Classifications

• • H—ELECTRICITY
  • H01—ELECTRIC ELEMENTS
  • H01J—ELECTRIC DISCHARGE TUBES OR DISCHARGE LAMPS
  • H01J35/00—X-ray tubes
  • H01J35/02—Details
  • H01J35/14—Arrangements for concentrating, focusing, or directing the cathode ray
  • H01J35/153—Spot position control
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
  • A61B6/48—Diagnostic techniques
  • A61B6/482—Diagnostic techniques involving multiple energy imaging
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
  • A61B6/06—Diaphragms
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
  • A61B6/12—Arrangements for detecting or locating foreign bodies
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
  • A61B6/40—Arrangements for generating radiation specially adapted for radiation diagnosis
  • A61B6/4021—Arrangements for generating radiation specially adapted for radiation diagnosis involving movement of the focal spot
  • A61B6/4028—Arrangements for generating radiation specially adapted for radiation diagnosis involving movement of the focal spot resulting in acquisition of views from substantially different positions, e.g. EBCT
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
  • A61B6/42—Arrangements for detecting radiation specially adapted for radiation diagnosis
  • A61B6/4208—Arrangements for detecting radiation specially adapted for radiation diagnosis characterised by using a particular type of detector
  • A61B6/4241—Arrangements for detecting radiation specially adapted for radiation diagnosis characterised by using a particular type of detector using energy resolving detectors, e.g. photon counting
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01T—MEASUREMENT OF NUCLEAR OR X-RADIATION
  • G01T1/00—Measuring X-radiation, gamma radiation, corpuscular radiation, or cosmic radiation
  • G01T1/16—Measuring radiation intensity
  • G01T1/20—Measuring radiation intensity with scintillation detectors
  • G01T1/202—Measuring radiation intensity with scintillation detectors the detector being a crystal
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01T—MEASUREMENT OF NUCLEAR OR X-RADIATION
  • G01T1/00—Measuring X-radiation, gamma radiation, corpuscular radiation, or cosmic radiation
  • G01T1/29—Measurement performed on radiation beams, e.g. position or section of the beam; Measurement of spatial distribution of radiation
  • G01T1/2914—Measurement of spatial distribution of radiation
  • G01T1/2964—Scanners
  • G01T1/2971—Scanners using solid state detectors
• • H—ELECTRICITY
  • H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
  • H05G—X-RAY TECHNIQUE
  • H05G1/00—X-ray apparatus involving X-ray tubes; Circuits therefor
  • H05G1/08—Electrical details
  • H05G1/10—Power supply arrangements for feeding the X-ray tube
• • H—ELECTRICITY
  • H05—ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
  • H05G—X-RAY TECHNIQUE
  • H05G1/00—X-ray apparatus involving X-ray tubes; Circuits therefor
  • H05G1/08—Electrical details
  • H05G1/64—Circuit arrangements for X-ray apparatus incorporating image intensifiers
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
  • A61B6/02—Arrangements for diagnosis sequentially in different planes; Stereoscopic radiation diagnosis
  • A61B6/027—Arrangements for diagnosis sequentially in different planes; Stereoscopic radiation diagnosis characterised by the use of a particular data acquisition trajectory, e.g. helical or spiral
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
  • A61B6/40—Arrangements for generating radiation specially adapted for radiation diagnosis
  • A61B6/4035—Arrangements for generating radiation specially adapted for radiation diagnosis the source being combined with a filter or grating
  • A61B6/4042—K-edge filters
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B6/00—Apparatus or devices for radiation diagnosis; Apparatus or devices for radiation diagnosis combined with radiation therapy equipment
  • A61B6/44—Constructional features of apparatus for radiation diagnosis
  • A61B6/4488—Means for cooling

Definitions

• the present invention relates to diagnostic x-ray imaging equipment. More particularly, the present invention relates to a real time scanning beam digital x-ray imaging system having improved resolution and reduced x-ray emissions provided by inco ⁇ oration of a multi-apertured collimation grid and a segmented x-ray detector array.
• Real time x-ray imaging is increasingly being required by medical procedures as therapeutic technologies advance. For example, many electro-physiologic procedures in cardiology, peripheral vascular procedures, urological procedures, and orthopedic procedures rely on real time x-ray imaging.
• a number of real time x-ray imaging systems are known in the prior art. These include fluoroscope-based systems where x-rays are projected into an object to be x- rayed and shadows caused by relatively x-ray opaque matter within the object are displayed on the fluoroscope located on the opposite side of the object from the x-ray source. Scanning x-ray tubes have been known in conjunction with the fluoroscopy art since at least the early 1950s. Moon, Amplifying and Intensifying the Fluoroscopic Image bv Means of a Scanning X-rav Tube. Science, October 6, 1950, pp. 389-395. Scanning beam digital x-ray imaging systems are also well known in the art.
• an x-ray tube is employed to generate X-ray radiation.
• an electron beam is generated and focussed upon a small spot on the relatively large anode (transmission target) of the tube, inducing x-ray radiation emission from that spot.
• the electron beam is deflected (electromagnetically or electrostatically) in a raster scan pattern over the entire anode.
• a small x-ray detector is placed at a distance from the anode of the x-ray tube. The detector converts x-rays which strike it into an electrical signal in proportion to the detected x-ray flux.
• x-rays are attenuated and scattered by the object in proportion to the x-ray density of the object.
• the signal from the detector is modulated in proportion to the x-ray density of the object.
• Examples of prior art scanning beam digital x-ray systems include those described in United States Patent No. 3,949,229 to Albert; United States Patent No. 4,032,787 to Albert; United States Patent No. 4,057,745 to Albert; United States
• Patent No. 4,144,457 to Albert United States Patent No. 4,149,076 to Albert; United States Patent No. 4,196,351 to Albert; United States Patent No. 4,259,582 to Albert; United States Patent No. 4,259,583 to Albert; United States Patent No. 4,288,697 to Albert; United States Patent No. 4,321,473 to Albert; United States Patent No. 4,323,779 to Albert; United States Patent No. 4,465,540 to Albert; United States Patent No. 4,519,092 to Albert; and United States Patent No. 4,730,350 to Albert.
• an output signal from the detector is applied to the z-axis (luminance) input of a video monitor.
• This signal modulates the brightness of the viewing screen.
• the x and y inputs to the video monitor are derived from the same signal that effects deflection of the x-ray signal of the x-ray tube. Therefore, the luminance of a point on the viewing screen is inversely proportional to the absorption of x-rays passing from the source, through the object, to the detector.
• Medical x-ray systems are operated at the lowest possible x-ray dosage level that is consistent with the resolution requirements for the procedure. Accordingly, both dose and resolution are limited by the signal to noise ratio.
• low dosage refers to an x-ray exposure level during operation of less than or equal to about 2.0 R/min (Roentgens/min) at the entrance to the patient.
• the randomness is expressed as the standard deviation of the mean flux, and equals its square root.
• the signal to noise ratio of an x-ray image under these conditions is therefore equal to the mean flux divided by the square root of the mean flux. I.e., for a mean flux of 100 photons, the noise is +/- 10 photons, and the signal to noise ratio is 10.
• the spatial resolution and the signal to noise ratio of x-ray images formed by scanning x-ray imaging systems are dependent, to a large extent, upon the size of the sensitive area of the detector.
• the detector aperture is increased in area, more of the diverging rays are detected, effective sensitivity increases and the signal to noise ratio is improved.
• the larger detector aperture reduces attainable spatial resolution as the "pixel" size (measured at the plane of the object to be imaged) becomes larger. This is necessarily so because most objects to be imaged in medical applications (e.g., structures internal to the human body) are some distance from the x-ray source.
• the detector aperture size must be selected so as to effect a compromise between resolution and sensitivity, it not being possible to maximize both resolution and sensitivity simultaneously.
• patient dosage, frame rate (the number of times per second that the object is scanned and the image refreshed), and resolution of the image of the object are key parameters.
• a high x-ray flux may easily yield high resolution and a high frame rate, yet result in an unacceptabiy high x-ray dosage to the patient and attending staff.
• low dosage may be achieved at the cost of an invisible image or an inadequate refresh rate.
• a successful medical imaging system must provide low dosage, high resolution and an adequate refresh rate of up to at least about 15 images per second - all at the same time. Therefore, systems such as the prior art scanning beam digital x-ray imaging system described above will not work with diagnostic medical procedures where exposure times are relatively long and where, as is always the case with real patients, the x-ray dose received by the patient must be kept to a minimum.
• a scanning beam digital x-ray imaging system (“SBDX”) according to the present invention includes an x-ray tube having an electron beam source and a target anode. Circuitry is provided for focussing the beam and directing or scanning the beam across the target anode in a predetermined pattern.
• the predetermined pattern may be a raster scan pattern, a serpentine or "S" shaped pattern, a spiral pattern, a random pattern, a gaussian distribution pattern centered on a predetermined point of the target anode, or such other pattern as may be useful to the task at hand.
• a collimating element preferably in the form of a grid, may be interposed between the x-ray source and an object to be x-rayed.
• the collimating element may, for example, comprise a round metal plate having a diameter of about 25.4 cm (10 in) and including an array of apertures numbering 500 by 500 at the center row and column of the collimating element.
• the collimating element is preferably placed immediately in front of the emitting face of the x-ray tube. Other configurations of collimating element could also be used.
• each of the apertures in the collimating element is constructed so that it is directed toward (or points at) a detection point on a plane located a selected distance from the collimating element.
• That distance is selected to allow placing the object to be x-rayed between the collimating element and the detection point.
• the function of the collimating element is to form thin beams of x-rays, arrayed like pixels, and all directed from a point on the anode of the x-ray tube toward the detector.
• a segmented detector array containing an array of detector elements (preferably an area array such as a DET X by DET Y rectangle or square, or, more preferably, a relatively round array) is centered at the detection point.
• the detector array preferably comprises a plurality of densely packed x-ray detectors.
• Such an array can be designed, positioned and applied according to the present invention in a manner that yields high sensitivity without loss of resolution, resulting in an x-ray system having a resolution comparable to or better than that of prior art x-ray units at a dosage at least an order of magnitude less than that of prior art x-ray systems.
• This feature of the present invention has important implications in medical and other fields. Exposure to patients and attending medical staff involved in current procedures will be reduced. Procedures now impossible due to the radiation exposure risk will become possible.
• the output of the detector array is an intensity value for each element of the detector array at each point in time that the x-ray beam is emitted through an aperture in the grid. Because each aperture is located at a different point in space relative to the object under investigation and the detector array, a different output will be available from the detector array for each aperture that the x-ray beam travels through.
• the detector array outputs may be converted into an image in a number of ways. One method is to perform a simple convolution upon the array output, i.e., summing the intensity values of the array elements corresponding to each aperture scanned, and then normalizing. The output array could then be used to drive a video or other display.
• the SBDX imaging system is also capable of stereo imaging where a collimation grid having two groups of apertures is used. In this case, one group of apertures is constructed to point to a first detection point where a first segmented detector is located and a second group of apertures is constructed to point to a second detection point where a second segmented detector is located. By constructing two images from the two segmented detectors and using conventional stereoscopic display methods, a stereo image may be produced.
• the SBDX imaging system is also capable of highlighted imaging of materials which exhibit different x-ray transmissivities at different x-ray photon energies. Accordingly, for example, microcalcification, a precursor of breast cancer, may be imaged.
• the grid and/or anode By constructing the grid and/or anode to emit two or more groups of beams of x-rays each having different x-ray energy spectra, and directing each group to the detector array (plural detector arrays could also be used), the difference of transmissivities of the object under investigation at the various x-ray photon energies can be turned into an image, thus highlighting only those materials within the object under investigation which exhibit differential x-ray transmissivity.
• Optimized for the detection of calcium for example, such an imaging system is a powerful tool for the early detection of breast cancer and other anomalies.
• Utilizing a segmented array which intercepts the entire collimated x-ray beam and image processing the array output provides maximum sensitivity without sacrificing the resolution provided by using small surface area detectors.
• a non- segmented detector of the same size as the segmented array would provide the same sensitivity at lower resolution.
• sub-sampling techniques may be used for processing the data from the array detector which reduce the complexity of the system and the required processing speed and energy consumption while providing virtually the same image quality.
• the system described herein is capable of being used in conjunction with the
• Fig. 1 is a diagram showing the basic components of a low dosage scanning beam digital x-ray imaging system.
• Fig. 2 is a diagram showing the distribution of x-rays from an SBDX system in the absence of a collimation grid.
• Fig. 3 is a magnified view of the grid and anode of an x-ray tube for a low dosage scanning beam digital x-ray imaging system.
• Figs. 3A, 3B and 3C are partial cross-sections of collimation grids useful in the inventive device.
• Fig. 4 is a diagram of an x-ray tube for a low dosage scanning beam digital x- ray imaging system.
• Fig. 5 is a cross sectional diagram showing the fabrication of an x-ray tube for a low dosage scanning beam digital x-ray imaging system.
• Fig. 6 is a diagram of a stereoscopic scanning beam digital x-ray imaging system.
• Fig. 7A is a diagram of an apertured x-ray source interacting with a simple non- segmented detector.
• Fig. 7B is a diagram of x-rays from a single aperture of an apertured x-ray source interacting with a segmented detector array.
• Fig. 7C is a diagram of x-rays from a number of apertures of an apertured x-ray source interacting with a segmented detector array.
• Fig. 7D is a diagram of x-rays from two apertures of an x-ray collimation grid interacting with an object under investigation and then a segmented detector array.
• Fig. 8 is a diagram of the exposed surface of a 5 x 5 detector array for a low dosage scanning beam digital x-ray imaging system.
• Fig. 9 is a diagram of a 5 x 5 detector array for a low dosage scanning beam digital x-ray imaging system.
• Fig. 9A is a diagram depicting a scintillator element according to one preferred embodiment of the present invention.
• Fig. 10 is a diagram of a detector element for a low dosage scanning beam digital x-ray imaging system.
• Fig. 11 is a diagram showing an array of pencil-type detector elements for a non-planar detector array.
• Fig. 12 is a diagram of a 3 x 3 detector array for a low dosage scanning beam digital x-ray imaging system.
• Fig. 13 is a diagram showing the basic components of a low dosage scanning beam digital x-ray imaging system utilizing negative feedback to control x-ray flux.
• Fig. 14 is a perspective diagram showing the grid seal assembly.
• Fig. 15 is a diagram of the layout of a 96 element detector array according to a presently preferred embodiment of the invention.
• Fig. 16 is a diagram showing the interaction of the collimation grid and the detector array.
• Fig. 17 is a diagram showing a presently preferred embodiment of the detector assembly.
• a scanning beam digital x-ray imaging system according to a preferred embodiment of the present invention is diagrammed.
• a scanning x-ray tube 10 is used as the x-ray source.
• An approximately -100kV to -120kV power supply is used to power x-ray tube 10 as is well known in the art.
• a 100 kV power supply will provide a spectrum of x-rays ranging to 100keV. As used herein, 100kV x-rays refers to this spectrum.
• X-ray tube 10 includes a deflection coil 20 under the control of scan generator 30 as is well known in the art.
• An electron beam 40 generated within x-ray tube 10 is scanned across a grounded anode 50 within x-ray tube 10 in a predetermined pattern.
• the predetermined pattern may be a raster scan pattern, a se ⁇ entine or "S" shaped pattern, a spiral pattern, a random pattern, a gaussian distribution pattern centered on a predetermined point of the target anode, or such other pattern as may be useful to the task at hand.
• the se ⁇ entine or "S" shaped pattern which eliminates the need in a raster scan pattern for "fly back."
• a cascade of x-rays 70 is emitted and travels outside of x-ray tube 10 toward the object 80 to be investigated with the x-ray.
• a cone of x-ray photons must be generated that will diverge in a manner that will just cover the detector array 110. This is preferably accomplished by placing a collimation grid between the anode of the scanning x-ray tube and the detector. Collimation grid 90 is therefore disposed between object 80 and x-ray tube 10. Collimation grid 90 is designed to permit only those x-rays 100 which are directed toward detector 110 to pass through it. Collimation grid 90 does not move with respect to detector array 110 while the system is in operation. Thus, as electron beam 40 is scanned across anode 50, at any given moment, there can only be a single x-ray beam 100 passing from anode 50 to detector array 110.
• Fig. 2 depicts the distribution of x-rays in the absence of a collimation grid.
• the output of detector array 110 is then processed and may be displayed on monitor 120 as a luminance value at an x,y location on monitor 120 corresponding to the x,y location on anode 50. This may be accomplished by using the same scan generator to drive the x,y position of electron beam 40 and the position of the electron beam within the video monitor 120. Alternatively, image processing techniques can be used to produce a computer driven image on an appropriate display or photographic medium.
• the inventive system disclosed herein is a low dosage system in that it typically doses the patient at a rate of about 0.15 R/min with a 15 frame/sec refresh rate to about 0.33 R/min with a 30 frame/sec refresh rate - again - measured at the entrance to the patient.
• Whole body exposure with a 30 frame/sec refresh rate with this system will be about 0.50 R/min.
• the practical range of dosage at the entrance to the patient for operation of the invention disclosed herein is within the range of 0.15 R/min to 2.00 R/min.
• the X-Rav Tube Fig. 3 depicts a magnified view of the grid and anode structure.
• Anode 50 is preferably fabricated of a target layer of a material having good vacuum characteristics and the ability to withstand high heat and electron bombardment formed upon a beryllium anode support 130. Aluminum or other relatively x-ray transparent materials could be used for the anode support 130 as well.
• the presently preferred construction of the target layer is, in order of preference: (1) a first layer of niobium approximately 1 micron thick sputter-deposited upon the anode support to which is then sputter- deposited a second layer of tantalum approximately 5 microns thick (this structure is preferred because the niobium has a thermal coefficient of expansion intermediate to the coefficients of thermal expansion of beryllium (the anode support 130) and tantalum, thus reducing or preventing microcracking due to thermal cycling of the target anode between the ON and OFF conditions of the tube; (2) a sputter-deposited layer of tantalum approximately 5 microns thick; (3) a sputter-deposited layer of tungsten-rhenium approximately 5 microns thick; and (4) a sputter-deposited layer of tungsten approximately 5 to 7 microns thick.
• Tantalum, tungsten and tungsten- rhenium are preferred for anode 50 because, having relatively high atomic numbers and densities, they readily emit x-rays when irradiated by an electron beam. Tungsten's high melting point of 3370°C and good vacuum characteristics make it suitable for the high temperature and hard vacuum conditions within the tube. Tantalum and tungsten-rhenium have similar characteristics as known to those of skill in the art.
• the thicknesses of the anode layers are selected so that they are approximately equivalent to the distance necessary to efficiently convert 100 kV electrons to x-rays. Beryllium is preferred for anode support 130 because it is strong and does not significantly attenuate or scatter the x-rays emitted from anode 50.
• collimation grid 90 preferably consists of an array of apertures 140, each of which according to one preferred embodiment of the present invention is oriented or pointed toward detector array 110. That is to say that the apertures within the collimation grid 90 are not parallel to each other and for use with, for example, a chest x-ray application, may have an angle with the frontal plane 260 of the collimation grid 90 of between 0° at the center of the collimation grid 90 to as much as 20° at the edge of the grid 90.
• the grid 90 may be fabricated so that the apertures form an angle with the frontal plane ranging to 45° at the edge of the grid.
• the number of apertures 140 in collimation grid 90 may correspond to the number of pixels, e.g., 500 by 500 to 1024 by 1024 at the center of preferably round collimation grid 90 and, in part, determines the system resolution.
• fewer apertures than pixels may be used in conjunction with the technique of sub-sampling discussed below.
• the thickness of grid 90 and size of apertures 140 are determined by the distance of the detector array 110 from x-ray tube 10 (here, preferably 91.4 cm (36 in)), the need to attenuate all x-rays not heading to the detector, and the size of detector elements 160 of detector array 110 (not shown in this figure).
• apertures 140 as viewed from frontal plane 260, are preferably laid out in a rectangular row and column pattern having a circular boundary 25.4 cm (10 in) in diameter.
• the aperture array may be of any convenient layout which may be correlated using the detection and convolution techniques outlined below to resolve the image of object 80. This aperture array is called the "circular active area".
• the aperture count is preferably, according to one preferred embodiment of the present invention, 500 by 500.
• the non-aperture portion 150 of collimation grid 90 is designed to absorb errant x-rays so that they do not illuminate object 80. This is accomplished by fabricating the grid so that x-rays striking the non-aperture portion 150 will see at least ten times the "1/2 value" (the amount of material necessary to attenuate 1/2 the x-rays striking it at the system energy, here, 100 keV). Errant x-rays would provide the object and attending staff with x-ray dosage but contribute no meaningful information to the image.
• Collimation grid 90 as shown in FIGS.
• the collimation grid 90 is preferably fabricated of 50 thin sheets of 0.0254 cm (0.010 in) thick molybdenum which are stacked and held together. Molybdenum is preferred because it readily absorbs x-rays so that x-rays generated by x-ray tube 10 which are not directed to detector 110 will be stopped before they impinge, uselessly and potentially harmfully, upon object 80, which, of course, may be a human patient. Lead or similar x-ray dense materials could also be used.
• the apertures 140 of collimation grid 90 are preferably square in cross section in order to obtain the maximum packing density and be compatible with the preferred square shape of the detector array elements 160. Other shapes could also be used, particularly hexagons.
• the square apertures 140 are preferably 0.0381 cm (0.015 in) by 0.0381 cm in dimension which yields a cross sectional area that is about 1/100 the cross sectional area of conventional collimators used with fluoroscopes. Because of this tighter collimation, a smaller beam width for x-ray beam 100 is achieved. This means that the cross sectional area of the face of the detector may be correspondingly much smaller than in conventional systems. As a result, x-rays scattered at the object miss the detector and do not fog the image as they do in conventional systems which utilize relatively large surface area detectors.
• a preferred method for fabricating the collimation grid 90 is by photo-chemical milling or etching.
• Photo-chemical milling is presently preferred because it is cost effective and accurate.
• a set of 50 photo masks is created to etch holes or interstices into 50 thin sheets of 0.0254 cm (0.010 in) thick material.
• the etched sheets are then stacked and aligned and held together to form a grid assembly having a plurality of stepped apertures, each of a predetermined angular relationship with respect to the sheets.
• FIG. 3A shows a variation of the inventive collimation grid 90. This variation includes a number of x-ray absorbing sheets 143 having individual apertures with a constant cross-section (however, the cross-section need not be constant).
• the resulting aperture 14 is stepped, as shown, but allows the x-ray beam 100 to pass through to the detector array 110.
• the variation shown in FIG. 3B is quite similar to that shown in FIG. 3A except that the individual apertures formed in x-ray absorbing sheets 144 are themselves stepped. These stepped apertures may be made by milling or chemical etching from each side of sheet 144 with a slight offset so as to result in the configuration shown as would be obvious to one of ordinary skill in the art.
• the FIG. 3B configuration is highly desirable because less x-ray energy need be absorbed within the stepped apertures 140 of collimation grid 90 and consequently, the x-ray flux at the edge of the x-ray beam 100 is not attenuated as much as in the variation shown in FIG. 3A.
• Etched sheets 91 are each provided with alignment holes or alignment apertures 94. Alignment pegs 95 are placed in each alignment aperture 94 to align the etched sheets 91. The assembly of sheets 91 and pegs 95 is then placed in aluminum ring 359.
• Aluminum ring 359 is provided with a vacuum port 370 which may be sealed with pinch off 375.
• Aluminum sheet 365 which is 0.1 cm in thickness is then bonded and sealed with a vacuum adhesive to upper surface 380 of ring 359.
• Aluminum sheet 360 is similarly bonded to a lower surface 385 of ring 359.
• a partial vacuum is then pulled through port 370 and the port 370 is then sealed at pinch off 375 as is well known in the art.
• relatively x-ray transparent aluminum sheets 360, 365 provide a clamping action tending to hold etched sheets 91 together and in alignment as grid assembly 90.
• the apertures 140 furthest from the center of grid 90 have a stepped surface and are preferably square in cross section. X-rays are generally unaffected by the roughness of the channels due to the stepped surface, and even if they are scattered, they will not measurably affect the resultant beam.
• the material used for the collimation grid 90 as discussed above can be molybdenum, brass, lead, or copper with molybdenum presently preferred. Presently preferred tolerances for the positions of the holes are +/- 0.00127 cm (0.0005 in) center to center without cumulative error and for the hole sizes are +/- 0.00254 cm (0.001 in).
• Alternative methods for fabricating collimation grid 90 which could be used include electron beam machining, drilling or mini-machining, and laser drilling. Drilling and laser drilling have the drawback that they generate round rather than square holes. Circular apertures are not presently preferred although they should work as well.
• Electron gun 161 is located opposite the face of x-ray tube 10 and is operated at a potential of up to about -100kV to -120kV Grounded anode 50 is located at the face of the tube and an electron beam 40 travels between electron gun 161 and anode 50.
• a grounded electron aperture plate 162 is located near electron gun 161 and includes an aperture 163 at its center for electron beam 40 to pass through.
• a magnetic focus lens 164 and deflection coil 20 position the beam spot on anode 50 utilizing dynamic focussing as is well known in the art.
• the tube is fabricated to have a 25.4 cm (10 in) diameter circular active area in which electron beam 40 may intersect anode 50 with the electron beam deflected up to about 30° at the extremities of the circular active area.
• the beam is not being "fired” through a particular aperture it is preferably left off, resulting in a power savings of up to about 25%.
• a cross sectional view of the front portion of a suitable x-ray tube 10 is depicted.
• the interior of the x-ray tube 340, maintained at a vacuum is rearward of anode 50.
• Anode 50 is a coating of anode material as discussed above.
• Forward of anode 50 is beryllium anode support 130 which is 0.5 cm thick.
• Forward of beryllium anode support 130 is cooling jacket 350 which is preferably 0.4 cm thick and may be adapted to carry water or forced air.
• Aluminum grid supports 360, 365 are each 0.1 cm thick and help support collimation grid 90 which is preferably 1.27 cm (0.5 in) thick.
• the electron beam 40 may be shut off when the electron beam 40 is not positioned directly in front of an aperture 140.
• the x- ray tube may be operated effectively in a scanned-pulsed mode to reduce power consumption and wear and tear on the target anode 50.
• a grid having more than one focal point may be provided so that stereoscopic x-ray images may be obtained. If, for example, every other row of apertures in grid 90 were pointed at focal point F1 (92) and the remaining apertures were pointed at focal point F2 (93), by placing a first sensor array at F1 (92) and a second sensor array at F2 (93) it is possible to scan the apertures in a raster or se ⁇ entine pattern and thereby create a "line" of data for the first sensor array, then a line of data for the second sensor array.
• Fig. 3C it is shown how one may construct such a stereoscopic collimation grid out of layers 144 of x-ray abso ⁇ tive material.
• the apertures 140A, 140B may in fact be shaped like a "V * as shown providing separate paths along the "legs" of the "V" for x-ray beams 100A, 100B.
• apertures 140A, 140B be joined as shown, but an advantage of the "V'-shaped aperture where the x-rays enter at the apex of the "V is that both detectors will be illuminated simultaneously, the "V' acting as a signal splitter with some of the x-rays going to F1 and some to F2. This halves the power required for the beam and deflection currents. The price is a small but acceptable increase in scattering and thus fogging of the image.
• the spatial resolution limit is in large part determined by the size of the detector. This is because, with today's x-ray tube technology, it is not feasible either to produce the very high power levels that would be required in order to obtain sufficiently intense highly directionalized x-ray emissions or to develop the associated x-ray directionalizing means.
• resolution improves with the use of smaller detectors, but x-ray dose is minimized when the area of the detector equals or exceeds the area defined by the cone of emitted x-rays intersecting detector plane 270.
• Resolution of a scanning x-ray imaging system is determined by the cross sectional area of a detector element projected onto the object plane 280 (the plane pe ⁇ endicuiar to a line between the center of anode 50 and the center of detector 110 in which object 80 is located).
• the large area detector is subdivided into smaller array elements, e.g., as shown by the front view of the detector array in Fig. 8, the large capture area of the aggregate detector is maintained, while simultaneously retaining an image resolution that is proportional to the size of an individual small detector element 160.
• the resolution defined by the individual detector elements 160 is maintained by distributing and summing the readings from the individual elements into a memory buffer in which each address, i.e., pixel, corresponds to a specific location in the object plane 280.
• each address i.e., pixel
• the address to which the output of a given detector element is added, changes.
• the imaging geometry is shown in Fig. 7B and 7C. In Fig. 7B a single beam position is shown along with how it is divided among 5 pixels. In Fig. 7C the sequential beam positions are shown along with how they are added together within a single pixel.
• the signal for each of the detector elements is stored in an image buffer, at a memory address that corresponds to a very small specific region in the object plane 280, i.e., a single pixel.
• the memory storage address for each detector element changes with the location of the scanning x-ray beam in an ordered fashion such that each pixel in memory contains the sum of the radiation passing through a specific spot in the object plane 280.
• the resolution of the system is determined by the size of a single detector element, while the sensitivity of the system is optimized, since virtually all of the x-rays reaching the detector plane 270 are recorded.
• the object plane 280 is narrowly defined. Structures lying in front of or behind it will be blurred (out of focus). X-rays from a first aperture 141 and a second aperture 142 are depicted in Fig. 7D passing through an object plane 280 a distance SO from apertures
• the resolution degrades to about 1/2 that available at SO at the distance twice SO. This feature provides for improved localization and visualization of detailed structures in the plane of interest 280, while providing an adequate depth of field that may be modified by the system geometry.
• the array of the presently preferred embodiment is a 96 element pseudo-round array of square detector elements 0.135 cm on a side disposed within a circle of diameter about 1.93 cm (0.72 in). It need not be so large and could be three or more detectors disposed so that not all are in a line within a circle of radius equal to the length of a side of one of the detectors, here 0.135 cm.
• One of the primary objects of the present invention is to provide an SBDX imaging system which will ensure that the subject under examination is exposed to the lowest possible level of x-rays commensurate with achieving image quality adequate to meet the requirements of the procedure being performed. This means that the system used to detect the x-ray photons emerging from the subject must have the highest possible photon to electrical signal conversion efficiency.
• the material used for the detector must have a length in the direction in which the photons travel that is sufficient to ensure that no photons emerge from the end farthest away from the incident x-rays, i.e., the photon energy must be adequately dissipated in the material in order to maximize the output of the detector.
• the scintillator in which x-ray photon energy is converted to visible light energy and the light intensity is then converted to an electrical signal by means of a photomultiplier, photo diode, CCD or similar device.
• the scintillator material must have a fast response and a minimum afterglow time. Afterglow is the phenomenon wherein the scintillator continues to emit light after the stimulating incident x-radiation has ceased.
• Plastic scintillators such as organic loaded polystyrene, are suitable in that they have the required fast response characteristics but they have a relatively small x-ray photon interaction cross section so that their linear x-ray abso ⁇ tion coefficients are also small in value. The consequence is that a considerable thickness is required to stop all the x-ray photons.
• a typical plastic scintillator must be about 28 cm (11 in) thick to capture 99% of the incident x-rays. More preferred at present (and in order of preference) are: (1) YSO cerium doped (yttrium oxy-orthosilicate, available from Airtron (Litton) of Charlotte, NC); (2) LSO cerium doped (lutetium oxy- orthosilicate, available from Schlumberger, Inc.); and (3) BGO (bismuth germanate, available from Rexon Components, Inc. of Beachwood, OH). YSO and LSO are advantageous in that they may be used at room temperature. BGO must be heated to about 100° C in order to achieve a suitable light output decay period of the order of 50 nanoseconds. These scintillator materials need not be as long as the plastic scintillator and are effective at a length of 0.10 cm.
• the SBDX array detector 110 comprises a 12 by 12 pseudo-round array of 96 densely packed discrete x-ray detectors 160 spaced at a distance of 91.4 cm (36 in) from the x-ray source 50.
• a 5 by 5 and a 3 by 3 array are also contemplated as is a non- square array having square detectors filling a circle about the x-ray target: see, e.g., TABLE I below).
• the geometry of the collimation grid aspect ratio, its spacing from x- ray source 50 and the size of x-ray source 50 gives a square section pyramid of x- rays with a 1.46° total included angle which is about 2.23 cm (0.9 in) across at the entrance to detector array 110.
• Each individual scintillator 170 must therefore be about 0.152 cm (0.06 in) center-to-center within the detector plane. If scintillator 170 has parallel sides, x-rays entering near to the edges will not be able to travel the requisite distance without striking the scintillator walls.
• the individual scintillators according to one preferred embodiment of the invention are preferably tapered so that their bounding faces 173 have an included angle ⁇ equal to that of the most peripheral of the incident x-rays 100'. This is particularly useful with long plastic scintillators.
• each scintillator 170 would thus preferably be a frustrum of a pyramid 28 cm long, with an entrance face (172) 0.285 cm across and a face at the photodetector end 174 which is 0.37 cm across.
• the whole bundle of 81 detectors therefore has multifaceted ends, each facet being tangential to the surface of a sphere centered at x-ray source 50.
• a further improvement in detection efficiency for scintillators may be achieved by tapering the scintillator at an angle that is greater than that of incident x-ray beam 100.
• Photoelectrons and scattered x-rays produced by interaction between the incident x-ray and scintillator atoms near to the edges of the scintillator may be lost to the shielding material which preferably separates adjacent scintillators. These lost photoelectrons will not produce any light so they will not contribute to the light output from the scintillator. Their loss therefore reduces the efficiency of the scintillator.
• the maximum distance travelled by a photoelectron depends upon its energy and on the material in which it is travelling.
• each scintillator element 170 in contact with each scintillator element 170 is a light pipe or fiber optic cable 180 which optically couples each scintillator element 170 with a corresponding photomultiplier tube 190 or solid state detector.
• scintillators 170 may be located in close physical proximity to appropriate photodetectors.
• Fig. 10 shows a preferred configuration of a detector element 160.
• An x-ray opaque sheet 200 with apertures 210 corresponding to each detector element 160 is disposed in front of detector array 110.
• Each detector element 160 is enclosed in a light tight enclosure 220 which may also be x-ray opaque.
• a light blocking window 230 preferably made of thin aluminum sheet is located at the front of light tight enclosure 220.
• Light blocking window 230 is x-ray transparent.
• a scintillator element 170 in close proximity to a photomultiplier tube 190 which is electrically connected to a pre-amplifier 240.
• the analog signal from the pre-amplifier 240 is converted to a digital signal in a conventional manner for further processing.
• scintillators could be placed in direct or close contact with an array of photo diodes, photo transistors or charge coupled devices (CCDs) to achieve a more rugged and compact detector.
• CCDs charge coupled devices
• solid state devices particularly CCDs
• cooling such as with a Peltier-type cooler, or the like, may be employed to increase the signal to noise ratio of the device.
• the scintillator array could be placed in direct or close contact with one or more position sensitive photomultiplier tubes which provide an output signal which identifies the position coordinates of the light source as well as its amplitude.
• the sensor array may comprise a collection of pencil-type detectors 285 arrayed as shown, for example, in Fig. 11.
• tapered scintillators 290 are arrayed in the path of x-ray beam 100 so that the scintillator corresponding to a particular cross-sectional area of beam 100 will fully absorb x-rays within that cross-sectional area.
• Photo multiplier tubes 300 are located in close physical proximity to scintillators 290 so that an electrical signal will be generated in response to the abso ⁇ tion of x-rays by scintillators 290. Solid state devices could also be used in place of photo multiplier tubes 300. According to a presently preferred embodiment of the present invention, the scintillators are coated along their lengths and the input face with a material which reflects light such as silicon dioxide to prevent light from escaping (or entering) and to aid in internal reflection within the scintillators.
• each scintillator element 179 is isolated from its adjacent scintillator elements 170 by a thin sheet 171 of a highly x-ray opaque material such as, for example, gold or lead.
• Sheets 171 may preferably be about 0.0102 cm (0.004 in) to 0.0127 cm (0.005 in) thick.
• the position of sheets 171 between the scintillators 170 is shown in Fig. 12.
• the area of the circular active area of collimation grid 90 is larger than the area of detector array 110.
• Image Processing An important refinement of the present invention concerns the application of an image processing system to further reduce the required dosage.
• the signal from the detector is not usually applied directly to the "z" or luminance input of a video monitor. Instead, digitized intensity data for each pixel are stored in a discrete address in a "frame store buffer". More than one such buffer may be used in certain applications. Pixel addresses within the buffer can be randomly accessed and the numeric intensity value can be manipulated mathematically. This function has application in applying various image enhancement algorithms and it allows for pixel assignment of the data from discrete segments of the detector array.
• an SBDX image would consist of up to about 250,000 pixels, arranged in 500 rows and 500 columns (corresponding to the 500 rows by 500 columns of apertures at the center of collimation grid 90).
• the scanning x-ray source is momentarily centered upon the pixel, P, located at row 100 and column 100 of collimation grid 90.
• the detector array 110 consists of a 3 by 3 array 110 containing 9 segments 179 (Fig. 12) and that each segment 179 is sized so as to intercept ail of the x-ray emissions associated with a single pixel.
• Other array configurations obviously may be used as are detailed herein.
• the numerical values, digitized from the individual segments of the detector array 110, are assigned to pixel addresses as follows:
• the detector array 110 has the effect of fixing the working distance at which optimum focus is obtained and providing a plane of optimum focus not available in prior art non-segmented detector array SBDX imaging systems.
• the total area of the array must be large enough to intercept all of the x-rays from the collimation grid 90.
• the distance between the x-ray source 50 and the exit side 260 of collimation grid 90 is about 2.271 cm (0.894 in) (see Figs. 3, 5).
• Apertures 140 are 0.0381 cm (0.015 in) by 0.0381 cm square.
• the spot size of electron beam 40 on anode 50 is about 0.0254 cm (0.010 in) in diameter.
• the detector array 110 is 91.4 cm (36 in) from anode 50.
• the beam width of x-ray beam 100 is
• the detector array 110 should be about 2.54 cm (1 in) on a side for this preferred embodiment.
• the object to be imaged is 22.86 cm (9 in) from anode 50 and the desired pixel size is 0.0508 cm (0.020 in) at the object, and the distance from source to detector, again, is 91.4 cm (36 in) with an optimal detector array size of 2.54 cm (1 in) square
• the projected size of pixels at the detector plane 270 is simply (SD/SO) * pixel size at object, or 0.2032 cm (0.080 in). Dividing 2.54 cm (1 in) by 0.2032 cm (0.080 in) we see that the desired resolution may be obtained with a square segmented detector having 12 to 13 segments on a side. Obviously, many other configurations could be used depending upon the circumstances in which the SBDX system is to be used.
• a number of methods can be used to obtain a useable image from the data obtained as described above. As described above, a simple convolution may be used, however, in this case, resolution will not be fully optimized. Two additional methods are presently preferred for obtaining maximal resolution and sensitivity from the captured data. These are called the multi-image convolution method and the multi- output convolution method. For both cases, the following is assumed:
• collimation grid 90 There are AP X rows of apertures and AP Y columns of apertures in collimation grid 90. Each intersection of a column and row is a "pixel.” Those pixels outside of the circular active area of collimation grid 90 are treated as if they contribute no measured intensity to the image, i.e., they are treated as if they are "dark”. Pixels not illuminated by x-ray beam 100 during a scan are similarly treated as if they contribute no measured intensity to the image, i.e., they are also treated as if they are "dark".
• FIG. 15 there are a maximum of DET X rows of sensor elements 160 in detector array 110 and a maximum of DET Y columns of sensor elements 160 in detector array 110 in a pseudo-round sensor array 110.
• IMAGE is a data array of dimension DET X x DET Y containing the intensity information for a particular scan and corresponding to a particular pixel.
• PIXEL is a 4 dimensional array of dimension AP X x AP Y x DET X x DET Y which contains the DET X x DET Y IMAGE data arrays obtained by scanning all (or part of) the apertures. PIXEL is refreshed after each scan according to one preferred embodiment of the present invention.
• an IMAGE array of data will be acquired. While these images could be constructed into a displayable image having some use directly, more resolution and sensitivity is obtained by combining them.
• the first preferred method for combining the images is called the multi-image convolution method.
• an OUTIMAGE array of intensities of dimensions AP X x AP Y which can be displayed on a CRT or like display means, is formed by assigning to OUTIMAGE(y.x) the value of:
• the second presently preferred method for combining the AP X x AP Y IMAGE data arrays into a useful picture is called the multi-output convolution method.
• a sensor array of DET X x DET Y sensors there will be DET X x DET Y digitizers (or their equivalents, multiplexed) and the same number of pixel summing circuits.
• the digitized values from each sensor are called SENSOR(j,i).
• a further improvement upon these techniques may be obtained by performing linear inte ⁇ olation based upon the fractional part of the FOCUS factor.
• An advantage of the multi-image convolution method over the multi-output convolution method is that the former allows the plane of optimum focus to be selected in software after the data is captured while the latter does not.
• the latter method may be performed quicker where timing is a limitation.
• the SBDX system described herein may be used to generate a set of sequential planar images which can then be used to form a tomograph or a three dimensional display of the object 80.
• An image set can be analyzed to produce a 3D image consisting of a series of images at various depths by re-analyzing the data set with various values of FOCUS.
• the natural FOCUS values to use are n/DET x or n/DET ⁇ where n is an integer from 0 to DET X or DET Y , respectively.
• F t (FOCUS) Distance from the anode to the particular focal plane of interest
• Fig. 13 an SBDX imaging system employing a negative feedback path 305 to control the x-ray flux of x-ray beam 100 is depicted.
• negative feedback from the sensor array is utilized to control x-ray flux so that the sensor array always sees approximately the same flux level.
• differential amplifier 310 has an adjustable reference level 320 which may be set by the user. Negative feedback loop 305 feeds back to x-ray tube 10 to control the x-ray flux.
• a time domain x-ray imaging system may also be implemented using the principles disclosed herein.
• the time to reach a predetermined measured x-ray flux from the various pixels could be computed and mapped.
• Negative feedback control could then be employed to turn off or reduce x-ray flux from apertures corresponding to pixels which had reached the predetermined flux level for the scan period in question.
• the information gathered would be time to flux level and the mapped or imaged information would correspond to time rather than intensity.
• Such a system has the potential to provide much higher signal to noise ratios, improved contrast, drastically reduced x-ray dosage to the object under investigation, and improved dynamic range.
• two or more groups of x-ray beams 100 are directed toward one or more detector arrays.
• a first group of x-ray beams has a first characteristic x-ray energy spectrum.
• a second group of x-ray beams has a different second characteristic x-ray energy spectrum.
• the two groups of x-rays may be generated in a number of ways.
• One such way is by fabrication of a special anode 50 having a first material or first thickness of a material adjacent to the apertures of the first group of apertures and a second material or second thickness of material adjacent to the apertures of the second group of apertures.
• the apertures associated with the first group will emit x-rays having a first characteristic energy spectrum and the apertures associated with the second group will emit x-rays having a second characteristic energy spectrum.
• K-filtering or K-edge filtering
• filter material such as, for example, molybdenum
• a first group of apertures would comprise a first filter inserted therein and a second group of apertures would comprise a second filter inserted therein.
• the second filter could be no filter at all.
• two groups of x-rays having different characteristic energy spectra would be associated with the two groups of apertures.
• micro-calcification a precursor of breast cancer
• other abnormalities not normally visible with broadband x-rays. For example, by performing a scan of the first group of apertures to form a first image, then performing a scan of the second group of apertures to form a second image, and dividing the images to highlight their ratios, it is possible to detect micro-calcification and other such abnormalities with a low dosage scanning beam x-ray imaging system - in real time.
• a multiple detector array arrangement could be used with group 1 apertures directed toward a first detector array and group 2 apertures directed toward a second detector array, etc.
• Aperture Pitch 0.0508 cm (0.020in)
• Aperture cross-sectional shape round Aperture width: 0.0381 cm (0.015 in) Space between apertures: 0.0127 cm (0.005 in) Dist. between anode surface and Collimation Grid Output Face: 2.5 cm (0.98 in)
• Shape of input face of detector elements square
• Pixel size at Detector Plane 0.152 cm center-to-center detector spacing
• an SBDX imaging system utilizing a segmented detector array has been shown and described which simultaneously provides high resolution, high sensitivity, and low x-ray dosage to the object under investigation.
• the system also permits the point of optimum focus to be set at any point between the source 50 and the detector array 110, and provides an effective working depth of field.
• Standard video quality images use 640 x 480 pixels and are updated at 30Hz.
• This mechanism is referred to as sub-sampling and is best implemented with the embodiment of the SBDX described in this section, although it could obviously be adapted to be used with other configurations of the SBDX.
• Advantages of this embodiment include reduced power consumption and simpler circuitry for electron beam deflection within the x-ray tube, reduced cost of fabrication of the collimation grid 90, reduced complexity of the calculations needed to resolve an image of the object 80 and other advantages as would be obvious to those of skill in the art.
• the advantage of this reduction from a computational point of view will become apparent below. From a manufacturing point of view, however, it is a much simpler structure with approximately one-ninth the number of apertures which need to be fabricated. Because of the reduction in the number of apertures, it is easier to fabricate grids with higher deflection angles (i.e., the angle that the aperture makes with respect to the front face 260 of the collimation grid) without running into problems of having apertures intersect with adjacent apertures. This is particularly useful when stereo grids are to be manufactured as adjacent apertures in a stereo grid are directed to different detector arrays and hence require more physical separation than non-stereo grids to avoid aperture intersection.
• the apertures of the collimator grid are arranged in a circle of maximum dimension AP X rows by AP Y columns. For computational pu ⁇ oses this may be treated as a rectangle of dimension AP X rows by AP Y columns with the elements outside of the circle contributing no information, i.e., always being "dark" or non- illuminated by x-rays.
• the sensors 160 of the x-ray detector array 110 are arranged in a circular array of maximum dimension DET X rows by DET Y columns as shown in FIG. 15.
• the pixel sample rate may be reduced by illuminating less than all of the apertures of the collimation grid, i.e., by sub-sampling.
• Preferably a collimation grid without the not-to- be-illuminated apertures is used.
• only every DET x -th collimator hole in each row and every DET ⁇ -th collimator hole in each column needs to be illuminated and thus the image may be built up out of image tiles of pixels, each DET X pixels by DET Y pixels in size.
• the image is fabricated from a plurality of non-overlapping images which are in effect "pasted" together - much like a David Hockney photomosaic. Because real world scintillators and detectors are not all perfectly and identically responsive, the x-ray pencil beam is not perfectly uniform, the collimation grid apertures are not all exactly identical with identical areas, and because a circular, rather than a square detector is used, some degree of overlap is highly desirable in order to permit averaging out detector non- linearities and noise.
• the image will be built up from overlapping "tiles", which must be summed or averaged. If the sub-sampling ratios are not even multiples of the detector size (in pixels) or if the detector array is not rectangular, there will be different numbers of samples added to each pixel, and different divisors needed to average each pixel. The techniques for handling these less than ideal circumstances are well known to those of skill in the art and need not be disclosed here to avoid over-complicating the disclosure.
• SSX represents the sub-sampling dimension in the X direction (rows)
• 1/(SSX * SSY) apertures in the original collimation grid 500 x 500 apertures
• the frame rate is kept constant, e.g., 30Hz
• the number of electron beam motions is reduced by SSX * SSY, as is the frequency response of the circuit that drives the electron beam.
• the total distance travelled by the electron beam (and the number of scan lines) is reduced by 1/SSY, so that the average beam velocity across the target anode is reduced by 1/SSY.
• the image reconstruction pixel rate is the same as the collimation grid aperture rate (rate at which apertures are scanned or illuminated), and is also reduced by 1/(SSX*SSY).
• the number of samples averaged into each display pixel is (DET X /SSX) * (DET Y /SSY).
• the amount of sub-sampling (SSX and SSY) must be set to an appropriate level for the conditions presented in order to assure acceptable image quality. This may be adjusted by the user on the fly in accordance with the user's preference for image quality and the conditions presented by a particular set of circumstances.
• the detector array 110 shown in FIG. 15 is preferably an array of 96 individual detector elements 160 arranged roughly in a circular area having a diameter of about one inch. There are 12 detectors (DET X ) in the vertical column at the center of the array and 12 detectors (DET Y ) in the horizontal row at the center of the array.
• the scintillator crystals are preferably cut to a square horizontal cross-section and are supported by an "egg crate" structure made out of 0.005" thick stainless steel strips.
• the circle 400 of FIG. 15 within which all of the scintillator crystals (cross-hatched) are located, is preferably about 0.800" in diameter.
• the length of the scintillator crystals in detector array 110 is preferably about 0.10 cm and the front input faces are preferably 0.135 cm x 0.135 cm.
• the scintillator crystals are preferably YSO, LSO or BGO but other materials may also be used as discussed above.
• BGO needs to be heated to approximately 100°C. Accordingly a resistive heating element may be provided.
• FIG. 17 depicts the detector assembly 402 according to a presently preferred embodiment of the present invention.
• X-rays enter from the top through x-ray window 404 in lead shield 406.
• X-ray window 404 is preferably circular and about 1.91 cm (0.75 in) in diameter in order to permit x-rays coming from the apertures of the collimation grid 90 to strike the detector array 110 while attenuating scattered x-rays.
• a light shield 408 is provided to shield the detector from errant light. It may be made of a thin sheet of aluminum or beryllium chosen to attenuate light without substantially attenuating the x-rays. It is 0.0125 cm thick.
• Detector array 110 is located near optional heating element 410 for use with a BGO scintillator.
• Heating element 410 may be a resistive heating element designed to keep the detector array 110 at an operating temperature of about 100°C.
• a fibre optic imaging taper 412 directs photons emerging out of the bottom 414 of detector array 110 to a 96 channel photomultiplier tube (PMT) 416.
• the detector assembly 402 is enclosed in a light tight outer housing 418 in order to prevent stray light from generating noise.
• Three shoulder screws 420 and three centering screws 422 are provided for planar and linear alignment as is well known to those of ordinary skill in the art. Rotational alignment is achieved by rotating outer housing 418 with respect to PMT mount 426.
• the fibre optic imaging taper 412 is available from Collimated Holes of Campbell, CA and has a circular input aperture of diameter 2.03 cm (0.8 in) and a circular output aperture of diameter 3.38 cm (1.33 in). Taper 412 matches each scintillator crystal pitch dimension (0.06") to that of the PMT 416 (0.10"), i.e., it has a magnification of 1.667 times.
• High viscosity optical coupling fluid available from Dow Corning (Type 200) with a refractive index approximately matching that of the glass is used at the two faces of the taper as an optical coupling medium in order to maximize the light transfer efficiency from the scintillator crystals 160 to the taper 412 and from the taper 412 to the PMT input face 424.
• Photomultiplier tube 416 is a 96 channel tube (one channel corresponding to each scintillator crystal 160) available under model number XP1724A from the Philips Co ⁇ oration. It has a fibre optic face plate so that the spatial arrangement of the scintillator array is accurately carried through to the PMT photocathode located in the PMT on the other face of the faceplate. An x-ray photon striking one of the scintillators 160 produces a light pulse which is coupled to the PMT photocathode. This produces a corresponding electron pulse at the photocathode and the pulse is amplified in one channel of the PMT dynode structure up to 1,000,000 times.
• the PMT output pulse is connected to the input of a 30 MHz bandwidth amplifier, the output pulse of which is in the range of 0.5 to 5.0 volts and about 30 nsec in duration.
• the amplifier is AC coupled to eliminate offset drift problems.
• the AC coupling low frequency cut-off is high, e.g., 30 MHz, so that the pulse is differentiated. This eliminates the need for a DC restorer circuit to keep the baseline reference voltage constant as the pulse rate varies.
• the amplifier output feeds a comparator which gives a constant amplitude output pulse regardless of the amplitude of its input.
• the reference voltage for the comparator is set to a value which is slightly higher than the amplifier noise output level so that it will not trigger on the noise level.
• the amplifier chain is repeated 96 times, once for each scintillator crystal in the detector array.
• the comparator output pulses provide the raw data for the data acquisition and image re-construction system. Tests have shown that the prototype system is capable of counting randomly occurring x-ray photons up to about a 10 MHz rate.

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