A detection element includes an exposed electrode on the first surface of an insulating substrate, the exposed electrode including first exposed electrode, second exposed electrode, third exposed electrode, and fourth exposed electrode provided; a first electrode pattern provided on a side opposite to the first surface, the first electrode pattern including a pattern connected to the first exposed electrode and the second exposed electrode, a pattern connected to the third exposed electrode and the fourth exposed electrode, a second electrode pattern having a first exposed portion and a pattern provided along the second direction, and a third electrode pattern having a second exposed portion and a pattern provided along the third direction, provided so as to sandwich the third electrode pattern between the first electrode pattern and the second electrode pattern.

A gas electron multiplier (GEM), used to track cosmic ray muons, can have readout electrodes oriented in a helical pattern so that it can fit inside a narrow aperture borehole. The helical orientation of the readout electrodes provides for high spatial resolution and yet is cost effective to manufacture. The GEM can have an insulation layer, a plurality of conduction layers and an inner layer comprising a plurality of helical conductive stripes extending between two ends of the GEM.

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.

Resistive plate electrode (110, 120; 210, 220; 310, 320) with modulable surface resistivity comprising a supporting plate (130; 230; 330) coupled to a layer (131; 231; 331) of polymer material on which a DLC layer (135; 235; 335) is deposited that is connected to a connection assembly (145, 245, 345) configured to be connected to a high voltage power supply.

Various embodiments are described herein for sensors that may be used to measure radiation from radiation generating device. The sensors may use a collector plate electrode with first and second collection regions having shapes that are inversely related with one another to provide ion chambers with varying sample volumes along a substantial portion of the first and second collection regions which provides virtual spatial sensitivity during use.

This gaseous elementary-particle detector is equipped with a readout plate comprising: conductive tiles (80) that are all identical to one another and all located at the same distance from an exterior face (39), these conductive tiles being distributed over the front face of a dielectric layer (72) and being mechanically separated from one another by a dielectric material (76), the smallest dimension of each tile being larger than 300 μm, and electrical connections (88), which are located under the dielectric layer (72) and which electrically connect the conductive tiles in series so as to form conductive strips, these electrical connections being arranged so that each conductive tile belongs to a single conductive strip and each side of one tile is adjacent to the side of another tile belonging to another conductive strip.

This gaseous elementary-particle detector is equipped with a readout plate comprising: conductive tiles (80) that are all identical to one another and all located at the same distance from an exterior face (39), these conductive tiles being distributed over the front face of a dielectric layer (72) and being mechanically separated from one another by a dielectric material (76), the smallest dimension of each tile being larger than 300 μm, and electrical connections (88), which are located under the dielectric layer (72) and which electrically connect the conductive tiles in series so as to form conductive strips, these electrical connections being arranged so that each conductive tile belongs to a single conductive strip and each side of one tile is adjacent to the side of another tile belonging to another conductive strip.

A positron tomography device using a micropattern detector is provided. The positron tomography device comprises: a micropattern gas detection device accelerating electrons so as to generate second ionized electrons; a lead-out strip through which an electrical signal is transmitted by the second ionized electrons; and a signal processing unit for processing the electrical signal detected in the lead-out strip arranged at a predetermined position, wherein a plurality of micropattern gas detection devices is disposed in a ring shape, and the lead-out strip is disposed outside the micropattern gas detection device.

A Detection element includes a substrate having a first surface and a second surface opposing the first surface, substrate comprising: a substrate provided with a through hole having inner diameters that differ from each other at two points along the thickness of substrate; a through electrode disposed in through hole; a first electrode connected to through electrode and disposed on the first surface; a patterned electrode connected to through electrode and disposed on the second surface; and a second electrode disposed on the first surface and spaced apart from the first electrode.

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.