A camera housing includes four walls configured to enclose and secure a camera: a top wall, a bottom wall, a right wall, and a left wall. The bottom wall includes a first segment and a segment coupled by a latching mechanism. The latching mechanism comprises a tongue component coupled to the second segment and a groove component coupled to the first segment. The tongue and groove components are configured such that the tongue component securely couples the second segment to the first segment when the camera frame is in the closed configuration. In the open configuration, the first and second segment can decouple and the left wall and second segment rotates upwards relative to the top wall such that a camera can be inserted or removed from the camera system. The camera housing also includes a button interface, an input/output interface, and a mounting mechanism.

A camera housing includes four walls configured to enclose and secure a camera: a top wall, a bottom wall, a right wall, and a left wall. The bottom wall includes a first segment and a segment coupled by a latching mechanism. The latching mechanism comprises a tongue component coupled to the second segment and a groove component coupled to the first segment. The tongue and groove components are configured such that the tongue component securely couples the second segment to the first segment when the camera frame is in the closed configuration. In the open configuration, the first and second segment can decouple and the left wall and second segment rotates upwards relative to the top wall such that a camera can be inserted or removed from the camera system. The camera housing also includes a button interface, an input/output interface, and a mounting mechanism.

An image capturing apparatus includes an electronic viewfinder unit configured to move between a stored state stored in a main body and a projecting state projecting from the main body, wherein the electronic viewfinder unit is held to be able to turn in the projecting state and is held not to be able to turn in the stored state.

An image capturing apparatus includes an electronic viewfinder unit configured to move between a stored state stored in a main body and a projecting state projecting from the main body, wherein the electronic viewfinder unit is held to be able to turn in the projecting state and is held not to be able to turn in the stored state.

Digital cameras comprising a lens assembly comprising N lens elements L.sub.1-L.sub.N starting with L.sub.1 on an object side, wherein N is ≥4, an image sensor having a sensor diagonal S.sub.D, and a pop-out mechanism that controls a largest air-gap d between two consecutive lens elements within lens elements L.sub.1 and L.sub.N to bring the camera to an operative pop-out state and a collapsed state, wherein the lens assembly has a total track length TTL in the operative pop-out state and a collapsed total track length cTTL in the collapsed state, wherein S.sub.D is in the range of 7-20 mm and wherein cTTL/S.sub.D<0.6.

Digital cameras comprising a lens assembly comprising N lens elements L.sub.1-L.sub.N starting with L.sub.1 on an object side, wherein N is ≥4, an image sensor having a sensor diagonal S.sub.D, and a pop-out mechanism that controls a largest air-gap d between two consecutive lens elements within lens elements L.sub.1 and L.sub.N to bring the camera to an operative pop-out state and a collapsed state, wherein the lens assembly has a total track length TTL in the operative pop-out state and a collapsed total track length cTTL in the collapsed state, wherein S.sub.D is in the range of 7-20 mm and wherein cTTL/S.sub.D<0.6.

Various embodiments of an interconnect mechanism facilitate the connection of an image capture device to an accessory (either directly or indirectly). In one embodiment, the interconnect mechanism includes a rotatable support that is movable between a series (plurality) of discrete rotational positions through an unlimited range of motion. In another embodiment, the interconnect mechanism includes a pivotable support, which allows for reconfiguration of the interconnect mechanism between a stowed configuration, in which the support is concealed, and a deployed configuration, in which the support is exposed so as to facilitate the connection of the interconnect mechanism and the accessory. In yet another embodiment, the interconnect mechanism includes protrusions that are pivotably reconfigurable between a stowed configuration, in which the protrusions are rotatably fixed, and a deployed configuration, in which the protrusions are rotatable through a range of motion about an axis of rotation.

Various embodiments of an interconnect mechanism facilitate the connection of an image capture device to an accessory (either directly or indirectly). In one embodiment, the interconnect mechanism includes a rotatable support that is movable between a series (plurality) of discrete rotational positions through an unlimited range of motion. In another embodiment, the interconnect mechanism includes a pivotable support, which allows for reconfiguration of the interconnect mechanism between a stowed configuration, in which the support is concealed, and a deployed configuration, in which the support is exposed so as to facilitate the connection of the interconnect mechanism and the accessory. In yet another embodiment, the interconnect mechanism includes protrusions that are pivotably reconfigurable between a stowed configuration, in which the protrusions are rotatably fixed, and a deployed configuration, in which the protrusions are rotatable through a range of motion about an axis of rotation.

A method for controlling an image acquisition component includes: when a terminal including a movable image acquisition component receives an activating instruction for the image acquisition component, acquired data acquired by a Proximity Sensor (P-sensor) is obtained, the image acquisition component being capable of moving in and out of the terminal under driving of a driving component of the terminal; it is determined whether there is an obstacle in a preset range of the terminal based on the acquired data; and when there is the obstacle in the preset range of the terminal, the activating instruction is forbidden to be executed, and the image acquisition component is kept at a first position in the terminal.