| 主权项 |
1. A method for generating an approximate function of a total modulation transfer function (MTF) of an x-ray image of an object, based on conditions for imaging with an x-ray emitted by an x-ray tube, the total MTF indicating a resolution characteristic of the x-ray image, the x-ray image being obtained by imaging the object which is a predetermined part of a human body with a motion, the method comprising:
an obtaining step of obtaining imaging condition combinations for the x-ray and conditions for the human body at a time of imaging, the imaging condition combinations including a magnification ratio obtained by dividing a distance between an x-ray tube focal plane and an x-ray detector system plane by a distance between the x-ray tube focal plane and an object plane, an x-ray tube nominal focal spot value, a tube voltage, a tube current, imaging time, and a kind of an x-ray detector system, the conditions for the human body including a kind of the object, a state of the object, a maximum amount of motion of the human body, and time required for an amount of motion of the human body to reach the maximum amount of motion of the human body; a first generating step of (i) generating an approximate function of an MTF based on an x-ray tube effective focal spot value on the x-ray tube focal plane by checking an imaging condition combination of the x-ray tube nominal focal spot value, the tube voltage, and the tube current among the imaging condition combinations obtained in the obtaining step, against a predefined first correspondence relation between the imaging condition combination of the x-ray tube nominal focal spot value, the tube voltage, and the tube current and values in the approximate function of the MTF based on the x-ray tube effective focal spot value on the x-ray tube focal plane, and (ii) converting, using the magnification ratio, the approximate function generated into an approximate function of an MTF based on the x-ray tube effective focal spot value on the object plane; a second generating step of (i) generating an approximate function of an MTF based on the kind of an x-ray detector system on the x-ray detector system plane by checking the kind of the x-ray detector system among the imaging condition combinations obtained in the obtaining step, against a predefined second correspondence relation between the kind of the x-ray detector system and values in the approximate function of the MTF based on the kind of the x-ray detector system on the x-ray detector system plane, and (ii) converting, using the magnification ratio, the approximate function generated into an approximate function of an MTF based on the kind of the x-ray detector system on the object plane; a third generating step of generating an approximate function of an MTF based on an amount of motion of the object, the amount of motion of the object being determined by: (a) a maximum amount of motion made by an organ in the object, (b) time required for an amount of motion made by the organ in the object to reach the maximum amount of motion made by the organ in the object, (c) the imaging time, (d) the maximum amount of motion of the human body, and (e) the time required for the amount of motion of the human body to reach the maximum amount of motion of the human body, (a) the maximum amount of motion made by an organ in the object and (b) the time required for an amount of motion made by the organ in the object to reach the maximum amount of motion made by the organ in the object being obtained by checking the kind of the object and the state of the object obtained in the obtaining step against a predefined third correlation relation between (i) the kind of the object and the state of the object and (ii) the maximum amount of motion made by the organ in the object and the time required for the amount of motion made by the organ in the object to reach the maximum amount of motion made by the organ in the object; and a fourth generating step of generating an approximate function of a total MTF by multiplying the approximate function of the MTF based on the x-ray tube effective focal spot value on the object plane, the approximate function of the MTF based on the kind of the x-ray detector system on the object plane, and the approximate function based on the amount of motion of the object on the object plane, wherein values in the approximate function of the MTF based on the x-ray tube effective focal spot value on the x-ray tube focal plane in the first correspondence relation are values predetermined for each imaging condition combination of the x-ray tube nominal focal spot value, the tube voltage, and the tube current, so that a function which indicates the MTF based on the x-ray tube effective focal spot value on the x-ray tube focal plane approximates to a measured MTF based on the x-ray tube effective focal spot value for each imaging condition combination of the x-ray tube nominal focal spot value, the tube voltage, and the tube current on the x-ray tube focal plane in a spatial frequency domain on the x-ray tube focal plane calculated by setting the magnification ratio to be a value within a predetermined range and setting a spatial frequency domain which has a spatial frequency on the object plane to be a predetermined spatial frequency domain, values in the approximate function of the MTF based on the kind of the x-ray detector system on the x-ray detector system plane in the second correspondence relation are values predetermined for each kind of the x-ray detector system, so that a function which indicates the MTF based on the kind of the x-ray detector system on the x-ray detector system plane approximates to a measured MTF for each kind of the x-ray detector system on the x-ray detector system plane in a spatial frequency domain on the x-ray detector system plane calculated by setting the magnification ratio to be a value within a predetermined range and setting a spatial frequency domain which has a spatial frequency on the object plane to be a predetermined spatial frequency domain, and the amount of motion of the object is: an amount of motion expressed as a product of the imaging time and a sum of an amount of motion of the human body per second and an amount of motion made by the organ per second when time required for the amount of motion of the human body to reach a maximum amount of motion of the human body is longer than the imaging time and time required for the amount of motion made by the organ to reach a maximum amount of motion made by the organ is longer than the imaging time; an amount of motion expressed as a sum of (i) a product of the imaging time and an amount of motion of the human body per second and (ii) a maximum amount of motion made by the organ when time required for the amount of motion of the human body to reach a maximum amount of motion of the human body is longer than the imaging time and time required for the amount of motion made by the organ to reach a maximum amount of motion made by the organ is shorter than the imaging time; an amount of motion expressed as a sum of (i) a maximum amount of motion of the human body and (ii) a product of the imaging time and an amount of motion made by the organ per second when time required for the amount of motion of the human body to reach a maximum amount of motion of the human body is shorter than the imaging time and time required for the amount of motion made by the organ to reach a maximum amount of motion made by the organ is longer than the imaging time; and an amount of motion expressed as a sum of a maximum amount of motion of the human body and a maximum amount of motion made by the organ when time required for the amount of motion of the human body to reach a maximum amount of motion of the human body is shorter than the imaging time and time required for the amount of motion made by the organ to reach a maximum amount of motion made by the organ is shorter than the imaging time. |
