A high-resolution imaging apparatus that includes a multi-purpose high-energy particle sensor array to initially stop high-energy particles and then transfer the down-converted photons into near zero energy photoelectrons is described, as well as the method to produce the same. The imaging apparatus is a segmented scintillator structure optically coupled to a closely placed photocathode structure for high-efficiency conversion of high-energy particles with an arbitrary spatial distribution to the corresponding distribution of photoelectrons, emitted with a very low spread in energy and momentum.

Disclosed herein are methods of making and using an absorption-unit array suitable for X-ray detection and a detector comprising such an absorption-unit array. The methods of making the absorption-unit array may include forming the absorption-unit array on a substrate and forming a guard ring encompassing more than one absorption units of the absorption-unit array after separating the absorption-unit array from the substrate; or may include forming a plurality of absorption units and a guard ring encompassing more than one of the absorption units on a portion of a substrate after separating the portion from the substrate. The method of using an absorption-unit array may include using some of the absorption units of the absorption-unit array as a guard ring by applying an electrical voltage. A detector suitable for X-ray detection comprises an absorption layer and an electronics layer, wherein the absorption layer comprises an absorption-unit array.

Disclosed herein is a detector, comprising: a plurality of pixels; a first guard ring comprising a plurality of segments, wherein the detector is configured to detect charge carriers collected by the segments; a controller configured to detect charge sharing between at least one pixel of the plurality of pixels and at least one segment of the first guard ring.

Disclosed herein is a detector, comprising: a plurality of pixels, a plurality of segments of guard ring, and a controller, is configured to count numbers of X-ray photons that incident on each pixel of the plurality, and whose energy falls in a plurality of bins, within a period of time. The controller, is configured to detect charge sharing between pixels and segments of guard ring. With charge sharing detected, the controller is also configured to disregard one single photon. With no charge sharing detected, the controller is configured to add the numbers of X-ray photons that incident on the all pixels, for the bins of the same energy range. The detector may compile all the added numbers as an energy spectrum of the incident X-ray photons thereon.

A monocrystalline scintillator comprises a monocrystal and an optical plate wherein a first side of the monocrystal is adhered to the optical plate. The monocrystal comprises at least one of a rare earth garnet, a perovskite crystal, a rare-earth silicate, and a monocrystal oxysulphide. The scintillator assembly includes an adhesive adhering the optical plate to the first side of the monocrystal. The adhesive can comprise an ultra-high vacuum compatible adhesive. The adhesive is substantially transparent and has a refractive index matching the optical plate. The scintillator assembly can also include a reflective coating on the second side of the monocrystal. The monocrystalline scintillator assembly can be incorporated in a microchannel plate image intensifier tube to provide improved spatial resolution and temporal response.

A radiation imaging system that is capable of controlling a radiation generating apparatus and a radiation detector based on communication between a first control application and a second control application is provided. The radiation imaging system comprises a holding unit configured to hold a plurality of processing requests transmitted from the second control application, a determination unit configured to determine whether the plurality of processing requests held in the holding unit are processing requests to be continuously executed, and a control right obtaining unit configured to obtain a control right to control an imaging control unit of the first control application that performs the control in order to continuously process the processing requests.

Disclosed herein is an image sensor comprising: a plurality of packages arranged in a plurality of layers; wherein each of the packages comprises an X-ray detector mounted on a printed circuit board (PCB); wherein the packages are mounted on one or more system PCBs; wherein within an area encompassing a plurality of the X-ray detectors in the plurality of packages, a dead zone of the packages in each of the plurality of layers is shadowed by the packages in the other layers.

Disclosed herein is an image sensor comprising: a plurality of packages arranged in a plurality of layers; wherein each of the packages comprises an X-ray detector mounted on a printed circuit board (PCB); wherein the packages are mounted on one or more system PCBs; wherein within an area encompassing a plurality of the X-ray detectors in the plurality of packages, a dead zone of the packages in each of the plurality of layers is shadowed by the packages in the other layers.

Disclosed herein is a detector, comprising: a plurality of pixels, a plurality of segments of guard ring, and a controller, is configured to count numbers of X-ray photons that incident on each pixel of the plurality, and whose energy falls in a plurality of bins, within a period of time. The controller, is configured to detect charge sharing between pixels and segments of guard ring. With charge sharing detected, the controller is also configured to disregard one single photon. With no charge sharing detected, the controller is configured to add the numbers of X-ray photons that incident on the all pixels, for the bins of the same energy range. The detector may compile all the added numbers as an energy spectrum of the incident X-ray photons thereon.

Disclosed herein are methods of making and using an absorption-unit array suitable for X-ray detection and a detector comprising such an absorption-unit array. The methods of making the absorption-unit array may include forming the absorption-unit array on a substrate and forming a guard ring encompassing more than one absorption units of the absorption-unit array after separating the absorption-unit array from the substrate; or may include forming a plurality of absorption units and a guard ring encompassing more than one of the absorption units on a portion of a substrate after separating the portion from the substrate. The method of using an absorption-unit array may include using some of the absorption units of the absorption-unit array as a guard ring by applying an electrical voltage. A detector suitable for X-ray detection comprises an absorption layer and an electronics layer, wherein the absorption layer comprises an absorption-unit array.