RU2690713C1 - Method of obtaining and processing images formed using proton radiation - Google Patents

Abstract

FIELD: physics.SUBSTANCE: use for proton radiography. Summary of invention consists in the fact that in the camera for placing the object of investigation, a test object is first placed, which is a substrate with identical reference marks, for example, steel balls, in nodes of orthogonal grid and fixed in centre of substrate with extended element, for example, tube; performing adjustment of test object perpendicular to axis of magnetooptical system on digital image of proton beam, which is passed through a magnetooptical system and a camera with a test object, achieving angular displacement of the test object of the size of the through hole of the tube on the image of the actual geometrical size. To determine conformity between dimensions of test object on obtained image and its actual geometric dimensions, test-object image is used, on which through hole of tube corresponds to actual geometrical size. Between dimensions of test object during through calibration of scaling coefficient of image transfer in channel of formation and recording of images conformity is established by determination of pixel coordinates of centres of all steel balls and selection of projective transformation, allowing to translate installed pixel coordinates into known coordinates of centres of steel balls in plane of test object. Further, the test object is replaced with the analysed object and a digital image of the proton beam is obtained, which is passed through the magnetooptical system and the camera with the object of analysis. Projective transformation selected on test object image is then used to process images of survey object.EFFECT: high quality and accuracy of processing registered proton images.5 cl, 3 dwg

Description

The invention relates to the field of proton radiography, in particular to methods of processing images generated using proton radiation, and can be used, for example, in digital imaging systems to determine the internal structure of objects or to study fast processes.

When registering proton images, there are geometrical distortions associated with magnetic optics, with a non-perpendicular arrangement of the scintillator and beam, with different angles, under which proton images are recorded by various recording channels.

The task in this technical field is to obtain reliable information about the objects under study.

A known method of obtaining and processing images generated using proton radiation (Physics Division Progress Report 1999-2000 Proton Radiography, DA Clarc et al., P. 156-168), including obtaining two digital images of the proton beam before passing through the field of study the first and second registration systems and the digital image of the proton beam after it has passed the study area in the focusing plane of the magneto-optical system using the third registration system. Each of the registration systems includes a converter that converts proton radiation into photons recorded by a CCD matrix. The first image of the proton beam is obtained directly in front of the diffuser, the presence of which is necessary for further image processing and which is placed in the magneto-optical channel. The second image is obtained at a considerable distance from the diffuser - 6 m. Next, the obtained digital images are processed and an image of the study area is obtained by calculation. The following operations are carried out. Using the first two images by calculation, an image of the proton beam is obtained in the area of study / plane of the object of study, then pixel-by-pixel division of the third image into that obtained by calculation is performed to obtain an image of the area of study.

The disadvantage of this method is that obtaining a calculated image from two experimental images leads to a decrease in processing accuracy.

There is another method of obtaining and processing images generated using proton radiation (D. Varentsov, O. Antonov, A. Bakhmutova, CW Barnes, A. Bogdanov, CR Danly, S. Efimov, M. Tndres, A. Fertman, AA Golubev , DHH Hoffmann, B. Lonita, A. Kantsyrev, Ya.E. Krasik, PM Lang, I. Lomonosov, FG Mariam, N. Markov, FE Merrill, VB Mintsev, D. Nikolaev, V. Panyushkin, M. Rodionova, M. Schanz, K. Schoenberg, A. Semennikov, L. Shestov, VS Skachkov, V. Turtikov, S. Udrea, O. Vasylyev, K. Weyrich, C. Wilde, A. Zubareva, Commissioning of the PRIOR proton microscope, arxiv: 1512.05644v2 [physics.ins-det] 19 jan 2016), selected as the closest equivalent. The method includes obtaining images of the proton beam using the registration system by passing it through the magneto-optical system and the area of research in which the test object is first installed, and then replaced with the object under study and the subsequent processing of the obtained images. The test object is a copper square substrate with holes in the nodes of an orthogonal grid deposited on an area of 9 × 9 mm. The test object is set counter to the flow of protons. When a proton beam is passed through a test object, an image is obtained that establishes a correspondence between the dimensions of the test object in the resulting image and its actual geometric dimensions by spatial calibration (taking into account the distance between the extreme elements in the horizontal and vertical directions), which is used in processing the image of the object research.

The disadvantage of the method is that due to the construction of the used test object, it is impossible to set it strictly perpendicular to the axis of the magneto-optical recording system, which does not completely eliminate the effect on the proton image of the inaccuracy in positioning the object of study on the angle relative to this axis and leads to a decrease in processing accuracy images.

The technical result of the proposed method is to improve the quality and accuracy of processing of registered proton images.

This technical result is achieved due to the fact that in the method of obtaining and processing images generated using proton radiation, including obtaining digital images of the proton beam using a recording system by passing it through the magneto-optical system and the area of research in which the test object is first placed representing the substrate with the same reference marks in the nodes of the orthogonal lattice, with the subsequent replacement of the test object on the object under study, according to the obtained image To the test object, the correspondence between its dimensions in the image with the actual geometrical dimensions is established, which is taken into account when processing the obtained image of the object of study, is that before receiving the image of the test object, it is adjusted relative to the axis of the magneto-optical system, for which purpose in the center of the test an object perpendicular to the substrate fix an extended element of constant cross section, and, carrying out the angular displacement of the test object, expose it perpendicular to the axis of the magneto The determination of the pixel coordinates of the reference marks and the selection of a projective transformation that translates the pixel coordinates into the known coordinates of the reference marks in the plane of the test object.

As a test object, an object can be used, which is a set of identical elements made of a less dense material than the substrate material.

Spherical metal elements can be used as a set of identical elements.

In the extended element can be made through hole. The substrate can be made of plexiglass.

By aligning the test object with respect to the axis of the magneto-optical system, for which an extended constant section element is fixed perpendicular to the substrate in the center of the test object, and by angular displacement of the test object, it is perpendicular to the axis of the magneto-optical system, it is possible to achieve accuracy in positioning the test object along angle relative to the axis of the magneto-optical system, which will further lead to accuracy in positioning the object of study relative to this axis, which ultimately will increase achestvo and machining accuracy for the proton images.

Establishing the correspondence between the dimensions of the test object on the resulting image and its actual geometric dimensions by determining the pixel coordinates of all reference marks and selecting a projective transformation that translates the established pixel coordinates into the known coordinates of reference marks in the plane of the test object, allows you to more accurately determine the coordinates of the elements found in plane test object.

Using an object as a test object, which is a set of identical elements made of a less dense material than the substrate material, allows you to get a better image of the test object.

The use of high-precision spherically-symmetric objects makes it possible to maximally eliminate the effect on the proton image of inaccuracy in the positioning of the object in an angle relative to the axis of the magneto-optical system.

The execution in the extended element of the through hole allows the most accurate adjustment of the test object relative to the axis of the magneto-optical system.

FIG. 1 shows a fragment of a test object; FIG. 2 is a photograph of the test object, in FIG. 3 - the image of the test object during the transmission of a proton beam, where: 1 - an extended element of constant cross section; 2 - reference marks in the nodes of the orthogonal lattice; 3 - substrate.

As an example of a specific implementation of a device that allows the inventive method to be implemented, a device can be used that is made on the basis of the current U-70 synchrophasotron built in the city of Protvino [News and Problems of Fundamental Physics, No. 1 (5), 2009, p. 32-42], and includes a camera for placing the object of study, a system for the formation and registration of the proton image. The formation system is a magneto-optical system consisting of magnetic lenses and a collimator. The registration system consists of a scintillation converter, a mirror and digital cameras. For the measurements, a test object was used (Fig. 2), which is a set of 110 high-precision steel balls 9 mm in diameter, mounted on an organic glass substrate in the nodes of an orthogonal lattice with a strict interval (20 mm) between them. Seats for mounting the balls are made on a CNC machine with an accuracy of ± 10 microns. In the center of the test object perpendicular to the substrate there is fixed an extended element of one cross section, in which a through hole is made - a tube.

To eliminate geometric distortions associated with different angles, which are used to record proton images by various recording channels, and bring the obtained digital images to the correct angle, a test object is placed in the camera to accommodate the object of study (Fig. 2). Using a test object with high-precision spherically symmetric reference marks in the form of steel balls and adjusting the test object perpendicular to the axis of the magneto-optical system, one can almost completely eliminate the effect on the proton image of the inaccuracy in the positioning of the test object along an angle relative to the axis of the magneto-optical system. The perpendicularity of the substrate 3 axis of the magneto-optical system is checked by a digital image of the proton beam, which is passed through the magneto-optical system and the camera with the test object by angular movement of the test object until the through hole of tube 2 in the image matches the actual geometric size. The image of the test object thus obtained is used to determine the correspondence between the dimensions of the test object on the obtained image and its actual geometric dimensions. The correspondence between the dimensions of the test object with end-to-end calibration of the scale image transfer coefficient in the imaging and recording paths is established by determining the pixel coordinates of the centers of all steel balls and selecting a projective transformation that translates the installed pixel coordinates into the known coordinates of the centers of the steel balls in the plane of the test object. Having determined the projective transformation, they apply it when processing images of the objects under study, for which they replace the test object with the object under study and obtain a digital image of the proton beam, which is passed through the magneto-optical system and the camera with the object of study. Then, the projective transformation selected using the image of the test object is used in image processing of the object of study.

So The inventive method allows improving the quality and accuracy of processing the registered proton images.

Claims (5)

1. A method of obtaining and processing images generated using proton radiation, including obtaining digital images of a proton beam using a recording system by passing it through a magneto-optical system and an area of research in which a test object is first placed, which is a substrate with the same reference marks in the nodes of the orthogonal lattice, with the subsequent replacement of the test object on the object under study, according to the received image of the test object establish the correspondence between its size On the image with actual geometrical dimensions, which is taken into account when processing the obtained image of the object of study, characterized in that before receiving the image of the test object, it is adjusted relative to the axis of the magneto-optical system, for which an extended constant section element is fixed in the center of the test object, and, carrying out the angular movement of the test object, put it perpendicular to the axis of the magneto-optical system, and the correspondence between the dimensions of the test object n the acquired image and the actual geometrical dimensions set by determining pixel coordinates of reference marks and the selection of a projective transformation allowing transfer set the pixel coordinates in the known coordinates of reference marks in the plane of the test object. 2. The method according to p. 1, characterized in that as a test object using an object that represents a set of identical elements made of a less dense material than the substrate material. 3. The method according to p. 2, characterized in that as a set of identical elements using metal balls. 4. The method according to p. 1, characterized in that in the extended element perform a through hole. 5. The method according to p. 1, characterized in that the substrate is made of Plexiglas.

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