A multiscale telescopic imaging system is disclosed. The system includes an objective lens, having a wide field of view, which forms an intermediate image of a scene at a substantially spherical image surface. A plurality of microcameras in a microcamera array relay image portions of the intermediate image onto their respective focal-plane arrays, while simultaneously correcting at least one localized aberration in their respective image portions. The microcameras in the microcamera array are arranged such that the fields of view of adjacent microcameras overlap enabling field points of the intermediate image to be relayed by multiple microcameras. The microcamera array and objective lens are arranged such that light from the scene can reach the objective lens while mitigating deleterious effects such as obscuration and vignetting.

Described herein is an aerial imaging system (100) including a plurality of cameras (104-107) configured to be mounted in operable positions on an underside of an aerial vehicle (102). Each camera (104-107) is oriented at a respective angle in a direction transverse to a direction of flight of the aerial vehicle (102) such that the cameras image separate non-overlapping fields of view during image capture. Also described herein is a method (400) of performing aerial photogrammetry using the aerial imaging system (100).

In an embodiment, a system includes an immersive camera module including a camera mounting block having a plurality of camera mounting sites and a plurality of cameras mounted to the plurality of camera mounting sites. Each of the plurality of cameras includes a partially-overlapping field of view, and the camera module is configured to comprehensively capture a target space. The system further includes a chassis operatively coupled with the immersive camera module, the chassis configured to smoothly maneuver the camera module comprehensively through the target space. Aspects herein can also relate to methods for capturing immersions, systems and methods for providing immersions, and systems and methods for viewing and controlling immersions.

System and method for improving the shaving experience by providing improved visibility of the skin shaving area. A digital camera is integrated with the electric shaver for close image capturing of shaving area, and displaying it on a display unit. The display unit can be integral part of the electric shaver casing, or housed in a separated device which receives the image via a communication channel. The communication channel can be wireless (using radio, audio or light) or wired, such as dedicated cabling or using powerline communication. A light source is used to better illuminate the shaving area. Video compression and digital image processing techniques are used for providing for improved shaving results. The wired communication medium can simultaneously be used also for carrying power from the electric shaver assembly to the display unit, or from the display unit to the electric shaver.

A plurality of multi-camera systems and methods for imaging faint objects are disclosed, which includes an array of cameras that, when taken alone, are incapable of imaging such objects. The systems and methods may include common field arrays, hybrid field arrays, and/or adaptive field arrays.

Many embodiments can comprise a system. The system can comprise one or more processors and one or more storage devices. The one or more storage devices can be configured to store computing instructions that, when executed, cause the processor to receive a plurality of images of an object, the plurality of images comprising different views of the object from around the object; iteratively align one or more images within one or more subsets of the plurality of images until the object is aligned from image to image within the one or more subsets of the plurality of images; and selectively align respective images of the one or more subsets to each other to produce a surround image. Other embodiments are disclosed herein.

A system comprises a photodetector array comprising a plurality of pixels, and a plurality of image processors. The photodetector array is logically partitioned into a plurality of regions comprising a central region, a first peripheral region, and a second peripheral region. Each image processor is configured to process image data generated by a respective one of the regions of the photodetector array.

Illustrative methods and systems for generating virtual reality content based on corrections to stitching errors are described. An illustrative computer-implemented method includes receiving raw virtual reality video data representing images recorded by camera modules of a camera array, using a stitching algorithm to stitch the images together to generate an initial virtual reality render, determining that the initial virtual reality render has a stitching error, determining a correction for the stitching error, and modifying the stitching algorithm based on the correction for the stitching error. The modified stitching algorithm may be used to generate a corrected virtual reality render that corrects the stitching error.

A solid-state imaging device including an imager that acquires image data, a processing unit that performs a process based on a neural network calculation model for data based on the image data acquired from the imager, and a control unit that switches between a first process mode of performing a first process at a first frame rate and, based on a result of the first process, a second process mode of performing a second process at a second frame rate.

Generally described, one or more aspects of the present application correspond to systems and techniques for spectral imaging using a multi-aperture system with curved multi-bandpass filters positioned over each aperture. The present disclosure further relates to techniques for implementing spectral unmixing and image registration to generate a spectral datacube using image information received from such imaging systems. Aspects of the present disclosure relate to using such a datacube to analyze the imaged object, for example to analyze tissue in a clinical setting, perform biometric recognition, or perform materials analysis.