Abstract: A ?-radiation detection system that includes at least one semiconductor detector such as HPGe-Detector, a position-sensitive ?-Detector, a TOF Controller, and a Digitizer/Integrator. The Digitizer/Integrator starts to process the energy signals of a ?-radiation sent from the HPGe-Detector instantly when the HPGe-Detector detects the ?-radiation. Subsequently, it is determined whether a coincidence exists between the ?-particles and ?-radiation signal, based on a determination of the time-of-flight of neutrons obtained from the ?-Detector and the HPGe-Detector. If it is determined that the time-of-flight falls within a predetermined coincidence window, the Digitizer/Integrator is allowed to continue and complete the energy signal processing. If, however, there is no coincidence, the Digitizer/Integrator is instructed to be clear and reset its operation instantly.

Abstract: Methods for setting up, maintaining and operating a radiopharmaceutical infusion system, that includes a radioisotope generator, are facilitated by a computer of the system. The computer includes pre-programmed instructions and a computer interface, for interaction with a user of the system, for example, in order to track contained volumes of eluant and/or eluate, and/or to track time from completion of an elution performed by the system, and/or to calculate one or more system and/or injection parameters for quality control, and/or to perform purges of the system, and/or to facilitate diagnostic imaging.

Abstract: Methods for setting up, maintaining and operating a radiopharmaceutical infusion system, that includes a radioisotope generator, are facilitated by a computer of the system. The computer includes pre-programmed instructions and a computer interface, for interaction with a user of the system, for example, in order to track contained volumes of eluant and/or eluate, and/or to track time from completion of an elution performed by the system, and/or to calculate one or more system and/or injection parameters for quality control, and/or to perform purges of the system, and/or to facilitate diagnostic imaging.

Abstract: The present disclosure provides novel measurement techniques based on moiré techniques and optical frequency conversion. For example, in the IR realm, the configuration can be any moiré configuration, the detector is an IR detector, and the light source can be at any wavelength. The optical configuration, the detector, and the type of light source depend on the physical properties of object/scene and the parameter(s) to be measured.

Abstract: A method is provided for operating a device for sterilising containers, wherein the containers are transported along a predetermined transport path by a transport device and during the transportation at least one wall of the containers is irradiated with radiation, in particular charge carrier radiation, by at least one first radiation device, and wherein a sensor device is also provided which detects charge carrier radiation and/or radiation caused by the charge carriers and which is arranged such that the radiation incident on the sensor device fluctuates due to the movement of the containers along the transport path, and this sensor device detects at least one characteristic radiation variation. Wherein at least one first limit value is defined and a comparison between this limit value and the radiation variation is performed. According to the method, the limit value has a value that changes over time.

Abstract: A radiation imaging system includes: a sensor unit including a plurality of pixels arranged in a matrix, and configured to convert a radiation into an electric charge and to output a pixel output value; a detecting unit configured to detect an irradiation start of the radiation; and a control unit configured to output image information based on the irradiation of the radiation and to output dark image information for the plurality of pixels.

Abstract: A flux detection apparatus can include a radioactive sample having a decay rate capable of changing in response to interaction with a first particle or a field, and a detector associated with the radioactive sample. The detector is responsive to a second particle or radiation formed by decay of the radioactive sample. The rate of decay of the radioactive sample can be correlated to flux of the first particle or the field. Detection of the first particle or the field can provide an early warning for an impending solar event.

Abstract: Disposable, pre-sterilized, and pre-calibrated, pre-validated sensors are provided. The sensor comprises a disposable fluid conduit or bioreactor bag and a reusable sensor assembly. An optical bench or inset optical component or module is integrated within the disposable fluid conduit or bioreactor bag, which provides an optical light path through the conduit or bag. These sensors are designed to store sensor-specific information, such as calibration and production information, in a non-volatile memory chip on the disposable fluid conduit or bag and on the reusable sensor assembly. Methods for calibrating the sensor and for determining a target property of an unknown fluid are also disclosed. The devices, systems and methods relating to the sensor are suitable for and can be outfitted for turbidity sensing.

Abstract: The system for measuring chlorine concentration in fly ash cement concrete utilizes a portable neutron generator and a gamma-ray detector for performing prompt gamma neutron activation analysis of chlorine concentration in a fly ash cement concrete specimen. The system includes a portable neutron generator for generating a pulsed neutron beam having a neutron energy of approximately 2.5 MeV and a gamma-ray detector, such as a bismuth germanate (BGO) gamma-ray detector. A moderator having opposed first and second faces is further provided. The first face is positioned adjacent a target plane of the portable neutron generator, and the second face is adapted for positioning adjacent the fly ash cement concrete specimen. A detection axis of the gamma-ray detector is angled at approximately 45° with respect to an axis of symmetry of the fly ash cement concrete specimen.

Abstract: A system for detecting and counting ions comprises a source of atoms, a hot filament ion source, means for generating an electric field and a magnetic field, and means for detecting and counting the ions, and the filament comprises a portion that is concave along its longitudinal and/or transverse axis.

Abstract: Novel normoxic N-(Hydroxymethyl) acrylamide (NHMAGAT) polymer gel dosimeters for MRI scanning are introduced for radiotherapy planning system. The composition of the NHMAGAT polymer gel and method of making the NHMAGAT polymer gel dosimeter are disclosed. The dosimeters are irradiated with Varian Rapid Arc linear systems at different absorbed doses. The results show that the percent depth dose and 2D plan dose distribution of NHMAGAT polymer gel dosimeters are in a good agreement with the ionization chamber measurements and CT planned dose distribution, respectively.

Abstract: Apparatuses, methods, and systems relating to radiological characterization of environments are disclosed. Multi-detector probes with a plurality of detectors in a common housing may be used to substantially concurrently detect a plurality of different radiation activities and types. Multiple multi-detector probes may be used in a down-hole environment to substantially concurrently detect radioactive activity and contents of a buried waste container. Software may process, analyze, and integrate the data from the different multi-detector probes and the different detector types therein to provide source location and integrated analysis as to the source types and activity in the measured environment. Further, the integrated data may be used to compensate for differential density effects and the effects of radiation shielding materials within the volume being measured.

Abstract: [Problem] To provide a system and a method for objectively evaluating plasma by easily measuring a current generated by a plasma treatment equipment for medical purposes, etc., and a current flowing through a living body, etc. [Solution] A plasma evaluation system and method for evaluating plasma, including: a treatment target material; and a weak current measurement unit including a resistor unit and a differential amplifier, wherein the treatment target material is connected to the weak current measurement unit via a treatment target side measurement terminal, the resistor unit of the weak current measurement unit is connected to a ground side of a plasma generation current source, and the system and method evaluate plasma by receiving plasma generated by a plasma treatment equipment with the treatment target material, measuring a current by measuring a voltage across resistors of the resistor unit through the differential amplifier, and measuring an output voltage of the plasma generation power source.

Abstract: The invention provides a method for optimizing the spectroscopy performance of a spectroscopy scintillator by surrounding the scintillator by a reflector material, performing a scan measuring resolution and light output at three or more axial locations on the crystal, where at least one location is close to the PMT or below the crystal (near the PMT) at least one location is at the end away from the PMT of the scintillator), and adjusting the surface finish of the crystal and/or the reflector to obtain equal light output and optimal resolution over the length and different azimuth of the crystal.

Abstract: An apparatus for generating x-rays includes an electron beam generator and a first device arranged to apply an RF electric field to accelerate the electron beam from the generator. A photon source is arranged to provide photons to a zone to interact with the electron beam from the first device so as to generate x-rays via inverse-Compton scattering. A second device is arranged to apply an RF electric field to decelerate the electron beam after it has interacted. The first and second devices are connected by RF energy transmission means arranged to recover RF energy from the decelerated electron beam as it passes through the second device and transfer the recovered RF energy into the first device.

Abstract: In a particle beam therapy system which scans a particle beam and irradiates the particle beam to an irradiation position of an irradiation subject and has a dose monitoring device for measuring a dose of the particle beam and an ionization chamber smaller than the dose monitoring device, the ionization chamber measuring a dose of a particle beam passing through the dose monitoring device, the dose of the particle beam irradiated by the dose monitoring device is measured; the dose of the particle beam passing through the dose monitoring device is measured by the small ionization chamber; and a correction coefficient of the dose measured by the dose monitoring device corresponding to the irradiation position is found based on the dose of the particle beam measured by the small ionization chamber.

Abstract: A radiation generating apparatus and a radiographing apparatus configured to allow a radiation generating unit to be installed at arbitrary positions include an arm configured to support a radiation generating unit that generates radiation, a pillar configured to rotatably support the arm, and a movable base configured to support the pillar and move on a floor surface are provided, and the arm includes an expandable mechanism configured to expand and contract in a longitudinal direction of the arm.

Abstract: A radiation generating apparatus includes a support structure that supports a radiation generating unit that generates radiation; and a base frame that supports the support structure and includes a plurality of leg portions configured to be arranged in a predetermined manner in accordance with an imaging state or storage state of the radiation generating apparatus.

Abstract: A pulsed neutron source is used in a porosity logging tool with a single gamma ray detector coated with a neutron absorbing material. By using a ratio of the spectral peak associated with hydrogen to a spectral peak associated with the neutron absorbing material, the formation porosity is estimated.

Abstract: A radiation image pickup system includes a correction coefficient calculation unit that calculates a correction coefficient using pixel output values of a plurality of pixels, and a correction unit that corrects pixel output values of a plurality of pixels using the correction coefficient. A drive control unit repeatedly resets an electric charge caused by a dark current of a plurality of pixels until a detection unit detects a start of radiation exposure. The reset operation is performed simultaneously for n rows that are not adjacent to each other, where n is an integer equal to or greater than 2. The correction coefficient calculation unit calculates the correction coefficient using pixel output values of pixels in a row subjected to the reset operation in a period from a start of radiation exposure to a start detection time and pixel output values of pixels in an adjacent row.

Abstract: A radiation detecting device of a cassette type having flexibility includes a deformation maintaining mechanism configured to maintain a state of the radiation detecting device that is deformed to match an arbitrary surface profile of a subject. The deformation maintaining mechanism is arranged on at least one of a surface of a sensor panel on a sensor substrate side and a surface of the sensor panel on a scintillator side.

Abstract: A radiological image-capturing device includes: a first read control section that executes a first read mode in which electric signals stored in a plurality of pixels are read out simultaneously in units of a plurality of rows; and an emission-start determining section that determines that the emission of radiation from a radiation source onto an image-capturing panel has started when the values of the electric signals read by the first read control section have become greater than an arbitrarily settable threshold. If it is determined by the emission-start determining section that the emission of said radiation has started, the first read control section terminates the reading of the electric signals, and thereby brings the image-capturing panel into an exposure state.

Abstract: Embodiments of a semiconductor processing chamber described herein include a substrate support, a source of radiant energy opposite the substrate support, a window between the source of radiant energy and the substrate support, a detector sensitive to the radiant energy positioned to detect the radiant energy transmitted by the window, and a detector sensitive to radiation emitted by the substrate positioned to detect radiation emitted by the substrate. The chamber may also include a showerhead. The substrate support may be between the detectors and the window. A second radiant energy source may be included to project energy through the window to a detector. The second radiant energy source may also be located proximate the first radiant energy source and the detectors.

Abstract: A radiation image pickup apparatus includes a pixel array including a plurality of pixels arranged in a matrix and configured to convert a radiant ray into electric signals, signal processors configured to output digital signals obtained in accordance with the electric signals output from the pixel array in parallel, and a controller configured to operate the signal processors after the signal processors enter a second power consumption state in which power consumption is higher than that of a first power consumption state from the first power consumption state after irradiation of a radiant ray to the pixel array is terminated, and to cause the signal processors to output digital signals after the signal processors are operated.

Abstract: Various embodiments of systems, components, modules, routines, and processes for luminescence based spectral measurement are described herein. In one embodiment, a method for measuring a scintillation property of a sample includes directing an ionizing radiation toward the sample, thereby inducing the sample to produce an emission. The method also includes acquiring a spectral luminescence of the produced emission by the sample, the spectral luminescence including a plurality of luminescence intensities at corresponding emission wavelengths or frequencies. The scintillation property of the sample may then be determined based on the acquired spectral luminescence.

Abstract: An imaging operation includes a first imaging operation for outputting image data according to irradiation to the detector with radiation or light in an irradiation field A corresponding to a part of the plurality of pixels, and a second imaging operation for outputting image data according to irradiation to the detector 104 with radiation or light in an irradiation field B wider than the irradiation field A, wherein, responsive to a changing from irradiation in the irradiation field A to irradiation in the irradiation field B, an operation of the detector is controlled so that the detector performs an initializing operation for initializing conversion elements during a period between the first and second imaging operations.

Abstract: In order to determine whether an exposure apparatus is outputting the correct dose of radiation and its projection system is focusing the radiation correctly, a test pattern is used on a mask for printing a specific marker onto a substrate. This marker is then measured by an inspection apparatus, such as a scatterometer, to determine whether there are errors in focus and dose and other related properties. The test pattern is configured such that changes in focus and dose may be easily determined by measuring the properties of a pattern that is exposed using the mask. The test pattern may be a 2D pattern where physical or geometric properties, e.g., pitch, are different in each of the two dimensions. The test pattern may also be a one-dimensional pattern made up of an array of structures in one dimension, the structures being made up of at least one substructure, the substructures reacting differently to focus and dose and giving rise to an exposed pattern from which focus and dose may be determined.

Abstract: A radiation imaging apparatus, comprising a pixel array on which a plurality of pixels are arrayed, a readout unit configured to read out a signal from the pixel array, a first unit configured to specify a portion of the signal read out by the readout unit, at which a saturated signal whose value has reached a saturation level of an output by the readout unit and a non-saturated signal whose value has not reached the saturation level are mixed, and a second unit configured to correct, based on the non-saturated signal, the saturated signal at the portion specified by the first unit.

Abstract: Described herein are systems and methods for positioning a radiation source with respect to one or more regions of interest in a coordinate system. Such systems and methods may be used in emission guided radiation therapy (EGRT) for the localized delivery of radiation to one or more patient tumor regions. These systems comprise a gantry movable about a patient area, where a plurality of positron emission detectors, a radiation source are arranged movably on the gantry, and a controller. The controller is configured to identify a coincident positron annihilation emission path and to position the radiation source to apply a radiation beam along the identified emission path. The systems and methods described herein can be used alone or in conjunction with surgery, chemotherapy, and/or brachytherapy for the treatment of tumors.

Abstract: One embodiment relates to an apparatus comprising a light source adapted to transmit light through a liquid, and a detector adapted to detect an intensity of the light after it passes through the liquid. The apparatus may also include a device to process data relating to the intensity of the infrared light and compare the processed data to predetermined control data. The apparatus may also include a controller adapted to transmit a signal to a liquid dispenser if the processed data differs from the control data by a predetermined amount. The light may be selected from the group consisting of ultraviolet, visible, infrared, and microwave light. Other embodiments are described and claimed.

Abstract: A method and system for calibrating an imaging system in which a positron-emitting radioisotope source is arranged in or adjacent to an imaging region of the imaging system, an annihilation target is arranged at a position separated from the positron-emitting radioisotope source by a predetermined distance, coincident event pairs resulting from annihilation of positrons at the annihilation target are detected, a calibration time offset for a detector element in the imaging system is calculated based on the detected coincident event pairs, and the detector element is calibrated with the completed calibration time offset.

Abstract: A radiation generating tube includes an electron emitting source configured to emit an electron beam; a target configured to generate radiation when the target is irradiated with the electron beam; a rear shield body having a tube-shaped electron passage with openings thereof at each end of the passage, and being located at the side of the electron emitting source with respect to the target, a first opening of the passage facing the electron emitting source and being separated from the electron emitting source, a second opening of the passage facing the target; and a brazing material joining the rear shield body with a peripheral edge of the target, at a position separated from the second opening. A closed space isolated from the electron passage is provided between the target and the rear shield body.

Abstract: An apparatus employs a plurality of transducers distributed along a cable to sample a medium. Some of the transducers may be operated according to various sequences which specific wavelengths and/or magnitudes of emission of electromagnetic energy. Some of the transducers sample, detect or measure responses of the fluid medium to the emissions. Various other transducers may sample or measure temperature, depth or pressure, and flow characteristics of the fluid medium, and optionally flow characteristics above a surface or above a surface of the fluid medium. Such may allow identification and/or characterization of characteristics of the fluid medium and/or substances (e.g., contaminants for instance petroleum, phytoplankton, red tide microorganisms, nutrients, dissolved oxygen or other gasses). The apparatus may communicate with remote facilities, allowing monitoring, remote control, and/or analysis with or with information from other platforms.

Abstract: A positron annihilation characteristics measurement system 10 comprises a positron source; radiation detection means 14 for detecting radiation emitted when a positron generated by the positron source is annihilated; and a positron detector 40 that detects a positron that is not injected into a measured sample S after being generated by the positron source. The positron source is disposed between the measured sample S and the positron detector. An arithmetic device 50 calculates the annihilation characteristics of the positron in the measured sample S after eliminating the radiation that is detected by the radiation detection means 14 and is expected to be emitted when the positron detected by the positron detector 40 is annihilated.

Abstract: The state of an emitter can be determined by measurements of how the current changes with the extraction voltage. A field factor ? function is determined by series of relatively simple measurements of charged particles emitted at different conditions. The field factor can then be used to determine derived characteristics of the emission that, in the prior art, were difficult to determine without removing the source from the focusing column and mounting it in a specialized apparatus. The relations are determined by the source configuration and have been found to be independent of the emitter shape, and so emission character can be determined as the emitter shape changes over time, without having to determine the emitter shape and without having to redefine the relation between the field factor and the series of relatively simple measurements, and the relationships between the field factor and other emission parameters.

Abstract: Methods, systems, and apparatuses, including computer programs encoded on a computer storage medium, for generating location and size measurements for small scattered objects in a large medium are disclosed.

Abstract: A radiological image-capturing device includes: a first read control section that executes a first read mode in which electric signals stored in a plurality of pixels are read out simultaneously in units of a plurality of rows; and an emission-start determining section that determines that the emission of radiation from a radiation source onto an image-capturing panel has started when the values of the electric signals read by the first read control section have become greater than an arbitrarily settable threshold. If it is determined by the emission-start determining section that the emission of said radiation has started, the first read control section terminates the reading of the electric signals, and thereby brings the image-capturing panel into an exposure state.

Abstract: A drawing apparatus includes: a detector configured to output a current in accordance with a pulse of a charged particle beam; and a processor including a capacitor and configured to detect a value of a voltage of the capacitor and to obtain an intensity of the pulse based on a value of a capacitance of the capacitor and the detected voltage value. The processor is configured to detect a current output from the detector in accordance with a charged particle beam incident thereon through a voltage drop, to supply a current having a value determined based on the detected current, to the capacitor to detect a value of a voltage of the capacitor, and to obtain the value of the capacitance based on the determined current value and the detected value of the voltage of the capacitor.

Abstract: The invention is related to a method and apparatus for verifying the beam range in a target irradiated with a charged hadron beam, such as a proton beam. The beam range is the location of the Bragg peak in the target, being the location where the largest portion of the dose is delivered. The method utilizes a prompt gamma camera provided with a slit-shaped opening, so as to be able to produced a 1-dimensional profile of the dose distribution along the beam line. The camera is mounted with the slit oriented perpendicularly to the beam line. The method comprises the steps of calculating a position of the camera with respect to a target, for a plurality of beam energies and spots to be irradiated. The method further comprises the steps of verifying the beam range for said plurality of spots, and delivering a value representative of the difference between the estimated beam range and the actual beam range. The apparatus of the invention is provided with a positioning module for positioning the camera.

Abstract: An X-ray detector is provided with a plurality of modules each having a plurality of detection elements each composing a pixel, in which the detection elements convert incoming radiations to electric data depending on amounts of the radiations. The plural modules are mutually adjacently arranged on the same surface with a gap having a known width formed therebetween, such that the modules are arranged along at least one of a first X-axis and a first Y-axis, wherein the radiation detector is given a scan direction which is set along one of the first X- and Y-axes and the first Y-axis is perpendicular to the first X-axis. The plural detection elements of each module are two-dimensionally arranged along a second X-axis and a second Y-axis which are set obliquely to the first X-axis and the first Y-axis respectively and which are perpendicular to each other.

Abstract: The present invention provides a projection method of 3D ray tracing, so as to construct a geometric factor required for the reconstruction of a medical image in the imaging field. The present invention mainly projects a radiation field and a voxel detected by each detector on two 2D planes, then calculates the geometric ratio of a rectangular unit, corresponding to each voxel on the two 2D planes, to the radiation field, respectively, and multiplies the geometric ratios to obtain a sub-geometric factor with respect to the voxel. The sub-geometric factors gij of all voxels i corresponding to all detectors j are combined to form a geometric factor matrix Gij.

Abstract: A radiation imaging system includes a portable radiation imaging device, a radiation generating device, a console and a portable terminal. When the console receives data for preview image from the radiation imaging device before receiving a completion signal from the portable terminal the console transmits a cancel signal to the radiation imaging device, stops a process which is being performed by the radiation imaging device, and makes the radiation imaging device resume detection of whether irradiation has started. When the console receives the data for preview image from the radiation imaging device after receiving the completion signal from the portable terminal, the console generates a preview image on the basis of the data for preview image.

Abstract: This radiation imaging system has a radiation source, a case, and a radiation detection device which is housed in the case, and is equipped with a radiation detector having a conversion unit that converts radiation from the radiation source, which has passed through at least a subject, to radiation image information, wherein a prediction is made as to whether the afterimage phenomenon has occurred in the conversion unit, and if it is predicted that the phenomenon has occurred, at least the conversion unit is moved.

Abstract: A motion recognizing apparatus and method are provided. According to an aspect, a motion recognizing apparatus may include: an optical sensor configured to sense at least a portion of a subject where a motion occurs and to output one or more events in response thereto; a motion tracing unit configured to trace a motion locus of the portion where the motion occurs based on the one or more outputted events; and a motion pattern determining unit configured to determine a motion pattern of the portion where the motion occurs based on the traced motion locus.

Abstract: An apparatus includes a light emitting diode operative to emit mostly invisible light within an invisible bandwidth, and a scattering surface configured to scatter a first portion of the invisible light from the light emitting diode out of the window. The scattering surface is also partially transparent to allow a second portion of the invisible light from the light emitting diode to pass through the scattering surface and strike the reflector that is configured to reflect at least some of the second portion of the invisible light towards the window. The apparatus further includes a photodetector configured to detect returned invisible light from the target object.

Abstract: A sample analyzer is offered which creates a ternary scatter diagram representing a concentration ratio distribution of three elements out of several elements to be analyzed. This three-dimensional graph is created by adding an axis to the ternary scatter diagram and representing concentration information about the two additional elements on the added axis. The sample analyzer performs elemental analysis of a sample by scanning a primary beam over the sample and detecting a signal emanating from the sample. The added axis intersects the plane of the ternary scatter diagram.

Abstract: Spatial acquisition of measurement data over a cross section of a high-energy, high-intensity radiation beam bundle without impairment of measuring accuracy due to saturation or degradation of detectors occurs by imaging an entire cross section of the beam bundle on a shading element, the cross section being separated successively into partial beam bundles having reduced cross sections and reduced intensity through movement of at least one opening, whereby measurement values of the partial beam bundles passing the opening are associated temporally and spatially with positions of the opening.

Abstract: An interactive display device is disclosed. The interactive display device comprises: a housing, a user interface surface which is coupled with the housing, a display panel which is disposed under the user interface surface, an area light detector which is disposed under the display panel and configured to detect invisible light reflected by an object which is on or adjacent to the user interface surface, a plane light guide plate which is disposed under the area light detector, and an invisible light source which is disposed at the side of the plane light guide plate. The interactive display device has small size and better appearance, and thus is easy to be transported and more competitive.

Abstract: This is a way interrogating an object using retro-reflection of non-visible light. It uses e.g. IR transmitted toward the object from a distance and covertly detects the retro-reflection. Highly reflective passive non-visible light retroreflectors on the object reflects and refracts light back toward the light transmitter, with the returned light being very nearly parallel to the light from a narrow beam light transmitter.

Abstract: Applying a Double Slit System in combination with Cathode Ray Tube-type electron directing plates between which an electron travels on its way to the Slits, and to which plates are applied precise voltage potentials in use, allows controlling where, within the width of a Double Slit System Slit an electron passes, and perhaps enables predicting where on a Double Slit Screen a specific electron will impinge.