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.

The imaging device includes a multiple-property lens that includes a first area having a first property and a second area having a second property different from the first property, an image sensor in which a first light receiving element 25A and a second light receiving element 25B having a different opening size of a light receiving section from the first light receiving element 25A are two-dimensionally arranged, and a crosstalk removal processing unit that removes a crosstalk component from each of a first crosstalk image acquired from the first light receiving element 25A of the image sensor and a second crosstalk image acquired from the second light receiving element to generate a first image and a second image respectively having the first property and the second property of the multiple-property 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.

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.

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.

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.

A cloud vision monitoring system and a cloud vision monitoring device are provided. The cloud vision monitoring system includes a server and a first cloud vision monitoring device. The first cloud vision monitoring device detects at least one feature of an object based on an image of the object. The first cloud vision monitoring device includes a camera, a multi-directional image capturing auxiliary module, and a serial control communication module. When the object is placed between a first side and a second side of the multi-directional image capturing auxiliary unit of the multi-directional image capturing auxiliary module, the camera module simultaneously captures a first image and a second image of the object, and the first image and the second image are images of two opposite sides of the object, respectively.

An imaging device includes an illuminator, a stage, a plurality of microlenses, an imaging element, and a controller. The controller is configured to control at least one of an irradiation position of light beams from the illuminator, and the position of the plurality of microlenses to realize a first state and a second state. A first angle of the light beams incident to each of the plurality of microlenses in the first state and a second angle of the light beams incident to each of the plurality of microlenses in the second state are different from each other.

In some embodiments, imaging apparatus for imaging blood vessels within a target region of tissue includes a housing having an aperture which, in use, is placed against a target region of tissue such that the target region of tissue occludes the aperture, a light source arranged to illuminate at least a portion of a target region of tissue occluding the aperture and to provide illuminating light having predetermined first and second spectral ranges which are different, an imaging device arranged to receive illuminating light reflected by the target region of tissue occluding the aperture, wherein the imaging device is configured to generate image output at the first and second spectral ranges, and a controlling element arranged to selectively control the imaging device and/or the light source to sequentially capture at least one image at the first spectral range and at least one image at the second spectral range.