A technique for strobe shooting using automatic irradiation direction control. A strobe device includes a light emission section that emits light, and a drive unit that changes an irradiation direction of light emitted from the light emission section. Exposure conditions set to the camera are notified to the strobe device, and light emission conditions are set according to the exposure conditions. The irradiation direction of light emitted from the light emission section is determined based on the exposure conditions and the light emission conditions.

An image pickup device (10) includes: an image pickup section (11) that captures an image of an object (16); an illumination section (12) that irradiates the object (16) with light to cast a shadow over the object (16); and a calculator that calculates an illumination optical path (25) extending from a virtual illumination (20). Furthermore, the image pickup device (10) includes: a first conveyer (14) that moves the image pickup section (11) and the illumination section (12) in a first direction when the image pickup section (11) scans the object (16) to capture the image of the object (16); and a second conveyer (15) that moves the light from the illumination section (12) into a plane containing the illumination optical path (25), in accordance with the movement of the image pickup section (11) and the illumination section (12) in the first direction.

A lamp for use with a computer, including cell phones and pads, comprises a body having a slot formed along its length for engaging the computer, by slipping over the edge of the computer's screen. The lamp includes a translucent cylinder, rotatably supported on the lamp body and supporting a parallel string of LEDs. A portion of the cylinder has an opaque cover so that the direction and intensity of the light cast by the lamp may be adjusted by rotating the cylinder.

A drive unit changes an irradiation direction of irradiation light from a light-emitting portion. A setting unit sets the irradiation direction of the irradiation light from the light-emitting portion. A control unit controls the drive unit. Depending on a cause of which the irradiation direction of the irradiation light from the light-emitting portion changes from the irradiation direction that is set by the setting unit, the control unit changes responsiveness of the drive unit that changes the irradiation direction of the irradiation light from the light-emitting portion into the irradiation direction that is set by the setting unit.

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.

A set-top flash lamp of a camera, comprising a lamp holder (2) and a lamp cap (1). A battery accommodating cavity (4) and a battery accommodating cavity cover (3) are formed in the lamp holder (2). A lithium battery (5) is accommodated in the battery accommodating cavity (4), and the lithium battery (5) comprises an electrical output contact (6). The electrical output contact (6) is in the shape of a right-angled sheet, and is composed of end surface right-angled sides (61) and bottom surface right-angled sides (62), wherein the end surface right-angled sides (61) are located on the front end surface (51) of the lithium battery (5); and the bottom surface right-angled sides (62) are arranged on the bottom surface (52) of the lithium battery (5). An electrical access contact (7) is contained in the battery accommodating cavity (4), and is arranged on a side wall of the battery accommodating cavity (4) which is opposite to the bottom surface (52) of the lithium battery (5). The set-top flash lamp improves the performance and reduces the costs.

A lighting device is provided in which a head part is allowed to be driven relative to a main unit in a horizontal circular direction and in a vertical circular direction separately without the need for increasing a space for the layout of the main unit and the like. The lighting device of the present invention includes a driving unit (7) connecting a main unit (3) and a head part (6). The driving unit (7) includes first and second motors, a first power transmission mechanism that rotates the driving unit (7) in a horizontal circular direction (the direction of an arrow F) with the driving force of the first motor, and a second power transmission mechanism that rotates the driving unit (7) in a vertical circular direction (the direction of an arrow B) with the driving force of the second motor. With this configuration, the head part (6) is allowed to be driven relative to the main unit (3) in the horizontal circular direction and the vertical circular direction separately, without the need for increasing a space for the layout of the main unit (3) and the like.

An illumination device selectively disposed on an object having a first side and a second side is provided. The illumination device comprises a light-emitting module, a camera unit and a rotation mechanism. The lighting direction of the light-emitting module points towards the front of the first side. The central filming direction of the camera unit points towards the front of the first side. The light-emitting module is coupled to the rotation mechanism such that the light-emitting module is capable of rotating about an axis of the rotation mechanism. When the lighting direction falls in a first angular range relative to the axis of the rotation mechanism, the light-emitting module provides a first mode illumination. When the lighting direction falls in a second angular range relative to the axis of the rotation mechanism, the light-emitting module provides a second mode illumination. Said first angular range is different from said second angular range. When the light-emitting module provides the second mode illumination, the central filming direction falls in the second angular range.

A case for an artificial light. An articulating arm or arms attaches a hood to the case. The arm(s) allow the hood to be oriented to function as both a protective cover, shade, or stand.

An illumination device selectively disposed on an object having a first side and a second side is provided. The illumination device comprises a light-emitting module, a camera unit and a rotation mechanism. The lighting direction of the light-emitting module points towards the front of the first side. The central filming direction of the camera unit points towards the front of the first side. The light-emitting module is coupled to the rotation mechanism such that the light-emitting module is capable of rotating about an axis of the rotation mechanism. When the lighting direction falls in a first angular range relative to the axis of the rotation mechanism, the light-emitting module provides a first mode illumination. When the lighting direction falls in a second angular range relative to the axis of the rotation mechanism, the light-emitting module provides a second mode illumination. Said first angular range is different from said second angular range. When the light-emitting module provides the second mode illumination, the central filming direction falls in the second angular range.