Abstract: Systems and methods are provided for implementing an analytical approach to digital volumetric laminar tomography. The volumetric data visualizations generally take the form of volumetric images which approximate the spatial distribution of an x-ray attenuation coefficient throughout the region of interest in the object, such as a person, under examination. These visualizations are produced from a set of basic two dimensional data. One numerical technique employed in this regard takes the form of a process of convolution and back projection, where the convolution function is determined through the use of various analytic and empirical techniques.

Abstract: An apparatus for use in a radiation procedure includes a radiation filter having a first portion and a second portion, the first and the second portions forming a layer for filtering radiation impinging thereon, wherein the first portion is made from a first material having a first x-ray filtering characteristic, and the second portion is made from a second material having a second x-ray filtering characteristic. An apparatus for use in a radiation procedure includes a first target material, a second target material, and an accelerator for accelerating particles towards the first target material and the second target material to generate x-rays at a first energy level and a second energy level, respectively.

Abstract: In one embodiment, a scanning unit for inspecting cargo conveyances uses a partial radiation beam and a detector of reduced length. In another embodiment, a scanning unit for inspecting objects comprises a detector with gaps along its expanse. In both cases, the cost of the scanning system may be reduced. The object, the source, and or the detector may be moved to enable generation of computed tomographic images. Methods are disclosed, as well.

Abstract: Systems and methods for the radiation scanning of objects, including large objects such as cargo containers, to identify contraband.

Abstract: An apparatus for use in a radiation procedure includes a radiation filter having a first portion and a second portion, the first and the second portions forming a layer for filtering radiation impinging thereon, wherein the first portion is made from a first material having a first x-ray filtering characteristic, and the second portion is made from a second material having a second x-ray filtering characteristic. An apparatus for use in a radiation procedure includes a first target material, a second target material, and an accelerator for accelerating particles towards the first target material and the second target material to generate x-rays at a first energy level and a second energy level, respectively.

Abstract: Systems and methods for the radiation scanning of objects, including large objects such as cargo containers, to identify contraband.

Abstract: Devices and methods for implementing selective, or asymmetric, attenuation of an x-ray beam. In one example, a filter is provided that is substantially in the form of a wedge where some portions of the filter are thicker, and thus provide greater attenuation, than other, thinner portions of the filter. The filter is situated between the target surface of the anode and the x-ray subject so that x-rays generated by the target pass through the filter before reaching the x-ray subject. Specifically, the filter is oriented so that the thicker portion of the filter receives the higher intensity portion of the x-ray beam, while the thinner portion of the filter receives the relatively lower intensity portion of the x-ray beam. Thus, the gain profile of the x-ray beam is flattened so that the intensity, or flux, of the x-ray beam is relatively uniform throughout a substantial portion of the beam profile.

Abstract: In one example, a scanning unit for examining contents of a cargo container is disclosed comprising a first path through the scanning unit for transport of a cargo container and one or more sources of respective beams of radiation. At least one of the one or more sources are movable across a second path transverse to the first path. The second path extends partially around the first path. The scanning unit further comprises a detector extending partially around the first path. The detector is positioned to detect radiation interacting with the cargo container during scanning, such as radiation transmitted through the container. The at least one source and the detector are positioned so that the cargo container is transportable along the first path, between the source and the detector. A transport system may be provided to convey the object through the scanning unit, along the first path.

Abstract: A scanning unit for inspecting objects comprises in one embodiment a radiation source to emit a beam of radiation, a rotatable platform to support an object for inspection by the beam of radiation and a detector positioned to receive radiation after interaction of the beam with the object. At least one of the platform, the source and the detector may be moved in a first direction, such as vertically. The object may be scanned while being rotated and moved to generate volumetric computed tomographic images. The rotational and movement of the platform and the object may also be indexed. The beam of radiation may be a horizontally extending cone beam or a fan beam. The detector may extend horizontally, as well. The rotational and/or vertical position of the platform may be used to direct the object along one of multiple exit paths. The scanning unit may provide a vertically extending radiation beam and a vertically extending detector to conduct line scanning.

Abstract: A radiation apparatus (10) includes a beam source (12) generating radiation beam toward a target (11). A projection detector (17) detects the images of the target (11) formed by the radiation beam. In a radiation treatment session using the apparatus (10), the beam source (12) first generates a low intensity beam. The projection detector (17) generates image signals of a patient under the treatment. A control module (18) in the apparatus (10) develops a treatment plan in accordance with a treatment prescription and the image signals. Subsequently, the beam source (12) generates a treatment beam according to the treatment plan. The projection detector (17) can generate further image signals formed by the treatment beam to verify the treatment process.

Abstract: An X-ray image acquisition apparatus (15) includes a conversion panel (20) aligned with a photo detector array (40). The conversion panel (20) includes a plurality of conversion cells (22), each including a conversion body (31), an X-ray transparent and light reflective file over the top (32) of the body (31), and a light reflective film (36) surrounding the body (31). The body (31) is made of a scintillating material that efficiently generates optical light photons in response to X-ray radiation illuminating thereon and is substantially transparent to the optical light photons. The body (31) is also sufficiently long to absorb the X-ray radiation over a wide range of energy levels. The light reflective films (36, 38) collimate the optical light photons generated in the body (31) toward the photo detector array (40) to form X-ray images.

Abstract: A method for collecting computed tomography (CT) image data includes determining a number of intervals N into which a respiratory cycle is to be divided, determining a number of respiratory cycles M to be covered in one gantry rotation, and rotating a gantry to collect at least M×N sets of CT image data of at least a portion of a patient, wherein each set of the CT image data corresponds to a phase of a respiratory cycle.

Abstract: A scanning unit for identifying contraband within objects, such as cargo containers and luggage, moving through the unit along a first path comprises at least one source of a beam of radiation movable across a second path that is transverse to the first path and extends partially around the first path. A stationary detector transverse to the first path also extends partially around the first path, positioned to detect radiation transmitted through the object during scanning. In one example, a plurality of movable X-ray sources are supported by a semi-circular rail perpendicular to the first path and the detector, which may be a detector array is also semi-circular and perpendicular to the path. A fan beam may also be used. Radiographic images may be obtained and/or computed tomography (“CT”) images may be reconstructed. The images may be analyzed for contraband. Methods of scanning objects are also disclosed.

Abstract: An imaging apparatus (10) includes a photon detector (20) and an accessing circuit (44) coupled thereto. The photon detector (20) detects photons and generates signals in response thereto. The accessing circuit (44) reads out the signals from the photon detector (20) at a sufficiently high rate so that it operates in an event sensitive mode. The apparatus (10) also includes a signal processing module (15) for processing the signals and generating data regarding the images of the object. In accordance with various embodiments of the present invention, the signal processing module (15) may include a spatial resolution circuit (56), a photon energy resolution circuit (57), a temporal resolution circuit (58), or any combination thereof.

Abstract: A multi-mode cone beam computed tomography radiotherapy simulator and treatment machine is disclosed. The radiotherapy simulator and treatment machine both include a rotatable gantry on which is positioned a cone-beam radiation source and a flat panel imager. The flat panel imager captures x-ray image data to generate cone-beam CT volumetric images used to generate a therapy patient position setup and a treatment plan.

Abstract: A scanning unit for inspecting objects comprises in one embodiment a radiation source to emit a beam of radiation, a rotatable platform to support an object for inspection by the beam of radiation and a detector positioned to receive radiation after interaction of the beam with the object. At least one of the platform, the source and the detector may be moved in a first direction, such as vertically. The object may be scanned while being rotated and moved to generate volumetric computed tomographic images. The rotational and movement of the platform and the object may also be indexed. The beam of radiation may be a horizontally extending cone beam or a fan beam. The detector may extend horizontally, as well. The rotational and/or vertical position of the platform may be used to direct the object along one of multiple exit paths. The scanning unit may provide a vertically extending radiation beam and a vertically extending detector to conduct line scanning.

Abstract: A multiple mode digital X-ray imaging system providing for preprocessing “binning” of analog pixel signals from a detector array by selectively summing, within the detector array, adjacent pixel charges on a row-by-row basis and selectively summing, within detector array readout circuits, the previously summed pixel charges (by rows) on a column-by-column basis. An array, or mapping, of “defective pixel” flags is used to identify defective pixels within the detector array, with such flags being added to, or inserted into, the incoming data stream for dynamic processing along with the incoming pixel data. A buffer and filter is used to perform still image capture during the radiographic mode of operation and to recursively filter incoming data frames during the fluoroscopic mode of operation by summing a scaled amount of pixel data from prior data frames with a scaled amount of incoming pixel data from the present data frame.

Abstract: A radiation apparatus (10) includes a beam source (12) generating radiation beam toward a target (11). A projection detector (17) detects the images of the target (11) formed by the radiation beam. In a radiation treatment session using the apparatus (10), the beam source (12) first generates a low intensity beam. The projection detector (17) generates image signals of a patient under the treatment. A control module (18) in the apparatus (10) develops a treatment plan in accordance with a treatment prescription and the image signals. Subsequently, the beam source (12) generates a treatment beam according to the treatment plan. The projection detector (17) can generate further image signals formed by the treatment beam to verify the treatment process.

Abstract: An imaging apparatus (10) includes a photon detector (20) and an accessing circuit (44) coupled thereto. The photon detector (20) detects photons and generates signals in response thereto. The accessing circuit (44) reads out the signals from the photon detector (20) at a sufficiently high rate so that it operates in an event sensitive mode. The apparatus (10) also includes a signal processing module (15) for process the signals and generating data regarding the images of the object. In accordance with various embodiments of the present invention, the signal processing module (15) may includes a spatial resolution circuit (56), a photon energy resolution circuit (57), a temporal resolution circuit (58), or any combination thereof.

Abstract: A scanning unit for identifying contraband, such as guns, explosives and illegal drugs, within objects, such as cargo containers and luggage, moving through the unit along a first path comprises at least one source of a beam of radiation movable across a second path that is transverse to the first path and extends partially around the first path. A stationary detector transverse to the first path also extends partially around the first path, positioned to detect radiation transmitted through the object during scanning. In one example, a plurality of movable X-ray sources, each transmitting a cone beam of radiation, are supported by a semi-circular rail perpendicular to the first path. In this example, the detector, which may be a detector array comprising a plurality of two-dimensional detectors, is also semi-circular and perpendicular to the path. A fan beam may also be used. Radiographic images may be obtained and/or computed tomography (“CT”) images may be reconstructed.