[Problem] To provide a dimension measurement device without influenced by change in a usage environment while being able to measure precisely a dimension of medicine.

[Solution] A dimension measurement apparatus S1 comprising a light source part L, a photographing part C, a medicine holder part H holding a medicine 1 disposed between the photographing part C and the light source part L while holding the medicine 1 being able to be photographed from different directions, a light source output power adjustment part U1 performing brightness adjustment of the light source part L based on luminosity of photographed image photographed by the photographing part C, and a shape measuring part U2, measuring an X direction and a Y direction of medicine 1 in an X direction and a Y direction each crossing at right angles with respect to the photographed image photographed after the brightness adjustment has performed at least one time.

A polyhedron lens architecture is disposed in a virtual sphere. The virtual sphere has a horizontal plane, an upper hemisphere above the horizontal plane and a lower hemisphere below the horizontal plane. The polyhedron lens architecture has an upper half part above the horizontal plane, and a lower half part below the horizontal plane. The polyhedron lens architecture includes: multiple bases, which are respectively disposed on the upper half part and the lower half part; and multiple lenses respectively disposed on surfaces of the bases. Optical axes of the lenses intersect at a central point, which is located at the horizontal plane and is a structural center of the polyhedron lens architecture.

An imaging apparatus includes a shake detector and a shake correction unit. The shake correction unit performs image shake correction by moving an imaging element in a plane orthogonal to an optical axis of an imaging optical system. A shutter operation is performed using an electronic front curtain by the imaging element and a rear curtain of a shutter mechanism unit. A camera system controller performs driving control of the shake correction unit using a detection signal of the shake detector. If the camera system controller performs exposure control using the electronic front curtain and the rear curtain, the camera system controller performs regulation control for reducing the amount of rotation of the imaging element in a period before exposure during which the shake correction unit is active according to exposure conditions. Alternatively, the camera system controller performs control for luminance correction of a captured image according to exposure conditions.

An image stabilization control apparatus acquires information regarding a shutter speed related to image capturing that is to be performed by the image capturing apparatus, and controls to cause a first correction unit and a second correction unit that respectively employ different correction methods, to correct shake of the image capturing apparatus. The image stabilization control apparatus changes the allocation of correction of the shake to the first correction unit and the second correction unit based on information regarding the shutter speed.

An image sensor includes a video acquiring circuit to convert light incident in a first direction through a lens into an electrical signal to acquire image data, a clock signal generating circuit to generate and output a clock signal on current time information, a stabilization data generating circuit to generate stabilization data, image time information on a time point at which the image data is acquired, and stabilization time information on a time point at which the stabilization data is generated, on the basis of the clock signal, and an output circuit. The stabilization data generating circuit generates first stabilization data on a position of the lens and first stabilization time information on a time point at which the first stabilization data is generated, and the output circuit outputs the image data, the image time information, the first stabilization data, and the first stabilization time information.

Visual content may be captured by an image capture device during a capture duration. The rotational positions of the image capture device may change during the capture duration. The rotational positions of the image capture device may be smoothed based on a look ahead of a rotation constraint. A punchout of the visual content may be determined based on the smoothed rotational positions. The punchout of the visual content may be used to generate stabilized visual content.

To facilitate conversion of a frame rate of moving image data in an imaging element that images the moving image data. A pixel array unit is divided into a plurality of divided regions each including a plurality of partial regions. A scanning circuit sequentially performs control of exposing a predetermined number of regions of the plurality of partial regions as first partial regions to output first pixel data in each of the plurality of divided regions, and control of exposing a region different from the first partial regions of the plurality of partial regions as a second partial region to output second pixel data in each of the plurality of divided regions. An image processing unit sequentially performs processing of arraying the first pixel data to generate a first frame and processing of arraying the second pixel data to generate a second frame.

An image capturing device includes a housing and a processor. The processor is configured to determine whether a state of movement of the housing relative to an observation target is either a first state or a second state, and perform a control based on the state of the movement of the housing to cause change in electric energy for drive of the image capturing device.

Provided in the present invention are a method for achieving a bullet time capturing effect and a panoramic camera. The method comprises: acquiring a panoramic video captured when a panoramic camera rotates around a capture target; acquiring from within the panoramic video hemispherical images close to the side of the capture target; splicing the hemispherical images to generate a spliced image; and fixing a viewpoint of the spliced image, thus achieving a bullet time capturing effect. According to the present invention, only one panoramic camera is needed to be able to capture the bullet time capturing effect, so that the capturing cost of the bullet time capturing effect in the present invention is low. Meanwhile, since the bullet time capturing effect is obtained by means of a panoramic video being captured when a panoramic camera rotates around a capture target and processing being carried out on the panoramic video, the precision is high.

Visual content may be captured by an image capture device during a capture duration. The rotational positions of the image capture device may change during the capture duration. The rotational positions of the image capture device may be smoothed based on a look ahead of a rotation constraint. A punchout of the visual content may be determined based on the smoothed rotational positions. The punchout of the visual content may be used to generate stabilized visual content.