FI61803C - STRAOLNINGSENERGIAPPARAT - Google Patents

Description

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Jna LbJ (11) utläggningsskrift o i o U .5 c Patent M ®yonn ott.y II 10 1932

Patent aoddelat (si) Kv.ik.3 / int.ci.3 A 61 B 6/00, 6/02 7727 ^ 0 ENGLISH —Fl N LAN D (21) PMentUhtkemu · - PMMOraeimlnt (22) H »k * ml * cloud «—AiwMcnlngidtf l6.09.77 (23) AlkupHvi — Glkl | k« adtg l6.09.77 (41) Tullut | ulklMk * l - Graters effmcltg 26.03.78

Patent and Registry Office »/ 44) NihtiviiuipMMii | * kuL | uiktiwndvm. - 30.06.82

Patent · och regitterstyrelaen AmMcm uthgd och utUkrUtM pubiicund (32) (33) (31) requested «TuoUtotii — Baglrd priorhet 27 · 09 · 76 U.S. Pat.

Cambridge, Massachusetts 02139, USA (72) Jay Alan Stein, Framingham, Massachusetts, Lawrence Alan Shepp,

This invention relates generally to imaging by radiant energy, and more particularly to a radiant energy device comprising a fan-shaped radiation source of transmissive radiant energy disposed outside the imaging region of the imaging region. a row of radiating energy detecting means positioned opposite the axis of rotation for converting the transmitted transmitting radiant energy into a series of corresponding detected signals representing the area between the source and the row.

Various methods and measurement geometries can be used for high-speed computed tomography. One technique uses an X-ray source and an array of detectors that are fixed to each other and moved past the patient. The beam fan that hits the detector row produces a fan of measurements from different angles at each given moment. During the transition, each detector memorizes a series of parallel measured values at one of these angles. In order to obtain the measured values from the new angle group, the structural difference between the radiation source and the detectors is rotated and then shifted again. The advantages of this two-movement technique are: 2 61803 (1) high sampling separation, as each detector can take a sample multiple times as it sweeps past the patient, (2) no coordination factor need to be coordinated because each detector sweeps over the entire patient, and (3) for calibration before and after each sweep. The disadvantages are: (1) the inertia due to the mechanical limitations of the two-motion technique, and (2) the small fan-like beam angle required to allow faster transition and which wastes usable X-rays.

Another scanning method, in turn, uses a fan-shaped beam source and detector rows fixed relative to each other, but the structure is rotated around the patient without any transfer movement. Each detector records the X-ray measurement values tangential to a particular circle. This single-motion method has the advantages of: (1) high sweep speeds because only one mechanical motion is required, and (2) the ability to use a large fan angle. However, its disadvantages are (1) the low sampling resolution due to the large number of small, close-up detectors required for accurate sampling, (2) the need to coordinate gain factors because each detector does not sweep over the entire patient, and (3) the inability to occur frequently. calibration, as calibration may only occur after the patient has been removed, as not every indicator sweeps over the entire patient.

The main object of the present invention is to provide a new and improved computer-based tomography system.

Another object of the present invention is to achieve the above object with a system which implements high sampling separation.

Yet another object of the present invention is to provide one or more of the above objects with a system which does not require precise coordination of the gain between the detectors.

Yet another object of the present invention is to accomplish one or more of the above purposes with a system that allows frequent calibration of detectors.

Yet another object of the present invention is to provide one or more of the above objects with a system for performing a fast scan.

Yet another object of the present invention is to realize one of the above 61,683 or more purposes with a system capable of using an X-ray fan-shaped jet with a wide angle.

The radiant energy device of the present invention is characterized in that the row of detectors covers a substantial portion of a complete circle about the axis and has means for relatively rotating the source and row relative to the axis by holding either source or row substantially in place in the same direction. .

Numerous other features, features and advantages of the invention will become apparent from the appended claims and the following description, with reference to the accompanying drawings, in which: Figure 1 is a combined block diagram and schematic diagram of a rotating X-ray source and stationary detector array is recorded by one detector during one revolution of the X-ray source.

Referring now to these drawings, and in particular to Figure 1 thereof, there is shown a combined block diagram and schematic diagram of a rotating X-ray source and a stationary detector row structure. The X-ray source 11 orbits the axis 12 and emits X-rays of a fan-shaped beam 13 at a certain angle wide enough to illuminate the patient's circle 14 centered on the axis 12. As the X-ray source 11 rotates, the fan-like beam 16 illuminates the beam 13 illuminates a continuous array of adjacent individual detectors 16 while simultaneously providing a corresponding number of detected electrical signals, each representing X-ray transmission between the radiation source 11 and the corresponding detector 16. The signal processing devices 17 are connected to the detectors 16, combining these detected output signals to provide an image of a representative signal of X-ray transmittance in a patient cross section within a particular patient circle 14 that has just been scanned. The image forming parts 21 operate on the basis of this image signal, providing a visible image of the scanned cross section. This scanning system and the patient are axially displaceable relative to each other to produce cartoons of respective axially spaced slices.

4 61803

Referring now to Figure 2, there is shown a graphical representation of the geometry showing the alternation order of the radiation directions 22 between the radiation source 11 and one of the detectors 16 'during one revolution of the X-ray source 11. The detector 16 * is illuminated by a fan-like beam 13 of a certain part of the rotation of the X-ray source 11.

As the X-ray source 11 moves past this portion of the cycle, the detector 16 'receives radiation primarily along a series of directions 22 as the radiation source 11 moves along a particular arc defining a certain angle, encompassing the entire patient circle 14. A corresponding alternation occurs for each of the detectors 16. within 11 rounds of a complete X-ray source. The signal processing devices 17 combine the signal from all the detectors 16 to obtain a cross-sectional image signal of good quality or a tomogram transverse to the axis, according to methods known per se using computer processing. The imaging devices 21 display the tomogram for viewing.

The invention has a number of features that allow it to generate high quality computer-based tomograms without the disadvantages of other systems. The present invention provides a high sampling resolution because each detector 16 can be tested numerous times as the radiation source 11 rotates around the patient. Precise adjustment of the gain factor is not required because each detector 16 collects data from the patient's cross section. The oblique fit of the gain coefficients results in only a small DC voltage setting on the final reconstructed image.

Another advantageous feature is that calibration of the detectors 16 can be performed during each sweep so that removal of the patient is not necessary for each calibration and frequent calibration is possible.

Other advantageous features include rapid data acquisition resulting from a single need for mechanical movement (rotation of the radiation source 11) and the advantage of using a large angle to the fan-like beam 13, which reduces the loss of usable X-rays and allows more efficient data collection. A high rate of data collection is desirable to eliminate the effects of patient breathing and other body movements.

In an exemplary embodiment of the present invention, which is actually constructed and has been successfully used to develop high resolution tomograms, 600 separate evenings were used in a row illuminated by an X-ray fan-like jet 5 61803 spread at an angle of substantially 50 degrees about a certain axis of rotation mm along that axis in width. An X-ray source with an energy of up to 150 kV and 100 mA was used, which was able to perform a rotation sweep in 5, 10 or 20 seconds. The computer was a Data General Eclipse-type computer that combined 600 expressed output signals converted to digital form with analog / digital converters using the methods described by the State University of New York at Buffalo Computer Scientes Dept. Technical Report No. 92, published in January 1975 and entitled "Reconstruction from Divergent Ray Data" by A. V. Lakshminarayanan.

When the radiation source rotates with the patient and the circular detector row remains in place, the arrangement should be considered the most preferred embodiment of the invention, but still the principles of this invention include allowing the X-ray source to remain stationary and rotating the subject and detectors together.

The new radiation energy system now presented is characterized by high resolution, very fast data collection, and other features that are desirable in a computer-based tomography system. It will be apparent that one skilled in the art will now be able to implement numerous applications and modifications, other than the embodiments specifically described herein, without departing from the principles of the present invention. Accordingly, the invention will incorporate each of the novel features and new combinations of those features contained in this apparatus and methods that are set forth and are limited only by the scope and spirit of the appended claims.

Claims (5)

6 61 8 G 3 A radiant energy device comprising a fan-shaped radiation source (11) of transmissive radiant energy (13) located outside the imaging region (14), a row (15) of adjacent radiant energy detecting means (16) located opposite the axis of rotation (12) to convert the relevant transmitting radiant energy into a series of corresponding detected signals representing the area between the source (11) and the row (15), characterized in that the row of detectors covers a substantial part of a complete circle around the axis and has means for relatively rotating the source (11) and rows (15) with respect to the axis (12) by holding either source or row substantially in place to sequentially illuminate different groups of detector members, in the same direction of rotation with respect to the axis. Radiation energy device according to claim 1, characterized in that it comprises parts (17) for combining all detected signals to form an image signal, and parts (21) which, depending on this image signal, provide an image representative of the response of said radiation energy. Radiant energy device according to claim 1, characterized in that the detector row (15) surrounds the axis of rotation (12) and that the radiation source (11) is located inside this detector row, but at a certain distance from said axis (12). Radiant energy device according to claim 3, characterized in that the detector row (15) is circular with its center on said axis (12) and the relative displacement groove between the radiation source (11) and the detector row (15) is circular inside and concentric with said detector row. Radiant energy device according to Claim 4, characterized in that the detector row (15) is stationary and that the radiation source (11) rotates about an axis. .1. · ·