An array imaging module includes at least two optical lenses and a molded photosensitive assembly, wherein the molded photosensitive assembly includes at least two photosensitive units, a circuit board that electrically couples to the photosensitive units, and a molded base having at least two optical windows. The molded base is integrally coupled at the circuit board at a peripheral portion thereof, wherein the photosensitive units are aligned with the optical windows respectively. The optical lenses are located along two photosensitive paths of the photosensitive units respectively, such that each of the optical windows forms a light channel through the corresponding photosensitive unit and the corresponding optical lens.

An image capturing apparatus comprises: a first image sensor having a plurality of pixels each counts a number of entering photons and outputs a count value as a first image signal; a second image sensor having a plurality of pixels each outputs an electric signal corresponding to a charge amount obtained by performing photoelectric conversion on entering light as a second image signal; and a generator that generates an image by selecting one of the first image signal and the second image signal.

Disclosed are systems, methods, and structures for monocentric multiscale gigapixel imaging systems and cameras employing a Galilean architecture wherein adjacent subimages do not overlap while advantageously producing a reduced system volume, improved relative illumination and image quality as compared with prior art systems.

An image capturing apparatus comprises: a first image sensor having a plurality of pixels each counts a number of entering photons and outputs a count value as a first image signal; a second image sensor having a plurality of pixels each outputs an electric signal corresponding to a charge amount obtained by performing photoelectric conversion on entering light as a second image signal; and a generator that generates an image by selecting one of the first image signal and the second image signal.

The invention relates to an apparatus (1) and a method for area mapping, wherein the apparatus (1) for area mapping includes a framework having a main camera (2) and/or a main sensor attached to the framework, and at least two auxiliary cameras (3) and/or auxiliary sensors attached to the framework, wherein the main camera (2) and/or the main sensor as well as the at least two auxiliary cameras (3) and/or the at least two auxiliary sensors have a defined camera footprint (8, 9) on the ground and a defined ground image resolution, wherein the camera footprint (8) of the auxiliary cameras (3) and/or auxiliary sensors on the ground is smaller than the camera footprint (9) of the main camera (2) and/or of the main sensor on the ground and lies at least partially within same, and the ground image resolution of the auxiliary cameras (3) and/or auxiliary sensors is greater than the ground image resolution of the main camera (2) and/or of the main sensor, and the auxiliary cameras (3) and/or auxiliary sensors are aligned such that images generated by the auxiliary cameras (3) and/or auxiliary sensors at least partially overlap, and the area mapping apparatus (1) has at least one GNSS receiver and a trigger mechanism, wherein the GNSS receiver, the main camera (2) and/or the main sensor and the at least two auxiliary cameras (3) and/or auxiliary sensors are coupled to the trigger mechanism, as a result of which quick creation of high-resolution, georeferenced orthomosaic images of areas and high area coverage is made possible.

An auto-focus method including at a same moment, collecting a first image of a first object using a first image shooting unit, collecting a second image of the first object using a second image shooting unit, calculating M pieces of first depth information of M same feature point pairs in corresponding areas in the first image and the second image, determining whether confidence of the M pieces of first depth information is greater than a threshold, obtaining focusing depth information according to N pieces of first depth information in the IM pieces of first depth information when the confidence of the M pieces of first depth information is greater than the threshold, obtaining a target position of a first lens of the first image shooting unit according to the focusing depth information, and controlling the first lens to move to the target position.

According to the present invention, it is an object to provide an imaging apparatus and an imaging method in which there is no need for registration between images corresponding to a plurality of specific wavelengths, which is capable of acquiring images corresponding to a plurality of specific wavelengths based on light information at the same position of a subject so as to reduce the calculation load for acquiring the images corresponding to the plurality of specific wavelengths. The imaging apparatus (10) includes: an optical member (101) that refracts first light and second light having mutually different wavelengths of light with refractive indexes corresponding to the respective wavelengths so as to shift a position of a first image of the first light and a position of a second image of the second light; a light transmissive filter (103); and a directional sensor (17). The optical member shifts the position of the first image and the position of the second image on the directional sensor by one pitch of the pixels on the basis of a difference in refractive index due to a difference between the wavelength of the first light and the wavelength of the second light.

The present disclosure provides an imaging device including a wide-angle camera and a telephoto camera. A field of view of the telephoto camera is located in a field of view of the wide-angle camera, the telephoto camera includes a telephoto lens. The telephoto lens includes: at least one first lens element, a light reflecting element and at least one second lens element arranged sequentially from an object side to an image side along a light axis. The light reflecting element is configured to make the light axis to reflect from a first direction to a second direction. An electronic device including the imaging device is further provided. In the imaging device and the electronic device above, the light axis of the telephoto camera is reflected, lowering a height of the telephoto lens and a height of the telephoto camera.

An imaging device includes a multifocal lens switchable between a plurality of types of angular fields, an angular field controller, an image sensor, a signal processor, and an image processor. The angular field controller receives angular field information indicating an angular field used for capturing an image, and controls the angular field of the multifocal lens based on the angular field information. The image sensor converts light passing through the multifocal lens into an electrical signal. The signal processor converts the electrical signal into an image signal. The image processor receives the angular field information and the image signal, performs predetermined image processing on the image signal based on a parameter which is predetermined in accordance with the angular field information, and externally outputs the image data obtained by the image processing.

An inventive device includes a multi-aperture imaging device comprising an image sensor; an array of adjacently arranged optical channels, each optical channel including an optic for projecting at least one partial field of view of a total field of view onto an image sensor area of the image sensor arrangement, a beam deflection means for deflecting an optical path of the optical channels, and a focusing means for setting a focal position of the multi-aperture imaging device. The device further comprises a control means configured to control the focusing means and to receive image information from the image sensor; the control means being configured to control the multi-aperture imaging device into a sequence of focal positions so as to capture a corresponding sequence of image information of the total field of view and to produce, from the sequence of image information, a depth map for the captured total field of view.