A portable remote controlled video production apparatus and method are provided, as is a teleprompter/Interrotron integrated with a camera. A computer is mounted in a rigid cage, the computer having a local portion of remote access remote control software. A camera is fixedly mounted in the cage in communication with the computer; either the camera or the computer have camera control software running thereon. A monitor is fixedly mounted in the cage in front of the camera and parallel to the lens axis; the monitor is in communication with the computer. A beamsplitter is fixedly mounted in the cage in front of the lens reflecting light from the monitor towards a front of the cage. The camera and computer are controllable remotely via a remote portion of the remote access remote control software running on a remote computer communicating with the local portion of the remote access remote control software.

Provided is an application program (app) for functioning a dermoscope, a dermoscope adapter, and a smartphone as a dermoscope. A dermoscope 100 for observing skin tissue according to the present invention includes a smartphone 110 including a camera 111 and a photoflash 107 and being communicable, and being capable of instructing from a graphical user interface displayed on a liquid crystal display; a case 101 containing the smartphone 110 and including a base member 103 fixed on a side opposite to a liquid crystal display to operate the smartphone 110; and an observation adaptor 102 detachably retained on the base member 103; wherein the camera 111 performs photographing through a first circular polarization filter 106; wherein the base member 103 movably retains a second circular polarization filter 108 for leading a polarization state of LED light emitted by the photoflash 107 to form circularly polarized light.

A strobe module can include a Fresnel lens that defines an external surface of the strobe module and a sidewall at least partially defining an internal volume and defining an external channel. A gasket can be disposed in the external channel. A substrate can be coupled to the sidewall to further define the internal volume and a light source can be disposed on the substrate in the internal volume.

A flash light emitting diode (LED) package includes a circuit board, a flash LED device disposed on an upper surface of the circuit board n, first and third optical sensors arranged to be adjacent to a first side of the flash LED device on the upper surface of the circuit board and configured to detect light of a first wavelength and light of a second wavelength, respectively, second and fourth optical sensors arranged to be adjacent to a second side of the flash LED device on the upper surface of the circuit board and configured to detect light of the first wavelength and light of the second wavelength, respectively, and an integrated circuit (IC) chip disposed to face a third side between the first and second sides of the flash LED device on the upper surface of the circuit board.

A small light-emitting device is provided. A light-emitting device which is less likely to produce a shadow is provided. A structure including a switching circuit for supplying a pulsed constant current and a light-emitting panel supplied with the pulsed constant current has been conceived.

A camera apparatus records only those objects in a surround which are situated in a predetermined object plane at a distance from the camera apparatus. To this end, the camera apparatus includes an illumination device for illuminating the desired object with an illumination light and an image capture device (for capturing the illumination light reflected by the object. For recording that is dependent on the object plane, the camera apparatus additionally comprises a control device for driving the illumination device to provide the illumination light in the form of light pulses and for controlling the image capture device to capture the reflected illumination light within recording intervals assigned to the light pulses. To avoid interference effects on a resultant image representation, provision is additionally made for a deflection unit for deflecting the respective illumination light between the surround and the illumination device and the image capture device.

Methods and apparatus for driving an emitter array are described. A method includes determining a thermal environment profile for a plurality of emitters of the emitter array, computing a current pulse profile for at least one of the plurality of emitters based on the thermal environment profile, and applying a current pulse with the computed current pulse profile to the at least one of plurality of emitters.

A camera wing system to a vehicle comprising such camera wing system and a method to operate such a camera wing system comprising at least one camera to record a scenery in a field of view of the camera and an illuminating system to emit light to illuminate the field of view of the camera, the camera being sensitive to the light emitted by the illumination system, wherein the illuminating system provides light to the scenery in one or more emission cones (EC), where the one or more emission cones are adaptable in emission direction (ED1, ED2) and/or cone angle (CA) depending on the driving situation (DS) of the vehicle in order to illuminate the scenery in the field of view being of interest for a driver due to the detected driving situation.

A packaging structure for a light emitter pixel array includes a plurality of pixels, with at least some pixels laterally separated from each other with a pixel light confinement structure. An inorganic substrate having a top redistribution layer is attached to the plurality of pixels and at least one through silicon via containing an electrical conductor is defined to pass through the inorganic substrate and support an electrical coupling with the top redistribution layer.

A mobile device contains an integrated structure (e.g., a semiconductor structure) that includes an LED matrix with one or more LED arrays and sensors on at least opposing edges of the LED matrix. Each LED array has LEDs that are separated by non-emitting areas and the LEDs are independently driven to provide light. The light is converted to white light using a phosphor disposed on the LEDs. The sensors detect ambient light or flicker. The semiconductor structure is attached to a semiconductor driver via conductive pillars and underfill between the conductive pillars. The driver is coupled to a PCB. The PCB is electrically coupled to the semiconductor structure via PCB contacts and LED contacts to drive the LEDs dependent on the ambient light.