Abstract: A heat management apparatus for disposition in a medical imaging system is disclosed. The apparatus includes a thermally conductive detector module, sensor components disposed upon the detector module, and signal processing electronics in thermal communication with the detector module, the signal processing electronics disposed proximate the sensor components. A main heat conductor is in thermal communication with a first defined portion of a length of the detector module, and a local heat conductor is in thermal communication with a second defined portion of the length of the detector module.

Abstract: An interface assembly for a sensor array is provided. The interface assembly may be made up of an integrated circuit package thermally coupled to the sensor array. The interface assembly may include a temperature control system for controlling the temperature of the sensor array. The temperature control system includes a temperature sensor for sensing a temperature variation of each sensor of the sensor array from an initial temperature beyond a predetermined threshold. A temperature controller is coupled to each temperature sensor and receives an output signal from the temperature sensor upon the sensor temperature variation exceeding the predetermined threshold. A temperature correction device is coupled to each temperature controller and causes the sensor temperature variation to fall within the predetermined threshold upon receiving a control signal from the temperature controller.

Abstract: A radiological imaging apparatus which can keep detectors at a low temperature, improve a time resolution and an energy resolution and perform an accurate diagnosis is provided. In the radiological imaging apparatus, an imaging apparatus imaging a testing subject supported by a bed couples a detector board having placed thereon radiation detectors detecting radiations emitted from the testing subject and a signal processing board having placed thereon a signal processing circuit processing detection signals of the radiation detectors via an intermediate board by connectors, and separates a detector space including the radiation detectors and a signal processing circuit space including the signal processing circuit.

Abstract: A real-time method and computer system for identifying radioactive materials which collects gamma count rates from a HPGe gamma-radiation detector to produce a high-resolution gamma-ray energy spectrum. A library of nuclear material definitions (“library definitions”) is provided, with each uniquely associated with a nuclide or isotope material and each comprising at least one logic condition associated with a spectral parameter of a gamma-ray energy spectrum. The method determines whether the spectral parameters of said high-resolution gamma-ray energy spectrum satisfy all the logic conditions of any one of the library definitions, and subsequently uniquely identifies the material type as that nuclide or isotope material associated with the satisfied library definition. The method is iteratively repeated to update the spectrum and identification in real time.

Abstract: Amplifiers are mounted on flexible boards connected to a solid-state detector. A first temperature adjustment member is disposed near one of the surfaces of the amplifiers and the flexible boards, and a second temperature adjustment member is disposed near the other surface of the flexible boards. The first temperature adjustment member adjusts the temperature of the amplifiers themselves, and prevents heat from being transferred from the one of the surfaces of the flexible boards to the solid-state detector. The second temperature adjustment member prevents heat from being transferred from the other surface of the flexible boards to the solid-state detector.

Abstract: A method and a control device are for controlling the temperature of a detector system inside a computed tomography unit. The CT unit includes a rotatable gantry with a gantry housing in which both an X-ray tube and the detector system are located. The detector system is arranged, in turn, inside a detector housing. The air temperature is set in the gantry housing via a temperature-controlled air circulation. The temperature of the ambient air of the detector housing is set by a control system that uses the temperature of the detector system as controlled variable.

Abstract: The present application discloses an x-ray detector for use in a computed tomography (CT) imaging system. The x-ray detector assembly comprises an array of detector cells coupled between detector rails. The present invention provides a self regulating heating element having a body that, when current is passed therethrough, radiates heat until a specific reference temperature is reached, at which point the resistance of the PTC heater increases, thus reducing the current through the PTC heater, and, as a result, the radiative heating of the PTC heater.

Abstract: Disclosed is an X-ray detector assembly for use in a computed tomography system. The X-ray detector assembly comprises an array of detector cells coupled between two rails. A thermoelectric cooler is coupled to an end of each of the rails, and is controlled to alternatively heat or cool the detector array to maintain the array in a substantially isothermal and thermally stable condition. The detector assembly preferably includes both passive and active cooling devices and insulation materials for controlling the temperature of the detector assembly. An electrical heater coupled at the center of the detector array can be used in conjunction with the TEC's to control the temperature profile of the detector array, and to minimize changes in the temperature gradients.

Abstract: A radiation detector system having a heat pipe based cooling. The radiation detector system includes a radiation detector thermally coupled to a thermo electric cooler (TEC). The TEC cools down the radiation detector, whereby heat is generated by the TEC. A heat removal device dissipates the heat generated by the TEC to surrounding environment. A heat pipe has a first end thermally coupled to the TEC to receive the heat generated by the TEC, and a second end thermally coupled to the heat removal device. The heat pipe transfers the heat generated by the TEC from the first end to the second end to be removed by the heat removal device.

Abstract: A light modulator assembly includes a substrate, a micro-electro mechanical semiconductor device (MEMS device) formed on the substrate, and a temperature control device coupled to the substrate and configured to maintain the MEMS device at or above an elevated threshold temperature.

Abstract: Deterioration of a photoconductive layer is prevented, by suppressing the application of heat during connection of a second electrode with an external terminal. A solid state detector is constituted by: an external terminal, which is electrically connected to a voltage source for applying a recording voltage to the second electrode when recording image information at a charge accumulating portion; and a connecting member formed by a conductive elastic material, of which a first end is fixed to the external terminal, and a second end contacts the second electrode by elastic force.

Abstract: An X-ray diagnosis apparatus is disclosed which includes two different cooling circuits and a single cooling portion. A first heat transfer medium is circulated for absorbing heat generated in the X-ray generator. A second heat transfer medium is circulated for absorbing the heat generated in the planer type X-ray detector. A heat exchanger is provided for exchanging heat between the first heat transfer medium and the second heat transfer medium. The cooling portion is coupled to the cooling circuit carrying the second heat transfer medium in order to cool the second heat transfer medium.

Abstract: A radiation detector is realized as, for example, a flat panel detector (FPD) for two-dimensionally detecting X-rays. The detector comprises a detection board and a control unit. The detection board on which a plurality of detection elements for detecting a radiation are two-dimensionally disposed in a matrix and circuits for collecting signals from the detection elements. The control unit for controlling the detection board so that the detection board is placed in a predetermined temperature state. The predetermined temperature state is defined, for example, as predetermined ranges of temperatures used during the operation and the non-operation states of the detector, respectively. This radiation detector can be mounted in a radiography system such as an X-ray radiography system.

Abstract: A detector for X-ray computer tomographs includes a plurality of detector modules which are mounted alongside one another on a frame. Each of the detector modules includes sensor elements for detection of the intensity of incident X-ray radiation. In order to simplify the production of calibration tables, a device for holding a pressure-contact apparatus, provided with a heating element, is provided on the detector so as to face away from the sensor elements.

Abstract: A portable gamma ray detection apparatus having a gamma ray detector encapsulated by a compact isolation structure having at least two volumetrically-nested enclosures where at least one is a thermal shield. The enclosures are suspension-mounted to each other to successively encapsulate the detector without structural penetrations through the thermal shields. A low power cooler is also provided capable of cooling the detector to cryogenic temperatures without consuming cryogens, due to the heat load reduction by the isolation structure and the reduction in the power requirements of the cooler. The apparatus also includes a lightweight portable power source for supplying power to the apparatus, including to the cooler and the processing means, and reducing the weight of the apparatus to enable handheld operation or toting on a user's person.

Abstract: The present invention discloses a method and apparatus for cooling the electronics associated with Computed Tomography (CT) detector arrays. More particularly, the present invention discloses use of thermoelectric coolers in cooling CT detector electronics. The present invention also provides for using blowers or fans to recirculated air within a plenum for the cooling of CT detector electronics. The present invention also discloses the use of wick type heat pipes being placed either horizontally or with the evaporator end radially farther out than the condenser end such that rotational forces assist with heat flow through the heat pipe for cooling CT detector electronics. The present invention also discloses use of axial groove heat pipes to cool the CT detector electronics because they have enhanced performance under revolving conditions. Lastly, the present invention discloses use of heat sinks and circulation fans in combination with either type of heat pipe.

Abstract: A solid-state detector is accommodated within a case housing. The solid-state detector is provided with a layer containing amorphous selenium as a principal constituent and operates such that the solid-state detector records image information as an electrostatic latent image, and such that the solid-state detector generates electric currents in accordance with the electrostatic latent image when the solid-state detector is scanned with reading light. A heat discharging device discharges heat within the case housing to the exterior of the case housing, such that a temperature of the layer containing the amorphous selenium as the principal constituent is kept at a temperature lower than 40° C.

Abstract: A nuclear camera system (10) includes a gantry (22, 23) disposed about an examination region (17) having detector heads (15 a,b,c) mounted to the gantry. The detector heads (15) include an enclosure (30, 34, 54, 56) defining a volume (61). A plurality of solid state detectors (40) are arranged in an array (36) within the enclosure volume. A first cold plate (46) is in thermally conductive contact with the plurality of solid state detectors. A first Peltier cooler (50) is in thermally conductive contact with the first cold plate, the first Peltier cooler provides for cooling the plurality of detectors in the array. A second cold plate (47) is located within the enclosure and is thermally insulated from first cold plate. A second Peltier cooler (52) is in thermally conductive contact with the second cold plate, the second Peltier cooler for removing moisture from the volume (61). A heat sink (56) is in thermally conductive contact with the first and second Peltier coolers.

Abstract: The invention relates to an X-ray detector for converting electromagnetic radiation, notably X-rays, into electric charge carriers. The invention also relates to a method of operating an X-ray detector and to a method of manufacturing an X-ray detector. The invention furthermore relates to an X-ray examination apparatus which includes an X-ray detector. In order to reduce image artefacts caused by bright burn effects, it is proposed to add a heating device (7) to an X-ray detector (1) for converting electromagnetic radiation, notably X-rays, into electric charge carriers by means of a converter arrangement, which heating device in accordance with the invention is arranged to apply heat to the converter arrangement (2) during operation of the X-ray detector (1).

Abstract: A computed tomography (CT) system comprises an X-ray radiation source to project a plurality of X-ray beams through an object and a detector array comprising a plurality of detector assemblies. Each of the detector assembly further comprises a detector subassembly adapted to detect the X-ray beams and further adapted to convert the X-ray beams to a plurality of electrical signals and at least one integrated circuit array, for example, data acquisition chip array to acquire data corresponding to the electrical signals. The integrated circuit array, for example, data acquisition chip array further comprises a plurality of integrated circuits, such as, data acquisition chips mounted on at least one printed circuit board and a thermal management system adapted for thermal communication between the data acquisition chip array and a heat sink assembly to control thermal environment of each detector assembly.

Abstract: A detector module for an X-ray computed tomography apparatus has a sensor array composed of a number of sensor elements that is mounted on a front side of a printed circuit board. In order to enhance the precision of the detector, at least one heating element for heating the sensor array is provided at the backside of the printed circuit board facing away from the sensor array.

Abstract: A solid state gamma camera module and integrated thermal management method thereof includes a printed circuit board having a first thermal layer and a second thermal layer. The first thermal layer is thermally and/or electrically bonded to the second thermal layer. A semiconductor detector module having the temperature sensitive material electrically communicates with the second thermal layer. A plurality of the integrated circuits each having a bottom metal layer and wire bonds are electrically connected to the first thermal layer. A cover is electrically and thermally bonded to the first thermal layer and covers the plurality of integrated circuits. The first thermal layer extracts heat from the integrated circuits by direct interface to the bottom metal layer (or the second thermal layer), and the second thermal layer extracts heat from an integrated circuit (IC) interconnect. The IC interconnect can be through a wire bond, die bond, direct solder flip chip attachment or the like.

Abstract: According to an embodiment of the present invention, a system for effecting temperature control in a camera includes a lens housing having an optical stop, a lens disposed within the lens housing, and a thermally conductive material disposed between the lens and the optical stop. The thermally conductive material, which may be an adhesive, has a thermal conductivity of at least approximately 1.90 W/m·K.

Abstract: A method is for exchanging a first detector module (m), in an X-ray detector in a computed tomograph having a module configuration a, for a second detector module (m?). The first detector module has an associated correction table (TS(a,m,x)) for eliminating temperature-dependent signal changes, which is dependent on the respective module configuration of the detector and which is recreatable following the exchange of a detector module. For the first and second detector modules (m, m?) in a detector in a reference computed tomograph having the module configuration b, a respective correction table (TS(b,m,x), TS(b,m?x) is created. Differences, preferably only in the area of the channels of the detector module which is to be exchanged, are ascertained. Finally, the new correction table (TS(a,m?,x)) for operating the second detector module (m?) in the computed tomograph having the module configuration a is calculated by transferring the ascertained difference values to the old correction table (TS(a,m,x)).

Abstract: A radiation detector is realized as, for example, a flat panel detector (FPD) for two-dimensionally detecting X-rays. The detector comprises a detection board and a control unit. The detection board on which a plurality of detection elements for detecting a radiation are two-dimensionally disposed in a matrix and circuits for collecting signals from the detection elements. The control unit for controlling the detection board so that the detection board is placed in a predetermined temperature state. The predetermined temperature state is defined, for example, as predetermined ranges of temperatures used during the operation and the non-operation states of the detector, respectively. This radiation detector can be mounted in a radiography system such as an X-ray radiography system.

Abstract: The invention relates to a photodetector capable of detecting even weak light with precision and having a structure permitting size reduction. In the photoelectric tube, a photoelectric tube is cooled down starting from a light receiving faceplate side via a supporting protrusion piece of a heat conductive supporting member fixed to the heat absorbing portion of a cooling device by the heat absorbing operation of the cooling device. At this time, the photoelectric tube is fixed only to the supporting protrusion piece, so that heat inflow through other members is prevented. Thus, the photoelectric surface is efficiently cooled down through the light receiving faceplate by the cooling device serving as a cooling source, so that a stable cooling temperature is obtained. This suppresses the emission of thermal electrons from the photoelectric surface, and hence sufficiently suppresses the occurrence of noise in the photoelectric tube.

Abstract: A photodiode device includes a silicon carbide photodiode including a second semiconductor layer on a first semiconductor layer and an integral aluminum gallium nitride filter on the second semiconductor layer. A method for fabricating a photodiode device for combustion flame temperature determination includes fabricating an integral filter over a silicon carbide photodiode. Examples of various filter fabrication techniques include growing an aluminum gallium nitride filter, fabricating a silicon oxynitride filter, and alternating thin film layers of silicon oxide and silicon nitride.

Abstract: A portable gamma ray detection apparatus having a gamma ray detector encapsulated by a compact isolation structure having at least two volumetrically-nested enclosures where at least one is a thermal shield. The enclosures are suspension-mounted to each other to successively encapsulate the detector without structural penetrations through the thermal shields. A low power cooler is also provided capable of cooling the detector to cryogenic temperatures without consuming cryogens, due to the heat load reduction by the isolation structure and the reduction in the power requirements of the cooler. The apparatus also includes a lightweight portable power source for supplying power to the apparatus, including to the cooler and the processing means, and reducing the weight of the apparatus to enable handheld operation or toting on a user's person.

Abstract: A real-time method and computer system for identifying radioactive materials which collects gamma count rates from a HPGe gamma-radiation detector to produce a high-resolution gamma-ray energy spectrum. A library of nuclear material definitions (“library definitions”) is provided, with each uniquely associated with a nuclide or isotope material and each comprising at least one logic condition associated with a spectral parameter of a gamma-ray energy spectrum. The method determines whether the spectral parameters of said high-resolution gamma-ray energy spectrum satisfy all the logic conditions of any one of the library definitions, and subsequently uniquely identifies the material type as that nuclide or isotope material associated with the satisfied library definition. The method is iteratively repeated to update the spectrum and identification in real time.

Abstract: A nuclear camera system (10) includes a gantry (22, 23) disposed about an examination region (17) having detector heads (15 a,b,c) mounted to the gantry. The detector heads (15) include an enclosure (30, 34, 54, 56) defining a volume (61). A plurality of solid state detectors (40) are arranged in an array (36) within the enclosure volume. A first cold plate (46) is in thermally conductive contact with the plurality of solid state detectors. A first Peltier cooler (50) is in thermally conductive contact with the first cold plate, the first Peltier cooler provides for cooling the plurality of detectors in the array. A second cold plate (47) is located within the enclosure and is thermally insulated from first cold plate. A second Peltier cooler (52) is in thermally conductive contact with the second cold plate, the second Peltier cooler for removing moisture from the volume (61). A heat sink (56) is in thermally conductive contact with the first and second Peltier coolers.

Abstract: An X-ray imaging system that utilizes the leakage, or dark current, of a detector panel's photodiodes to provide more accurate data about the temperature and spatial distribution of temperature of the X-ray detector panel. Offset images are taken at known temperatures and recorded for each photodiode at two or more known temperatures. A temperature versus offset image value curve is the created for each photodiode. A second offset image value is determined immediately prior to or immediately after X-ray acquisition to determine the temperature of the detector panel at the time of X-ray acquisition. A coupled closed-loop cooling system utilizes the determined temperature to maintain the detector panel within a preferred temperature range.

Abstract: A solid state gamma camera module and integrated thermal management method thereof includes a printed circuit board having a first thermal layer and a second thermal layer. The first thermal layer is thermally and/or electrically bonded to the second thermal layer. A semiconductor detector module having the temperature sensitive material electrically communicates with the second thermal layer. A plurality of the integrated circuits each having a bottom metal layer and wire bonds are electrically connected to the first thermal layer. A cover is electrically and thermally bonded to the first thermal layer and covers the plurality of integrated circuits. The first thermal layer extracts heat from the integrated circuits by direct interface to the bottom metal layer (or the second thermal layer), and the second thermal layer extracts heat from an integrated circuit (IC) interconnect. The IC interconnect can be through a wire bond, die bond, direct solder flip chip attachment or the like.

Abstract: In order to provide a radiation detector capable of implementing measurements with a good energy resolution and a high detection efficiency over a broad energy range using a single detector, in the present invention, a radiation detecting element composed of Si semiconductor and the radiation detecting element composed of CdZnTe or CdTe semiconductor are lined up as two layers longitudinally. The radiation detecting element composed of Si semiconductor is taken as a first layer at the side of incidence of the radiation and the radiation detecting element composed of CdZnTe or CdTe semiconductor is taken as a second layer.

Abstract: This invention relates to a radiation detector comprising at least one semiconducting junction capable of generating electron-hole pairs under the action of the detected radiation and connected in photovoltaic cell mode. The detector comprises means (8, 9, 10, 11, 12) for placing and maintaining the junction at an approximately constant temperature (TA).

Abstract: An X-ray imaging system that utilizes the leakage, or dark current, of a detector panel's photodiodes to provide more accurate data about the temperature and spatial distribution of temperature of the X-ray detector panel. Offset images are taken at known temperatures and recorded for each photodiode at two or more known temperatures. A temperature versus offset image value curve is the created for each photodiode. A second offset image value is determined immediately prior to or immediately after X-ray acquisition to determine the temperature of the detector panel at the time of X-ray acquisition. A coupled closed-loop cooling system utilizes the determined temperature to maintain the detector panel within a preferred temperature range.

Abstract: A special infrared photodetector is operable at high temperatures. The detector is a very wideband detector which may be operated in a direct detection mode or in a heterodyne mode. A multiple quantum well photodetector includes a plurality of wells and a plurality of barriers formed of alternating layers of gallium-arsenide and aluminum-gallium-arsenide material respectively. The gallium-arsenide layers are highly doped with an n-type dopant such as silicon atoms. The high doping produces an unexpected result of improved operational efficiency at elevated temperatures. Photodetectors of these inventions have a large number of quantum well structures to improve absorption or interaction cross section. In all versions, the middle portion of wells include a special region of a highly doped gallium arsenide material in a density of about one to three trillion silicon atoms per square centimeter.

Abstract: A subject (10) is disposed adjacent a detector array (18) for the purposes of nuclear imaging. The subject (10) is injected with a radioactive isotope (14) and &ggr;-ray emissions indicative of nuclear decay are detected at the detector array (18). P-ASIC (60) preamplifier circuits are complex low-noise integrated circuits which dissipate a considerable amount of power (300-500 mW each). These components account for most of the dissipated power on the daughter cards (62). In order to facilitate the cooling of these electrical components, they are mounted on circuit boards (62) that are arranged parallel to each other extending perpendicularly away from the detector array (18). This provides channels between the boards through which cooling air is drawn by an array of fans (84).

Abstract: A photodetecting device is characterized by comprising a photodetecting section having a photoelectric surface for emitting photoelectrons upon incidence of light, a semiconductor detection element having an electron incident surface on which the photoelectrons can be incident, and a vacuum vessel in which the photoelectric surface is arranged on one inner surface, and the semiconductor detection element is arranged on the other inner surface opposing the one surface, and cooling means for cooling a structure on the semiconductor detection element side of the vacuum vessel.

Abstract: A detection system for detecting X-ray radiation from a sample located in a microbeam instrument. The detection system comprises: a. a pulse tube cooler; b. a compressor connected to the pulse tube cooler; c. a sensor coupled to the pulse tube cooler; and, d. a housing containing the pulse tube cooler and the sensor. The pulse tube cooler, the sensor and at least part of the housing are sufficiently small to be positioned inside the microbeam instrument in use, thereby allowing the X-ray radiation from the sample to be detected by the sensor.

Abstract: A heat sink system and method for a radiographic sensor device includes a heat sink formed of a first material possessing a predetermined thermal conductivity. The heat sink system further includes a thermal channel device formed of a second material possessing a predetermined thermal conductivity. The thermal channel device includes at least one contact portion adapted to contact the radiographic sensor device and an extending member that extends away from the at least one contact portion and contacts the heat sink. The thermal channel device is designed to extend between and substantially contact the heat sink and the radiographic sensor device when the heat sink system is assembled. The thermal channel device conducts heat from the radiographic sensor device to the heat sink.

Abstract: Methods and apparatus for compensating a radiation sensor for ambient temperature variations. Ambient temperature variations may produce undesirable artifacts in electronic signals output by a radiation sensor. In some cases, such artifacts may detrimentally reduce the dynamic range of the sensor and/or processing circuitry associated with the sensor with respect to radiation of interest. The radiation sensor may be compensated for such undesirable artifacts by, for example, adding an appropriate offset to a sensor bias voltage or a sensor bias current, and/or controlling a temperature of the radiation sensor, based on variations in the ambient temperature.

Abstract: A radiation detector is realized as, for example, a flat panel detector (FPD) for two-dimensionally detecting X-rays. The detector comprises a detection board and a control unit. The detection board on which a plurality of detection elements for detecting a radiation are two-dimensionally disposed in a matrix and circuits for collecting signals from the detection elements. The control unit for controlling the detection board so that the detection board is placed in a predetermined temperature state. The predetermined temperature state is defined, for example, as predetermined ranges of temperatures used during the operation and the non-operation states of the detector, respectively. This radiation detector can be mounted in a radiography system such as an X-ray radiography system.

Abstract: An infrared camera with lower dissipation power, a wide range of operating environment temperature, and a shorter warmup is provided. The infrared camera includes a plurality of device operating-temperature setting circuits setting respective device operating temperatures different from one another, a device operating-temperature setting switch for selecting one of the output of the device operating-temperature setting circuits, and a temperature sensor, and performs imaging by switching the connection target of the device operating-temperature setting switch according to a measurement by the temperature sensor, that is to say, according to the temperature inside an enclosure and selecting an operating temperature for an imaging device among a plurality of device operating-temperature settings.

Abstract: A pixel sensor system that includes a photo-sensor, an output amplifier, and a feedback capacitor. The photo-sensor is configured to receive photons and to convert the photons into charge. The output amplifier has at least two transistors in a cascoded configuration. The amplifier converts the charge into electronic signal. The feedback capacitor is disposed between the photo-sensor and an input of the output amplifier.

Abstract: An X-ray CT radiation detector includes a heat insulating case mounted on a rotating base, a radiation incident window formed in the heat insulating case, a detection panel on which detection elements for detecting radiation incident through the radiation incident window are arrayed. The detection panel is positioned to form a fluid circulatory path in the heat insulating case. A circulator for circulating the fluid is placed in the circulatory path. The circulatory path and circulation of the fluid by the circulator make it possible to make the temperature of the detection panel relatively uniform.

Abstract: A scintillation detector having reduced temperature sensitivity is provided by having two circuits for temperature compensation. The two circuits may be a thermistor in parallel with both a resistive element and a switching element. The switching element can be various devices including a zener diode, a Schottky barrier diode or an MIM. The temperature compensation circuit may be included in the circuit of a photo-detector such as a photomultiplier tube.

Abstract: A thermal radiation shield for cooled portable gamma-ray spectrometers. The thermal radiation shield is located intermediate the vacuum enclosure and detector enclosure, is actively driven, and is useful in reducing the heat load to mechanical cooler and additionally extends the lifetime of the mechanical cooler. The thermal shield is electrically-powered and is particularly useful for portable solid-state gamma-ray detectors or spectrometers that dramatically reduces the cooling power requirements. For example, the operating shield at 260K (40K below room temperature) will decrease the thermal radiation load to the detector by 50%, which makes possible portable battery operation for a mechanically cooled Ge spectrometer.

Abstract: A germanium gamma-ray detector contained in a vacuum insulated cryostat is provided. The present invention provides a low-cost, high-performance, and highly reliable cooling system for germanium detectors. Moreover, the present invention provides a germanium detector operating environment that meets all the requirements for optimum performance of such detectors incorporating said cooling system. A self-cleaning cooler includes a counter-current heat exchanger which is received within a cooler housing. A removable cryostat is provided for being carried by the cooler housing. A capsule cold finger provides the cooling path to germanium detector element. A centering spacer/isolator is provided for maintaining the position and supporting the weight of the detector in an end cap without conducting an excessive amount of heat into the detector. A capsule flange is provided to substantially close the volume within the end cap. The heat exchanger and the throttle capillary of the cooler cool the cold block.

Abstract: An infrared spectrometer is adapted to capture spectral data at high frequency and includes an aperture defining slit and tuning fork chopper for periodically admitting infrared radiation. A lens and a plurality of mirrors direct the infrared radiation through pair of calcium fluoride prisms that split the infrared radiation into spectral components. The spectral components are directed by an additional mirror and lens to an array of lead selenide pixels that generate a set of data indicative of the spectral component intensities. Data collection circuitry coupled to the pixel array and coupled to the tuning fork chopper collects the set of data at a selectable rate at least once during each opening of the aperture. A serial output on the data collection circuitry provides a list of data values representative of the spectral intensity at each pixel which can be then stored in a mass storage device as well as immediately analyzed based on selected criteria.

Abstract: A dark current component included in an image signal output from a detector of optical reading type is reduced in a radiation image data obtaining method and apparatus using the detector. A detector having radiation-insensitive areas at both ends of a stripe electrode outside an image area along the longitudinal direction thereof is used. An image signal output from a current detection amplifier is converted into image data having digital values by an A/D converter and input to a memory. A correction data calculation circuit finds correction data gradually decreasing from a starting area to the ending area of vertical scan in accordance with each position of each element along the longitudinal direction thereof, based on image data of the insensitive areas corresponding to the scan starting and ending areas. For each element, a subtraction circuit subtracts the correction data from image data of an image area.