Abstract: A process of making a casting includes the steps of designing a mold (1010), fabricating the layers (or laminations) of the mold (1020), stacking and assembling the laminations into a mold (1030), producing a casting (1060) and demolding the casting (1070). If necessary, a derived mold can be made (1040, 1050) prior to producing the casing (1060).

Abstract: A method of providing with precision a number of long and narrow through holes (11) in a body (1) made of a high-density material. The body (1) is made in the form of a number of partial bodies (2, 2′, 2″), which are arranged close to each other and from the body (1). Each partial body (2, 2′, 2″) is defined by an outer surface (5), which is part of the outer surface of the entire body (1), an inner surface (6), which is part of the inner surface of the entire body (1), as well as a pair of boundary surfaces (7, 8), which extend from the outer surface (5) to the inner surface (6). Holes (11) are produced by machining at least one of the bounding surfaces (7, 8) adjacent partial bodies (2′, 2″). Each hole (11) extends from the outer surface (5) to the inner surface (6) along said at least one boundary surface (7, 8). The thus machined partial bodies (2, 2′, 2″) are fixedly attached to each other.

Abstract: A method for delivering radiation from a radiation source to treatment a area utilizing a multi-leaf collimator. The method includes positioning the multi-leaf collimator between the radiation source and the object to block a portion of the radiation. The leaves of the multi-leaf collimator are generally located within a plane and extend longitudinally along a first axis. The leaves are positioned to define a first treatment field. The method further includes delivering radiation to the first treatment field and rotating the multi-leaf collimator about a central axis extending generally perpendicular to the leaf plane.

Abstract: Cast collimators for use in CT imaging systems are described, as are methods of making them. Such collimators may comprise pre-patient collimators, pre-patient filter/collimator assemblies, and/or post-patient collimators. The filters and/or collimators may be made of any suitable high-density, high atomic number material such as lead, a lead alloy, tantalum, tungsten, tungsten suspended in an epoxy matrix, tungsten suspended in a slurry, or the like. Embodiments of these collimators comprise specially-designed channels and vanes that allow them to be precision cast to the necessary degree of accuracy. These channels and vanes are preferably tapered. These collimators and filter/collimator assemblies help minimize the x-ray dose to the patient by minimizing the scattered radiation creation mechanism and by collimating out much of the scattered radiation that would otherwise be subjected to the patient.

Abstract: A beamblock tray for use with multiple defining heads within a medical linear accelerator is disclosed. The beamblock tray comprises a tray portion, and a plurality of coded connectors coupled to the tray portion that make the tray “intelligent” enough to identify its orientation to a user. The tray portion can be inserted into the defining head in a plurality of directions based upon the plurality of coded connectors. A system and method in accordance with the present invention utilizes a plurality of coded connectors that can be used to identify a patient. In addition, the connectors and a mounting flange are such that they permit the tray to be inserted in a plurality of directions. Finally, a coding system is provided that prevents radiation from being delivered if the tray is oriented incorrectly.

Abstract: An X-ray CT apparatus comprises a large number of X-ray sources, a detector, and a collimator. The X-ray sources are arranged around an object P of inspection. The detector detects X rays emitted from the X-ray sources. The collimator is located between the X-ray sources and the object of inspection, and restricts the angle of emission of the X rays emitted from the X-ray sources so as to match the size of the detection surface of the detector.

Abstract: A radiation imaging system comprises a movable radiation source adapted to be disposed in a plurality of respective radiation source positions; a radiation detector and a collimator assembly configured to displace a collimator in a plurality of respective collimator positions, each of the collimator positions being coordinated with at least one of the radiation source positions such that a radiation beam emanating from the radiation source is collimated to limit radiation incident on the detector to a predetermined exposure area. Another radiation imaging system comprises a movable radiation source; a radiation detector; and a collimator comprising an adjustable geometry aperture assembly configured such that an adjustment of the aperture geometry is synchronized with the movement of the radiation source and coordinated with the radiation source position so as to limit the incident radiation to a predetermined exposure area at the detector.

Abstract: An X-ray inspection system is provided having an X-ray source and first and second collimators. The first and second collimators are arranged in relation to the source and the target such that the portion of the target actually illuminated by The X-ray beam is substantially equal to the size of a selected inspection zone.

Abstract: A method is described for making an x-ray collimator. A plurality of collimator sheets are formed. Each collimator sheet has a plurality of septa lands that are made of a material that substantially attenuates x-ray radiation. A respective region is defined between a respective pair of the septa lands which is free of the material. The collimator sheets are positioned adjacent to one another. Adjacent corresponding lands of the collimator sheets are positioned adjacent to one another.

Abstract: The parallel radiation (12) emanating from a sample 4 in a known apparatus for X-ray analysis (for example, for diffraction) is analyzed according to wavelength and focused in a focus 20 by a parabolic multilayer mirror 14. A collimator 28 is positioned around said focus. The resolution of the apparatus can be enhanced by making the angular passage width of the collimator smaller than the maximum range of its reflection angle &agr;max. In accordance with the invention the resolution of the apparatus will be better defined and hence enhanced by implementing the exit collimator 28 in such a way that the angular value for the passage width from every reflecting point A or B of the mirror surface is substantially independent of the position of the reflecting points. Preferably, the exit collimator 28 is implemented in the form of two mutually parallel knife edges which are situated at different distances from the reflecting points of the multilayer mirror.

Abstract: An apparatus for use with a combined CT-PET system wherein a CT source and detector are mounted to a front end of a CT support and the support forms a parking space about a translation axis, a PET detector is mounted to a rear end of the support and a collimator support extends from the PET detector at least part way into the parking space, a collimator is mounted to the collimator support for movement between first and second positions inside the PET detector and outside the PET detector and at least partially within the parking space, respectively, a radiation blocking shield is mounted to the PET detector opposite the CT support to block radiation from that direction from being detected by the PET detector.

Abstract: An X-ray inspection system is provided comprising an X-ray source having means for generating more than one beam defining an inspection plane, the beams being substantially parallel to each other; an X-ray detector having a plurality of detector arrays, each of which is aligned with one of the beams, and means for supporting an object between the X-ray source and the X-ray detector. The means for generating more than one beam may include an electron gun and means for steering an electron beam generated by the gun to multiple focal spots on a target.

Abstract: A method and apparatus for detecting radiation including x-ray, gamma ray, and particle radiation for radiographic imaging, and nuclear medicine and x-ray mammography in particular, and material composition analysis are described. A detection system employs fixed or configurable arrays of one or more detector modules comprising detector arrays which may be electronically manipulated through a computer system. The detection system, by providing the ability for electronic manipulation, permits adaptive imaging. Detector array configurations include familiar geometries, including slit, slot, plane, open box, and ring configurations, and customized configurations, including wearable detector arrays, that are customized to the shape of the patient. Conventional, such as attenuating, rigid geometry, and unconventional collimators, such as x-ray optic, configurable, Compton scatter modules, can be selectively employed with detector modules and radiation sources.

Abstract: An x-ray technique-based nonintrusive inspection apparatus is provided which is capable of inspecting 600 containers an hour which is small, and which is easily maintainable. Features of the apparatus include “radiation locking” with “active curtains”, “continuous scanning” utilizing an x-ray line scanner subsystem and a CT scanner subsystem, good structural integrity, radiation containment in a self-shielding manner, an easily maintainable driving arrangement, shielding curtains that can be raised and lowered quickly, a container jam release mechanism, and efficient air conditioning.

Abstract: A collimator for an X-ray inspection apparatus is provided comprising a carrier having a planar top surface; an arcuate base disposed on the carrier, comprising at least one arcuate bar section made from a radio-opaque material; and a plurality of radio-opaque collimator plates disposed on the arcuate base in a radial array with a bottom edge of each collimator plate in contact with the top surface of the arcuate base. A method for assembling such a collimator is also provided, as well as an alignment fixture useful for practicing the described method. The described structure, method, and alignment fixture permit the construction of large collimator assemblies while maintaining precision and minimizing cost.

Abstract: A micro collimator for compressing X-ray beams for use in a X-ray diffractometer is described, wherein said collimator has a channel means for providing a channel guiding said X-ray beams, said channel having a channel entrance portion and a channel exit portion. The object of the invention is to provide a micro beam collimator capable of being used in a conventional X-ray diffractometer with the Bragg-Brentano geometry, so as to enable the characterisation of very small sample regions without need of very large radiation sources (synchrotron). For solving this technical problem it is proposed to form the channel means by two opposite, polished, oblong plate means made of or coated with a material selected from the group consisting of the heavyweight metals and materials having total reflection properties comparable to those of the heavyweight metals.

Abstract: A collimator set for a radiotherapy apparatus comprises, in sequence, an aperture collimator, a multi-leaf collimator with a pair of opposing arrays of elongate leaves each moveable longitudinally in a Y direction, and a leaf edge collimator, the aperture collimator being adapted to collimate the beam in the X and Y direction to a first extent, and the leaf edge collimator being adapted to further collimate the extent of the beam in the Y direction to a second and therefore lesser extend. This means that to close a pair of opposing leaves, they are moved to their minimum separation, with the gap being convered by the leaf edge collimator. The MLC is after the aperture collimator, so in combination with thin leaves, the MLC leaves will project a much reduced leaf width at the isocentre of the radiotherapy apparatus and collimation of the radiation field by fractional leaf widths becomes unnecessary. A radiotherapy apparatus comprising a collimator set as defined above is also disclosed.

Abstract: An electron beam tomography (EBT) scanning system comprising an electron source generating an electron beam, a target ring that receives the electron beam and emits an x-ray fan beam upon impingement of the electron beam on the target ring, a pair of detector arrays arranged opposite the target ring, and a collimator arranged concentrically between the target ring and the pair of detector arrays. The collimator has interior and exterior walls concentrically arranged with one another and surrounding a patient examination area. The interior and exterior walls have a first set of apertures aligned to collimate the x-ray fan beam into a first collimated beam having a first width and a second collimated beam having a second width. Each collimated beam may form a single or double tomographic slice. The collimated beams are detected by the pair of detector arrays.

Abstract: Certain exemplary embodiments of the present invention comprise a device comprising a cast collimator derived from a metallic foil stack lamination mold, said collimator defining a feature adapted to contain a plurality of radiation detection elements. In certain embodiments, the collimator can define a feature adapted to contain a plurality of radiation detection elements, such as scintillators. Certain exemplary embodiments of the present invention comprise a device comprising a cast component derived from a metallic foil stack lamination mold. In various exemplary embodiments, the cast components can be a mechanical, electrical, electronic, optical, fluidic, biomedical, and/or biotechnological component. It is emphasized that this abstract is provided to comply with the rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure.

Abstract: A collimator for an X-ray inspection apparatus is provided comprising a carrier having a planar top surface; an arcuate base disposed on the carrier, comprising at least one arcuate bar section made from a radio-opaque material; and a plurality of radio-opaque collimator plates disposed on the arcuate base in a radial array with a bottom edge of each collimator plate in contact with the top surface of the arcuate base. A method for assembling such a collimator is also provided, as well as an alignment fixture useful for practicing the described method. The described structure, method, and alignment fixture permit the construction of large collimator assemblies while maintaining precision and minimizing cost.

Abstract: An X-ray inspection system is provided having an X-ray source and first and second collimators. The first and second collimators are arranged in relation to the source and the target such that the portion of the target actually illuminated by The X-ray beam is substantially equal to the size of a selected inspection zone.

Abstract: A system and method for recovery of phase information from recorded intensity values is disclosed. In one aspect, a phase filter is placed in a plane, which may be the back focal plane (BFP) of a lens used for observing an object. The phase filter changes the phase of a wave front distribution in the BFP in a known manner. Amplitude stops or combinations of phase and amplitude filtering patterns can also be used to capture N different sets of intensity data in a conjugate diffraction plane. The N intensity images are used to obtain an estimate of the wave front at the first plane. This wave front estimate is then used to generate N modified estimates of the wave front at the conjugate plane, each modified estimate corresponding to one of N filtering patterns. In one implementation, the N modified IP estimates are corrected by replacing the estimated amplitudes with the actually measured ones for that image.

Abstract: A method for fabricating a collimator includes mixing an x-ray absorbent material with at least one of a temporary binder and a temporary gel, and extruding the mixed x-ray absorbent material through a die to form a unitary collimator structure that is at least one of substantially honeycomb in shape and substantially rectangular in shape.

Abstract: The invention relates to an apparatus for X-ray imaging, in which imaging an X-ray beam (11) is directed through the object being imaged. The X-ray imaging apparatus (1) comprises an X-ray source (5) in front of the object being imaged, a primary collimator (6) in conjunction with the X-ray source, and radiation receiving means (15), which are located in a position behind the object being imaged. The apparatus relating to the invention comprises identifying means (20-22) which react to X-ray radiation, by means of which is ensured the entry of radiation inside the imaging area of the radiation receiving means (15).

Abstract: The present invention provides a high gain collimator producing generally uniform intensity profiles for use in lithography and other applications. A focusing optic is also provided. The collimator includes a reflector and guide channel. The guide channel preferably includes polycapillary tubes and/or microchannel plates. The polycapillary tubes are used to collimate or focus the central portion of the x-ray beam in a circular, elliptic, square, or rectangular shape. A conical, parabolic resonance reflector or grazing incidence reflector with a shape similar to the polycapillary collimator is used to increase the solid angle collected and produce a circular, square, etc. annular x-ray beam whose inside dimensions are approximately equal to the exit dimensions of the polycapillary collimator.

Abstract: Reduced dose megavoltage CT images are obtained using low flux data resulting from leakage through modulating shutters and/or collected by other means and augmented by incomplete high flux data collected during radiation therapy. The ability to construct tomographic projection sets from significantly varying flux rate data is provided by the use of air scans windowed to account for variations in mechanical leaf movement. These methods are also provide a means of imaging the patient entirely during radiation therapy treatments without any additional scan time.

Abstract: An x-ray shielding system includes a beam controller configured to surround an x-ray source and includes a detector shield configured to position behind an x-ray detector. The beam controller includes a source shield and an aperture. The source shield and the detector shield are adapted to block x-rays, and the aperture is adapted to transmit x-rays. A shielded digital radiographic inspection system includes the x-ray source and the beam controller surrounding the x-ray source. The beam controller includes the source shield and the aperture. The aperture is configured to rotate around the x-ray source. The inspection system further includes a digital x-ray detector positioned radially outward from the x-ray source and facing the aperture. The digital x-ray detector is configured to be movable along an orbit around the x-ray source. The inspection system further includes the detector shield configured to be movable with and positioned behind the digital x-ray detector.

Abstract: An x-ray system that uses an x-ray source to irradiate a subject with x-rays is provided. A collimator is located proximate to the x-ray source and blocks a portion of the x-rays. A detector receives the x-rays and creates subject data indicative of a subject and collimator data indicative of a collimator. A position detector identifies a position of the collimator with respect to a field of view of the x-ray source. A gating module receives the subject and collimator data and passes at least a portion of the subject data. The gating module blocks at least a portion of the collimator data based on the position of the collimator. A display displays an x-ray image based on the portion of the subject data passed by the gating module.

Abstract: Aspects of a multiple layer multileaf collimator capable of improving resolution for coverage of a target during radiation therapy are described. A multiple layer multileaf collimator includes a first layer of multiple elongated radiation blocking leaves supported by a first frame for individual leaf positioning in a first direction. The multiple layer multileaf collimator further includes a to second layer of multiple elongated radiation blocking leaves supported by a second frame for individual leaf positioning in a second direction, the second direction offset at a desired angle relative to the first direction, wherein the individual leaves of the first and second layers conform more closely with a target shape to improve resolution. Further, the second layer is positioned above the first layer and provides leakage coverage for the multiple elongated radiation blocking leaves of the first layer.

Abstract: A radiation imaging system comprises a movable radiation source adapted to be disposed in a plurality of respective radiation source positions; a radiation detector and a collimator assembly configured to displace a collimator in a plurality of respective collimator positions, each of the collimator positions being coordinated with at least one of the radiation source positions such that a radiation beam emanating from the radiation source is collimated to limit radiation incident on the detector to a predetermined exposure area. Another radiation imaging system comprises a movable radiation source; a radiation detector; and a collimator comprising an adjustable geometry aperture assembly configured such that an adjustment of the aperture geometry is synchronized with the movement of the radiation source and coordinated with the radiation source position so as to limit the incident radiation to a predetermined exposure area at the detector.

Abstract: Certain exemplary embodiments of the present invention comprise a device comprising a cast computed-tomography collimator descended from a lithographically-derived micro-machined metallic foil stack lamination mold. Certain exemplary embodiments of the present invention comprise a method comprising filling a mold having a stacked plurality of micro-machined metallic foil layers with a first casting material to form a first cast product; demolding the first cast product from the mold; filling the first cast product with a second casting material to form a cast computed-tomography collimator; and demolding the cast computed-tomography collimator from the first cast product. It is emphasized that this abstract is provided to comply with the rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. This abstract is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

Abstract: Certain exemplary embodiments of the present invention comprise a cast collimator descended from a stack lamination mold, said mold comprising a plurality of metallic foils. Certain embodiments of the present invention comprise a method comprising filling a mold having a stacked plurality of micro-machined metallic foil layers with a first casting material to form a first cast product; demolding the first cast product from the mold; filling the first cast product with a second casting material to form a cast collimator; and demolding the cast collimator from the first cast product. It is emphasized that this abstract is provided to comply with the rules requiring an abstract that will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. This abstract is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims. 37 CFR 1.72(b).

Abstract: An X-ray optical system with an X-ray source (Q) and a first graded multi-layer mirror (A), wherein the extension Qx of the X-ray source (Q) in an x direction perpendicular to the connecting line in the z direction between the X-ray source (Q) and the first graded multi-layer mirror (A) is larger than the region of acceptance (F) of the mirror (A) at a focus (Oa) of the mirror (A) in the x direction, is characterized in that a first collimator (bl) is disposed at a focus of the first graded multi-layer mirror (A) between the X-ray source (Q) and the mirror (A) whose opening in the x direction corresponds to the region of acceptance of the first graded multi-layer mirror (A) and the separation qzA between first collimator (bl) and X-ray source (Q) is:

Abstract: A method for defining an extended field area of an intensity map for use in delivering radiation from a radiation source to an object with a multi-leaf collimator is disclosed. The multi-leaf collimator includes a plurality of leaves operable to travel in a first direction and rotatable such that the leaves are operable to travel in a second direction extending generally orthogonal to the first direction. The method includes defining a central square area having dimensions approximately equal to two times an over travel margin of the multi-leaf collimator and defining four edge margins each extending from a side of the central square and having dimensions approximately equal to two times an over travel margin of the multi-leaf collimator along an edge adjacent to the central square and half the number of leaves within the multi-leaf collimator times leaf width minus half the central square dimension.

Abstract: The invention concerns an X-ray device 10 for medical examination comprising an X-ray source 3 emitting a beam 4 of X-rays towards an object 2 to be examined. An X-ray detector 5 is provided for receiving the X-rays passed through the object and connected to image processing means 6 for forming an image of said object. X-ray collimator means 9 are arranged between the X-ray source and the object to eliminate the effects of scattered radiation. The X-ray collimator means comprise a translatable element 9 that has at least one aperture 11 for narrowing the beam.

Abstract: A method of manufacturing a collimator including providing a plate-like body, coating a predetermined portion of a surface of the body with an x-ray absorbing material, and machining at least one collimating slit through the coating and the plate-like body. According to one exemplary embodiment, the coating is applied through a thermal spray process. According to another exemplary embodiment, wire electrical discharge machining (EDM) is used to machine the collimating slits. A collimator manufactured in accordance with the presently disclosed method produces precise energy beam cross-sections, yet is less expensive to manufacture.

Abstract: A method for producing a scattered radiation grid or collimator which, for an incident radiation type, has transmissive regions and nontransmissive regions of predeterminable geometry. First the geometry of the transmissive and the nontransmissive regions of the scattered radiation grid or collimator is set. On the basis of this geometry, a base body is constructed according to the geometry, optionally differing by a particular layer thickness, of the transmissive regions or the nontransmissive regions by a rapid prototyping technique through layer-wise solidification of a structural material under the action of radiation. On the basis of this base body, the scattered radiation grid or collimator is finally completed.

Abstract: A diffraction apparatus (10) for determining crystalline and polycrystalline materials of an item in objects, preferably in luggage, having a collimation/detector arrangement (11) and an X-ray source (12) and which is mounted to be adjustable in an X-ray testing machine (13). The collimation/detector arrangement (13) is adjustable in height relative to the X-ray source (12), and the two are also laterally and synchronously adjustable via respective adjustment elements (5,6). The collimator (13) has a conically-expanding round slot (15), which simulates a predetermined angle (&THgr;M) of a scatter-beam path.

Abstract: A synchronized moving radiation shield apparatus includes at least one shielding block disposed under a radiation pathway of a radiation therapy unit in such a manner that a radiation field is formed with the shielding block, wherein an affected portion of a person is exposed to radiation through the radiation field while radiation therapy of a portion, other than the affected portion, of the person, is shielded by the shielding block. The apparatus further includes a movable portion for movably holding the shielding block while not blocking the passing of radiation through the radiation field; drive means, connected to the movable portion, for moving the radiation field to a specific position; and control means for controlling the drive means in such a manner that the radiation field is movable in matching to a variation in position of the affected portion.

Abstract: An X-ray scatter reduction grid includes a first layer having a plurality of cells. The cells have a perimeter formed of an X-ray absorbing material. The shape of the perimeters can vary, but a polygonal shape is preferred. The grid can also include other layers, each with their own cells. The cells of the subsequent other layers are larger than and offset from the cells of the prior layer. The increased size of the cells allows a primary ray passing through the center of a first layer cell to also pass through the center of a subsequent layer cell. This allows for a maximum of primary ray passthrough and a maximum of scatter absorption.

Abstract: A method for calibration and/or quality assurance of nuclear medicine imaging, in which functional information of the organs to be studied is achieved by inserting radioactive solution emitting detectable radiation in the organs of a phantom simulating the organs to be studied and by detecting the radiation. The filling and emptying of the organs of the phantom to be studied is simulated by regulation of the detectable radiation from the phantom. The organs to be simulated by the phantom are in form of containers filled with radioactive solution, the apparatus further comprising movable isolating parts, like steel plates, between the containers and the gamma camera to isolate radiation from the containers to the camera. The invention is also concerned with an arrangement comprising the apparatus of the invention and a gamma camera.

Abstract: A multileaf collimator for use in a radiation system providing a radiation beam in a given beam direction, including a first layer of a plurality of radiation blocking leaves, the leaves being arranged adjacent one another so as to form two opposed rows of adjacently positioned leaves and being movable in a longitudinal direction (Y) which is generally transverse to the beam direction, defining a radiation beam shaping field between the opposed ends of the leaves, a second layer of a plurality of radiation blocking leave, the leaves of the second layer being arraigned adjacent one another as to form two opposed rows of adjacently positioned leaves and being movable in a cross-over direction (X) which is generally transverse to the beam direction and angled with respect to the longitudinal direction (Y), defining a radiation beam shaping field between the opposed ends of the leaves of the second layer.

Abstract: An apparatus for planar beam radiography comprises an ionizing radiation source and an ionizing radiation detector; the ionizing radiation source being line-like and extending substantially in a first direction; and the ionizing radiation comprising an elongated radiation slit entrance extending substantially in a second direction and being arranged for one-dimensional detection of radiation from the radiation source entering the detector through the radiation slit entrance. According to the present invention the radiation source and the radiation dectector are oriented such that the first and second directions are essentially perpendicular. Hereby,a facilitated alignment of the detector with respect to source is achieved.

Abstract: A method is provided for determining the positional accuracy of leaves of a multileaf collimator for delivering doses of radiation to a particular spatial location for treatment purpose. The method could be implemented as routine quality assurance check of the multileaf collimator leaf positioning errors. The method includes producing a first field and producing a second field, which is different from the first field. A dosimeter means is included for measuring a radiation dose difference or ratio between the first field and the second field at at least one spatial location. The dose difference or ratio is then used to determine the positional accuracy of the leaves by comparing with a known relationship between leaf positional errors and relative dosimeter outputs. The method provides a more simplified, accurate, efficient and reliable method over currently used methods.

Abstract: A system and method for inspecting an object, the system and method comprising a source for generating a penetrating radiation beam for irradiating the object, the beam having, for each instant of time, an instantaneous energy spectrum of intensity, a shaper for modulating the generated beam, thereby creating a shaped beam, the shaper comprising at least a first section and a second section, the first section attenuating the intensity of a portion of the generated beam by a first attenuation factor and the second section attenuating the intensity of another portion of the generated beam by a second attenuation factor, and at least one detector for detecting the shaped beam after the shaped beam interacts with the object. The source may scan a beam across an object while the source and at least one detector are moving on a platform capable of highway travel or on an inspection module movable with respect to the object.

Abstract: An X-ray fluorescence analysis apparatus in which a collimator for defining a range of passage of X-rays, can be safely and simply attached and detached by providing a right-hand screw thread for attachment of the collimator to a housing, an X-ray generator, or an X-ray detector, and further providing a left-hand screw thread on a side of the collimator opposite to that of the right-hand screw thread. An attachment jig having a left-hand screw thread corresponding to the left-hand screw thread provided on the collimator is used to attach and detach the collimator.

Abstract: A diffraction apparatus (10) for determining crystalline and polycrystalline materials of an item in objects, preferably in luggage, having a collimation/detector arrangement (11) and an X-ray source (12) and which is mounted to be adjustable in an X-ray testing machine (13). The collimation/detector arrangement (13)is adjustable in height relative to the X-ray source (12), and the two are also laterally and synchronously adjustable via respective adjustment elements (5,6). The collimator (13) has a conically-expanding round slot (15), which simulates a predetermined angle (&THgr;M) of a scatter-beam path.

Abstract: A collimator for an X-ray testing machine and a method for adjusting the collimator with the aid of a detection system disposed in the collimator that includes at least two spatially separate detection devices, disposed and spacing one behind the other.

Abstract: An X-ray shielding mechanism to block off-axis X-rays for example, in an X-ray analytical instrument such as a fluorescent X-ray spectroscope is provided. X-rays are guided on-axis by elongated glass guide tubes and outer elongated metallic protective pipes are spatially positioned on the exterior of the glass guide tubes to block off-axis X-rays.

Abstract: An x-ray alignment and measurement process including an x-ray source and a detection array. The detection array allows for the taking of images having a precisely known pixel size and location. Disposed between the x-ray source and the detection array is an object having a known size or position. The object is then imaged and the location and size of the object on the image can be determined and compared to the actual size or location. The calculation is performed on the multiple pixels in the image to mathematically determine the remaining unknown object location or size. For alignment purposes, any error in the location or size of the object can thus be corrected.