There is provided an imaging device including an imaging control unit that executes imaging control in first and second self-timer modes in which an automatic focusing process and an imaging process are executed in order after reception of an imaging start instruction. A first period from the reception of the imaging start instruction to execution of the automatic focusing process in the first self-timer mode is shorter than a second period from the reception of the imaging start instruction to execution of the automatic focusing process in the second self-timer mode.

There is provided an imaging device including an imaging control unit that executes imaging control in first and second self-timer modes in which an automatic focusing process and an imaging process are executed in order after reception of an imaging start instruction. A first period from the reception of the imaging start instruction to execution of the automatic focusing process in the first self-timer mode is shorter than a second period from the reception of the imaging start instruction to execution of the automatic focusing process in the second self-timer mode.

Provided is a projection-type video display device implementing further reduction of a projection distance and further miniaturization of a projection optical system. The projection-type video display device includes a lens group which includes a plurality of lenses, a free-form-surface lens, and a free-form-surface mirror which projects light from the free-form-surface lens on a screen, wherein the lens group includes a third lens which has a bi-convex shape, a fourth lens which has a bi-concave shape, a fifth lens which has a bi-convex shape, the third to fifth lenses constitute a triplet lens, and wherein the free-form-surface lens has a meniscus lens shape of which a convex surface is oriented toward the magnification side.

Provided is a projection-type video display device implementing further reduction of a projection distance and further miniaturization of a projection optical system. The projection-type video display device includes a lens group which includes a plurality of lenses, a free-form-surface lens, and a free-form-surface mirror which projects light from the free-form-surface lens on a screen, wherein the lens group includes a third lens which has a bi-convex shape, a fourth lens which has a bi-concave shape, a fifth lens which has a bi-convex shape, the third to fifth lenses constitute a triplet lens, and wherein the free-form-surface lens has a meniscus lens shape of which a convex surface is oriented toward the magnification side.

There is provided an image pickup device including: a composition detection unit configured to calculate a time at which an object that is specified by a user and is included in a captured image achieves a composition specified by the user; a time calculation unit configured to calculate a time after start instruction of image pickup operation is issued but before an image is captured; and an image pickup control unit configured to start image pickup processing of the image in response to the start instruction of the image pickup operation. The composition detection unit issues the start instruction of the image pickup operation to the image pickup control unit the time calculated by the time calculation unit before the time at which the composition specified by the user is achieved.

There is provided an image pickup device including: a composition detection unit configured to calculate a time at which an object that is specified by a user and is included in a captured image achieves a composition specified by the user; a time calculation unit configured to calculate a time after start instruction of image pickup operation is issued but before an image is captured; and an image pickup control unit configured to start image pickup processing of the image in response to the start instruction of the image pickup operation. The composition detection unit issues the start instruction of the image pickup operation to the image pickup control unit the time calculated by the time calculation unit before the time at which the composition specified by the user is achieved.

There is provided an imaging device including an imaging control unit that executes imaging control in first and second self-timer modes in which an automatic focusing process and an imaging process are executed in order after reception of an imaging start instruction. A first period from the reception of the imaging start instruction to execution of the automatic focusing process in the first self-timer mode is shorter than a second period from the reception of the imaging start instruction to execution of the automatic focusing process in the second self-timer mode.

An approach is provided to adjust a camera shutter lag. In the approach, data is collected that corresponds to an ambient light found in a physical environment with the ambient light being controlled using a pulse-width modulation (PWM). The pulse-width modulation corresponds to a PWM timing model. When an exposure request is received, the camera shutter lag is calculated using the PWM timing model. The calculated shutter lag is based on a future point in time at which the ambient light of the physical environment is predicted to be at a selected light output level, such as a power level selected by the user of a camera. When the calculated camera shutter lag has expired, a shutter of the camera is opened causing a camera lens to be exposed that results in a captured exposure.

An approach is provided to adjust a camera shutter lag. In the approach, data is collected that corresponds to an ambient light found in a physical environment with the ambient light being controlled using a pulse-width modulation (PWM). The pulse-width modulation corresponds to a PWM timing model. When an exposure request is received, the camera shutter lag is calculated using the PWM timing model. The calculated shutter lag is based on a future point in time at which the ambient light of the physical environment is predicted to be at a selected light output level, such as a power level selected by the user of a camera. When the calculated camera shutter lag has expired, a shutter of the camera is opened causing a camera lens to be exposed that results in a captured exposure.