A sensor chip includes a plurality of microcells to which an xy position is assigned, composed of a photodiode D.sub.n,m, a current divider S.sub.q,nm, with outputs S.sub.q,v,nm, for the y direction and outputs S.sub.q,h,nm for the x direction, the outputs S.sub.q,h,nm being equipped with a quenching apparatus R.sub.q,h,nm for quenching the current, and the outputs S.sub.q,v,nm being equipped with a quenching apparatus R.sub.q,v,nm for quenching the current, which divides the generated photocurrent of the diodes Dn,m into two equally large fractions. The microcells are arranged in a sequence of N columns in the x direction x.sub.n,=x.sub.1, x.sub.2, x.sub.3, . . . x.sub.n with n=1, 2, 3, . . . N and M rows in the y direction y.sub.m,=y.sub.1, y.sub.2, y.sub.3, . . . y.sub.m with m=1, 2, 3, . . . M. Outputs S.sub.q,h,nm of the current dividers S.sub.q,nm for the x direction are connected to the read-out channels Ch.sub.A and Ch.sub.B for the x direction.

The invention relates to a combined detector (660) comprising a gamma radiation detector (100) and an X-ray radiation detector (661). The gamma radiation detector (100) comprises a gamma scintillator array (101.sub.x, y), an optical modulator (102) and a first photodetector array (103.sub.a, b) for detecting the first scintillation light generated by the gamma scintillator array (101.sub.x, y). The optical modulator (102) is disposed between the gamma scintillator array (101.sub.x, y) and the first photodetector array (103.sub.a, b) for modulating a transmission of the first scintillation light between the gamma scintillator array (101.sub.x, y) and the first photodetector array (103.sub.a, b). The optical modulator (102) comprises at least one optical modulator pixel having a cross sectional area (102′) in a plane that is perpendicular to the gamma radiation receiving direction (104). The cross sectional area of each optical modulator pixel (102′) is greater than or equal to the cross sectional area of each photodetector pixel (103′.sub.a, b).

Disclosed herein is an image sensor comprising: a plurality of X-ray detectors; an actuator configured to move the plurality of X-ray detectors to a plurality of positions, wherein the image sensor is configured to capture, by using the detectors, images of portions of a scene at the positions, respectively, and configured to form an image of the scene by stitching the images of the portions.

The invention relates to a device for the detection of gamma rays (1) coming from a source (2) without image truncation and without image overlapping, comprising, at least, two detection cells (3) and each of said cells comprising a detection space (7) adapted to receive the gamma rays (1) that penetrate through an opening (5), wherein said detection space (7) comprises one or more detection assemblies (8, 8′), with some of said assemblies (8′) being positioned such that they stand in the way of the gamma rays (1) coming into the overlap volume (11) thereof.

A radiation detector assembly is provided that includes a semiconductor detector, plural pixelated anodes disposed on a surface of the semiconductor detector, and at least one processor. Each pixelated anode generates a primary signal responsive to reception of a photon by the pixelated anode. The at least one processor is operably coupled to the pixelated anodes, and determines when a primary signal is generated by a given pixelated anode. Responsive to determining the presence of the primary signal in the given pixelated anode, the at least one processor disconnects the given pixelated anode from an electrical source, wherein a re-directed primary signal is directed to a surrounding pixelated anode of the given pixelated anode. The at least one processor identifies the surrounding pixelated anode, and assigns an event for the primary signal to a pre-determined sub-pixel portion of the given pixelated anode based on the identified surrounding pixelated anode.

Among other things, one or more techniques and/or systems are described for setting a sampling frequency for a radiation imaging system. The radiation imaging system comprises a rotating gantry configured to rotate a radiation source and a detector array about an object to generate an image(s) of the object. A data acquisition system is configured to sample the detector array as views. One or more flag structures are arranged according to a partial arc segment (e.g., a structure less than a full 360 degree circle). One or more sensors are disposed on one of the rotating gantry or a stationary support about which the rotating gantry rotates. When a sensor encounters a flag structure, a current rotational speed of the rotating gantry is determined. A clock frequency is updated based upon the current rotational speed to establish a sampling frequency for the data acquisition system for sampling the detector array.

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

Various embodiments include methods of compensating for signal loss due to depth-of-interaction (DOI) effects in radiation detectors, thereby improving detector efficiency. Various embodiments may include detecting the amplitude of a primary charge signal in a first pixel of an array of detector pixels in response to a photon interaction event, detecting the amplitude of a secondary charge signal in a second pixel of the array, where the amplitude of the secondary charge signal has an opposite polarity than the polarity of the primary charge signal, and generating a corrected photon energy measurement of the photon interaction event by applying a correction to the detected amplitude of the primary charge signal based on the detected amplitude of the secondary charge signal. Further embodiments include methods of improving detector efficiency by compensating for both depth-of-interaction (DOI) and charge sharing effects.

A method of processing radiation from a source is described comprising: positioning a detector to receive radiation from the source; positioning a collimator between the source and the detector, wherein the collimator has a plurality of apertures; allowing radiation from the source to pass through the collimator and be incident upon the detector; receiving a plurality of responses each being a response to an interaction with incident radiation occurring within the detector; determining, for each of the plurality of responses, a characteristic of the interaction, wherein the characteristic comprises at least a position and depth of the interaction within the detector; processing the said plurality of responses by simultaneously processing position and depth of interaction data in such manner as to accommodate the effect of multiplexing due to overlap of the projected radiation pathways from multiple apertures in the collimator at the detector on the detected position on the detector. A radiation detection system for the detection of radiation from a source, in particular to perform the method, is also described.

The invention relates to a device for the detection of gamma rays coming from a source without image truncation and without image overlapping, comprising, at least, two detection cells and each of said cells comprising a detection space adapted to receive the gamma rays that penetrate through an opening, wherein said detection space comprises one or more detection assemblies, with some of said assemblies being positioned such that they stand in the way of the gamma rays coming into the overlap volume thereof.