An imaging apparatus according to the present technology includes an image sensor, and multiple lens sections each configured to form a subject image in a different area of the image sensor via a different wavelength filter. At least one of the multiple lens sections has an angle of view different from an angle of view of the other lens sections.

The present technology relates to a compound-eye camera module and an electronic device in which a plurality of monocular camera modules can be fixed together by a connecting member more effectively. In the compound-eye camera module, a camera-side positioning portion for positioning formed on a camera-side reference surface of each of the monocular camera modules and a member-side positioning portion for positioning formed on a member-side reference surface of the connecting member are fitted together, to connect the plurality of monocular camera modules together, whereby the plurality of monocular camera modules can be fixed together by the connecting member more effectively. The present technology can be applied to, for example, a compound-eye camera module in which a plurality of CMOS image sensors is connected together.

The present technology relates to a compound-eye camera module and an electronic device in which a plurality of monocular camera modules can be fixed together by a connecting member more effectively. In the compound-eye camera module, a camera-side positioning portion for positioning formed on a camera-side reference surface of each of the monocular camera modules and a member-side positioning portion for positioning formed on a member-side reference surface of the connecting member are fitted together, to connect the plurality of monocular camera modules together, whereby the plurality of monocular camera modules can be fixed together by the connecting member more effectively. The present technology can be applied to, for example, a compound-eye camera module in which a plurality of CMOS image sensors is connected together.

An imaging apparatus, an unmanned moving object, an imaging method, a system, and a program capable of favorably compositing a telephoto image group even in a case where an overlapping region between images of the telephoto image group is small, and accurately compositing a telephoto image regardless of a subject (scene) of a wide angle image are provided. An imaging apparatus (100) includes an imaging optical system, a directional sensor, a wide dynamic range image generation part (302) that generates a wide dynamic range wide angle image obtained by enlarging a dynamic range of a wide angle image, an image acquisition part (2a) that acquires a wide dynamic range wide angle image group and a telephoto image group configured with a telephoto image, a composition information acquisition part (2b) that acquires composition information to be used for compositing the telephoto image group by analyzing the acquired wide dynamic range wide angle image group, and a composite image generation part (2c) that generates an image in which the telephoto image group is composited, based on the composition information, information related to focal lengths of the wide angle optical system and the telephoto optical system, and the telephoto image group.

There is provided an all-celestial imaging apparatus enabling imaging of images that enable estimation of depth information relating to an object to be imaged by suppressing any generation of occlusion. An all-celestial imaging apparatus that is an aspect of the present technique includes plural imaging parts each arranged being directed in a direction different from that of each other, and the plural imaging parts are arranged such that all imaging ranges on at least one circumference of the imaging ranges by the plural imaging parts are each overlapped by angles of view of two or more pairs of the imaging parts. The present technique is applicable to, for example, an all-celestial camera imaging images that are used in the case where the depth information on a distance to an object to be imaged that may be present in an optional direction of all azimuth directions of 360 is estimated.

Provided are an excellent vehicle-mounted camera to be used by being attached to a windshield or the like of a vehicle, a vehicle-mounted camera apparatus, and a method of supporting a vehicle-mounted camera. The vehicle-mounted camera includes a substrate, an image pickup element mounted on the substrate, an image processing circuit that is mounted on the substrate and processes a captured image by the image pickup element, a light collection optical unit that collects incident light, and a reflection unit that reflects output light from the light collection optical unit to the image pickup element. The vehicle-mounted camera further includes a casing that accommodates the substrate on which at least the image pickup element and the image processing circuit are mounted, the light collection optical unit, and the reflection unit.

Provided are an excellent vehicle-mounted camera to be used by being attached to a windshield or the like of a vehicle, a vehicle-mounted camera apparatus, and a method of supporting a vehicle-mounted camera. The vehicle-mounted camera includes a substrate, an image pickup element mounted on the substrate, an image processing circuit that is mounted on the substrate and processes a captured image by the image pickup element, a light collection optical unit that collects incident light, and a reflection unit that reflects output light from the light collection optical unit to the image pickup element. The vehicle-mounted camera further includes a casing that accommodates the substrate on which at least the image pickup element and the image processing circuit are mounted, the light collection optical unit, and the reflection unit.

With a wide angle-of-view image acquired by an image pickup unit 21-1 as a reference, a signal processing unit 30 performs super-resolution processing by using a plurality of narrow angle-of-view images acquired by an image pickup unit 21-2 that uses a lens having a higher MTF (Modulation Transfer Function) than the image pickup unit 21-1. A control unit 60 controls the signal processing unit 30 so as to select an image having a range of angle of view according to a zoom magnification indicated by user's operation from the image subjected to the super-resolution processing. In the super-resolution processing, according to a detection result of parallax from a narrow angle-of-view image and the wide angle-of-view image acquired at the same time and a motion detection result for each of the plurality of narrow angle-of-view images, parallax compensation and motion compensation are performed on the plurality of narrow angle-of-view images. A captured image beyond the performance of the image pickup unit can be acquired.

The present invention provides an imaging device wherein an imaging unit can be stably supported by a bracket and adverse effects on the imaging unit caused by differences in the amount of thermal expansion between the bracket and the imaging unit can be reduced. This imaging device 1 is provided with an imaging unit 10 attachable to the bracket. The imaging unit 10 is provided with a plurality of supported parts 15 to be supported by the bracket. The supported parts 15 are provided on both ends of the imaging unit 10 in the width direction DW crossing the light axis OA direction at one end of the imaging unit 10 in the light axis OA direction, and in the center part in the width direction DW at the other end of the imaging unit 10 in the light axis OA direction. The supported parts 15 have supported points 15a, which are supported by the bracket, and load points 15b, which receive the biasing force operating toward the supported points 15a from the bracket.

The present invention provides an imaging device wherein an imaging unit can be stably supported by a bracket and adverse effects on the imaging unit caused by differences in the amount of thermal expansion between the bracket and the imaging unit can be reduced. This imaging device 1 is provided with an imaging unit 10 attachable to the bracket. The imaging unit 10 is provided with a plurality of supported parts 15 to be supported by the bracket. The supported parts 15 are provided on both ends of the imaging unit 10 in the width direction DW crossing the light axis OA direction at one end of the imaging unit 10 in the light axis OA direction, and in the center part in the width direction DW at the other end of the imaging unit 10 in the light axis OA direction. The supported parts 15 have supported points 15a, which are supported by the bracket, and load points 15b, which receive the biasing force operating toward the supported points 15a from the bracket.