Patent Number: 
Section: claims

1. An x-ray imaging device comprising two substantially planar panels, each panel comprising a plurality of x-ray emitters housed in a vacuum enclosure, wherein the at least two panels each have a central panel axis and are arranged such that their central panel axes are non-parallel to one another, and are in a common plane, the at least two panels held stationary in relation to an object during x-raying of the object, wherein each x-ray emitter includes a collimator having a common collimator angle and the two panels are arranged such that the angle between their central panel axes is approximately the same as the common collimator angle. 2. The x-ray imaging device of claim 1, wherein each x-ray emitter emits x-rays in a conelet having a central conelet axis, and each of the at least two panels is arranged such that the central conelet axes of each x-ray emitter in each respective panel are parallel to one another. 3. The x-ray imaging device of claim 1, having n panels, n being more than two, arranged side-by-side in a linear array each with its central panel axis in a common plane, wherein each x-ray emitter includes a collimator having a common collimator angle and the two outer panels of the array are arranged such that the angle between their central panel axes is approximately the same as the common collimator angle, and each intervening panel is arranged such that the angle between its central panel axis and that of the adjacent panel is calculated by the formula (the common collimator angle)/(n−1). 4. The x-ray imaging device of claim 1, having an arrangement of four or more panels, arranged in two or more rows, each panel arranged such that their central panel axes converge on a common point distal from the device, wherein each x-ray emitter includes a collimator having a common collimator angle and the panels at the ends of each row are arranged such that the angle between their central panel axes and a line connecting the common point to the centre of the arrangement of panels is approximately the same as the common collimator angle. 5. The x-ray imaging device of claim 1, having an arrangement of six or more panels, arranged in two or more rows, each panel in a first row arranged such that their central panel axes converge on a first common point distal from the device, and each panel in each subsequent row arranged such that their central panel axes converge on respective subsequent common points distal from the device, wherein each x-ray emitter includes a collimator having a common collimator angle and the panels at the ends of each row are arranged such that the angle between their central panel axes and a line connecting the relevant common point to the centre of the arrangement of panels in that row is approximately the same as the common collimator angle. 6. The x-ray imaging device of claim 1, having two panels arranged such that the angle between their central panel axes in each of two of the three cardinal axes lies in the range 1 to 89 degrees. 7. The x-ray imaging device of claim 6, wherein the angle between their central panel axes in each of two of the three cardinal panel axes lies in the range 5 to 45 degrees. 8. The x-ray imaging device of claim 6, wherein the angle between their central panel axes in each of two of the three cardinal panel axes lies in the range 10 to 20 degrees. 9. The x-ray imaging device of claim 1, wherein the common collimator angle lies in the range 10 to 45 degrees. 10. The x-ray imaging device of claim 1, further comprising a digital x-ray detector having a central detector panel axis and a controller for controlling each x-ray emitter individually. 11. The x-ray imaging device of claim 10, arranged such that the distance between the panels and the detector is in the range of one to two times the thickness of the object to be x-rayed. 12. The x-ray imaging device of claim 10, wherein the detector is held stationary in relation to the object during x-raying of the object. 13. The x-ray imaging device of claim 1, comprising between two and sixteen panels. 14. The x-ray imaging device of claim 10, further comprising a processor for processing data produced by the detector, as a result of receiving x-rays, and for producing an image. 15. The x-ray imaging device of claim 14, wherein the processor is configured to process data received over a period of time to produce a 3D tomosynthesis model of an x-rayed object wherein the received x-rays have been emitted by different emitters in the panels and have passed through the object in different directions. 16. The x-ray imaging device of claim 14, wherein the processor is configured to determine the relative angle of the central panel axis of each panel relative to the central detector panel axis in two of the three cardinal axes. 17. The x-ray imaging device of claim 1, wherein the position of at least one of the at least two panels, relative to the other of the at least two panels, is adjustable prior to x-raying of the object. 18. A method of producing an x-ray image of an object comprising the steps of providing an x-ray imaging device, comprising two substantially planar panels, each panel comprising a plurality of x-ray emitters housed in a vacuum enclosure, wherein the at least two panels each have a central panel axis and are arranged such that their central panel axes are non-parallel to one another, and are in a common plane, the at least two panels held stationary in relation to an object during x-raying of the object, wherein each x-ray emitter includes a collimator having a common collimator angle and the two panels are arranged such that the angle between their central panel axes is approximately the same as the common collimator angle, the x-ray image device further comprising a digital x-ray detector having a central detector panel axis and a controller for controlling each x-ray emitter individually, the x-ray image device further comprising a processor for processing data produced by the detector, as a result of receiving x-rays, and for producing an image, wherein the processor is configured to process data received over a period of time to produce a 3D tomosynthesis model of an x-rayed object, wherein the received x-rays have been emitted by different emitters in the panels and have passed through the object in different directions;providing an object between the detector and the panels;causing x-rays to be emitted from the panels;processing data received by the detector as a result of receiving x-rays; andproducing an image therefrom. 19. A method of producing an x-ray image of an object according to claim 18, further comprising the step of:using the processor to determine the relative angle of the central panel axis of each panel relative to the central detector panel axis of the detector in two of the three cardinal axes so as to improve the accuracy of the produced image. 20. The method of producing an x-ray image of an object according to claim 18, further comprising the step of:the detector receiving data over a period of time wherein the received x-rays have been emitted by different emitters in the panels and have passed through the object in different directions; andthe processor processing said data to produce a 3D tomosynthesis model of the object.