the imaging lens (1) that is not based on drive by a lens-driving device (5), the lens-driving device (5) drives the imaging lens (1) so as to reduce the displacement.

A lens driving device being capable of stabilizing a motion of a lens holder is provided. A lens driving device includes a lens holder configured to support a lens, a frame surrounding a periphery of the lens holder, and a support mechanism configured to support the lens holder so as to be freely movable relative to the frame in an optical axis direction of the lens. The support mechanism includes a support member provided in the frame and a guide portion provided in the lens holder. The support member extends in the optical axis direction of the lens, and the support member is in contact with the guide portion at least at two points in a cross section orthogonal to the optical axis direction of the lens.

A MEMS auto focus miniature camera module includes an image sensor and an optical train including at least one movable lens and one or more fixed lenses or fixed lens groups on either side of the movable lens. The movable lens provides an auto focus feature of the camera module. A MEMS actuator translates the movable lens through an auto focus range to adjust focus.

A camera includes a primary housing that has a cylindrical exterior surface and an opening located at a front end. The camera also includes a rotatable housing that has a spherical exterior surface and an aperture, where the rotatable housing is disposed in the opening of the primary housing and is rotatably mounted to the primary housing. The camera also includes an image sensor that is located in the rotatable housing for rotation in unison with the rotatable housing, where the image sensor receives light through the aperture of the rotatable housing.