Provided is a mobile information terminal that allows a high-performance camera to be directed in any arbitrary direction relative to the terminal body and that allows photographing to be performed in a free position, while allowing for the viewing of a camera viewpoint image. An information processing terminal 1 comprises: a camera 21 serving as an image capture unit for capturing an image of a subject; a body part 11 having a front surface 11a which is a predetermined surface on which a display unit 13 for displaying a captured image including the subject captured by the image capture unit is disposed; and a coupling part 12 that directly or indirectly couples the image capture unit relatively rotatably to the body part 11 via a plurality of rotation axes including a pivot axis Z1 that is a first rotation axis for changing an angle formed by an optical axis direction of the image capture unit and the normal direction to the display unit 13, and a pivot axis Z3 that is a second rotation axis in a direction different

Provided is a mobile information terminal that allows a high-performance camera to be directed in any arbitrary direction relative to the terminal body and that allows photographing to be performed in a free position, while allowing for the viewing of a camera viewpoint image. An information processing terminal 1 comprises: a camera 21 serving as an image capture unit for capturing an image of a subject; a body part 11 having a front surface 11a which is a predetermined surface on which a display unit 13 for displaying a captured image including the subject captured by the image capture unit is disposed; and a coupling part 12 that directly or indirectly couples the image capture unit relatively rotatably to the body part 11 via a plurality of rotation axes including a pivot axis Z1 that is a first rotation axis for changing an angle formed by an optical axis direction of the image capture unit and the normal direction to the display unit 13, and a pivot axis Z3 that is a second rotation axis in a direction different

A harsh environment enclosure for use with sensor systems, such as cameras. The enclosure can include a housing having an end wall, sidewalls, a top wall, and a bottom wall. A door is hinged to the top wall. The enclosure can have a linkage assembly including a door lever having an elongate first end portion connected to the door, a laterally extending second end portion, and an elbow positioned therebetween. A pivot arm having a proximal end is connected to an interior surface of the housing and a distal end of the pivot arm is connected to the elbow. An actuator can be connected between the housing and the laterally extending second end portion. The linear actuator can be positioned with respect to the door lever and pivot arm to move the door to an open position when extended and a closed position when retracted.

A harsh environment enclosure for use with sensor systems, such as cameras. The enclosure can include a housing having an end wall, sidewalls, a top wall, and a bottom wall. A door is hinged to the top wall. The enclosure can have a linkage assembly including a door lever having an elongate first end portion connected to the door, a laterally extending second end portion, and an elbow positioned therebetween. A pivot arm having a proximal end is connected to an interior surface of the housing and a distal end of the pivot arm is connected to the elbow. An actuator can be connected between the housing and the laterally extending second end portion. The linear actuator can be positioned with respect to the door lever and pivot arm to move the door to an open position when extended and a closed position when retracted.

A lens driving actuator includes an upper cover having an opening for passing light, a lens barrel arranged in the upper cover and including a light-transmitting lens, a driving pin formed on an outer circumferential surface of the lens barrel, a driving cam member formed to cover the outer circumference of the lens barrel, and having a cam groove that engages with the driving pin, and a driving source configured to supply a driving force to a gear formed in the driving cam member. When the driving cam member rotates along the outer circumferential surface of the lens barrel, the driving pin is guided by the cam groove, and the lens barrel moves in an optical-axis direction with respect to the upper cover.

A lens driving actuator includes an upper cover having an opening for passing light, a lens barrel arranged in the upper cover and including a light-transmitting lens, a driving pin formed on an outer circumferential surface of the lens barrel, a driving cam member formed to cover the outer circumference of the lens barrel, and having a cam groove that engages with the driving pin, and a driving source configured to supply a driving force to a gear formed in the driving cam member. When the driving cam member rotates along the outer circumferential surface of the lens barrel, the driving pin is guided by the cam groove, and the lens barrel moves in an optical-axis direction with respect to the upper cover.

The present disclosure relates to the display technical field and, specifically, relates to a camera apparatus and terminal device. The camera apparatus includes a mounting body, a camera, and an adjustment component. The camera includes a first surface for framing and a second surface opposite to the first surface. The adjustment component includes a plurality of telescopic rods, and each of the telescopic rods includes a first end and a second end, the first end being connected with the mounting body, and the second end being connected with the second surface of the camera. The orientation of the first surface of the camera is adjusted by adjusting the telescopic degree of each of the telescopic rods.

An electronic device includes a body and an image capturing assembly mounted on the body. The image capturing assembly comprising an imaging device and a device control assembly coupled to the imaging device to control a movement of the imaging device along a central axis of the image capturing assembly to allow the imaging device to be positioned at multiple positions along the central axis of the image capturing assembly. The device control assembly includes a first guide member, a second guide member rotatably disposed within the first guide member, and an inner body movably disposed within the second guide member. In response to a rotational motion of the second guide member with respect to the first guide member, the inner body is to move in axial direction with respect to the second guide member to move the imaging device along the central axis of the image capturing assembly.

A camera module includes: a control body, a lens assembly and at least one magnetic member. The control body includes a circuit board and a spatial magnetic field sensing member disposed on the circuit board. The lens assembly is configured to be controlled to move, so as to generate relative displacement between the lens assembly and the spatial magnetic field sensing member. The at least one magnetic member is assembled to the lens assembly to generate a preset magnetic field around the lens assembly. Along with a movement of the lens assembly, the spatial magnetic field sensing member senses changes of the preset magnetic field.

A camera module includes: a control body, a lens assembly and at least one magnetic member. The control body includes a circuit board and a spatial magnetic field sensing member disposed on the circuit board. The lens assembly is configured to be controlled to move, so as to generate relative displacement between the lens assembly and the spatial magnetic field sensing member. The at least one magnetic member is assembled to the lens assembly to generate a preset magnetic field around the lens assembly. Along with a movement of the lens assembly, the spatial magnetic field sensing member senses changes of the preset magnetic field.