US3906229A - High energy spatially coded image detecting systems - Google Patents

14 1 Sept; 16, 1975 8/1973 KIOIZ 350/162 21 4 1974 Barrett 250 460 OTHER PUBLICATIONS Primary Examiner-Harold A. Dixon Attorney, Agent, or FirmJseph D. Pannone; Milton D. Bartlett; David M. Warren ABSTRACT A system for detecting fine detail of large objects with 5?} 55.81.JJJJJJJJJJiJJJJJ;i5???.???T??%5f?i2 hhh ehhhgy hhhhhh h which .hhhhhhy hhhhh hhhhh 581 Field of Search 350/162 ZP; 250/237 G, i heated at a phlrality Posltions between i 250/321 312 452, 460 482 513, 364 336, ect and a detecting system. The apertures 1n the 308 masks are much larger than the wavelength of the h1gh energy particles and the detector, such as a film, de- 56] References Cited tects a hologram-like shadowgraph which is subsequently developed and the image reconstructed there- UNITED STATES PATENTS from by means of light from a substantially monochrol,38 l Tollsey matic ource 3,263,079 7/l966 Mertz et al 350/162 ZP 3,669,528 7/1972 Richardson 350/162 21 11 Claims, 4 Drawing

Figures FILM DEVELOPMENT

46 PATENTEBSEP 15 ms 3,906,229

DEVELOPMENT

46 DEVELOPE AND BLEACH HIGH ENERGY SPATIALLY CODED IMAGE DETECTING SYSTEMS BACKGROUND OF THE INVENTION Apparatus for determining the location and condition of structures and/or organs in living bodies by detecting high speed particles emanating from regions of the body which have selectively absorbed radioactive compounds requires substantial exposure of the body to potentially harmful radiation and, hence, apparatus which reduces the dosage required to obtain an image of the structure or organ of. sufficient definition and intensity to permit accurate diagnosis of the condition and location of the structure or organ is of paramount importance. Such definition is also a function of the length of time during which the body can as a practical matter be retained in an immobile position since movement of the body will cause substantial reduction in definition of the reconstructed image.

DESCRIPTION OF THE PREFERRED EMBODIMENT Referring now to FIGS. 1 and 2, there is shown a )urce of

radiation

20 which is illustrated herein, by ay of example only, as the chest of a living person. ortions of the chest area have been rendered radioacve by administering any of the well-known radioactive harmaceuticals to the person. As is well known, sected body elements such as the liver, lung regions or lood vessels have an affinity for selected radioactive harmaceuticals. Such an affinity varies, for example, ependent on the type of disease and the region afcted by the disease.

Positioned adjacent to

radiation source

20 is

mask

22 Jnsisting, as illustrated in greater detail in FIG. 2, of plurality of

curved bars

24 of material opaque to the idiation separated by

spaces

26 equal in width to the idth of the bars. As illustrated herein, the total open rea of the

mask

22 is made approximately equal to the ital opaque area of the mask and may be referred to a Fresnel zone pattern. The material of the

bars

24 chosen such that the radiation from the

source

20

hich hits bars

24 will be absorbed but those portions fthe radiation which are directed to the

spaces

26 beveen the

bars

24 will pass through.

While the

mask

22 may be placed at various dismces from the

source

20, it is preferably positioned as ose as convenient to the

source

20 which is the object eing detected. Hence,

mask

22 may be referred to as re object mask.

Mask

22 may be made, for example, y depositing a layer of lead on an aluminium plate and lachining off portions of the lead to expose portions fthe aluminum. Aluminum will transmit substantially l the high energy radiation impinging thereon and, ance, such exposed aluminum regions constitute

radizion aperture

26.

The pattern formed by the

bars

24 defining the apertures is a fragmented portion of a Fresnel pattern. The

bars

24 extend in arcuate form to the edges of the circular ring defining the perimeter of

mask

22. As illustrated herein, for purposes of clarity, only a few bars and spaces are shown, and adequate results may be achieved with such a system. However, applications have found that masks with more than fifty bars and apertures are preferably used to produce high definition images from the shadowgraph formed, as illustrated herein, directly on a film from a crystal scintillation layer.

The width of the

narrowest spacing

26 is several orders of magnitude greater than the wavelength of the radiation. For example, if the width of the narrowest aperture is on the order of one millimeter, any radiation beyond the visible range will have a wavelength many orders of magnitude less than a millimeter and, hence, any diffraction effects of

mask

22 on such radiation will be substantially undetectable.

As illustrated herein, the pattern of

bars

24 and

spaces

26 forms an off-center section of a Fresnel zone pattern. More specifically, the diameter of

mask

22, as shown in FIG. 2, is approximately equal to the distance from the center of the Fresnel zone pattern to the center of the

mask

22. Such an offset offsets the image during the reconstruction process and is preferably great enough to separate the multiple images produced as well as to separate detecting surface edge artifacts from the desired image.

Mask

22, which may be referred to as the object mask, is supported in a

housing

30 which spaces the element 22 a predetermined distance S from a second

spatial coding mask

32.

Mask

32, which may be referred to as the intermediate or equidistant mask, is formed in a similar manner to that of

mask

22 and has a pattern which is the off-center section of a Fresnel zone pattern as illustrated in FIG. 3. In general, the patterns of the

masks

22 and 32 are by way of example only, and any desired patterns or portions of patterns which are symmetrical about axes substantially parallel to the average direction of motion of the radiation through the masks could be used. While, as illustrated herein,

masks

22 and 23 are planar, they may if desired, be made as portions of spherical surfaces or cylindrical surfaces or other geometric shapes.

As may be seen from FIG. 3,

mask

32 is an off-center section of a Fresnel zone pattern identical to that of

zone plate mask

22 but scaled to substantially one-half the size of

zone plate

22, with the remainder of the space between the

support housing

30 being filled with the portion of the aluminum backing plate covered with lead which absorbs substantially all gamma radiamined point on the holographic image plane is intersected by a plurality of straight lines passing through different mask apertures of

masks

22 and 32, respectively, as illustrated, for example, by point 28. Since there are a plurality of such points which are essentially arcs of circles in the holographic image detector plane, particles emitted from the object will form maximum intensity by which is meant maximum number of radiation particles for that coding frequency even though

object

20 is of relatively large size. It may also be seen that various other arcuate configurations may be similarly projected on the detector plane and the sum total of these forms a shadowgraph containing all the spatial frequency components of the spatial code pattern upon which the intelligence data representing the particular outline and radiation intensity of the object are superimposed. Such a pattern is an amplitude or intensity pattern and, hence, may be detected by a

detector system

36.

As shown in FIG. 4,

housing

30 is formed from a circular cross section to a rectangular cross section in the region where it supports the detecting

system

36. It has been found that if a circular section is used for the detecting shadowgraph region, a reconstruction by optical means produces a series of circular patterns which, to some extent, interfere with or degrade the image. By the use of a rectilinear pattern, as indicated in FIG. 4, the reconstruction contains straight-line artifacts indicative of the straight-line borders of the periphery of the shadowgraph, and these intersect to form a cross with positive and negative images appearing in opposite quadrants of the cross so that by the use of an iris only one desired image may be selected and the remaining data, including the artifacts, eliminated.

The size and spacing of the

masks

22 and 32 and the size of the rectilinear detector plane may be selected from a wide range of possible configurations. For work with human bodies, the following size has been found useful:

Diameter of

mask

22 25 to cm.

Effective diameter of

mask

32 12 to 15 cm.

Rectilinear dimensions of the detecting surface 25 cm.

X

30 cm.

The number of

bars

24 which can, as a practical matter, be formed in

masks

22 and 32 depends upon the thickness and material of the masking medium.

Detector system

36 is illustrated herein as being substantially planar but, if desired, may have a spherical, cylindrical or other geometric surface shape. As illustrated herein by way of example only,

detector system

36 comprises a layer of

film

38 sandwiched between two

thin layers

40 of crystal material such as cesium iodide or calcium tungstate which produces scintillations of light when struck by gamma radiation. A backing support plate 42, preferably of light reflecting metal, is used to support the layers of

crystal

40 and the

film

38 positioned therebetween. The front surface of the

crystal

40 on the opposite side of

film

38 from the support plate 42 may also have a thin layer of light reflecting material such as an aluminum or silver surface coated thereon and, if desired, the entire package of support plate 42,

film

38 and

crystals

40 may be assembled as a unitary package or cassette.

In operation, gamma rays from

object

20 pass through

masks

22 and 32 as well as through

crystal

40. Some of the gamma rays will produce scintillations of light in one or the other of the crystal layers 40 having an intensity strength enough to partially expose the elemental areas of the film adjacent the regions of the crystals producing the light scintillation. Preferably, the crystal layers 40 are made only a few millimeters thick so that definition in the pattern recorded on the

film

38 is maintained in the millimeter range.

While the

film

38 is preferably in a cassette, it is shown herein as a portion of a roll of film 44 drawn through the

crystals

40 to illustrate the process steps involved. After exposure, the

film

38 is developed in accordance with conventional practice by passing through a

developer bath

46. Any desired degree of development can be used. Preferably, however, the film is developed sufficiently to provide maximum contrast between light and dark areas. However, different degrees of development may be used to accentuate different total intensities of the detected shadowgraph.

The

film

38 is then placed in a reducing

system

48 which may be of a conventional type in which a

light source

50 emanating from a

ground glass screen

52 passes through

film

38 and is focused on a

film

58 through a

lens

54 on the opposite side of

film

38 from the

light source

50. The focal length of

lens

54 is chosen such that the light rays converge as passing therethrough and the shadow of

film

38 is projected in reduced form on

film

58 to expose

film

58 and reproduce a negative of the pattern developed on

film

38 in reduced form on

film

58.

In accordance with this invention, the pattern on

film

58 is reduced sufficiently so that the projection of the spacing of

bars

24 in the pattern recorded on

film

38 will be sufficiently close to produce a substantial degree of refraction of a visible light beam passing therethrough. This has been found to produce a substantial improvement in image reproduction, both from the standpoint of image distortion and image clarity or intensity.

Film

58 may, if desired, also be in the form of a cassette but is shown herein in the form of a roll of film to illustrate the subsequent steps of the process.

Film

58 is passed through a conventional develop and bleach step illustrated at 60. The

film

58 is of any desired conventional type which is developed to produce substantially the same or a greater degree of contrast as the original

developed film

38 and is then bleached with any conventional film bleach to convert all of the light absorbing regions to a compound having a thickness and/or index of refraction different from the other regions of the film. In accordance with this invention, bleaching, in addition to enhancement of light transmission, is used as part of the conversion process from a shadowgraph pattern produced by noncoherent radiation into a refracting lens suitable for coherent light image reproduction in which size reduction of the image is used to further enhance the quality and clarity of the reproduced image.

The

film

58 is then used to reproduce an image of the

object

20 by a coherent

light reproduction system

62.

System

62 may be of any desired type and, as illustrated herein, comprises a source of

coherent light

64 such as a helium neon laser whose output is focused by a

lens

66 through a

pinhole iris

68 to remove spatial noise. Light projected through the pinhole 68 passes through a converging

lens

70 and then through the developed and bleached

film

58 which diffracts the informational content of the picture away from the center line of the ll'lOlE and

lens system

70 by a distance r. so that it ;ses through a hole having a diameter in an

iris

72 1 appears as a reconstructed image in an image plane any desired detection system such as a

ground glass een

74. The distance of

screen

74 may be varied ,h respect to the

film

58 to produce from the pattern :orded on

film

38 various slices corresponding to 'ious distances of object from the detector system [he aperture size d and its offset r from the

iris

72 functions of the diameter of the zone plate masks and 32 and the distance which the center of the zone tte patterns are offset from the center of the Fresnel 1e pattern. For example, if, as illustrated, the diameof each of the zone plates is equal to the offset of center of that zone plate from the center ofits Fresl zone pattern, the pattern size d in the

iris

72 is prefibly substantially equal to the offset distance r,. from center of the system. As illustrated herein, the

iris

72 is positioned substanlly in the plane where the pinhole liht from

iris

68 MM be focused by the

lens

70 in the absence of film which may be referred to as the Fourier plane. Hower, other locations of the

iris

72 may be used and/or ier means of separating the desired image from arti- :ts and/or undesired images. The image produced on

screen

74 may be viewed diztly and/or several pictures taken for various distces of

screen

74 from the Fourier plane by means of :

amera

76. Alternatively, a television pickup camera 1y be used to view the reproduced image and/or to )re images in a computer memory from which if deed, simultaneous three-dimensional views of the ob- :

t

20 may be reproduced. in accordance with this invention, individual scintilions of light from the

crystals

40 will not completely pose an elemental area of the film. Thus, overlapping tterns produced by adjacent point sources will subtntially all be recorded with optimum intensity and a nimum occurrence of the conditions where elemenareas of film are completely exposed so that addilnal scintillations of light occurring after such comate exposure go undetected. The

film

38 may be sufficiently thick for a given exsure time for such complete recording without satution to occur since the portions of the film which are are completely exposed simply remain transparent to ht in the reduction process. It should be noted that ose portions which are still transparent pass the most ht so that the reduced

film

58 is a negative of the

iginal film

38 causing a greater darkening of the neg- .ve 58. However, this also does not result in reduction image intensity since substantially all of the opaque gions are substantially completely bleached and the t result is simply a small average increase in the retction of the film. The substantial signal amplification obtained by the duction in size of fiom 58 from

film

38 and the :aching allows this system to be used for direct shad- Igraph recording, thereby allowing an improved defition of the image derived therefrom. The definition .provement varies as the total number of counts rerded which is a function of the time of exposure of e detecting system. Because of the large number of unts available compared with the prior pinhole or llimator type cameras, relatively

thin scintillator ystals

40 may be used, thereby permitting a shadowgraph detection definition substantially higher than those previously available. As a result, the fineness of the bar spacing of the finest bar of

zone plate mask

32 may be made substantially as fine as it is practical to fabricate such structures while still projecting patterns on the detecting surface which are within the spatial frequency pass band of the detecting system. For example, with a 20 to 1 reduction in size of the hologram from

film

38 to film 58, a high definition image of an object may be derived using high energy level incoherent radiation from a living tissue source, and the image constructed using coherent light in the image-forming process will be readily visible to the naked eye.

More specifically, useful results can occur when the radius of the first edge, r,, of each zone plate satisfies the following proportion in order to obtain the

frequency match r

22 taking r, 22 1% [one Since the two zone plates are the same function (scaled appropriately), the result is the correlation function of the two identical (except for scale) patterns. If the zone plates were infinite in extent, the correlation would be an impulse, lying on a line connecting the centers of the zone plates. If we look in the film plane, therefore, we see the Fourier transform of the object plane.

3. The method in accordance with

claim

2 wherein said step of deriving an image comprises:

4. The method in accordance with

claim

3 wherein said step of deriving said image comprises: