A part (91, 92) of a lower plate spring (9) of a lens driving device (1) includes a base-fixed section (911, 921) fixed to a base (11), a lens holder fixing section (912, 922) fixed to a lens holder (8), and an arm section (913, 923) connecting the base-fixed section (911, 921) and the lens holder fixing section (912, 922) to each other, the base-fixed section (911, 921) including a terminal connection section (911b, 921b) near which an elastic section (911c, 921c) is provided.

A lens driving device includes first and second support frames, lens barrel, anti-shake magnets, anti-shake coils, flexible PCB, metal sheets, and support assembly including support member and first and second guiding posts. Support member includes support plate and first and second support walls. First soft protruding rubbers are respectively provided at positions of top surface of first support frame corresponding first support walls, and second soft protruding rubbers are respectively provided at positions of inner wall of second support frame corresponding to two sides of each second support wall. Compared with the prior art, lens driving device of the present disclosure makes impact limit position of first support walls closer to deflection axis position in first direction, and makes impact limit positions of second support walls closer to deflection axis position in second direction to reduce speed of limit impact, thereby reducing risk of generating particles due to impact.

Provided is a lens barrel which causes at least one lens to be movable in an optical axis direction. The lens barrel includes a first tube; a second tube that holds the lens and is movable relatively to the first tube in the optical axis direction; and either one of the first and the second tube includes a first and a second roller which contact with the other tube in a plane orthogonal to the optical axis direction, and the first roller and the second roller are rotable in accordance with the relative movement of the second tube and movable in a direction orthogonal to the optical axis direction at the time of the movement of the second tube. One tube includes a limiting member for limiting the movement of the second roller in the direction orthogonal to the optical axis direction and in a direction to the other tube.

An actuator for moving a platform having electrical connections is provided. The actuator includes an outer frame connected to an inner frame by one or more spring elements that are electrically conductive. The actuator further includes one or more comb drive actuators that apply a controlled force between the outer frame and the inner frame. Each of the comb drive actuators includes one or more comb drives. Moreover, a method for moving a platform having electrical connections is also provided. The method includes connecting an outer frame to an inner frame using one or more spring elements that are electrically conductive. The method further includes generating a controlled force using one or more comb drive actuators. Each of the comb drive actuators includes one or more comb drives. In addition, the method includes applying the controlled force between the outer frame and the inner frame.

An optical component driving mechanism is provided and includes a fixed assembly, a movable assembly, a driving assembly and a circuit assembly. The movable assembly is movable relative to the fixed assembly, the movable assembly is configured to hold an optical component, and the optical component defines an optical axis. The driving assembly is for driving the movable assembly to move relative to the fixed assembly. The circuit assembly is disposed on a first side and a second side of the optical component driving mechanism, and the first side is not parallel to the second side.

A camera module is provided, including a lens driving mechanism, a lens unit, a housing, and an elastic member. The lens unit is disposed on the lens driving mechanism. The housing surrounds the lens driving mechanism. The elastic member is connected to the lens driving mechanism and comprises a metal base, a first insulation layer, and a first metal wire. The first insulation layer is disposed between the metal base and the first metal wire, and the first metal wire is electrically connected to the lens driving mechanism.

An optical imaging apparatus includes a plurality of optical lenses. The optical lenses are arranged along an optical axis to capture an image in an image capture direction and project the image on an imaging plane. The plurality of optical lenses are divided into at least one fixed lens set and at least one movable lens set. The fixed lens set is fixedly disposed, and the movable lens set is configured to move relative to the fixed lens set, so as to adjust focal lengths of the optical lenses.

A microelectromechanical systems (MEMS) device may be provided with one or more sintered electrical contacts. The MEMS device may be a MEMS actuator or a MEMS sensor. The sintered electrical contacts may be silver-paste metalized electrical contacts. The sintered electrical contacts may be formed by depositing a sintering material such as a metal paste, a metal preform, a metal ink, or a metal powder on a wafer of released MEMS devices and heating the wafer so that the deposited sintering material diffuses into a substrate of the device, thereby making electrical contact with the device. The deposited sintering material may break through an insulating layer on the substrate during the sintering process. The MEMS device may be a multiple degree of freedom actuator having first and second MEMS actuators that facilitate autofocus, zoom, and optical image stabilization for a camera.

A camera may include at least one suspension assembly as part of optical image stabilization and/or autofocus systems of the camera. The suspension assembly may include an inner frame, an outer frame, and one or more flexure arms. Electrical traces may be deposited at both sides of the suspension assembly. A connection may be created, for electrical traces at the different sides of the suspension assembly, through the suspension assembly by removing (e.g., using an etching process) one or more parts in the body of the suspension assembly to create one or more cavities. A remaining part of the suspension assembly surrounded (and thus isolated) by the cavities may thus form at least a part of the connection for the electrical traces. The connection may further include one or more filled trenches connecting the electrical traces to the remaining part of the suspension assembly.

A lens barrel includes a lens, a rotatable operation member, a rotation amount detector configured to detect a rotation amount of the operation member, an operation detector configured to detect a rotational operation of the operation member, the operation detector having a mechanism that is different from a mechanism of the rotation amount detector, and a controller configured to perform drive control of the lens depending on rotation of the operation member, and the controller is capable of operating the lens barrel in a first mode in which the rotation amount detector is used and a second mode in which the operation detector is used, and power consumption required in the second mode is less than power consumption required in the first mode.