Patent Number: 056688458
Section: claims

1. A computed-tomography apparatus for acquiring a cross-sectional image of an object on the basis of projection data of said object obtained by scanning said object with radiation while rotating a scanner around said object, comprising: image processing means for assigning individual weights to projection data in a predetermined rotation angle range including the vicinity of a scan start rotation position of said scanner and the vicinity of a scan end rotation position thereof and projection data in a rotation angle range opposite to said predetermined rotation angle range, respectively, determining corrected data for the entire circumference of said object by use of the projection data assigned with said weights and projection data assigned with no weight, and generating said cross-sectional image on the basis of said corrected data;  determining means for determining one of rotation positions of said scanner which has a smaller attenuation of radiation; and  scanner controlling means for controlling the operation of said scanner so that the scan is started from said rotation position having the smaller attenuation.  image processing means for assigning individual weights to projection data in a predetermined rotation angle range including the vicinity of a scan start rotation position of said scanner and the vicinity of a scan end rotation position thereof and projection data in a rotation angle range opposite to said predetermined rotation angle range, respectively, determining corrected data for the entire circumference of said object by use of the projection data assigned with said weights and projection data assigned with no weight, and generating said cross-sectional image on the basis of said corrected data;  determining means for determining one of rotation positions of said scanner which has a smaller attenuation of radiation;  position detecting means for detecting a scan start rotation position of said scanner; and  correction range adjusting means for narrowing said predetermined rotation angle range in the case where the scan start rotation position is not the rotation position having the smaller attenuation.  image processing means for generating said cross-sectional image on the basis of projection data obtained from the start of scan by said scanner until the end thereof;  a plurality of scan start rotation positions set on the locus of scan rotation of said scanner;  position detecting means for detecting said plurality of scan start rotation positions during the rotation of said scanner; and  scanner controlling means for starting the actual scan from the scan start rotation position which said position detecting means first detects after the point of time when a scan start signal is given.  determining one of rotation positions of said scanner which has a smaller attenuation of radiation;  controlling the operation of said scanner so that the scan is started from said rotation position having the smaller attenuation; and  assigning individual weights to projection data in a predetermined rotation angle range including the vicinity of a scan start rotation position of said scanner and the vicinity of a scan end rotation position thereof and projection data in a rotation angle range opposite to said predetermined rotation angle range, respectively, determining corrected data for the entire circumference of said object by use of the projection data assigned with said weights and projection data assigned with no weight, and generating said cross-sectional image on the basis of said corrected data.  determining one of rotation positions of said scanner which has a smaller attenuation of radiation;  detecting a scan start rotation position of said scanner;  assigning individual weights to projection data in a predetermined rotation angle range including the vicinity of a scan start rotation position of said scanner and the vicinity of a scan end rotation position thereof and projection data in a rotation angle range opposite to said predetermined rotation angle range, respectively, determining corrected data for the entire circumference of said object by use of the projection data assigned with said weights and projection data assigned with no weight, and generating said cross-sectional image on the basis of said corrected data; and  narrowing said predetermined rotation angle range in the case where the detected scan start rotation position is not the rotation position having the smaller attenuation.  setting a plurality of scan start rotation positions on the locus of scan rotation of said scanner;  detecting said plurality of scan start rotation positions during the rotation of said scanner;  starting the actual scan from the scan start rotation position which is first detected after the point of time when a scan start signal is given; and  generating said cross-sectional image on the basis of projection data obtained from the start of scan by said scanner until the end thereof.  determining means for determining one of rotation positions of said scanner which has a smaller attenuation of radiation; and  scanner controlling means for controlling the operation of said scanner so that the scan is started from said rotation position having the smaller attenuation.  image processing means for assigning individual weights to projection data in a predetermined rotation angle range including the vicinity of a scan start rotation position of said scanner and the vicinity of a scan end rotation position thereof and projection data in a rotation angle range opposite to said predetermined rotation angle range, respectively, determining corrected data for the entire circumference of said object by use of the projection data assigned with said weights and projection data assigned with no weight, and generating said cross-sectional image on the basis of said corrected data;  determining means for determining one of rotation positions of said scanner which has a smaller attenuation of radiation;  position detecting means for detecting a scan start rotation position of said scanner; and  correction range adjusting means for changing said predetermined rotation angle range in accordance with the scan start rotation position.  image processing means for generating said cross-sectional image on the basis of projection data obtained from the start of scan by said scanner until the end thereof;  position information provided on a rotating portion of said scanner;  position detecting means for detecting a plurality of scan start rotation positions of said scanner during the rotation of said scanner on the basis of said position information; and  scanner controlling means for starting the actual scan from the scan start rotation position which said position detecting means first detects after the point of time when a scan start signal is given.  providing position information on a rotating portion of said scanner;  detecting a plurality of scan start rotation positions of said scanner during the rotation of said scanner on the basis of said position information;  starting the actual scan from the scan start rotation position which is first detected after the point of time when a scan start signal is given; and  generating said cross-sectional image on the basis of projection data obtained from the start of scan by said scanner until the end thereof. 2. A computed-tomography apparatus according to claim 1, wherein said determining means includes storage means for holding information indicating a direction of said object which has a smaller attenuation, and when information concerning the orientation of said object relative to said scanner is given, said determining means determines said rotation position having the smaller attenuation on the basis of said information. 3. A computed-tomography apparatus according to claim 1, wherein said determining means determines said rotation position having the smaller attenuation on the basis of projection data obtained when said object is scanned by said scanner. 4. A computed-tomography apparatus according to claim 3, wherein said determining means includes means for determining an average value of projection data obtained through the scan of a predetermined rotation angle range, said determining means determining said rotation position having the smaller attenuation by comparing projection data in a plurality of predetermined different rotation angle ranges. 5. A computed-tomography apparatus according to claim 1, further comprising position detecting means for detecting a scan start rotation position of said scanner, wherein four scan start rotation positions are set on the locus of scan rotation of said scanner at the intervals of 90.degree. rotation angle, said determining means determines one of said four scan start rotation positions having the smallest attenuation, and said scanner controlling means starts the measurement when said position detecting means detects the scan start rotation position having the smallest attenuation. 6. A computed-tomography apparatus for acquiring a cross-sectional image of an object on the basis of projection data of said object obtained by scanning said object with radiation while rotating a scanner around said object, comprising: 7. A computed-tomography apparatus according to claim 6, wherein said determining means includes storage means for holding information indicating a direction of said object which has a smaller attenuation, and when information concerning the orientation of said object relative to said scanner is given, said determining means determines said rotation position having the smaller attenuation on the basis of said information. 8. A computed-tomography apparatus according to claim 6, wherein said determining means determines said rotation position having the smaller attenuation on the basis of projection data obtained when said object is scanned by said scanner. 9. A computed-tomography apparatus according to claim 8, wherein said determining means includes means for determining an average value of projection data obtained through the scan of a predetermined rotation angle range, said determining means determining said rotation position having the smaller attenuation by comparing projection data in a plurality of predetermined different rotation angle ranges. 10. A computed-tomography apparatus according to claim 6, wherein four scan start rotation positions are set on the locus of scan rotation of said scanner at the intervals of 90.degree. rotation angle, said determining means determines one of said four scan start rotation positions having the smallest attenuation, and said correction range adjusting means includes means for judging whether or not the actual scan start rotation position detected by said position detecting means is said scan start rotation position having the smallest attenuation. 11. A computed-tomography apparatus for acquiring a cross-sectional image of an object on the basis of projection data of said object obtained by scanning said object with radiation while rotating a scanner around said object, comprising: 12. A control method in a computed-tomography apparatus for acquiring a cross-sectional image of an object on the basis of projection data of said object obtained by scanning said object with radiation while rotating a scanner around said object, comprising the steps of: 13. A control method in a computed-tomography apparatus for acquiring a cross-sectional image of an object on the basis of projection data of said object obtained by scanning said object with radiation while rotating a scanner around said object, comprising the steps of: 14. A control method in a computed-tomography apparatus for acquiring a cross-sectional image of an object on the basis of projection data of said object obtained by scanning said object with radiation while rotating a scanner around said object, comprising the steps of: 15. A computed-tomography apparatus for acquiring a cross-sectional image of an object on the basis of projection data of said object obtained by scanning said object with radiation while rotating a scanner around said object, comprising: 16. A computed-tomography apparatus according to claim 15, wherein said determining means includes storage means for holding information indicating a direction of said object which has a smaller attenuation, and when information concerning the orientation of said object relative to said scanner is given, said determining means determines said rotation position having the smaller attenuation on the basis of said information. 17. A computed-tomography apparatus according to claim 15, wherein said determining means determines said rotation position having the smaller attenuation on the basis of projection data obtained when said object is scanned by said scanner. 18. A computed-tomography apparatus according to claim 17, wherein said determining means includes means for determining an average value of projection data obtained through the scan of a predetermined rotation angle range, said determining means determining said rotation position having the smaller attenuation by comparing projection data in a plurality of predetermined different rotation angle ranges. 19. A computed-tomography apparatus according to claim 15, further comprising position detecting means for detecting a scan rotation position of said scanner, wherein four scan start rotation positions are set on the locus of scan rotation of said scanner at the intervals of 90.degree. rotation angle, said determining means determines one of said four scan start rotation positions having the smallest attenuation, and said scanner controlling means starts the measurement when said position detecting means detects the scan start rotation position having the smallest attenuation. 20. A computed-tomography apparatus according to claim 15, further comprising position detecting means for detecting a scan rotation position of said scanner. 21. A computed-tomography apparatus according to claim 20, wherein two scan start rotation positions are set on the locus of scan rotation of said scanner at the intervals of approximately 90.degree. rotation angle, said determining means determines one of said two scan start rotation positions having the smaller attenuation, and said scanner controlling means starts the measurement when said position detecting means detects the scan start rotation position having the smaller attenuation. 22. A computed-tomography apparatus for acquiring a cross-sectional image of an object on the basis of projection data of said object obtained by scanning said object with radiation while rotating a scanner around said object, comprising: 23. A computed-tomography apparatus for acquiring a cross-sectional image of an object on the basis of projection data of said object obtained by scanning said object with radiation while rotating a scanner around said object, comprising: 24. A computed-tomography apparatus according to claim 23, wherein said position detecting means sets a number of the scan start rotation positions in accordance with a length of a scan rotation time of said scanner. 25. A control method in a computed-tomography apparatus for acquiring a cross-sectional image of an object on the basis of projection data of said object obtained by scanning said object with radiation while rotating a scanner around said object, comprising the steps of: