Abstract:
A variable spot size x-ray tube comprises a cathode having an electron emitting surface providing an electron beam that travels essentially along the tube axis of symmetry to an anode. The anode, spaced from the cathode, includes a target, the front surface of which is disposed at an oblique angle with respect to the axis of symmetry. The potential of the anode is generally positive with respect to that of the cathode. The cathode is heated to a temperature at which electrons are emitted by the thermionic emission process. Current from the cathode can be controlled by varying the cathode temperature if the cathode is operated in the temperature limited region. The incident electron beam forms a spot on the target surface whereupon x-rays are produced in response to impingement of the electron beam on the target. The x-rays propagate outwardly from the target spot through a vacuum window to form a beam of x-radiation outside the x-ray tube. An aperture grid is disposed between the cathode and the anode, and has a central aperture permitting the electron beam to pass therethrough. The aperture grid further has a variable voltage applied to it which may be positive, negative, or equal to the potential of the cathode. The voltage on the control grid is used to control the diameter of the electron beam which impinges upon the target. Specifically, the electron beam diameter varies in correspondence with the variable aperture grid voltage, and selective variation of the electron beam diameter results in a corresponding variation in size of the x-ray imaging spot.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to x-ray tubes, and more particularly, to a high power x-ray tube that produces an imaging spot size that is continuously adjustable over a given range. 
     2. Description of Related Art 
     It is well known in the art to use a source of x-rays to produce planar images for medical and technical diagnostic applications. In the field of technical diagnostic imaging, x-rays are especially effective at penetrating internal structures of a solid imaging object, and the images formed by the x-rays that pass therethrough reveal internal flaws or structural defects of the object. Technical diagnostic x-ray imaging thus provides a valuable quality control inspection tool for evaluating structural aspects of a product during manufacture and over the useful life of the product. This form of diagnostic analysis is advantageous over other types of evaluation, since the imaging object need not be destroyed in the process of the evaluation. For this reason, technical diagnostic imaging is also known as non-destructive testing. 
     A x-ray tube for technical imaging applications typically comprises an electron gun having a cathode that is excited to emit a beam of electrons that are accelerated to an anode. The anode may be comprised of a metal target surface, such as tungsten, from which x-rays are generated due to the impact of the accelerated electrons. By disposing the anode surface at an angle to the axis of the electron beam, the x-rays may be transmitted in a direction generally perpendicular to the electron beam axis. The x-rays may then be passed through a beryllium window used to provide a vacuum seal within the x-ray tube. Thereafter, the x-rays exit the x-ray tube along a generally conical path where the apex of the cone is roughly coincident with the spot on target formed by the impinging electron beam. 
     The amount of magnification provided by an x-ray tube is dependent, in part, upon the spot size, which is sometimes referred to as the imaging spot size. A smaller spot size typically enables greater magnification while maintaining desirable image sharpness, but covers a smaller portion of the imaged object. This is accomplished, for example, by situating the imaged object closer to the x-ray source, that is the x-ray imaging spot, with respect to the position of the photographic film or other x-ray image recording means. Conversely, a larger spot size can image a greater portion of the imaged object, but typically at a lower magnification level. In this case, in contrast to the smaller spot size, the area of electron beam impingement is larger on target; hence, a higher voltage, higher current, or higher voltage and current electron beam can be utilized without thermally overstressing the target. Conventional x-ray tubes are typically limited to providing either a single spot size, or in some cases, two discrete spot sizes. To provide two different spot sizes, the x-ray tubes have two distinct cathode filaments that are alternatively energized to provide electron beams of different diameters. An operator of an x-ray tube will select one of the cathode filaments depending upon the desired magnification level and size of the imaging object. A drawback of such systems is that the spot size of the x-ray tube cannot be optimized for a particular imaging operation. 
     In conventional x-ray tubes, another approach to reducing the effective spot size is to position the anode surface at an angle flatter than 45° to the beam axis while maintaining the x-ray output cone oriented at 90° to the beam axis. An advantage of this approach is that the flat anode angle lowers the power density on the anode, which, if excessive, can cause undesirable melting and vaporization of the tungsten target material. Moreover, to geometrically compensate for the flat anode angle, the electron gun is configured to provide an elliptical electron beam so that the x-ray spot will have a circular cross-section. This lack of axial symmetry of the electron gun can add cost and complexity to the manufacture of the x-ray tube. Further, the electron beam spot is rarely elliptical, and the resultant x-ray imaging spot is usually distorted in shape, has intensity irregularities, and is non-circular leading to inferior quality x-ray images. 
     Thus, it would be desirable to provide an x-ray tube having a spot size that is continuously adjustable over a given range to allow greater flexibility in the imaging operations. It would also be desirable to provide an x-ray tube constructed with an axially symmetric geometry to simplify manufacture and improve the symmetry and intensity of the x-ray spot. A further desirable advantage is that the spot size and x-ray intensity can be varied without repositioning the object. Finally, it would be desirable to provide an x-ray tube having a more uniform intensity circular x-ray imaging spot for improved quality x-ray images. 
     SUMMARY OF THE INVENTION 
     In accordance with the teachings of the present invention, an x-ray tube produces a continuously adjustable spot size over a given range. The continuously adjustable spot size enables an operator to select an optimum spot size and intensity for imaging a particular imaging object. In addition, the x-ray tube has an axially symmetric geometry leading to simpler mechanical fabrication, and a substantially more uniform intensity circular x-ray imaging spot for improved quality x-ray images. 
     More particularly, the x-ray tube comprises a cathode having an electron emitting surface providing an electron beam that travels along an axis of symmetry of the electron emitting surface. An anode is spaced from the cathode and has a target surface disposed at an angle of 157.5° with respect to the axis of symmetry. The target surface provides x-rays in response to impingement of the electron beam thereon. The x-rays are directed outwardly of the x-ray tube from an x-ray imaging spot on the x-ray target. An aperture grid is disposed between the cathode and the anode, and has a central aperture permitting the electron beam to pass therethrough. The aperture grid further has a variable voltage applied thereto with respect to the cathode, which is used to control a diameter of the electron beam. Specifically, the electron beam diameter varies in correspondence with the variable voltage, and selective variation of the electron beam diameter results in a corresponding variation in size of the x-ray imaging spot. 
     In an embodiment of the invention, the x-ray tube is adapted to alter a position of the electron beam with respect to the axis of symmetry to thereby alter a point of impingement of the electron beam on the target surface. At least one magnetic polepiece is disposed within the anode in a direction perpendicular to the axis of symmetry. A magnetic field is applied to the polepiece so that the magnetic field crosses through the electron beam. This way, the electron beam is caused to impinge upon a separate spot on the target surface in order to distribute the deleterious effects of thermal stress on the target surface. 
    
    
     A more complete understanding of the variable spot x-ray tube will be afforded to those skilled in the art, as well as a realization of additional advantages and objects thereof, by a consideration of the following detailed description of the preferred embodiment. Reference will be made to the appended sheets of drawings which will first be described briefly. 
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a side sectional view of an electron gun for an x-ray tube of the present invention; 
     FIG. 2 is a computer simulation approximation graph of the x-ray tube variable imaging spot size performance for beam radius as a function of aperture grid voltage; 
     FIG. 3 is an end view of an embodiment of an anode of the electron gun having a single-axis magnetic polepiece for altering the electron beam position; 
     FIG. 4 is an end view of an embodiment of an anode of the electron gun having a double-axis magnetic polepiece for altering the electron beam position; 
     FIG. 5 is a side sectional view of an alternative embodiment of a cathode assembly of the electron gun; 
     FIG. 6 is a schematic view of an x-ray output cone provided by a prior art double-filament cathode; 
     FIG. 7 is a schematic view of an x-ray output cone provided by a variable spot cathode of the present invention; 
     FIG. 8 illustrates the geometric relationship between the x-ray output cone and the anode target angle for the prior art x-ray tube; 
     FIG. 9 illustrates the geometric relationship between the x-ray output cone and the anode target angle in accordance with the present invention; 
     FIG. 10 is a side sectional view of an embodiment of the electron gun in accordance with the present invention; and 
     FIG. 11 is a side sectional view of an embodiment of the x-ray tube of the present invention. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
     The present invention satisfies the need for an x-ray tube having a spot size that is continuously adjustable over a given range to allow greater flexibility in the imaging operations. In the detailed description that follows, it should be appreciated that like element numerals are used to describe like elements illustrated in one or more of the above-described figures. 
     Referring first to FIG. 1, a first embodiment of an electron gun for use in an x-ray tube is illustrated. The electron gun includes a cathode assembly having an electron emitter  12 . The emitter  12  may be comprised of a helically coiled filamentary wire formed from thoriated tungsten or other similar electron emissive materials, and is disposed such that it occupies a generally circular or symmetrical space. The filamentary wire may have a generally flat cross-section of the type commonly referred to as “pancake.” An edge electrode  16  having an annular shape is disposed concentrically around and spaced from the emitter  12 , and an annular focus electrode  22  is disposed concentrically around and spaced from the edge electrode. 
     An aperture grid  18  is disposed concentrically between the edge electrode  16  and the focus electrode  22 . The aperture grid  18  is also annular shaped and has a central opening through which the emitter  12  is exposed. As shown in FIG. 1, the aperture grid  18  has a flat surface that lies in a plane parallel to the emitter  12 . The emitter  12 , the edge electrode  16 , and the focus electrode  22  are commonly coupled to the same negative electric potential, and the aperture grid  18  is coupled to a variable positive or negative voltage source with respect to these cathode elements. Moreover, the emitter  12 , the edge electrode  16 , the aperture grid  18 , and the focus electrode  22  are each symmetrically disposed about a common axis  15 . 
     An anode assembly is spaced from the cathode assembly. The anode assembly includes an annular portion  32  and a target portion  36 . The annular portion  32  includes an opening  34  that extends along the axis  15 . The target portion  36  comprises a target surface  38  that is disposed at an obtuse angle with respect to the axis  15 , and which is not symmetrical with the axis. The target surface  38  is comprised of an x-ray emissive material, such as tungsten. A conically shaped opening is provided between the annular portion  32  and the target portion  36  which provides an output passage for x-rays generated within the device, as will be further described below. A window  42  crosses the conically shaped opening to maintain a vacuum seal within the device. The window  42  may be comprised of beryllium or similar materials selected to permit transmission of x-rays therethrough. 
     In operation, an electric current is applied to the emitter  12  which causes its temperature to rise to a level sufficient to permit thermionic emission of electrons to occur. A highly negative voltage is applied to the cathode assembly with respect to the anode assembly, such as −160 kilovolts, so that a beam of electrons is drawn from the emitter  12  toward the anode assembly. Conversely, the cathode assembly may be grounded and a highly positive voltage, e.g., +160 kilovolts, may be applied to the anode assembly. As known in the art, the current of the electron beam is dependent upon the temperature of the emitter  12  when it is operated in the temperature limited region. The shape of the edge electrode  16  and the focus electrode  22  are selected to define a pattern of equipotential lines in the interelectrode space between the cathode assembly and the anode assembly such that the electron beam is generally focussed and directed towards the target surface  38 . 
     An outer envelope  17  of the electron beam is illustrated in FIG.  1 . The electron beam passes through the opening  34  of the annular portion of the anode  32 , and impinges upon the target surface  38  to produce x-rays  33 . The x-rays  33  transmit in a generally conical path through the opening provided between the annular portion  32  and the target portion  36  of the anode assembly. The x-rays  33  pass through the window  42  to form an imaging spot at a predetermined distance beyond the device. The voltage provided to the aperture grid  18  causes the electron beam to diverge or compress as the electron beam leaves the emitter  12 . After passing the aperture grid  18 , the electron beam expands to a generally diverging path whence it is subsequently focussed into a cone by the shape of the electrostatic fields between the aperture grid  18  and the anode assembly. 
     As a specific example, FIG. 2 provides a chart derived from a computer simulation approximation of the x-ray tube variable imaging control. The chart shows a plot of beam radius in millimeters (y axis) versus the aperture grid voltage (x axis) where the beam radius is defined as the radius enclosing 63.2 percent of the electron beam. Assuming +160 kilovolts has been applied to the anode assembly, the graph shows that minimization of the spot size on target occurs when the aperture grid voltage is set to approximately +990 volts with respect to the cathode assembly at 0 volts. Accordingly, the diameter of the electron beam at the point of impact on the target surface  38  may be modified by varying the voltage applied to the aperture grid  18 . For example, the size of the beam may be effectively doubled by applying a voltage of +910 volts to the aperture grid, or alternately +1,045 volts. 
     Furthermore, it is possible to switch all beam current off by application of a generally negative voltage to the aperture grid  18  with respect to the cathode assembly. By varying the focusing of the electron beam, the spot size of the generated x-rays also changes. This way, the imaging spot size provided by the x-ray device increases as the diameter of the electron beam striking the target surface  38  increases, and decreases as the diameter of the electron beam decreases. This relationship between the shape of the electron beam and the x-ray spot size will be further described below in the discussion of the geometry of the present and prior art devices. 
     Referring next to FIGS. 3 and 4, alternative embodiments of the electron gun of an x-ray tube are shown. These embodiments are directed to solving a problem of overstressing the target surface of the anode. As noted above, a drawback of conventional x-ray tubes is that the power density of the electron beam striking the anode can cause undesirable melting and vaporization of the tungsten material. One way to avoid the overstressing of the target surface is to move the impact point of the electron beam to different locations. This must be achieved without distorting the shape of the electron beam, so that the power density of the x-ray imaging spot is not degraded. 
     More particularly, FIG. 3 illustrates the annular portion  32  of the anode assembly in cross-section. A polepiece having first and second sections  51 ,  52  extend in a radial direction into the annular portion  32  of the anode assembly. The polepiece sections  51 ,  52  do not extend entirely to the opening  34 , but terminate before reaching the opening to ensure that the vacuum envelope of the x-ray tube is not affected by the introduction of the polepiece sections. The polepiece sections  51 ,  52  are further coupled to a magnetic return strap  56  having an inductive coil  50  connected thereto. Application of an electric current to the inductive coil  50  produces a magnetic field B that bisects the opening  34  and extends perpendicularly with the central axis  15  of the electron gun. By varying the level of the electric current applied to the inductive coil  50 , the magnitude of the magnetic field B can be altered. The magnetic field B will deflect the electron beam as it is projected through the opening  34 , causing the electron beam to strike an alternative location of the target surface  38 . In this manner, the electron beam may be periodically repositioned to spread the energy of the electron beam across a greater area of the target surface  38  to reduce the thermal stress to any one point. The deflection of the electron beam may be manually controlled by an operator of the x-ray tube, or alternatively, may be automatically controlled upon detection of any overheating of the target surface  38 . 
     Similarly, FIG. 4 illustrates another embodiment in which a pair of crossed polepieces having sections  51 ,  52  and  53 ,  54  are utilized. The polepiece sections are disposed perpendicularly with respect to each other, and each have respective inductive coils (not shown) to provide magnetic fields B 1  and B 2  that extend in two axes through the central axis  15 . It should be appreciated that the crossed magnetic fields B 1  and B 2  thus permit a greater range of control over deflection of the electron beam in the two axis directions. 
     In FIG. 5, an alternative embodiment of the cathode assembly is illustrated. In this alternative embodiment, the cathode assembly comprises a helically coiled filamentary wire  26  disposed within an oven region defined by a support sleeve  29  and a thermally sealed end cap  24 . A central portion of the end cap  29  provides an emitting surface  14  comprised of thoriated tungsten or other similar electron emissive materials. The emitting surface  14  has circular shape that is disposed concentrically within and spaced from the aperture grid  18 . Heat shields  28  may also be provided within the cathode assembly to contain heat within the oven region and preclude thermal transfer outside the oven region. 
     To operate the cathode assembly, a voltage potential V H  is applied across the filamentary wire  26 . As in the previous embodiment, the current conducted through the filamentary wire  26  causes its temperature to increase. The heat generated by the filamentary wire is radiated outwardly within the oven region (e.g., in a pattern illustrated with broken lines in FIG.  5 ), onto the end cap  24 , and particularly, the emitting surface  14 . The thermal radiation onto the emitting surface  14  causes thermionic emission of electrons to occur therefrom, and a beam of electrons may be drawn from the emitting surface  14  by application of a high negative voltage potential between the cathode assembly and the anode assembly. Furthermore, a potential difference can be applied between the filamentary wire  26  and the emitting surface  14 . In this case, electrons from filamentary wire  26  bombard the rear of the end cap  24  heating it to a temperature sufficient for thermionic emission to occur. This general embodiment is advantageous since the emitting surface  14  can provide an electron beam having a more consistent and uniform current density and a more clearly defined outer envelope than a beam produced by direct emission from a filamentary wire. 
     In another aspect of the present invention, the target angle is selected to further enable a continuously variable spot size with an axially symmetric geometry. FIG. 6 illustrates, in schematic form, a prior art x-ray tube using a conventional 22.5° target angle between a central axis  35 ′ of the x-ray output cone and the target surface  36 ′ (target surface  36 ′ is disposed at a 112.5° angle with respect to a central axis  15 ′ of the x-ray tube). The prior art x-ray tube provides two dissimilar size spots on target. To accomplish this, the tube includes two cathode filaments, shown as F 1  and F 2 , which occupy separate non-symmetrical regions of the electron emitter with respect to the central axis  15 ′. These filaments are typically wires wound in the form of helices, F 1  being generally longer in length and having a larger helical pitch than F 2 . In view of the general dissimilarity between filaments F 1  and F 2  and their non-symmetrical placement, the respective electron beams can and generally do strike different locations on the target surface  36 ′. As noted above, the two filaments F 1  and F 2  are adapted to generate different diameter beams such that the beam produced by filament F 1  is larger than the beam produced by filament F 2 . 
     Upon striking the target surface  36 ′, the impinging beams produce x-ray output cones that pass through the window  42 ′ to illuminate an object of interest  60  disposed a focal length f′ from the target surface. For either beam, the roughly circular cross-sectional area x-ray spots at the target as viewed from the illuminated object constitute the imaging spot sizes for the x-ray tube. In general, the beam from the longer filament F 1  will produce a larger spot size of higher current on target, while the shorter filament F 2  will produce a smaller size spot of lower current on target. By situating the film or other x-ray image recording means  37 ′ at a distance g′ from the image spot, a magnified x-ray image results. In the prior art x-ray tube, the focal length f′ is most likely less than or equal to 6 inches to permit sufficient intensity. A central axis  35 ′ of the x-ray output cone forms a 90° angle to the central axis  15 ′ of the x-ray tube. Thus, the x-ray tube emits an imaging spot in a generally perpendicular direction from the axis of the x-ray tube. The typical cone angle in tubes of this type is typically 40° as shown in FIG.  6 . 
     FIG. 7 illustrates a target angle in accordance with an embodiment of the present invention. Unlike the prior art x-ray tube, the target surface  36  is disposed at a 157.50° angle with respect to a central axis  15  of the x-ray tube. With the larger target angle, the central axis  35  of the x-ray output cone forms a 135° angle to the central axis  15  of the x-ray tube. Since the electron beam is axially symmetric about the central axis  15 , the x-ray output cone similarly has symmetrical intensity to illuminate an imaging object  60  at a focal length f from the target surface. Higher magnification than the prior art x-ray tube can be obtained in the tube of the present invention since the object can be situated closer to the imaging focual spot, for example, as close as 1.2 inches. It should be appreciated that the enlarged target area of the present invention upon which the electron beam inpinges also results in lower heating per unit area of the target surface  36 . Furthermore, situating the object closer to the imaging spot reduces the intensity required for a given degree of magnification and image brightness. The cone angle in a x-ray tube of this invention as shown in FIG. 7 is typically 40° like that of the prior art x-ray tube. 
     In FIG. 8, the geometric relationship between the apparant x-ray image spot and the incident electron beam onto the target for the prior art x-ray tube is illustrated. An electron beam e having a length in the direction of the filamentary cathodes d 1 ′ is projected onto a target surface  36 ′ that is disposed at an angle aa′ with respect to the axis of the outgoing x-ray beam. The beam of x-rays has a apparant spot length d 2 ′ equivalent to d 1 ′ tan aa′ and the width of the impingement region d 3 ′ of the target surface  36  is equivalent to d 2 ′ /sin aa′. Therefore, the apparent spot size of the x-ray beam is smaller than the incident electron beam if the anode target angle aa′ is less than 45°. For the case of aa′=22.5° target angle used in the prior art device, the reflected beam will be 41% smaller than the incident beam length. In the direction parallel to the helical filament windings F 1  and F 2 , there is no reduction in the apparent size of the x-ray beam spot size over the size of the electron beam inpinging on the target surface since the target surface is not inclined in this direction. For a given spot length of the apparent x-ray beam size d 2 ′, it can be appreciated that inclining the target at an angle is a means of reducing electron beam power density on target surface for a given x-ray beam spot size. For the case of aa′=22.5°, the length of target surface upon which the beam strikes is 2.6 times longer than the length of the apparant x-ray beam spot size. 
     In contrast, FIG. 9 shows the geometric relationship between the x-ray output cone and the anode target angle for the x-ray tube of the present invention. As described above, the x-ray tube of the present invention has an anode target angle aa of 22.5° with respect to the x-ray cone axis, and an x-ray beam angle of 135° with respect to the angle of the axis of the incident electron beam. Accordingly, the extent of the target surface upon which the electron beam e impinges, d 3 , is d 2 /sin aa. Since the angle of the electron beam incidence equals the angle of the outgoing x-ray beam, it follows that d 2  is equal to d 1 . Thus, for the case of aa =22.5° in the tube of the present invention, the length of target upon which the beam strikes is 2.6 times longer than the length of the apparant x-ray beam spot size like that in the prior art x-ray tube. 
     Referring now to FIGS. 10 and 11, an embodiment of an x-ray tube constructed in accordance with the teachings of the present invention is illustrated. FIG. 10 illustrates an enlarged view of the cathode assembly of the x-ray tube. As in the embodiment of FIG. 5, the cathode assembly comprises a helically coiled filamentary wire  112  disposed within an oven region defined by shell halves  108 ,  114  coupled to opposite sides of a support ring  113 . The forward facing one of the shell halves  114  provides a circular emitting surface comprised of thoriated tungsten or other set of electron emissive materials. An edge electrode  116  having an annular shape is disposed concentrically around and spaced from the emitting surface, and an annular focus electrode  142  is disposed concentrically around and spaced from the edge electrode. The focus electrode  142  has a convex, dome-shaped outer surface  144  and a constant diameter bore  146  extending concentrically with the central axis of the emitting surface. A housing  122  substantially encloses the outer portion of the cathode assembly. 
     An aperture grid  118  is disposed concentrically between the edge electrode  116  and the focus electrode  142 . The aperture grid  118  is also annular shaped and has a central opening through which the emitting surface  114  is exposed. The emitting surface  114 , the edge electrode  116 , and the focus electrode  142  are commonly coupled to the same negative electric potential, and the aperture grid  118  is coupled to a voltage which is positive, negative, or equal to these other cathode elements. As in the embodiment of FIG. 1, the voltage of the aperture grid  118  alters the focusing characteristics of the cathode assembly in order to change the diameter of the electron beam produced at the emitting surface  114 . An electrical lead  132  is coupled to one terminal of the filamentary wire  112 , with the other terminal of the filamentary wire coupled to a conductive support plate  124  of the cathode assembly. Cylindrical isolator  136  electrically separates the remaining cathode assembly from where electrical lead  132  couples to filamentary wire  112 . A voltage potential V H  applied across the filamentary wire  112  causes heating of the emitter surface  114  enabling thermionic emission of electrons from the emitting surface  114 . Application of a highly negative voltage potential between the cathode assembly and the anode assembly produces a generally circular electron beam at the plane of the target. A separate electrical lead  134  provides voltage to the aperture grid  118 . A separate cylindrical isolator  138  electrically separates electrical lead  134  leading to aperture grid  118  from the remaining cathode assembly. Isolator ring  140  provides further electrical separation between aperture grid  118  and the remaining cathode assembly. Cylindrical isolators  136 ,  138  and isolator ring  140  may be comprised of a thermally conductive, electrically insulating material such as alumina ceramic. 
     In FIG. 11, a side sectional view of the entire x-ray tube is provided. The cathode assembly (described above with respect to FIG. 10) extends from an insulator post  152  that is axially disposed within the x-ray tube. An external housing  154  is disposed radially outward from the cathode assembly, and couples the distal end of the x-ray tube that includes the anode assembly to the proximal end of the x-ray tube that permits the device to be mounted to another structure (not shown). The anode assembly is spaced from the cathode assembly, and includes an annular portion  152  and a target portion  156 . The annular portion  152  includes an opening  154  that extends along the central axis of the cathode assembly. The target portion  156  comprises a target surface  158  that is disposed at a 157.5° angle with respect to the central axis, and which is not symmetrical with the central axis. The target surface  158  is comprised of an x-ray emissive material, such as tungsten. A conically shaped opening  164  is provided between the annular portion  152  and the target portion  156  which provides an output passage for x-rays generated within the device. A window  162  crosses the conically shaped opening  164  to maintain a vacuum seal within the device. The window  162  may be comprised of beryllium or similar materials selected to permit transmission of x-rays therethrough. 
     As described above, a highly negative voltage is applied to the cathode assembly with respect to the anode assembly to draw a beam of electrons from the emitting surface  114  toward the anode assembly. The electron beam passes through the opening  154  of the annular portion of the anode  152 , and impinges upon the target surface  158  to produce x-rays. The x-rays transmit in a generally conical path through the window  162  to form an imaging spot on the target. The voltage provided to the aperture grid  118  causes the electron beam to diverge or compress slightly as the electron beam leaves the emitting surface  114 . Accordingly, the diameter of the electron beam may be controlled by altering the voltage of the aperture grid to change the diameter of the beam at the point of impact on the target surface  158 . By varying the focusing of the electron beam, the imaging spot size provided by the x-ray device increases as the diameter of the electron beam striking the target surface  158  increases, and decreases as the diameter of the electron beam decreases. 
     Having thus described a preferred embodiment of an x-ray tube having variable imaging spot size, it should be apparent to those skilled in the art that certain advantages of the within system have been achieved. It should also be appreciated that various modifications, adaptations, and alternative embodiments thereof may be made within the scope and spirit of the present invention. The invention is further defined by the following claims.