초록 ▼

A method for examining an object includes the steps of: producing ionizing radiation photons; providing other particles or photons, each of which carrying information regarding position, time, movement direction, and/or energy of a respective one of said ionizing radiation photons before having inte

A method for examining an object includes the steps of: producing ionizing radiation photons; providing other particles or photons, each of which carrying information regarding position, time, movement direction, and/or energy of a respective one of said ionizing radiation photons before having interacted with said object to be examined; detecting each of said other particles or photons to retrieve said information; having said ionizing radiation photons to interact with said object to be examined; detecting at least some of said ionizing radiation photons after having interacted with said object to retrieve information regarding position, time, movement direction, and/or energy of each of said detected ionizing radiation photons; correlating each of said detected ionizing radiation photons with a respective one of said other particles or photons; and deducing information of said examined object by means of said information as retrieved in the steps of detection.

대표청구항 ▼

What is claimed is: 1. A method for examining an object comprising the steps of: producing ionizing radiation photons; providing other particles or photons, said other particles or photons having participated in the production of said ionizing radiation photons, being produced through interaction

What is claimed is: 1. A method for examining an object comprising the steps of: producing ionizing radiation photons; providing other particles or photons, said other particles or photons having participated in the production of said ionizing radiation photons, being produced through interaction of said ionizing radiation photons with matter, or being produced simultaneously with the production of said ionizing radiation photons; wherein each of said other particles or photons carries information regarding position at a given point of time, time of arrival at a given position, movement direction, and/or energy of a respective one of said ionizing radiation photons before having interacted with said object to be examined; detecting each of said other particles or photons to retrieve said information of a respective one of said ionizing radiation photons before having interacted with said object to be examined; causing said ionizing radiation photons to interact with said object to be examined; detecting at least some of said ionizing radiation photons after having interacted with said object to be examined to retrieve information regarding position at a given point of time, time of arrival at a given position, movement direction, and/or energy of each of said detected ionizing radiation photons; correlating each of said detected ionizing radiation photons with a respective one of said other particles or photons; and deducing information of said examined object by means of said information as retrieved in said steps of detection. 2. The method of claim 1 wherein said information regarding position at a given point of time, time of arrival at a given position, movement direction, and/or energy of a respective one of said ionizing radiation photons before having interacted with said object to be examined includes information regarding position at a given point of time, time of arrival at a given position, and movement direction of a respective one of said ionizing radiation photons before having interacted with said object to be examined; and said information regarding position at a given point of time, time of arrival at a given position, movement direction, and/or energy of each of said detected ionizing radiation photons includes information regarding position at a given point of time, time of arrival at a given position, and movement direction of each of said detected ionizing radiation photons. 3. The method of claim 2 wherein said information regarding position at a given point of time, time of arrival at a given position, movement direction, and/or energy of a respective one of said ionizing radiation photons before having interacted with said object to be examined includes also information regarding energy of a respective one of said ionizing radiation photons before having interacted with said object to be examined; and said information regarding position at a given point of time, time of arrival at a given position, movement direction, and/or energy of each of said detected ionizing radiation photons includes also information regarding energy of each of said detected ionizing radiation photons. 4. The method of claim 1 wherein said ionizing radiation photons are produced by a source of synchrotron radiation; and said other particles or photons are electrons from said source of synchrotron radiation, which have emitted said ionizing radiation photons while being accelerated in an electromagnetic field. 5. The method of claim 4 wherein said electrons are separated due to their energy-momentum by an electromagnetic separator, and subsequently detected. 6. The method of claim 5 wherein said electrons are separated due to their energy-momentum by an electromagnetic separator, and subsequently detected by a position-sensitive detector. 7. The method of claim 1 wherein said ionizing radiation photons are produced by an X-ray tube; and said other particles or photons are electrons released from a photon scatterer as a result of said ionizing radiation photons being scattered off said photon scatterer. 8. The method of claim 7 wherein said photon scatterer is comprised of a thin foil. 9. The method of claim 8 wherein said thin foil is a metallic foil. 10. The method of claim 9 wherein said metallic foil is an aluminum foil. 11. The method of claim 7 wherein said photon scatterer is comprised of a multilayer structure. 12. The method of claim 1 wherein said ionizing radiation photons and said other particles or photons are produced simultaneously pair by pair in a nuclear decay process. 13. The method of claim 1 wherein said ionizing radiation photons and said other particles or photons, which are photons, are produced simultaneously pair by pair in a reaction of electron-positron annihilation following the emission of positrons from a positron-emitting radioactive isotope. 14. The method of claim 1 wherein said ionizing radiation photons detected after having interacted with said object to be examined are substantially photons that are transmitted through said object without being absorbed or scattered. 15. The method of claim 14 wherein each of said other particles or photons carries information regarding position, direction and time of emission of a respective one of said ionizing radiation photons; each of said other particles or photons is detected to retrieve said information regarding position, direction and time of emission of a respective one of said ionizing radiation photons; said at least some of said ionizing radiation photons are detected spatially and temporally resolved after having interacted with said object to retrieve information regarding detection position and time of each of said at least some of said ionizing radiation photons; and information regarding composition, structure or density of said examined object is deduced by means of said information regarding position, direction and time of emission of said ionizing radiation photons, and position and time of said at least some of said ionizing radiation photons as detected after having interacted with said object. 16. The method of claim 15 wherein said object to be examined has thin parts, which are highly transparent to said ionizing radiation photons, information regarding composition, structure or density of said examined object is deduced by means of subtracting the number of ionizing radiation photons as detected at each position from those emitted in a direction towards said position. 17. The method of claim 1 wherein said ionizing radiation photons detected after having interacted with said object to be examined are substantially photons that are scattered in said object. 18. The method of claim 1 wherein the step of detecting at least some of said ionizing radiation photons after having interacted with said object to be examined is performed by means of spatially resolved two dimensional imaging; and the step of deducing information of said examined object by means of said information as retrieved in said steps of detection comprises to provide a two-dimensional image of said object. 19. A method for tomography including the method of claim 1. 20. An apparatus for examining an object comprising: a source for producing ionizing radiation photons; means for providing other particles or photons, said other particles or photons having participated in the production of said ionizing radiation photons, being produced through interaction of said ionizing radiation photons with matter, or being produced simultaneously with the production of said ionizing radiation photons; wherein each of said other particles or photons carries information regarding position at a given point of time, time of arrival at a given position, movement direction, and/or energy of a respective one of said ionizing radiation photons before having interacted with said object to be examined; a first detector for detecting each of said other particles or photons to retrieve said information of a respective one of said ionizing radiation photons; an object area for housing an object to be examined, the object area being arranged so that said ionizing radiation photons are directed to and interact with said object; a second detector for detecting at least some of said ionizing radiation photons after having interacted with said object to be examined to retrieve information regarding position at a given point of time, time of arrival at a given position, movement direction, and/or energy of each of said detected ionizing radiation photons; and a signal-processing device connected to said first and second detectors for correlating each of said detected ionizing radiation photons with a respective one of said other particles or photons, and for deducing information of said examined object by means of said information as retrieved by said first and second detectors. 21. The apparatus of claim 20 wherein said information regarding position at a given point of time, time of arrival at a given position, movement direction, and/or energy of a respective one of said ionizing radiation photons before having interacted with said object to be examined includes information regarding position at a given point of time, time of arrival at a given position, and movement direction of a respective one of said ionizing radiation photons before having interacted with said object to be examined; and said information regarding position at a given point of time, time of arrival at a given position, movement direction, and/or energy of each of said detected ionizing radiation photons includes information regarding position at a given point of time, time of arrival at a given position, and movement direction of each of said detected ionizing radiation photons. 22. The apparatus of claim 21 wherein said information regarding position at a given point of time, time of arrival at a given position, movement direction, and/or energy of a respective one of said ionizing radiation photons before having interacted with said object to be examined includes also information regarding energy of a respective one of said ionizing radiation photons before having interacted with said object to be examined; and said information regarding position at a given point of time, time of arrival at a given position, movement direction, and/or energy of each of said detected ionizing radiation photons includes also information regarding energy of each of said detected ionizing radiation photons. 23. The apparatus of claim 20 wherein said source and said means for providing other particles or photons are comprised of a source of synchrotron radiation; and said other particles or photons are electrons from said source of synchrotron radiation, which have emitted said ionizing radiation photons while being accelerated in an electromagnetic field. 24. The apparatus of claim 20 further comprising an electromagnetic separator for separating said electrons due to their energy-momentum prior to being detected by said first detector. 25. The apparatus of claim 20 wherein said source is an X-ray tube; and said means for providing other particles or photons is a photon scatterer arranged to scatter said ionizing radiation photons and as a result thereof to release electrons. 26. The apparatus of claim 25 wherein said photon scatterer is comprised of a thin foil. 27. The apparatus of claim 26 wherein said thin foil is a metallic foil. 28. The apparatus of claim 27 wherein said metallic foil is an aluminum foil. 29. The apparatus of claim 25 wherein said photon scatterer is comprised of a multilayer structure. 30. The apparatus of claim 20 wherein said photon scatterer is comprised in said first detector for detecting each of said other particles or photons. 31. The apparatus of claim 20 wherein said source and said means for providing other particles or photons are comprised of a nuclear decaying substance, wherein said ionizing radiation photons and said other particles or photons are produced simultaneously pair by pair. 32. The apparatus of claim 20 wherein said source and said means for providing other particles or photons are comprised of a radioactive isotope emitting positrons and a substance for electron-positron annihilation emitting said ionizing radiation photons and said other particles or photons, which are photons, simultaneously pair by pair. 33. The apparatus of claim 20 wherein said second detector is arranged to detect ionizing radiation photons that are transmitted through said object without being absorbed or scattered. 34. The apparatus of claim 33 wherein said first detector is adapted to detect each of said other particles or photons to retrieve information regarding position, direction and time of emission of a respective one of said ionizing radiation photons; said second detector is adapted to detect said at least some of said ionizing radiation photons after having interacted with said object to be examined spatially and temporally resolved to retrieve information regarding detection position and time of each of said detected ionizing radiation photons; said signal-processing device is adapted to deduce information regarding composition, structure or density of said examined object by means of subtracting the number of ionizing radiation photons as detected at each position from those emitted in a direction towards said position. 35. The apparatus of claim 20 wherein said second detector is arranged to detect ionizing radiation photons that are scattered in said object. 36. The apparatus of claim 20 wherein said second detector is a two dimensional detector for spatially resolved two dimensional imaging; and said signal-processing device is adapted to provide a two-dimensional image of said object by means of said information as retrieved by said first and second detectors. 37. A method for examining an object comprising the steps of: producing ionizing radiation photons; providing other particles or photons, said other particles or photons having participated in the production of said ionizing radiation photons, being produced through interaction by said ionizing radiation photons with matter, or being produced simultaneously with the production of said ionizing radiation photons, wherein a ratio of a number of said other particles or photons and a number of ionizing radiation photons is known; detecting each of said other particles or photons; having said ionizing radiation photons to interact with said object to be examined; detecting at least some of said ionizing radiation photons after having interacted with said object to be examined; subtracting the number of said detected ionizing radiation photons from the product of the number of said detected other particles or photons and the ratio of the number of said other particles or photons and the number of ionizing radiation photons; and deducing information of said examined object by means of said difference. 38. The method of claim 37 wherein said at least some of said ionizing radiation photons detected after having interacted with said object to be examined are propagating in paths being essentially parallel with, and close to, each other. 39. An apparatus for examining an object comprising: a source for producing ionizing radiation photons; means for providing other particles or photons, said other particles or photons having participated in the production of said ionizing radiation photons, being produced through interaction by said ionizing radiation photons with matter, or being produced simultaneously with the production of said ionizing radiation photons, wherein a ratio of a number of said other particles or photons and a number of ionizing radiation photons is known; a first detector detecting each of said other particles or photons; an object area for housing an object to be examined, the object area being arranged so that said ionizing radiation photons are directed to and interacting with said object; a second detector for detecting at least some of said ionizing radiation photons after having interacted with said object to be examined; a signal-processing device connected to said first and second detectors for subtracting the number of said detected ionizing radiation photons from the product of the number of said detected other particles or photons and the ratio of the number of said other particles or photons and the number of ionizing radiation photons, and for deducing information of said examined object by means of said difference.