A multi-functional and multi-modality radiation detector (10) is provided. The radiation detector (10) comprises at least two detector units (12a, 12b) having photosensitive pixels (14) and at least one scintillation device (20) optically coupled to the photosensitive pixels (14). The detector units (12a, 12b) are arranged next to each other on a substrate foil (24). Therein, the scintillation devices (20) of the detector units (12a, 12b) are spaced apart from each other, such that the radiation detector (10) is bendable. This allows the radiation detector (10) to be used in many different geometrical configurations.

The present invention relates to a photon counting detector comprising a first direct conversion layer (10) comprising a low-absorption direct conversion material (11) for converting impinging high-energy electromagnetic radiation (100) into a first count signal and first electrical contacts (12), a second direct conversion layer (20) comprising a high-absorption direct conversion material (21) for converting impinging high-energy electromagnetic radiation (100) into a second count signal and second electrical contacts (22), said high-absorption direct conversion material having a higher absorption than said low-absorption direct conversion material, and a carrier layer (30, 30a, 30b) comprising first and second terminals (31, 32) in contact with the first and second electrical contacts and processing circuitry (35) configured to correct, based on the first count signal, the second count signal for errors, wherein said first direct conversion layer and the second direct conversion layer are arranged such that the high-energy electromagnetic radiation transmits the first direct conversion layer before it hits the second direct conversion layer.

To optimize image quality and/or sensitivity, a Compton camera is adaptable. The scatter and/or catcher detectors may move closer to and/or further away from a patient and/or each other. This adaptation allows a balancing of image quality and sensitivity by altering the geometry.

A sensor unit (14) for a radiation detector (12), the sensor unit (14) comprising a conversion element (22) comprising a plurality of imaging pixels (30), wherein each imaging pixel (30) is configured to directly convert radiation into an electrical charge and wherein each imaging pixel (30) comprises a charge collection electrode (28); and a readout substrate (24) comprising a plurality of readout pixels (32), wherein each readout pixel (32) is connected to an associated imaging pixel (30) by means of an interconnection (36) at a connection position on the charge collection electrode (28); wherein each readout pixel (32) has a smaller area than an associated imaging pixel (30) of the plurality of imaging pixels (30); and wherein the connection positions in relation to the charge collection electrodes (28) arc varied with respect to a neighboring charge collection electrode (28). A radiation detector (12) and a method of manufacturing a sensor unit (14) are also provided.

A photon detector includes at least one sensor element, formed by a semiconductor material and sensitive to incident radiation, forming a pixel array including sensor pixels; and a detector circuit, situated after the sensor element in the direction of incident radiation, to detect charge carriers generated in the semiconductor material as a result of radiation. The detector circuit includes an integrated circuit with detector pixels in signal communication contact with the sensor pixels; and an enclosure surrounding the integrated circuit and in which the integrated circuit is embedded, and on which is formed on a pixel face facing the sensor element. A contact redistribution layer is formed, in which contact pads are formed for signal-communicatively connecting the detector pixels to the correspondingly assigned sensor pixels, and also conductor tracks are formed for connecting the contact pads to the detector pixels of the integrated circuit.

A radiation imaging apparatus includes a sensor base, a sensor array that includes a plurality of sensor chips arranged in an array, and in which three or more sensor chips out of the plurality of sensor chips are arranged in one row of the sensor array, a scintillator positioned on a side opposite to the sensor base with respect to the sensor array, a bonding member that bonds the sensor array and the scintillator, and a plurality of bonding sheets that are separated from each other and bond the sensor base and the plurality of sensor chips. Two adjacent sensor chips out of the three or more sensor chips are bonded to the sensor base using separate bonding sheets out of the plurality of bonding sheets.

Methods and systems are provided for a medical imaging system having a detector array. In one example, the detector array may include a plurality of adjustable imaging detectors arranged in subsets thereof, each of the plurality of adjustable imaging detectors including a detector unit, each detector unit having a plurality of rows of detector modules, wherein the plurality of adjustable imaging detectors may be arranged on an annular gantry, where an inner surface of the annular gantry may circumscribe a substantially rectangular aperture therethrough, and wherein each subset of the plurality of adjustable imaging detectors may be respectively disposed on a side of the inner surface and may extend within the substantially rectangular aperture.

An imager unit and computerized tomography system are disclosed. The imager unit comprises a radiation source unit comprising at least one radiation source emitting selected radiation and configured to provide diffused radiation with general direction of propagation, and an image collection unit comprising aperture unit and detector array located downstream of the aperture unit with respect to said general direction of propagation. The aperture unit comprises a set of two or more aperture arrays each aperture array having a predetermined arrangement of apertures. The aperture unit is configured for utilizing said set of aperture arrays for collecting the radiation during corresponding collection time periods.

Radiation imaging apparatus includes pixel array having pixels, readout circuit for reading signals from the pixel array, and detector for detecting, based on radiation emitted from radiation source or information provided from the radiation source, start of radiation irradiation by the radiation source, and controller for determining timing of each of operations of sample and hold in each of the pixels each time the start of radiation irradiation is detected by the detector. The timing of at least one operation of the operations is timing in radiation irradiation period, and each of the pixels includes convertor for converting radiation into electrical signal, and sample and hold circuit for sample-holding the signal from the conversion element over plural times in accordance with the timing of each of the operations determined by the controller.

Disclosed herein is a radiation detector system, comprising a radiation detector, the radiation detector comprising a semiconductor substrate and a pixel array in the semiconductor substrate, wherein the pixel array comprises (a) M first-row pixels, and (b) N second-row pixels, both M and N being positive integers and greater than 1, and wherein each pixel of the N second-row pixels is larger than any pixel of the M first-row pixels in a radiation direction perpendicular to a straight line segment having a first end in a first-row end pixel of the M first-row pixels and a second end in a second-row end pixel of the M first-row pixels.