Patent Number: 
Section: claims

1. An x-ray/gamma-ray imaging apparatus, the apparatus including a pulse mode x-ray/gamma-ray detector having a dynamic range and comprising a member that is pixelated and configured to convert incident x-ray/gamma-ray wavelength photons directly into an electronic signal, a position for a material under test, an x-ray/gamma-ray source, and a structure configured to perturb an x-ray/gamma-ray energy spectrum, each lying on a common axis, wherein the structure comprises at least three regions adjacent and to the side of each other, each different from each other and having a different x-ray perturbing characteristic, and wherein said structure lies between the x-ray/gamma-ray source and the member and to one side of the position for material under test, the said structure intersecting the common axis such that x-ray/gamma-ray photons perturbed differently by respective regions of the at least three regions of said structure impinge upon different pixels of the pixelated detector substantially simultaneously, and wherein by means of the different perturbation characteristics of the at least three regions of the structure at least some of the pixels of the pixelated detector are impinged upon by x-ray/gamma-ray photons that are within the dynamic range of the detector. 2. An x-ray/gamma-ray imaging apparatus according to claim 1, wherein the at least three regions lie laterally of one another. 3. An x-ray/gamma-ray imaging apparatus according to claim 2, wherein the at least three regions lie laterally of one another in two orthogonal directions. 4. An x-ray/gamma-ray imaging apparatus according to claim 1, wherein at least three regions of the structure are formed in an array. 5. An x-ray/gamma-ray imaging apparatus according to claim 4, wherein the array comprises an x by y array wherein the multiple of x and y is greater than or equal to three. 6. An x-ray/gamma-ray imaging apparatus according to claim 4, wherein the array repeats itself in the structure. 7. An x-ray/gamma-ray imaging apparatus according to claim 4, wherein the structure includes a multiplicity of arrays. 8. An x-ray/gamma-ray imaging apparatus according to claim 1, wherein individual regions each include one or more x-ray/gamma-ray perturbation elements. 9. An x-ray/gamma-ray imaging apparatus according to claim 8, wherein the x-ray/gamma-ray perturbation elements are one of the same and different. 10. An x-ray/gamma-ray imaging apparatus according to claim 1, wherein the structure is one of planar and non-planar. 11. An x-ray/gamma-ray imaging apparatus according to claim 10, wherein the structure is curved in at least one plane. 12. X-ray/gamma-ray imaging apparatus according to claim 1, wherein the structure is configured to perturb both the energy distribution and the intensity of the x-ray/gamma-ray energy spectrum. 13. An x-ray/gamma-ray imaging apparatus according to claim 1, wherein the difference between adjacent regions of the structure includes the thickness of the material of the structure in adjacent regions. 14. An x-ray/gamma-ray imaging apparatus according to claim 13, wherein the thickness of the region changes continuously across the structure in at least one direction. 15. An x-ray/gamma-ray imaging apparatus according to claim 14, wherein the thickness of the region changes continuously across the structure in two orthogonal directions. 16. An x-ray/gamma-ray imaging apparatus according to claim 1, wherein the difference between adjacent regions includes the material from which the individual adjacent regions of the structure are formed. 17. An x-ray/gamma-ray imaging apparatus according to claim 13, wherein the individual regions of the structure include discrete layers. 18. An x-ray/gamma-ray imaging apparatus according to claim 17, wherein the discrete layers differ and the difference between discrete layers is selected from the group comprising the thickness of the discrete layers between regions; the thickness of the discrete layers within a region; the material from which the discrete layers are formed differs between regions; the material from which the discrete layers are formed differs within a region; the number of discrete layers differs between regions; and the number of discrete layers differs within a region. 19. An x-ray/gamma-ray imaging apparatus according to claim 17, wherein the structure includes a plurality of discrete layers and at least one of the discrete layers includes at least one aperture. 20. An x-ray/gamma-ray imaging apparatus according to claim 19, wherein a plurality of the discrete layers include at least one aperture and wherein apertures of different layers within the structure are of different dimensions. 21. An x-ray/gamma-ray imaging apparatus according to claim 19, wherein the discrete layers are formed of foil. 22. An x-ray/gamma-ray imaging apparatus according to claim 1, wherein the structure is configured to perturb the count rate whilst preserving the energy distribution of the x-ray/gamma-ray energy spectrum. 23. An x-ray/gamma-ray imaging apparatus according to claim 22, wherein the structure is a collimator, each of the at least three regions of the structure comprises an aperture of a different size to an aperture of an immediately adjacent region, wherein adjacent apertures are separated by an x-ray/gamma-ray absorbing material and the structure providing at least two different sizes of aperture. 24. An x-ray/gamma-ray imaging apparatus according to claim 23, wherein the structure comprises a plate of x-ray/gamma-ray absorbing materials have said apertures formed therein. 25. An x-ray/gamma-ray imaging apparatus according to claim 22, wherein the structure is formed from a selected one of tungsten, gold or lead. 26. An x-ray/gamma-ray imaging apparatus according to claim 22, wherein the said apertures are formed in the structure by spark erosion. 27. An x-ray/gamma-ray imaging apparatus according to claim 1, further including means for generating absorption edges and fluorescence peaks in the x-ray/gamma-ray energy spectrum. 28. An x-ray/gamma-ray imaging apparatus according to claim 27, wherein the means for generating absorption edges and fluorescence peaks in the x-ray/gamma-ray energy spectrum is comprised in the structure. 29. An x-ray/gamma-ray imaging apparatus according to claim 28, wherein the at least three regions of the structure each have a different absorption edge and fluorescence peak. 30. A structure suitable for use in an x-ray/gamma-ray detector according to claim 1, the structure configured to perturb an x-ray/gamma-ray energy spectrum incident thereon, the structure comprising at least three regions adjacent each other lying on a common plane, wherein each region is different from each other, each adjacent region configured to perturb the x-ray/gamma-ray energy spectrum differently. 31. A structure according to claim 30, wherein the structure includes a plurality of protrusions or depressions, the thickness of said protrusions or depressions changing in at least one direction thereof, each protrusion or depression providing at least three adjacent regions configured to perturb the x-ray/gamma-ray energy spectrum. 32. A structure according to claim 31, wherein the protrusions or depressions are pyramidal in shape. 33. A structure according to claim 31, wherein the structure comprises a non-metallic layer having a multiplicity of depressions formed therein, each depression filled with metal. 34. A structure according to claim 33, wherein the structure comprises a first non-metallic layer having a multiplicity of depressions formed therein and a second metallic layer including a corresponding number of protrusions each protrusion filling a corresponding depression. 35. A structure according to claim 34, wherein the second layer covers the surface of the first layer in which the openings to the depressions are situated. 36. A structure according to claim 31, wherein adjacent depressions or protrusions are separated from one another by x-ray/gamma-ray perturbing material and wherein the material separating adjacent depressions or protrusions constitute one of the at least three regions. 37. A structure according to claim 33, wherein the non-metallic layer is formed of silicon. 38. A method of determining a material property of a substance comprising the steps of:a) positioning the substance in an x-ray/gamma-ray imaging apparatus as claimed in claim 1;b) causing the x-ray/gamma-ray source to direct an x-ray/gamma-ray energy spectrum along the common axis;c) analyzing electronic signals emitted by the member configured to convert incident x-ray/gamma-ray wavelength photons into electronic signals; andd) deleting those electronic signals outwith the dynamic range of the member. 39. A method according to claim 38, wherein the member is pixilated, the method comprising the further step of analyzing the electronic signal for each pixel; and deleting those electronic signals outwith the dynamic range of the member. 40. A method according to claim 39, comprising the further step of assigning to each pixel of the member where the electronic signal has been deleted, the electronic signal of an adjacent pixel that is within the dynamic range of the member. 41. A method according to claim 39, comprising the further step of assigning to each pixel of the member where the electronic signal has been deleted, an electronic signal that is one of: interpolated and extrapolated, from the electronic signals of surrounding pixels. 42. A method according to claim 40, wherein the pixel from which an electronic signal is selected, interpolated or extrapolated is a nearest neighbor or nearest neighbor associated with a region having the same material properties. 43. An x-ray/gamma-ray imaging apparatus, the apparatus including a pulse mode x-ray/gamma-ray detector having a dynamic range and comprising a member that is pixelated and configured to convert incident x-ray/gamma-ray wavelength photons directly into an electronic signal, a position for a material under test, an x-ray/gamma-ray source, and a structure configured to perturb an x-ray/gamma-ray energy spectrum, each lying on a common axis, wherein the structure comprises at least three regions adjacent and to the side of each other, each different from each other and having a different x-ray perturbing characteristic, and wherein said structure lies between the x-ray/gamma-ray source and the member and to one side of the position for material under test, the said structure intersecting the common axis such that x-ray/gamma-ray photons perturbed differently by respective regions of the at least three regions of said structure impinge upon different pixels of the pixelated detector substantially simultaneously, and wherein by means of the different perturbation characteristics of the at least three regions of the structure at least some of the pixels of the pixelated detector are impinged upon by x-ray/gamma-ray photons that are within the dynamic range of the detector further comprising image processing software and a data processor, the image processing software configured to perform the method steps of:a) positioning the substance in the x-ray/gamma-ray imaging apparatus;b) causing the x-ray/gamma-ray source to direct an x-ray/gamma-ray energy spectrum along the common axis;c) analyzing electronic signals emitted by the member configured to convert incident x-ray/gamma-ray wavelength photons into electronic signals; andd) deleting those electronic signals outwith the dynamic range of the member. 44. An x-ray/gamma-ray imaging apparatus according to claim 43, further including a database. 45. An x-ray/gamma-ray imaging apparatus according to claim 43, further including a data recording means.