A sub imaging apparatus 60 used by a user generates a sub captured image by imaging a subject OB. A main imaging apparatus 20 of which an imaging direction can be changed by a camera platform 40 is remotely controlled by the sub imaging apparatus 60 to image the subject imaged by the sub imaging apparatus 60 so as to generate a main captured image with an angle of view different from that of the sub captured image. An image combination section included in the sub imaging apparatus 60 generates a display image by combining the sub captured image generated by the sub imaging apparatus 60 with the main captured image generated by the main imaging apparatus 20. A display section included in the sub imaging apparatus 60 displays the display image generated by the image combination section. Using the sub imaging apparatus 60, the user may cause the main imaging apparatus 20 away from the sub imaging apparatus 60 to image a desired subject easily. The user may further verify the subject by using captured images with different angles of view.

A camera module includes a circuit board, a bracket arranged on the circuit board, and at least one electronic component embedded in the bracket and/or arranged on an inner side wall of the bracket. The electronic component is electrically coupled to the circuit board.

A lens driving apparatus includes a holder, a metal cover, a carrier, a sensing magnet, a printed circuit board, a position sensor, a coil and at least one driving magnet. The metal cover is coupled with the holder and has an opening. The carrier is assembled to a lens assembly having an optical axis, wherein the carrier is disposed in the metal cover and is movable along a direction parallel to the optical axis. The sensing magnet is coupled with the carrier. The printed circuit board is disposed near to one of the four lateral sides of the holder. The position sensor is disposed on the printed circuit board and corresponds to the sensing magnet. The coil is disposed on an outer surface of the carrier. One of the driving magnet is disposed in the metal cover and corresponds to the coil.

A lens driving apparatus includes a holder, a metal cover, a carrier, a sensing magnet, a printed circuit board, a position sensor, a coil and at least one driving magnet. The metal cover is coupled with the holder and has an opening. The carrier is assembled to a lens assembly having an optical axis, wherein the carrier is disposed in the metal cover and is movable along a direction parallel to the optical axis. The sensing magnet is coupled with the carrier. The printed circuit board is disposed near to one of the four lateral sides of the holder. The position sensor is disposed on the printed circuit board and corresponds to the sensing magnet. The coil is disposed on an outer surface of the carrier. One of the driving magnet is disposed in the metal cover and corresponds to the coil.

A multi-axis MEMS assembly includes a micro-electrical-mechanical system (MEMS) actuator configured to provide linear three-axis movement. The micro-electrical-mechanical system (MEMS) actuator includes: an in-plane MEMS actuator, and an out-of-plane MEMS actuator. An optoelectronic device is coupled to the micro-electrical-mechanical system (MEMS) actuator. The out-of-plane MEMS actuator includes a multi-morph piezoelectric actuator.

A multi-axis MEMS assembly includes a micro-electrical-mechanical system (MEMS) actuator configured to provide linear three-axis movement. The micro-electrical-mechanical system (MEMS) actuator includes: an in-plane MEMS actuator, and an out-of-plane MEMS actuator. An optoelectronic device is coupled to the micro-electrical-mechanical system (MEMS) actuator. The out-of-plane MEMS actuator includes a multi-morph piezoelectric actuator.

A high-stability 360-degree photo booth includes a supporting main shaft and a supporting base. The supporting base includes at least two supporting rods intersecting and connected with each other, or the supporting base includes a supporting ring and at least one supporting rod connected to the supporting ring. A plurality of anti-collision slots capable of engaging with the supporting rod is defined at a first end of the supporting main shaft. The at least two supporting rods are or the at least one supporting rod is welded to the supporting main shaft at a portion where the supporting main shaft is engaged with the at least two supporting rods are or the at least one supporting rod.

An optical module is provided, including a movable portion, a fixed portion and a driving assembly. The movable portion is used to hold an optical element having an optical axis. The movable portion is movably connected to the fixed portion. The driving assembly disposed in the fixed portion to drive the movable portion to move along the optical axis relative to the fixed portion. The driving assembly includes a first magnetic element and a second magnetic element. The first magnetic element and the second magnetic element are aligned along the optical axis. The size of the first magnetic element and the size of the second magnetic element along the optical axis are different.

A camera system (100) comprising: an image capturing device (1) further comprising: a lens unit (3), wherein the lens unit (3) comprised a lens barrel (30), a front lens (4) comprising an inner surface (4a) facing the lens barrel (30); a heater device (500), further comprising a lens heater (510) for heating the front lens (4); wherein an annular heat insulating device (6) is arranged between the lens barrel (30) and the lens heater (510).

A wearable device includes a strap, a base coupled to the strap, and a display coupled to the base. The wearable device includes a plurality of cameras embedded within the display. The display is configured to activate a specific camera of the plurality of cameras according to user interaction with the display.