A camera has a shutter trigger connected to the body, a controller operably connected to the trigger, and a shutter operably connected to the trigger. The shutter is operable at a plurality of frame rates and the controller is responsive to the shutter trigger in the first condition to operate the shutter at a first frame rate. The controller responsive to the shutter trigger in the second condition to operate the shutter at a different second frame rate.

A camera has a shutter trigger connected to the body, a controller operably connected to the trigger, and a shutter operably connected to the trigger. The shutter is operable at a plurality of frame rates and the controller is responsive to the shutter trigger in the first condition to operate the shutter at a first frame rate. The controller responsive to the shutter trigger in the second condition to operate the shutter at a different second frame rate.

This optical element driving device is provided with: a movable part capable of holding an optical element; a driving part that includes an ultrasonic motor and drives the movable part; a voltage boosting part having an inductor that boosts input voltage inputted to the driving part and supplies the boosted input voltage to the ultrasonic motor; a position detection part that detects the position of the movable part; and a substrate part on which the position detection part and the voltage boosting part are disposed.

A method for film production includes the steps of obtaining information on the position of a defect (D) in a separator (12a) and providing marks (LA, LB) at the respective positions in the vicinity of the defect (D), the marks indicating the position of the defect.

According to an embodiment of the present disclosure, an asynchronous control system of a camera built-in lamp may include a headlight module including a one-side headlight module integrated with a first camera and a first light source, and an other-side headlight module integrated with a second camera and a second light source, and transmits a sync signal for controlling driving of the first light source and the second light source to the one-side headlight module and the other-side headlight module, causes the first light source and the second light source to be turned off when the shutters of the first camera and the second camera operate to be opened, and causes the first light source and the second light source to be turned on when the shutters of the first camera and the second camera operate to be closed.

The present invention provides a board mountable system for filming underwater video. The inventive board mountable system can be mounted to the underside of water vehicles for incorporating a camera for filming from an underwater perspective. The inventive board mountable system is shaped to minimize drag as a result of the mounted camera or camera system. Embodiments of the inventive system includes a fin shaped housing for holding a camera or camera system. In certain embodiments, the fin is removably attached to the water vehicle, such as a surf board, where the fin housing can be swapped with other fins being used with the water vehicle for controlling the direction of a watersports board in motion. These embodiments of the inventive system further include a connection means for connecting the fin to the underside of a water vessel.

The present invention provides a board mountable system for filming underwater video. The inventive board mountable system can be mounted to the underside of water vehicles for incorporating a camera for filming from an underwater perspective. The inventive board mountable system is shaped to minimize drag as a result of the mounted camera or camera system. Embodiments of the inventive system includes a fin shaped housing for holding a camera or camera system. In certain embodiments, the fin is removably attached to the water vehicle, such as a surf board, where the fin housing can be swapped with other fins being used with the water vehicle for controlling the direction of a watersports board in motion. These embodiments of the inventive system further include a connection means for connecting the fin to the underside of a water vessel.

According to an embodiment of the present disclosure, an asynchronous control system of a camera built-in lamp may include a headlight module including a one-side headlight module integrated with a first camera and a first light source, and an other-side headlight module integrated with a second camera and a second light source, and transmits a sync signal for controlling driving of the first light source and the second light source to the one-side headlight module and the other-side headlight module, causes the first light source and the second light source to be turned off when the shutters of the first camera and the second camera operate to be opened, and causes the first light source and the second light source to be turned on when the shutters of the first camera and the second camera operate to be closed.

The present disclosure relates to an imaging device, an imaging operation device, and a control method that enable better imaging.

A reaction force generating unit generates a reaction force with respect to the operation direction of the operation unit, and a control unit sets the reaction force on the basis of imaging-related information during operation on the operation unit. Further, the operation unit gives an instruction on a start of image capture by the imaging device, a position detection unit detects an amount of operation with respect to the operation direction of the operation unit, and the control unit sets the reaction force according to the amount of operation. The present technology can be applied, for example, to imaging devices such as single-lens reflex cameras and compact cameras.

A lens driving device is describes that includes a stator and a mover, with a lens support for supporting the lens and for moving in an optical axis direction of the lens with respect to the stator. Any one of the stator and the mover has protruding portions and any other one of the stator and the mover has recessed portions into which the protruding portions are inserted. The protruding portions and the recessed portions each have opposing surfaces where the protruding portions and the recessed portions are opposed to each other, and a resin with viscoelasticity is provided to contact the opposing surfaces of the protruding portions and the opposing surfaces of the recessed portions.