Patent Number: 
Section: claims

1. A radiation image acquiring device comprising:a plurality of detectors to measure radiation;a collimator including a plurality of through-holes having the detectors disposed therein and configured to limit an incident direction of the radiation; anda data processing device to measure a positional displacement between the detectors and the collimator by use of profiles of a radiation source measured by the detectors,wherein:pixels of the detectors are two-dimensionally arranged in an x direction and a y direction, where m detectors in the x direction and n detectors in the y direction (m×n detectors), where m and n are integers, are included in single ones of the through-holes of the collimator,Pa denotes one of the profiles in the x direction measured when the radiation source is disposed above the m×ix-th (ix is an integer) detector pixel position in the x direction, which is designated as a position counted from 0,Pb denotes one of the profiles in the x direction measured when the radiation source is disposed above the m×ix+(m−1)th detector pixel, andPb is inverted about the detector pixel position m×ix+(m−1)/2 to obtain Pb′,wherein the data processing device sets an amount of movement of the collimator in the x direction such that a residual sum of squares Rx of Pa and Pb′ is less than a predetermined threshold,wherein:Pc denotes one of the profiles measured when the radiation source is disposed above the n×iy-th (iy is an integer) detector pixel position in the y direction, which is designated as a position counted from 0,Pd denotes one of the profiles measured when the radiation source is disposed above the n×iy+(n−1)th detector pixel, andPd is inverted about the detector pixel position n×iy+(n−1)/2 to obtain Pd′, andwherein the data processing device sets an amount of movement of the collimator in the y direction such that a residual sum of squares Ry of Pc and Pd′ is less than the predetermined threshold. 2. The radiation image acquiring device according to claim 1,wherein the data processing device sets an amount of movement of the collimator in the x direction so as to minimize Rx, andwherein the data processing device sets an amount of movement of the collimator in the y direction so as to minimize Ry. 3. The radiation image acquiring device according to claim 1,wherein the data processing device estimates a positional displacement amount Dx in the x direction from Rx, an amount of positional displacement of the collimator obtained beforehand, and a graph showing a relationship of the residual sum of squares of Pa and Pb′,wherein the data processing device sets Dx as an amount of movement of the collimator in the x direction so as to minimize Rx,wherein the data processing device estimates a positional displacement amount Dy in the y direction from Ry, an amount of positional displacement of the collimator obtained beforehand, and a graph showing a relationship of the residual sum of squares of Pc and Pd′, andwherein the data processing device sets Dy as an amount of movement of the collimator in the y direction so as to minimize Ry. 4. The radiation image acquiring device according to claim 1,wherein the data processing device obtains pa and pb′ by plotting only the m×jx-th (jx is an integer) values in Pa and Pb′,wherein the data processing device determines a direction of positional displacement in the x direction based on a positional relationship between main peaks and sub-peaks of pa and pb′,wherein the data processing device obtains pc and pd′ by plotting only the n×jy-th (jy is an integer) values in Pc and Pd′, andwherein the data processing device determines a direction of positional displacement in the y direction based on a positional relationship between main peaks and sub-peaks of pc and pd′. 5. The radiation image acquiring device according to claim 1,wherein the data processing device obtains beforehand Pa as Pa(x) which is a positional displacement x obtained by simulation in a range of −Hx/2 to Hx/2, where Hx denotes a hole pitch of the collimator in the x direction,wherein the data processing device obtains a residual sum of squares of Pa(x) obtained by simulation and Pa obtained during positional displacement measurement,wherein the data processing device obtains a direction of positional displacement in the x direction from the value of the positional displacement x of Pa(x) where the residual sum of squares of Pa(x) and Pa is minimized,wherein the data processing device obtains beforehand Pc as Pc(y) which is a positional displacement x obtained by simulation in a range of −Hy/2 to Hy/2, where Hy denotes a hole pitch of the collimator in the y direction,wherein the data processing device obtains a residual sum of squares of Pc(y) obtained by simulation and Pa obtained during positional displacement measurement, andwherein the data processing device obtains a direction of positional displacement in the y direction from the value of the positional displacement y of Pc(y) where the residual sum of squares of Pc(y) and Pc is minimized. 6. The radiation image acquiring device according to claim 1,wherein the data processing device obtains positional displacement information from profiles of the radiation source in the x direction at both ends of the collimator in the y direction,wherein the data processing device sets different movement amounts at both the ends of the collimator in the y direction so as to move the collimator in the x direction,wherein the data processing device obtains positional displacement information from profiles of the radiation source in the y direction at both ends of the collimator in the x direction, andwherein the data processing device sets different movement amounts at both the ends of the collimator in the x direction so as to move the collimator in the y direction. 7. The radiation image acquiring device according to claim 1,wherein the data processing device obtains positional displacement amounts at spots of the collimator in the x direction, and sets an amount of movement of the collimator in the x direction so as to minimize the sum of the positional displacement amounts at the spots of the collimator in the x direction,wherein the data processing device obtains positional displacement amounts at spots of the collimator in the y direction, andwherein the data processing device sets an amount of movement of the collimator in the y direction so as to minimize the sum of the positional displacement amounts at the spots of the collimator in the y direction. 8. The radiation image acquiring device according to claim 1,wherein the data processing device obtains positional displacement amounts at spots of the collimator in the x direction,wherein the data processing device sets an amount of movement of the collimator in the x direction such that the positional displacement amounts at the spots of the collimator in the x direction are smaller than a predetermined threshold,wherein the data processing device obtains positional displacement amounts at spots of the collimator in the y direction, andwherein the data processing device sets an amount of movement of the collimator in the y direction such that the positional displacement amounts at the spots of the collimator in the y direction are smaller than a predetermined threshold. 9. The radiation image acquiring device according to claim 1, whereinthe data processing device data processing device identifies the position of the radiation source relative to the detectors. 10. The radiation image acquiring device according to claim 9,wherein the data processing device obtains the position of the radiation source from a position of a centroid of the profiles,wherein the position identification unit obtains the position of the centroid of the profile of the radiation source expressed by the count in the vertical axis and the position of the detector in the horizontal axis while designating the position of the detector with an integer counted from 0, andwherein the position identification unit sets a value obtained by rounding the position of the centroid as the position of the radiation source. 11. The radiation image acquiring device according to claim 1,wherein the radiation source is a line source,wherein the line source is disposed at an angle with respect to the y direction when the profiles in the x direction are obtained,wherein the line source is disposed at an angle with respect to the x direction when profiles in the y direction are obtained, andwherein the data processing device obtains positional information of the collimator by using Pa and Pb, obtained by:when obtaining the profiles in the x direction, obtaining the profiles in the x direction for each detector pixel position in the y direction, designating the position of the detector with an integer counted from 0, obtains the position of the centroid of the profile of the radiation source expressed by the position of the detector in the horizontal axis and the count in the vertical axis, setting a value obtained by rounding the position of the centroid as a radiation source position in the x direction, and setting average values of the profiles in which the radiation source positions are m×ix-th and m×ix+(m−1)th positions as Pa and Pb, andwherein the data processing device obtains positional information of the collimator by using Pc and the Pd, obtained by:when obtaining the profiles in the y direction, obtaining the profiles in the y direction for each detector pixel position in the x direction, designating the position of the detector with an integer counted from 0, obtains the position of the centroid of the profile of the radiation source expressed by the position of the detector in the horizontal axis and the count in the vertical axis, setting a value obtained by rounding the position of the centroid as a radiation source position in the y direction, and setting average values of the profiles in which the radiation source positions are n×iy-th and n×iy+(n−1)th positions as Pc and Pd. 12. The radiation image acquiring device according to claim 1,wherein collimator has a plurality of ceptors which define the through-holes,wherein the data processing device measures the profiles of the radiation source disposed immediately above the position of one of the ceptors of the collimator or immediately above an intermediate position between the ceptors, andwherein the data processing device obtains an asymmetry degree of the profiles, andwherein the data processing device sets an amount of movement of the collimator so as to minimize the asymmetry degree. 13. An alignment method for a radiation image acquiring device comprising:arranging a plurality of detectors to measure radiation and a collimator including a plurality of through-holes having the detectors disposed therein and configured to limit an incident direction of the radiation, so that pixels of the detectors are two-dimensionally arranged in an x direction and a y direction, where m detectors in the x direction and n detectors in the y direction (m×n detectors), where m and n are integers, are included in single ones of the through-holes of the collimator;setting an amount of movement of the collimator in the x direction such that a residual sum of squares Rx of Pa and Pb′ is less than a predetermined threshold, where:Pa denotes one of the profiles in the x direction measured when the radiation source is disposed above the m×ix-th (ix is an integer) detector pixel position in the x direction, which is designated as a position counted from 0,Pb denotes one of the profiles in the x direction measured when the radiation source is disposed above the m×ix+(m−1)th detector pixel, andPb is inverted about the detector pixel position m×ix+(m−1)/2 to obtain Pb′;moving the collimator by the set amount of movement in the x direction;setting an amount of movement of the collimator in the y direction such that a residual sum of squares Ry of Pc and Pd′ is less than the predetermined threshold, where:Pc denotes one of the profiles measured when the radiation source is disposed above the n×iy-th (iy is an integer) detector pixel position in the y direction, which is designated as a position counted from 0,Pd denotes one of the profiles measured when the radiation source is disposed above the n×iy+(n−1)th detector pixel, andPd is inverted about the detector pixel position n×iy+(n−1)/2 to obtain Pd′; andmoving the collimator by the set amount of movement in the y direction. 14. The alignment method according to claim 13, wherein the amount of movement of the collimator in the x direction is set to minimize Rx, andwherein the amount of movement of the collimator in the y direction is set to minimize Ry. 15. The alignment method according to claim 13, further comprising:estimating a positional displacement amount Dx in the x direction from Rx, an amount of positional displacement of the collimator obtained beforehand, and a graph showing a relationship of the residual sum of squares of Pa and Pb′;setting Dx as an amount of movement of the collimator in the x direction so as to minimize Rx;estimating a positional displacement amount Dy in the y direction from Ry, an amount of positional displacement of the collimator obtained beforehand, and a graph showing a relationship of the residual sum of squares of Pc and Pd′; andsetting Dy as an amount of movement of the collimator in the y direction so as to minimize Ry. 16. The alignment method according to claim 13, further comprising:providing Pa as Pa(x) which is a positional displacement x obtained by simulation in a range of −Hx/2 to Hx/2, where Hx denotes a hole pitch of the collimator in the x direction;obtaining a residual sum of squares of Pa(x) obtained by simulation and Pa obtained during positional displacement measurement;obtaining a direction of positional displacement in the x direction from the value of the positional displacement x of Pa(x) where the residual sum of squares of Pa(x) and Pa is minimized;providing Pc as Pc(y) which is a positional displacement x obtained by simulation in a range of −Hy/2 to Hy/2, where Hy denotes a hole pitch of the collimator in the y direction;obtaining a residual sum of squares of Pc(y) obtained by simulation and Pa obtained during positional displacement measurement; andobtaining a direction of positional displacement in the y direction from the value of the positional displacement y of Pc(y) where the residual sum of squares of Pc(y) and Pc is minimized. 17. The alignment method according to claim 13,wherein the positional displacement information from profiles of the radiation source in the x direction is obtained at both ends of the collimator in the y direction,wherein different movement amounts are set at both the ends of the collimator in the y direction so as to move the collimator in the x direction,wherein the positional displacement information from profiles of the radiation source in the y direction is obtained at both ends of the collimator in the x direction, andwherein different movement amounts are set at both the ends of the collimator in the x direction so as to move the collimator in the y direction. 18. The alignment method according to claim 13,wherein the radiation source is a line source,wherein the line source is disposed at an angle with respect to the y direction when the profiles in the x direction are obtained, andwherein the line source is disposed at an angle with respect to the x direction when profiles in the y direction are obtained.