In order to provide a range measurement apparatus which enables an accurate distance measurement while an anti-vibration mechanism is operated, the range measurement apparatus includes an image information acquisition unit configured to acquire an image captured by an image pickup optical system having an anti-vibration optical system, a distance information acquisition unit configured to acquire distance information regarding a distance to a subject based on the image, and a distance correction unit configured to correct the distance information based on aberration information according to a driving amount of the anti-vibration optical system.

Disclosed are an image capturing system and method. In the image capturing system and method, a light path is changed by controlling a reflection angle of a mirror surface using a rotating mirror so that a single camera obtains consecutive images at various angles or at a wide photographing width.

Disclosed are an image capturing system and method. In the image capturing system and method, a light path is changed by controlling a reflection angle of a mirror surface using a rotating mirror so that a single camera obtains consecutive images at various angles or at a wide photographing width.

A terminal includes a camera, a laser transceiver, a protection glass, and an infrared cut-off coating. The camera includes an image sensor and N lenses; the image sensor is disposed at the rear of the N lenses, and is configured to: receive an optical signal penetrating the protection glass and the N lenses, and convert the optical signal into an electrical signal. The protection glass is disposed in front of the N lenses, and is configured to protect the N lenses. The laser transceiver is configured to transmit or receive a laser. The infrared cut-off coating is located on at least one surface of the protection glass and/or on at least one surface of at least one lens in the N lenses, and a cut-off wavelength of the infrared cut-off coating is corresponding to a center wavelength of the laser transmitted by the laser transceiver.

A terminal includes a camera, a laser transceiver, a protection glass, and an infrared cut-off coating. The camera includes an image sensor and N lenses; the image sensor is disposed at the rear of the N lenses, and is configured to: receive an optical signal penetrating the protection glass and the N lenses, and convert the optical signal into an electrical signal. The protection glass is disposed in front of the N lenses, and is configured to protect the N lenses. The laser transceiver is configured to transmit or receive a laser. The infrared cut-off coating is located on at least one surface of the protection glass and/or on at least one surface of at least one lens in the N lenses, and a cut-off wavelength of the infrared cut-off coating is corresponding to a center wavelength of the laser transmitted by the laser transceiver.

A processing apparatus includes a control unit that performs a control of performing, a plurality of times in parallel, a recognition operation in which a recognition unit recognizes a specific subject included in an imaging region based on a captured image obtained by imaging the imaging region by an imaging unit, and a distance measurement operation in which a distance measurement unit performs distance measurement by emitting light to the imaging region and receiving reflected light of the light from the imaging region, and a change unit that changes irradiation energy of the light to the imaging region for each distance measurement operation.

The present technology relates to an imaging device capable of efficiently separating signals having different characteristics. An image generating unit generates an image of a subject on the basis of pixel signals obtained by performing imaging in a state where light of a predetermined pattern from a structured light (SL) light source is irradiated to projection areas of specific pixels of an imaging unit that images the subject. The present disclosure can be applied to, for example, a camera system including an SL light source and an imaging device.

The present technology relates to an imaging device capable of efficiently separating signals having different characteristics. An image generating unit generates an image of a subject on the basis of pixel signals obtained by performing imaging in a state where light of a predetermined pattern from a structured light (SL) light source is irradiated to projection areas of specific pixels of an imaging unit that images the subject. The present disclosure can be applied to, for example, a camera system including an SL light source and an imaging device.

A camera for detecting an object moved through a detection zone is provided that has an image sensor for recording image data, a reception optics having a focus adjustment unit for setting a focal position, a distance sensor for measuring a distance value from the object, and a control and evaluation unit connected to the distance sensor and the focus adjustment unit to set a focal position in dependence on the distance value, and to trigger a recording of image data at a focal position at which there is a focus deviation from a focal position that is ideal in accordance with the measured distance value, with the focus deviation remaining small enough for a required image definition of the image data.

An image pickup device, provided with a camera unit that is provided with a lens barrel, an autofocus unit disposed on the outside of the lens barrel, a lens barrel holding member that holds the lens barrel, and a camera case that engages the lens barrel holding member and covers the autofocus unit, the camera unit provided with a base member that supports the camera unit rotatably around a rotation axis, and a regulating member that restricts the rotation of the camera unit to a first rotation range. In the image pickup device, the camera case engages with the lens barrel holding member when the camera unit is in the first rotation range, the regulating member being detachable, and the camera case being detachable from the lens barrel holding member when the camera unit is in the second rotation range.