A CPU of a controller of a mounting device determines an aperture and a light exposure time so that tip portion falls within the depth of field (DOF) of component camera based on information about the height of tip portion which is an imaging target portion in component and controls component camera so as to image the component with the determined aperture and light exposure time.

Provided is a technology enabling an imaging apparatus and an interchangeable lens to appropriately perform initialization processes. An interchangeable lens includes a lens control unit configured to transmit lens-side initialization execution element information indicating a plurality of lens-side elements on which the lens control unit itself performs initialization to an imaging apparatus in response to reception of body-side initialization execution element information indicating body-side elements on which the imaging apparatus performs initialization from the imaging apparatus. The technology can be applied to, for example, a camera system including a detachable interchangeable lens and an imaging apparatus serving as a camera body side.

A method of obtaining an image from an image sensor provided in a vehicle includes obtaining a vehicle speed of the vehicle; adjusting a shutter speed of the image sensor; adjusting either one or both of an international organization for standardization sensitivity (ISO) of the image sensor and an aperture of the image sensor based on the vehicle speed; and obtaining the image from the image sensor based on the adjusted shutter speed and the adjusted either one or both of the ISO and the aperture.

[Object] To provide an imaging control apparatus that enables a parameter that complies with the intention of a user, to be automatically set at the time of image capturing.

[Solution] Provided is an imaging control apparatus including: a control unit configured to change a display that consecutively describes a relationship between parameters of two or more image capturing conditions, in accordance with an operation performed by a user, and to change a setting of the relationship in accordance with a change of the display. With this configuration, the imaging control apparatus enables a parameter that complies with the intention of a user, to be automatically set at the time of image capturing.

An imaging system includes a digital camera and illuminating devices. The digital camera includes an imaging optical system, a shutter, a shutter driving mechanism, an imaging element, an illumination control unit, and a wireless I/F. The shutter is a focal-plane shutter. In a case in which a main imaging operation is performed in a plural illumination control mode, the shutter driving mechanism drives the shutter to generate a transition period for which a partial exposure region is transferred to the lower side of an imaging area of the imaging element over time. The illumination control unit controls the emission times of the illuminating devices to be different times within the transition period.

Provided is a technology enabling an imaging apparatus and an interchangeable lens to appropriately perform initialization processes. An interchangeable lens includes a lens control unit configured to transmit lens-side initialization execution element information indicating a plurality of lens-side elements on which the lens control unit itself performs initialization to an imaging apparatus in response to reception of body-side initialization execution element information indicating body-side elements on which the imaging apparatus performs initialization from the imaging apparatus. The technology can be applied to, for example, a camera system including a detachable interchangeable lens and an imaging apparatus serving as a camera body side.

The present invention relates to the field of video camera image processing. Disclosed are an intelligent adjustment method when a video camera performs automatic exposure and an apparatus therefor. In the present invention, a first corresponding relationship between a rate and an aperture is pre-set. The first corresponding relationship records corresponding upper and lower aperture limits required by each rate for achieving the best depth of field of an image. The method comprises the following steps: acquiring the current rate of a video camera; searching for upper and lower aperture limits corresponding to the current rate in a first corresponding relationship; if the current aperture value exceeds the range of the searched upper and lower aperture limits corresponding to the current rate, adjusting the current aperture value to be within the range of the upper and lower aperture limits; and according to the adjusted aperture value, adjusting exposure time and gain to satisfy the need of image brightness. In the present invention, according to different field scenario rates, the aperture is adjusted to be within the aperture range corresponding to the best depth of field so as to acquire the best depth of field, and a shutter and gain are adjusted accordingly, so that the best brightness can be ensured and the best depth of field is achieved at the same time so as to improve image quality.

A control apparatus according to the present disclosure includes a frame rate control unit configured to control a frame rate of imaging, and a transmittance control unit configured to control transmittance of a filter which transmits light incident on an imaging element according to change of the frame rate so that brightness of an imaged subject is maintained. According to this configuration, even when the frame rate changes, it is possible to maintain fixed brightness according to change of the frame rate without causing change in imaging quality.

To enable achievement of a reduction in the thickness in a blade driving device that includes a driving member, and to enable a reduction in size of an installation area in a blade driving device that includes a driving member. The blade driving device 1 comprises a base member 2 that has an opening 2A, one or more blade members 3 that operate so as to advance into the opening 2A or withdraw from the opening 2A, and a driving member 4 that is supported on the base member 2 and that moves within a plane that is perpendicular to an optical axis that passes through the opening 2A, for driving the blade member, wherein the driving member 4 is disposed at a position that overlaps the blade member on the periphery of the opening 2A.

The present disclosure generally discloses single-aperture multi-sensor lensless compressive image acquisition capabilities. The present disclosure generally discloses a single-aperture multi-sensor lensless camera including a programmable aperture and a set of sensors. The programmable aperture is configured to modulate an amount of light permitted to pass through the programmable aperture and has a shape defined based on a set of vertices of the programmable aperture. The sensors are arranged, with respect to each other, based on the vertices of the programmable aperture. The sensors may be arranged such that respective reference lines, between the respective vertices of the programmable aperture and the respective sensors, are parallel or substantially parallel.