A method for capturing and consolidating multi-spectral image data for regions of interest using one or more spectral boost mechanisms or techniques is disclosed. A first multi-spectral or hyperspectral workflow comprising time-stamped two-dimensional pixelated images of a region of interest is obtained by a first computer-enabled imaging device. Each of the images corresponds to image data captured for a respective frequency band of a plurality of frequency bands. First meta data is associated with the images of the first workflow and includes: a plurality of first positions and first orientations of the first imaging device indicating first positional and orientation data for the first imaging device, and indications of a respective frequency band for each of the images of the first workflow. A consolidated multi-spectral workflow for the region of interest is generated, which includes spectrally and spatially consolidating the images of the first workflow using the first meta data.

A periscope module includes a mounting ring for mounting the periscope module over a camera lens of a mobile phone. A first periscope end is for attachment to the mobile phone at the mounting ring. A second periscope end is for capturing images. A periscope tube is connected between the first periscope end and the second periscope end. A light tube is configured for attachment to a light source from the mobile phone. The light tube is configured to receive light into the first periscope end, the light exiting the second periscope end so as to provide illumination for capturing intra-oral images.

A soft box includes a housing and a main body detachably connected to the housing by a connecting device. The connecting device includes a first locking portion and a second locking portion. An installing base is connected to the bottom of the housing and the main body is embedded in the installing base, thereby the housing can rotate around the main body. The first locking portion passes through the installing base and the main body to tightly fix with the second locking portion. The housing includes a snap-fitting member and a light passageway which is a cylindrical hole and a flash lamp cap fixing device formed therein. The flash lamp cap fixing device includes a supporting platform and a pressing plate opposite to the supporting platform and having an adjustable position relative to the supporting platform. The present disclosure can quickly disassembly and be easy to carry.

A digital camera (an imaging device) includes: a camera body (an imaging device body); a flash light emitter having a stored state in which the flash light emitter is stored in the camera body and a projected state in which the flash light emitter projects from the camera body; and a packing (an elastic deformation member). The digital camera has a drip-proof specification in which the packing is pressed and deformed between the flash light emitter and the camera body in the stored state, thereby drip-proof sealing a clearance between the camera body and the flash light emitter.

Systems, methods and media for providing modular cameras are provided. In some embodiments, a modular imaging device is provided, comprising: a base module comprising: a user device interface configured to receive signals from a user device; a first magnet; a first plurality of electrical contacts; and one or more circuits that are configured to receive information transmitted to the base module from the user device via the user device interface; and an image sensor module comprising: a second plurality of electrical contacts; a second magnet; a third plurality of electrical contacts; an image sensor; and one or more circuits that are configured to: receive a first control signal; cause the image sensor to capture image data; and transmit the captured image data.

An image pickup apparatus equipped with a flash unit that is capable of popping up a light emitting unit even if a display panel is directed to a photographing direction. The flash unit is provided on an upper face of a body of the image pickup apparatus and includes three parallel rotating shafts, a first support member that is rotatably connected with the light emitting unit through the first rotating shaft, and a second support member that is rotatably connected with the first support member through the second rotating shaft and is rotatably connected with the body through the third rotating shaft. The light emitting unit is movable between a light-emitting position projected and a retracted position inside the body even if the display unit is in a stand-up position that is rotated from a regular position opposite to a back face of the body by 180 degrees.

A flash discharge tube includes tungsten pins configuring a pair of discharge electrodes, and an envelope. The envelope includes a central region, serving as an alkali-free region, which is configured with an alkali-free glass except for quartz glass. The central region becomes in a high temperature state during a firing operation of the flash discharge tube. The central region is smaller than a maximum region enclosing a gas-tight space formed by hermetically sealing the pair of the discharge electrodes and is not smaller than a minimum region enclosing an arc-discharge space formed between the tungsten pins of the pair of the discharge electrodes. The alkali-free region contains either no alkali metal component or not larger than a predetermined amount of an alkali metal component. Then, a trigger electrode is disposed in the alkali-free region. This provides the flash discharge tube featuring a stable short-interval continuous-firing operation.

In one embodiment of an enclosure device, a camera casing and light source casing are secured to a plate frame, and the enclosure device is configured to be mounted to an arm, such as a robotic welding arm. A shutter mounting arm may also be secured to the plate frame. A flap may be pivotally mounted to the distal end of the shutter mounting arm, such that the flap may be actuated between a first and second position by an actuator cooperatively engaged with the flap. The first position may be defined as to protect a camera lens positioned in the camera casing and a light source lens positioned in the light source casing. The second position may be defined as to not obscure a line-of-sight from either the light source and/or the camera to the work piece on the arm. A light source casing may be sandwiched between two side plates that are generally configured as mirror images of one another. The light source casing housing a light source may be configured as a laser designed to measure distances,

In one embodiment of an enclosure device, a camera casing and light source casing are secured to a plate frame, and the enclosure device is configured to be mounted to an arm, such as a robotic welding arm. A shutter mounting arm may also be secured to the plate frame. A flap may be pivotally mounted to the distal end of the shutter mounting arm, such that the flap may be actuated between a first and second position by an actuator cooperatively engaged with the flap. The first position may be defined as to protect a camera lens positioned in the camera casing and a light source lens positioned in the light source casing. The second position may be defined as to not obscure a line-of-sight from either the light source and/or the camera to the work piece on the arm.

An extension photoflash light and a camera system using the same are provided. The extension photoflash light to be externally mounted on a mobile device with a photographing function comprises a HID lamp, a mounting mechanism, a light sensing circuit and a control circuit. The mounting mechanism is for mounting the extension photoflash light. The light sensing circuit is disposed on the mounting mechanism. The control circuit is coupled to the HID lamp and the light sensing circuit. When a camera program is executed, a specific block on a flat panel display of the mobile device emits a light signal. The control circuit controls the light sensing circuit to detect the light signal of the specific block, and decodes a decoding message according to luminance of the detected light signal, and controls the HID lamp to perform flashing at a specific timing according to the decoding message.