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| United States Patent | 4044240 |
| Link to this page | http://www.wikipatents.com/4044240.html |
| Inventor(s) | Cox, Jr.; Jerome P. (St. Louis, MO);
Gerth, Jr.; Vernon W. (Kirkwood, MO) |
| Abstract | A transverse section tomography system has an ultra-high-speed data
processing unit for performing back projection and updating. An X-ray
scanner directs X-ray beams through a planar section of a subject from a
sequence of orientations and positions. The scanner includes a movably
supported radiation detector for detecting the intensity of the beams of
radiation after they pass through the subject. The detector generates a
series of scan data signals representative of the detected intensities.
The data processing unit is coupled to the scanner and operates on the
scan data signals to produce a set of filtered scan data signals
representative of the contribution of each of the scan data signals
towards reconstructing an image of the planar section of the subject.
The data processing unit includes a scan storage section for retrievably
storing the filtered scan signals in scan storage locations corresponding
to predetermined beam orientations. An array storage section is provided
for storing image signals as they are generated. The image signals are
stored in array storage locations coordinated with a preselected array of
points of the planar section. The image signals are each successively
updated to eventually represent the density of the planar section at each
of the selected array of points. The processing unit also includes array
storage and scan storage address calculators. The array storage address
calculator determines, on a row-by-row basis, the addresses of the array
storage locations corresponding to points of the planar section. The scan
storage address calculator calculates the addresses of the scan storage
locations containing the filtered scan signals which contribute to the
reconstruction of the image at the points determined by the array storage
address calculator. A reconstruction updating unit is provided for
combining the addressed filtered scan signal with the addressed image
signal to provide the updated image signal. According to one feature, a
control unit is provided for operating the scan storage address calculator
concurrently with the array storage address calculator for minimizing
overall data processing time. According to another feature, the array
storage section is equipped with addressing and data transfer circuitry
which is operated concurrently with at least one of the address
calculators for writing the updated image signal into the appropriate
array storage location. |
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Title Information  |
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Drawing from US Patent 4044240 |
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Tomography system having an ultra high speed processing unit |
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| Publication Date |
August 23, 1977 |
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| Filing Date |
November 28, 1975 |
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Title Information |
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References |
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| *references marked with an asterisk below are user-added references |
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U.S. References |
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| | Reference | Relevancy | Comments | Reference | Relevancy | Comments | 3946234
Hounsfield
378/14
Mar,1976 |  Your vote accepted
[0 after 0 votes] | | 3936636
Percival
250/336.1
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Hounsfield
378/11
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Blum
250/303
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Muehllehner
250/369
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Cesar
378/27
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Foreign References |
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Other References |
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Public's "Guesstimation" of Royalty Value
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Market Review |
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Technical Review |
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Claims |
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What is claimed is:
1. A transverse section tomography system for providing a reconstructed
image of a planar section of a subject, comprising:
a. a movably supported radiation detector for detecting radiation which has
passed through the planar section of the subject and for generating a
sequence of scan data signals indicative of the intensity of the radiation
after it has passed through the subject, said scan data signals being
generated at predetermined orientations and positions whereby detection of
the radiation at a given orientation and position defines a scan element
and detection of the radiation at all predetermined orientations and
positions defines a scan cycle; and,
b. data processing means responsive to the sequence of scan data signals
for generating a set of repeatedly updated, elemental image signals
characterizing structure of the planar section of the subject, said data
processing means including:
i. input storage means for storing the respective scan data signals in
particular input storage locations;
ii. filter processing means coupled to the input storage for successively
retrieving the scan data signals from the input storage locations of the
filter processing means and for producing filtered scan signals from the
retrieved scan data signals which are representative of the reconstructed
image contribution of each of the scan data signals;
iii. scan storage means for retrievably storing the filtered scan signals
in scan storage locations corresponding to scan elements occurring at
predetermined orientations during the scan cycle;
iv. array storage means for storing as they are generated, elemental image
signals which are to be repeatedly updated; the elemental image signals
being stored in array storage locations coordinated with a preselected
array of points of said planar section;
v. an array storage address calculator for addressing a selected array
storage location containing the elemental image signal corresponding to a
selected one of said preselected points of the planar section;
vi. a scan storage address calculator for addressing the scan storage
location containing the filtered scan signal corresponding to a given scan
element which resulted in the detection of radiation sufficiently near
said selected point to contribute to the reconstruction of the image at
said selected point;
vii. updating means for combining the addressed filtered scan signal with
the addressed elemental image signal to provide one of the updated,
elemental image signals; and,
viii. a controller coupled to the storage address calculators for operating
them concurrently.
2. The scanning system according to claim 1 and further including
addressing means operable concurrently with at least one of said address
calculators for writing said one elemental image signal into one of the
array storage locations.
3. The scanning system according to claim 2 wherein the addressing means is
operated to write said one elemental image signal into the array storage
location corresponding to said selected point.
4. The scanning system according to claim 1 wherein said controller
includes a memory unit for storing a sequence of program words which
characterize at least partial operation of the data processing means.
5. In a transverse section tomography system for providing a reconstructed
image of a planar section of a subject and having a radiation detector for
detecting radiation which has passed through the planar section of the
subject and for generating a sequence of scan data signals indicative of
the intensity of the radiation after it has passed at predetermined
orientations and positions through the subject, whereby detection of the
radiation at a given orientation defines a scan element and detection of
the radiation through all predetermined orientations and positions defines
a scan cycle, and further having data processing means responsive to the
sequence of scan data signals for generating repeatedly updated elemental
image signals which eventually characterize structure of the planar
section of the subject, the improvement wherein the data processing means
comprises:
a. input storage means for storing the respective scan data signals in
particular input storage locations;
b. filter processing means coupled to the input storage for successively
retrieving the scan data signals from the input storage locations and for
producing therefrom filtered scan signals representative of the
reconstructed image contribution of each of the scan data signals;
c. scan storage means for retrievably storing the filtered scan signals in
scan storage locations corresponding to scan elements occurring at
predetermined orientations during the scan cycle;
d. array storage means for storing as they are generated, the elemental
image signals which are to be updated; the storing being in array storage
locations coordinated with a preselected array of points of said planar
section;
e. an array storage address calculator for addressing a selected array
storage location containing the elemental image signal corresponding to a
selected one of said preselected points of the planar section;
f. a scan storage address calculator for addressing the scan storage
location containing the filtered scan signal corresponding to a given scan
element which resulted in the detection of radiation sufficiently near
said selected point to contribute the reconstruction of the image at said
selected point;
g. updating means for combining the addressed filtered scan signal with the
addressed elemental image signal to provide the updated, elemental image
signal; and,
h. addressing means coupled to the updating means and operable concurrently
with at least one of said address calculators for writing said updated,
elemental image signal into a location in said array storage.
6. The improved tomography system according to claim 5 wherein the
addressing means is configured to write said updated, elemental image
signal into the array storage location corresponding to said selected
point.
7. The improved tomography system according to claim 5 and further
including control means coupled to the address calculators for operating
them concurrently.
8. The improved tomography system according to claim 7 wherein the control
means includes a memory unit for storing a sequence of program words which
characterize at least partial operation of the data processing means.
9. A transverse section tomographic scanning system for providing a
reconstructed image of a planar section of a subject, comprising:
a. a scanner for directing at least one beam of X-radiation of relatively
small cross-section through a plane of the subject from a succession of
predetermined orientations and positions coplanar with said plane and for
generating a sequence of scan data signals indicative of the intensity of
the beam of radiation after it has passed through the subject, whereby
passing the beam through the subject at a given orientation and position
defines a scan element and passing the beams through all predetermined
orientations and positions defines a scan cycle; and,
b. data processing means responsive to the sequence of scan data signals
for generating a set of repeatedly updated, elemental image signals
characterizing structure of the planar section of the subject, said data
processing means including:
i. input storage means for storing the respective scan data signals in
particular input storage locations;
ii. filter processing means coupled to the input storage for successively
retrieving the scan data signals from the input storage locations, the
filter processing means producing filtered scan signals from the retrieved
scan data signals which are representative of the reconstructed image
contribution of each of the scan data signals;
iii. scan storage means for retrievably storing the filtered scan signals
in scan storage locations corresponding to scan elements occurring at
predetermined orientations during the scan cycle;
iv. array storage means for storing, as they are generated, the elemental
image signals which are to be repeatedly updated; the storing being in
array storage locations coordinated with a preselected array of points of
said planar section;
v. an array storage address calculator for addressing a selected array
storage location containing the elemental image signal corresponding to a
selected one of said preselected points of the planar section;
vi. a scan storage address calculator for addressing the scan storage
location containing the filtered scan signal corresponding to a given scan
element which resulted in the passage of radiation sufficiently near said
selected point to contribute to the reconstruction of the image at said
selected point;
vii. updating means for combining the addressed filtered scan signal with
the addressed elemental image signal to provide an updated elemental image
signal; and,
viii. a controller coupled to the scan storage address calculator and the
array storage address calculator for operating them concurrently.
10. The scanning system according to claim 9 and further including
addressing means operable concurrently with at least one of said address
calculators for writing said updated, elemental image signal into the
array storage location corresponding to said selected point.
11. The scanning system according to claim 9 wherein the controller
includes a memory unit for storing a sequence of program words which
characterize at least in part the operations of the data processing means.
12. A transverse section tomographic scanning system for providing a
reconstructed image of a planar section of a subject, comprising:
a. a scanner for directing at least one beam of X-radiation of relatively
small cross-section through a plane of the subject from a succession of
predetermined orientations and positions coplanar with said plane and for
generating a sequence of scan data signals indicative of the intensity of
the beam of radiation after it has passed through the subject, whereby
passing the beam through the subject at a given orientation and position
defines a scan element and passing the beams through all predetermined
orientations and positions defines a scan cycle; and,
b. data processing means responsive to the sequence of scan data signals
for generating repeatedly updated, elemental image signals characterizing
structure of the planar section of the subject, said data processing means
including:
i. input storage means for storing the respective scan data signals in
particular input storage locations;
ii. filter processing means coupled to the input storage for successively
retrieving the scan data signals from the input storage locations, the
filter processing means producing filtered scan signals from the retrieved
scan data signals which are representative of the reconstructed image
contribution of each of the scan data signals;
iii. scan storage for retrievably storing the filtered scan signals in scan
storage locations corresponding to scan elements occurring at
predetermined orientations during the scan cycle;
iv. array storage means for operably storing, as the are generated and for
operably providing, the elemental image signals which are to be repeatedly
updated; the storing being in array storage locations coordinated with a
preselected array of points of said planar section;
v. an array storage address calculator for addressing a selected array
storage location containing the elemental image signal corresponding to a
selected one of said preselected points of the planar section;
vi. a scan storage address calculator for addressing the scan storage
location containing the filtered scan signal corresponding to a given scan
element which resulted in the passage of radiation sufficiently near said
selected point to contribute to the reconstruction of the image at said
selected point;
vii. updating means for combining the addressed filtered scan signal with
the addressed elemental image signal to provide the updated elemental
image signal; and,
viii. addressing means coupled to the updating means and operable
concurrently with at least one of said address calculators for operating
the array storage means.
13. The scanning system according to claim 12 wherein the addressing means
is structured to write said updated, elemental image signal into the array
storage location corresponding to said one point.
14. A transverse section tomographic scanning system for providing a
reconstructed image of a planar section of a subject, comprising:
a. a scanner for directing at least one beam of X-radiation of relatively
small cross-section through a plane of the subject from a succession of
positions coplanar with said plane about the subject, the scanner
including:
i. generator means for axially producing the at least one beam in said
plane;
ii. detector means for detecting the at least one beam and producing scan
data signals indicative of the intensity of the beam of radiation after
the beam has passed at predetermined scan orientations and positions
through the subject; and,
iii. support means for relatively moving the generator means and the
detector means about the subject for passing the beam through the subject
at said predetermined orientations and positions, whereby the passage of
the beam through a given orientation and positions defines a scan element
which produces the associated scan data signal, and passing the beam
through all said predetermined orientations and positions defines a scan
cycle;
b. a first data processor having:
i. input storage means for storing the respective scan data signals in
particular input storage locations;
ii. filter processing means coupled to the input storage for successively
retrieving the scan data signals and for producing therefrom filtered scan
signals representative of the contribution of each of the scan data
signals towards reconstructing said image;
iii. scan storage means for retrievably storing the filtered scan signals
in groups of scan storage locations respectively corresponding to each
scan element occurring at predetermined orientations during the scan
cycle; and,
iv. array storage means for storing, as they are produced, elemental image
signals in array storage locations;
c. a second data processor operated in association with said first data
processor and responsive to said filtered scan signals for producing
elemental image signals, said elemental image signals each being
successively updated to eventually represent the density at each of a
preselected array of points of said planar section, the second data
processor including:
i. an array storage address calculator for generating an array storage
address signal which specifies the array storage location containing a
particular elemental image signal corresponding to a selected point of the
planar section;
ii. a scan storage address calculator for generating a scan storage address
signal for specifying the scan storage location containing a particular
filtered scan signal corresponding to a given scan element which resulted
in the passage of an X-ray beam sufficiently near said selected point to
contribute to the reconstruction of the image at said selected point;
iii. scan addressing means responsive to said scan storage address signals
for addressing the scan storage means to provide said particular filtered
scan signal;
iv. array addressing means responsive to said array storage address signals
for addressing the array storage means to provide said particular
elemental image signals;
v. updating means for combining the particular filtered scan signal with
the particular elemental image signal to provide the updated, elemental
image signal;
vi. said array addressing means also being responsive to said updated,
elemental image signal for writing it into a selected array storage
location; and,
vii. a controller coupled to the scan storage address calculator and to the
array storage address calculator for operating them concurrently.
15. The scanning system according to claim 14 wherein said array addressing
means is structured to write said updated, elemental image signal into the
array storage location corresponding to said selected point.
16. The scanning system according to claim 14 wherein the controller
includes a programmable memory unit for storing a sequence of program
words which characterize operation of the second data processor.
17. A transverse section tomographic scanning system for providing a
reconstructed image of a planar section of a subject, comprising:
a. a scanner for directing at least one beam of X-radiation of relatively
small cross-section through a plane of the subject from a succession of
positions coplanar with said plane about the subject, the scanner
including:
i. generator means for axially producing the at least one beam in said
plane;
ii. detector means for detecting the at least one beam and producing scan
data signals indicative of the intensity of the beam of radiation after
the beam has passed at predetermined scan orientations and positions
through the subject; and,
iii. support means for relatively moving the generator means and the
detector means about the subject for passing the beam through the subject
at said predetermined orientations and positions, whereby the passage of
the beam through a given orientation and position defines a scan element
which produces the associated scan data signal, and passing the beam
through all said predetermined orientations and positions defines a scan
cycle;
b. a first data processor having:
i. input storage means for storing the respective scan data signals in
particular input storage locations;
ii. filter processing means coupled to the input storage for successively
retrieving the scan data signals and for producing therefrom filtered scan
signals representative of the contribution of each of the scan data
signals towards reconstructing said image;
iii. scan storage means for retrievably storing the filtered scan signals
in groups of scan storage locations respectively corresponding to each
scan element occurring at predetermined orientations during the scan
cycle; and,
iv. array storage means for storing, as they are produced, elemental image
signals in array storage locations;
c. a second data processor operated in association with said first data
processor and responsive to said filtered scan signals for producing
elemental image signals, said elemental image signals each being
successively updated to eventually represent the density at each of a
preselected array of points of said planar section, the second data
processor including:
i. an array storage address calculator for generating an array storage
address signal which specifies the array storage location containing a
particular elemental image signal corresponding to a selected point of the
planar section;
ii. a scan storage address calculator for generating a scan storage address
signal for specifying the scan storage location containing a particular
filtered scan signal corresponding to a given scan element which resulted
in the passage of an X-ray beam sufficiently near said selected point to
contribute to the reconstruction of the image at said selected point;
iii. scan addressing means responsive to said scan storage address signals
for addressing the scan storage means to provide said particular filtered
scan signal;
iv. array addressing means responsive to said array storage address signals
for addressing the array storage means to provide said particular
elemental image signals;
v. updating means for combining the particular filtered scan signal with
the particular elemental image signal to provide the updated, elemental
image signal;
vi. said array addressing means also being responsive to said updated,
elemental image signal for writing it into a selected array storage
location;
vii. a controller for operating said array addressing means concurrently
with at least one of said address calculators.
18. The scanning system according to claim 17 wherein the array addressing
means is structured to write said updated, elemental image signal into the
array storage location corresponding to said selected point.
19. The scanning system according to claim 17 wherein the controller
includes a memory unit for storing a sequence of program words which
characterize operation of the second data processor.
20. The scanning system according to claim 17 wherein the updating means
includes:
a. an arithmetic unit for performing arithmetic operations on values of the
filtered scan signal and on the elemental image signal; and,
b. a detector coupled to the arithmetic unit for detecting, during the
arithmetic operations on the filtered scan and the elemental image
signals, simultaneously whether overflow or underflow conditions have
occurred.
21. The scanning system according to claim 17 wherein said first data
processor includes a control unit operable concurrently with said
controller, whereby said data processor can operate concurrently with said
second data processor.
22. The scanning system according to claim 21 wherein there is direct
memory access by the second data processor to the storage means of the
first data processor and said second data processor comprises contention
circuitry for assigning control of memory access to either the first data
processor or to the second data processor.
23. The scanning system according to claim 22 wherein the contention
circuitry is structured to assign priority to the second data processor
whenever both data processors seek memory access to the storage means.
24. In a tomographic scanning system for providing a reconstructed image of
a planar section of a subject which is relatively scanned from a plurality
of predetermined scan orientations and positions by X-radiation, a method
of providing elemental image signals which are successively updated and
stored to represent the reconstructed image, comprising the steps of:
a. defining at least one beam of X-radiation having a relatively small
cross-section;
b. directing the at least one beam through a plane of the subject from a
succession of orientations and positions coplanar with the plane, whereby
passing the beam through a given orientation and position defines a scan
element and passing the beam through all the predetermined orientations
and positions defines a scan cycle;
c. detecting the intensity of the beam after it passes through the subject
at the succession of positions;
d. generating a sequence of scan data signals representative of the
intensity of the detected radiation corresponding to each scan element;
e. storing the respective scan data signals in input storage locations;
f. filtering the scan data signals to provide filtered scan signals
representative of the contribution of each of the scan data signals
towards reconstructing said image;
g. retrievably storing the filtered scan signals in scan storage locations
corresponding to scan elements occurring at respective predetermined
orientations during the scan cycle;
h. defining a preselected array of points corresponding to positions in
said planar section;
i. storing, as they are produced, in array storage locations elemental
image signals which are to be repeatedly updated;
j. calculating the address of the array storage location containing the
elemental image signal corresponding to a selected one of said point;
k. concurrently with said step of calculating the address of said elemental
image signal, calculating the address of the scan storage location
containing the filtered scan signal corresponding to a particular scan
element which resulted in the passage of a beam of X-radiation
sufficiently close to said selected point to contribute to the
reconstruction of the image at said selected point;
l. retrieving the addressed filtered scan signal and the addressed
elemental image signal;
m. combining the addressed filter scan signal with the addressed elemental
image signal to provide an updated, elemental image signal; and,
n. writing the updated, elemental image signal into one of said array
storage locations.
25. The method according to claim 24 wherein said step of writing comprises
the step of writing the updated, elemental image signal to the array
storage locations corresponding to said selected point.
26. In a tomographic scanning system for providing a reconstructed image of
a planar section of a subject which is relatively scanned from a plurality
of predetermined scan orientations and positions by X-radiation, a method
of providing elemental image signals which are successively updated and
stored to represent the reconstructed image, comprising the steps of:
a. defining at least one beam of X-radiation having a relative small
cross-section;
b. directing the at least one beam through a plane of the subject from a
succession of orientations and positions coplanar with the plane, whereby
passing the beam through a given orientation and position defines a scan
element and passing the beam through all the predetermined orientations
and positions defines a scan cycle;
c. detecting the intensity of the beam after it passes through the subjecft
at the succession of positions;
d. generating a sequence of scan data signals representative of the
intensity of the detected radiation corresponding to each scan element;
e. storing the respective scan data signals in input storage locations;
f. filtering the scan data signals to provide filtered scan signals
representative of the contribution of each of the scan data signals
towards reconstructing said image; g. retrievably storing the filtered
scan signals in scan storage locations corresponding to scan elements
occurring at respective predetermined orientations during the scan cycle;
h. defining a preselected array of points corresponding to positions in
said planar section;
i. storing, as they are produced, in array storage locations elemental
image signals which are to be repeatedly updated;
j. calculating the address of the array storage locations containing the
elemental image signal corresponding to a selected one of said points;
k. calculating the address of the scan storage locations containing the
filtered scan signal corresponding to a particuar scan element which
resulted in the passage of a beam of X-radiation sufficiently close to
said selected point to contribute to the reconstruction of the image at
said selected point;
retrieving the addressed filter scan signal and the addressed elemental
image signal;
m. combining the addressed filtered scan signal with the addressed
elemental image signal to provide an updated, elemental image signal; and,
n. concurrently with said step of calculating the address of said filtered
scan signal, the step of writing the updated, elemental image signal into
one of said array storage locations.
27. The method according to claim 26 wherein said step of writing comprises
writing the updated, elemental image signal into the array storage
locations corresponding to said selected point. |
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Claims |
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Description |
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REFERENCES TO RELATED AND RELEVANT PATENTS AND APPLICATIONS
U.S. Patent Application Ser. No. 559,411, entitled TOMOGRAPHY SYSTEM HAVING
NONCONCURRENT COMPOUND AXIAL SCANNING, filed Mar. 18, 1975;
United States Patent Application Ser. No. filed Nov. 28, 1975, Ser. No.
635,952, entitled TRANSVERSE TOMOGRAPHY SYSTEM HAVING MULTIBEAM ORBITAL
SCANNING WITH ALL BEAMS OFFSET FROM THE CENTER OF ORBIT (7-343), (here the
BACKSIDE SCANNING case).
BACKGROUND OF THE INVENTION
This invention relates generally to tomography and, more particularly,
relates to a data processing unit for processing data generated in a
transverse section, tomographic system to provide a characterization of an
internal planar section of a subject.
FIELD OF THE INVENTION
A conventional radiograph is a two-dimensional shadow image of a
three-dimensional subject. The depth dimension is not apparent as all
interior portions of the subject appear to be in a single plane. As a
consequence, a conventional radiograph often fails to provide necessary
detail as to spatial location of a condition, is difficult to interpret,
and may not reveal a condition which exists.
Tomographic procedures have been developed to fulfill some objectives which
are unobtainable by conventional radiographic procedures. In tomography,
an image of a crosssectional plane of a subject is developed by
sequentially directing radiation through the subject from a plurality of
origins. Tomography, in which the radiation is only in what is essentially
a single plane and which produces an image of the section of the subject
in the plane which includes the axis of the radiation, is known as
transverse section tomography.
According to one type of transverse section tomography, called transmission
scanning, one or more X-radiation detectors are supported in alignment
with one or more highly collimated beams of radiation generated by an
X-radiation source. If, as will be assumed for purposes of discussion, a
plurality of beams are utilized, they are coplanar. The radiation source
and the detectors are moved relative to the subject. The beams are
positioned such that they pass through the subject with their axes lying
within the plane containing the section of the subject to be examined.
The relative movement may be orbital or rectinlinear with respect to the
subject. If rectilinear, the relative movement (referred to as scanning)
causes the beams to pass through a succession of coplanar, parallel paths
through the subject. The intensity of each beam is detected and recorded
after it has passed through the subject. The paths are spaced from one
another by predetermined increments. The paths are orientated to be
orthogonal to selected radii lying in the plane and extending at
predetermined angles from a central axis intersecting the plane. The
passage of a beam of radiation along a give path is referred to as a scan
element.
The data corresponding to detected intensities at all successive scan
elements at a particular orientation about the central axis is said to be
data from a particular "view." The angular orientation of the source and
detectors about the central axis is incremented after each view and before
another view is obtained. This process continues until a predetermined
number of views, such as 180, have been performed and the sets of
collected data have been stored.
Where studies are conducted with orbital movement of a radiation source and
the detectors about the subject, generally a radiation source is utilized
which produces a plurality of nonparallel beams of X-radiation. A system
of this type is described in the referenced BACKSIDE SCANNING application.
The intensities of these nonparallel beams are detected after they have
passed through the subject and as the source and detectors orbit the
subject. Since the beams are not parallel to one another, sequential
detection of the intensities of adjacent beams does not provide data
arranged according to a particular "view" at any given orientation about
the oribital axis. Accordingly, the data representing the detected
intensities must be rearranged if it is to be recorded according to
"views" about the oribital axis.
The detected intensities of the beams are utilized for computing X-ray
transmission or X-ray absorption characteristics throughout the scanned
section. A plot of these characteristics provides a reliable image of the
internal structure of the patient in the scanned plane.
A type of transverse section tomography, called emission scanning, which
utilizes nuclear radiation has also been proposed. According to this
proposal, radioisotope is administered to the subject. A pair of detectors
diametrically disposed about the subject measures the intensity of emitted
radiation. These measurements are made from a variety of orientations and
positions. The values of the detected intensity are used in reconstructing
an image of a planar section of the subject. A proposed emission scanning
tomographic system is described in Kuhl, et al., "Cylindrical and Section
Radioisotope Scanning of the Liver and Brain," Radiology, Vol. 83, No. 5,
pp 926-936; 1964.
In transverse section tomography, a back projection computational process
is commonly utilized. The back projection computational process operates
on a filtered form of the detected radiation intensity data to recontruct
an image of the planar section under study.
In order to use the back projection computational process in transmission
tomography, the detected X-ray intensity values are stored, in the form of
scan data signals, in locations partitioned according to views. Thus, for
orbital studies, the stored scan data signals are rearranged according to
views, i.e., so that the signals stored at adjacent locations have values
which correspond to intensities detected along adjacent parallel paths.
After the scan data signals are arranged according to views they are
usually compensated (referred to as the filtering stage) to place them in
a form compatib | | |
