When detecting particulate radiation, such as electrons, with a pixelated detector, a cloud of electron/hole pairs is formed in the detector. Using the signal caused by this cloud of electron/hole pairs, a position of the impact is estimated. When the size of the cloud is comparable to the pixel size, or much smaller, the estimated position shows a strong bias to the center of the pixel and the corners, as well to the middle of the borders. This hinders forming an image with super-resolution. By shifting the position or by attributing the electron to several sub-pixels this bias can be countered, resulting in a more truthful representation.

An image generation apparatus includes first and second light sources, an image sensor, a mask, and a processing circuit. The image sensor acquires a first image when the first light source is energized and acquires a second image when the second light source is energized. The processing circuit obtains a pixel value based on a direct light component or a pixel value based on a component other than the direct light component corresponding to a focal point by using pixel values of first pixel regions of the first image, pixel values of second pixel regions of the second image, the ratios of the direct light and the light other than the direct light from the first light source, and the ratios of the direct light and the light other than the direct light from the second light source and generates a cross-sectional image of a substance on the focal plane.

Systems and methods for implementing array cameras configured to perform super-resolution processing to generate higher resolution super-resolved images using a plurality of captured images and lens stack arrays that can be utilized in array cameras are disclosed. An imaging device in accordance with one embodiment of the invention includes at least one imager array, and each imager in the array comprises a plurality of light sensing elements and a lens stack including at least one lens surface, where the lens stack is configured to form an image on the light sensing elements, control circuitry configured to capture images formed on the light sensing elements of each of the imagers, and a super-resolution processing module configured to generate at least one higher resolution super-resolved image using a plurality of the captured images.

The present invention regards a method for measuring displacement of a surface at a region of interest when the region of interest is exposed to a load. The method includes the steps of (1) evenly illuminating the surface; (2) by means of a camera capturing a first set of images comprising a first image of the surface, applying a load to the surface at the region of interest, and capturing a second image of the surface; and (3) transmitting the first and second image to a processing module of a computer, wherein the processing module: (a) includes data relating to the image capture, such as the spatial position and field of view of the camera relative to the surface when the images were captured; (b) generates a global perspective transform from selected regions out of the displacement area (c) performs a global image registration between the two images using perspective transform to align the images; (d) computes vertical pixel shift and horizontal pixel shift between the first image and the second image for the region of interest; and (e) computes displacement of the region of interest between the images, in length units. The images are captured by the camera at an image camera position relative to the surface. In some embodiments two cameras are used, each capturing a single image from the same image camera position; in some embodiments multiple sets of images are captured by multiple cameras, from different perspectives.

Described herein are systems and methods for noninvasive functional brain imaging using low-coherence interferometry (e.g., for the purpose of creating a brain computer interface with higher spatiotemporal resolution). One variation of a system and method comprises optical interference components and techniques using a lock-in camera. The system comprises a light source and a processor configured to rapidly phase-shift the reference light beam across a pre-selected set of phase shifts or offsets, to store a set of interference patterns associated with each of these pre-selected phase shifts, and to process these stored interference patterns to compute an estimate of the number of photons traveling between a light source and the lock-in camera detector for which the path length falls within a user-defined path length range.

A system for generating an image of a region of interest (ROI) of a target object, the system including a camera, a target stage configured to receive the target object, the target stage configured to provide a translational movement and a rotational movement of the target object, and a controller. The controller is configured to control the camera and target stage to iteratively shift the target along scan trajectories of sample locations to capture images of each of a plurality of concentric rings and sub-rings of a predefined radial pitch over the ROI, the sample locations represented by polar coordinates defining sectors of each of the sub-rings. The controller is further configured to extract super resolution (SR) pixels from the images to reconstruct an SR image of each of the rings in the polar coordinates, and project the SR images into Cartesian coordinate images.

This invention describes a technique to enhance pixel resolution of high-speed laser scanning imaging by the means of sub-pixel sampling, applicable to one-dimensional (1D), two-dimensional (2D), and three-dimensional (3D) imaging.

An image pickup apparatus includes: an image pickup device that includes pixels in a predetermined color array and is configured to be able to acquire a plurality of color array images corresponding to the color array through pixel shift; a chromatic aberration correction processing section configured to receive the plurality of color array images and to perform chromatic aberration correction processing on each of the plurality of color array images; a pixel shift composition processing section configured to perform pixel shift composition processing on the plurality of color array images that are subjected to the chromatic aberration correction processing by the chromatic aberration correction processing section, to acquire a pixel shift high-resolution image; and a demosaicking processing section configured to perform demosaicking processing on the pixel shift high-resolution image.

An image-processing apparatus includes a computer configured to: detect a positional-displacement amount between low-resolution images including a standard image and at least one reference image that are acquired in a time series; generate a high-resolution combined image by positioning, based on the positional-displacement amount detected, pixel information of the reference image at a standard-image position and by performing combining thereof in a high-resolution image space; evaluate a positioning error caused by a resolution-enhancement magnification used when positioning the reference image in the high-resolution image space when generating the high-resolution combined image; and correct the high-resolution combined image based on the evaluation result, wherein the correcting of the high-resolution combined image combines a high-resolution correction image generated by applying a filter to the high-resolution combined image based on the evaluation result obtained, and the high-resolution combined image in accordance with combining ratios based on the evaluation result.

An image generating system according to an aspect of the present disclosure includes an image obtaining device, an image generating circuit, and an image processing circuit. The image obtaining device includes an illuminating system that irradiates an object included in a module in which the object and an imaging element are integrated together, with light sequentially from a plurality of different radiation directions. The image obtaining device obtains a plurality of images corresponding to the plurality of different radiation directions. The image generating circuit generates a high-resolution image of the object having a higher resolution than each of the plurality of images by combining the plurality of images together. The image processing circuit detects noise resulting from a foreign object located farther from an imaging surface of the imaging element than the object and removes the noise.