RU2137114C1 - Method of small-angle introscopy and device for its realization ( versions ) - Google Patents

Abstract

FIELD: ultrasonic visualization. SUBSTANCE: tested object is exposed to narrow, slightly diverging beam or set of narrow, slightly diverging beams of penetrating radiation. Distribution of radiation intensity along section of beam in presence and absence of object is recorded with the help of two- coordinate position-sensitive detector of high resolution. Redistribution of radiation intensity in beam with positioning of object in its path is caused by coherent radiation scattering through small angles by substances included in tested object. As function of coherent scattering of each substance is unambiguously determined by its structure it can be used for identification of substance by recorded redistribution of radiation intensity in beam during its comparison with results stored in data base for monitored substances. EFFECT: decreased radiation dose when generating image of internal structure of object with allowance for structural characteristics of substances included in it. 6 cl, 4 dwg

Description

 The invention relates to determining the composition and structure of inhomogeneous objects that are opaque to visible light, using transmitted and scattered at small angles (SANS) radiation.

 Known devices for acquiring images of the internal structure of an object, as a rule, are based on the principles of traditional absorption radiography, i.e. on the registration of the distribution of the intensity of the radiation transmitted through the object (US, 4,651,002, G 01 T / 161, 03.17.87). The differences in intensity in this case are the result of unequal absorption of radiation by various parts of the object. For absorption X-rays, scattered radiation is a spurious phenomenon that creates a background and impairs image contrast.

 To combat scattered radiation, it was proposed to register it separately, using a collimation grating and a filter, and subtract the intensity of the recorded scattered radiation as a background from the total signal obtained by scanning the object (US patent, 4,651,002). Since the scattering pattern in this case is measured integrally, the authors do not care about the exact adjustment of the mutual position of the collimation lattice and the filter lattice. In this regard, the filter is designed as a movable element, and the scattered radiation is recorded at large angles.

 In another patent (US, 4,549,307), it is proposed to use dampers that form portions in the image of the object in which only the background is recorded, that is, only scattered radiation. The background level over the entire image is determined by the approximation and subtracted from the total absorption signal to obtain a more contrast image.

 As already mentioned, the devices described above are based on the principle of obtaining an image of the internal structure of an object according to the distribution of the intensity of the radiation transmitted through the object, depending on the distribution of the absorbing properties of the object. If the object contains substances that are not very different in absorption capacity, then on the resulting image the areas of the object containing such substances will practically not differ in intensity, that is, as a result, it will not be possible to obtain an image with the desired contrast. To obtain an image of the structure of an object in such cases, a different approach is required, which differs from the absorption X-ray diffraction, and based on a different type of interaction between the penetrating radiation and the substance.

 In the patent GB, 2,299,251, G 01 N 23/207, 1996, a method for identifying crystalline and polycrystalline substances is proposed, based on the registration of Bragg reflection from the crystal structure of the object. The distribution of the energy spectrum of polychromatic radiation reflected at a certain angle from the crystalline structure of a substance is characteristic of this substance and allows it to be identified using the existing database. The collimator of the proposed device is designed in such a way that allows you to record the energy spectrum for each individual area of the object through which the radiation passes. This allows you to obtain a holistic image of its internal structure when moving an object in the device. This method is proposed to be used to detect explosives during baggage control. However, its use is limited to the detection of objects having a crystalline and polycrystalline structure.

 The works (SU, 1402871, G 01 N 23/06, 1987; RU, 2012872, G 01 N 23/02, 1994) describe devices for visualizing the internal structure of an object, which use the effect of refraction of X-rays at the boundaries of regions of an object with different electron density, which leads to the deviation of the rays by angles up to three seconds. In these works, single crystals were used to collimate radiation incident on an object and to filter radiation rejected as a result of refraction.

The disadvantage of this method and devices based on it is its low aperture ratio. This is due to the fact that the single crystal reflects the radiation incident on it according to the Bragg law. The radiation of each wavelength is reflected at a certain angle in the divergence interval equal to the angular Bragg reflection interval, which is about 10 arc seconds. This means that out of the total radiation flux produced by the source, less than 10 ^-5 parts of it are used to illuminate the object.

 To increase the efficiency of such a device in the patent (WO 95/05725, G 01 N 23/04, 1995) it was proposed to use an aperture grating instead of single crystals, which forms narrow X-ray beams. The refraction of x-rays at the boundaries of regions of an object with different electron densities leads to a deviation of the x-ray beam behind the object from the original direction, which can be detected by a high-resolution position-sensitive detector. Such a device in its use requires a high degree of mechanical and thermal stabilization.

Common drawbacks of the method of visualizing the internal structure of an object by using the x-ray refraction effect is the distortion of the recorded information in the presence of several boundaries of regions with different electron densities in the beam path and the difficulties encountered in identifying the various substances that make up the object. The noted drawbacks can be avoided by using the method of detecting radiation coherently scattered by an object. In the patent US 4751772, G 01 N 23/201, 1988. which is the closest analogue of the invention in terms of essential features, the apparatus and method are described based on recording the spectrum of coherent scattered radiation at angles ranging from 1 to 12 ^o with respect to to the direction of the incident beam. As indicated in these works, most of the elastically scattered radiation is concentrated in these angles if the energy of the x-ray radiation is not very large. The basis of these inventions is the fact that the energy spectra of elastically scattered radiation (in contrast to inelastically scattered - Compton radiation) and the radiation of the primary beam are identical and the elastically scattered radiation has a characteristic angular dependence determined both by the irradiated substance itself and by the energy of the incident radiation. Since the intensity distribution of coherently scattered radiation at small angles depends on the molecular structure of the substance, various substances having the same absorbing capacity (which cannot be distinguished by conventional transillumination) can be distinguished from each other by the angular intensity distribution characteristic of each substance coherently scattered radiation. As examples in these patents, the possibility of determining explosives in baggage, as well as the recognition of biological tissues, is indicated.

 In these patents, it is proposed to use a narrow collimated beam of monochromatic or polychromatic radiation to illuminate the object. The intensity of coherently scattered radiation is measured using a detecting system with a resolution in both energy and coordinate (scattering angle).

The described devices have a relatively low aperture, since the cross section for coherent radiation scattering in this angular range is small, and requires high doses of the object when it is studied. (Here, by the cross-section of coherent scattering of radiation, we mean the ratio of the number of quanta experiencing elastic scattering at a certain angle per unit time to the density of the incident quantum flux.)
The objective of the invention is to reduce the radiation dose when obtaining an image of the internal structure of an object, taking into account the structural characteristics of its constituent substances. The invention is based on the registration of small-angle scattering of penetrating radiation limited by the region of the central diffraction peak.

 The essence of the physical method used in the described device for detecting radiation scattered at small angles is as follows: a beam of penetrating radiation having a point or dash shape in cross section is recorded by a high-resolution position-sensitive detector. The distribution of the radiation intensity in the plane of the detector will be determined by the optical transfer function of the device. When an object is placed in a device, the full optical transfer function of the device, and, consequently, the distribution of the radiation intensity in the plane of the detector will change. A change in the shape of the radiation intensity distribution will be determined by the scattering function of the object. The explicit calculation of the scattering function (in the form of an analytic function) by changing the shape of the intensity distribution in space is possible only for a limited number of cases. However, in an implicit form, it will uniquely determine the scattering properties of the substance and when comparing the data obtained in the measurement with the available database for standard substances, it is possible to identify the substance by its scattering properties.

 Based on the physical method described above, a method for determining the composition and structure of an inhomogeneous object consists in irradiating the controlled object with a narrow, slightly diverging beam of penetrating radiation, detecting the radiation transmitted through the object using a two-coordinate position-sensitive detector, and identifying substances entering the controlled object by small-angle coherent scattering of the transmitted through the object radiation and radiation absorbed in the object. The distribution of radiation intensity is recorded over the beam cross section in the absence and presence of an object. The resulting intensity distributions are normalized to the total intensity of the incident and transmitted radiation, respectively. By changing the normalized spatial distribution of intensities due to the scattering of radiation at small angles by the substances entering the object, and comparing it with the reference values previously obtained under the same conditions, the substances entering the object are identified.

 Another variant of the method, which allows to determine the content of substances included in the controlled object, is as follows. The controlled object is irradiated with a narrow, slightly diverging beam of penetrating radiation and the radiation transmitted through the object is recorded using a two-coordinate position-sensitive detector. The distribution of radiation intensity is recorded over the cross section of the beam passing through the controlled object. At the same time, from the same radiation source, the distribution of the radiation intensity over the cross section of the beam passing through the standard sample is recorded. From a comparison of the intensities of the radiation scattered at the same angles for each beam, the content of substances in the controlled object is determined.

 As one of the variants of the device for determining the composition and structure of an inhomogeneous object, we consider an installation for medical diagnostics. It consists of an x-ray source, one or more collimators, each of which generates radiation in the form of a flat fan beam, having in one direction an angular distribution of intensity, similar in shape to a δ-function, and in the other - covering the entire studied region of the object, and high-resolution two-coordinate detector. The optical part of the device (source, collimator, detector) and the object under study have the ability to move relative to each other for sequential scanning of the object under study. A high-resolution detector measures the distribution of radiation intensity in an X-ray beam in the presence and absence of an object. To ensure the accuracy of the measurements, it is necessary that the dimensions of the individual sensitive elements of the detector are less than half the width of the distribution of the intensity of the X-ray beam in the registration plane, preferably less by an order of magnitude. Such a measurement method makes it possible to register x-rays scattered at small angles, not only extending beyond the boundaries of the beam, but also those that lead to a redistribution of the radiation intensity inside the beam. In order to be able to compare minor changes in large signals during data processing, the obtained distributions of the radiation intensity in the beam in the presence and absence of an object are normalized to the total intensity of the incident and transmitted radiation, respectively. Thus, the obtained data are reduced to general conditions, and a change in the shape of the distribution curve of the radiation intensity in the beam (the difference between the normalized spatial distribution of intensity) will reflect the distribution function of the medium through which the radiation passes.

 The optimal registration conditions when examining various objects can be by choosing the stiffness, i.e. wavelength used by penetrating radiation. The softer the radiation used (the longer the wavelength), the more the normalized curve of the intensity distribution in the transmission beam behind the object changes, however, the fraction of radiation absorbed in the object increases and the signal at the detector decreases. The choice of the optimal parameters of the penetrating radiation depends on the nature of the investigated object and in each case is carried out individually. When using a polychromatic radiation source, this can be achieved either by selecting a filter that cuts out the required spectral range, or by using a detector selectively sensitive to the selected energy range of the recorded quanta. In the latter case, the detector for each spectral range of penetrating radiation records its intensity distribution in the beam behind the object.

 As described above, the scattering function of each substance is determined by its structure and is the "calling card" of this substance, which can be used to identify it, i.e. by comparing the measured difference in the normalized spatial intensity distribution for the test substance with the results contained in the database for the control substances, it is possible to determine which of the substances has a scattering power, which leads to such changes in the intensity in the beam. Moreover, from the ratio of the total integral intensity before and after the object, the absorption capacity of the substances entering the object is determined, which can also be used for preliminary identification of these substances.

 Thus, in one measurement, for each region of the object illuminated by the x-ray beam, the absorption coefficient and the implicit function of the scattering of the material entering the region illuminated by the beam are determined. This makes it possible to distinguish even substances entering the object that have the same elemental composition but different structure, which is very important in the diagnosis of cancer.

Since the scattering properties of a substance are determined by measuring the intensity in a direct beam, this makes it possible to significantly reduce the radiation dose of an object in such measurements compared with measurements of radiation scattered outside the primary beam (by 10 ³ - 10 ⁵ times), which is important in medical diagnostics. The sensitivity of the described device to the detection of inhomogeneities in the object is determined by the spatial distribution of the penetrating radiation: the narrower the beam, the more its shape changes after passing through the studied object. In addition, the larger the scattering cross section of the desired substance in the object under study, the more the shape of the primary beam changes after passing through the object, and the easier it is to determine the scattering function of this substance. For low-scattering substances, the installation provides for the possibility of increasing the sensitivity to registration of scattered radiation. This can be achieved by increasing the number of sensitive elements of the detector in the angular range of measurements, in order to more accurately measure the distribution of radiation intensity in the x-ray beam, or by recording only the primary radiation beam scattered outside the boundaries. The first is achieved by increasing the distance from the object under investigation to the detection plane, the second by introducing a trap into the channel of the primary beam, separating radiation scattered at small angles and extending beyond the boundaries of the primary beam from radiation transmitted without scattering. However, both methods lead to a significant decrease in the radiation flux density at the detector and an increase in the exposure dose of the object.

 Thus, the setup described above can operate in two modes: a high-intensity mode with a low exposure dose to the object, and a mode highly sensitive to scattered radiation, which requires an increase in the radiation dose of the object. Switching from one mode to another can be carried out at the operator’s command, depending on the nature of the object being studied.

 To study objects that differ in the anisotropy of scattering (diffraction) properties, i.e., having a different distribution of electron density in different directions, a collimator is provided that forms a dashed beam of penetrating radiation and rotates around its longitudinal axis. In this case, the plane of the beam intersects the object at different azimuthal angles. At a position-sensitive detector, for each fixed position of the beam, the radiation transmitted through the object and the radiation scattered through it is recorded simultaneously according to the above-described scheme. From the measured distributions of the transmitted and scattered radiation intensities recorded per revolution of the collimator, it is possible to determine the total distribution of the absorbing and scattering properties of the object under study in the translucent region in a plane perpendicular to the direction of beam incidence. This makes it possible to more accurately identify the substances that make up the object under study by the radiation scattered by them, since an additional parameter (spatial distribution of electron density) appears, which makes it possible to distinguish between similar substances. In addition, the quality of the image obtained in the absorbing contrast is improved, since the use of a narrowly collimated beam reduces the spurious radiation scattering in the object.

 To study large objects, the installation provides the ability to scan an object. This can be, for example, line-by-line scanning carried out by vibrations of the optical system (radiation source, collimator and detector), as a whole, in two mutually perpendicular directions, and simultaneous rotation of the collimator around its longitudinal axis, or moving an object relative to a stationary optical axis, around which the collimator rotates. There are also other options for scanning an investigated object. The collimator rotation speed is determined by the exposure time necessary to create an image of the transmitted region of the object in the scattered and transmitted rays without scattering on the detector. The required exposure can be obtained in one revolution of the collimator or in several. The scanning speed of an object is also determined by the time it takes to create the necessary exposure on the detector for each area of the object under study.

 The devices described above for their successful operation include the formation of a narrowly collimated transmission beam, which imposes restrictions on the efficiency of use of energy produced by an x-ray source. Another variant of the described device allows to distinguish similar substances by their scattering and absorbing properties when using a wide beam of penetrating radiation. This embodiment of the device is characterized in that the collimator is a multi-gap periodic structure that forms the x-ray flux in the form of a wide beam modulated with a high spatial frequency. A detector with high spatial resolution in the registration plane measures a periodically modulated distribution of the radiation intensity in the presence and absence of an object. The presence of an object in the device leads to a change in the modulation function of the intensity distribution in the plane of the detector, which allows you to determine the following parameters of the test substance: a decrease in the average value of the intensity along the direction of modulation of the beam determines the amount of X-ray absorption by various parts of the object, and the change in the depth of modulation of the intensity distribution contains implicitly scattering function of the object. When comparing the obtained results with the existing database, these parameters allow us to identify the substances that make up the studied object. To detect inhomogeneity in an object occupied by the substance under study, it is necessary that the period of spatial modulation of radiation in the object be at least two times smaller than the size of the inhomogeneity itself.

 The sensitivity of the described setup to recording the intensity of scattered radiation is determined by the spatial frequency and depth of modulation of the incident radiation and the resolution of the detector used. The higher the spatial frequency of the radiation modulation and the greater the depth of the modulation, the stronger the distribution function of the radiation intensity will change when an object is introduced. However, the maximum values of the permissible spatial frequency of the radiation modulation are limited by the parameters of the modulator used and the resolution of the detecting elements. The spatial sensitivity of the detector should be less than the period of spatial modulation of the radiation, preferably an order of magnitude.

 Based on the principles described above for detecting penetrating radiation coherently scattered at small angles, a facility has been built to determine the percentage of known substances in the object under study. The described device contains a source of penetrating radiation, a measuring and reference system and an information processing system. The measuring part of the device consists of a collimator that generates a radiation flux incident on the object in the form of a narrow, slightly divergent beam, a position-sensitive detector, and a device for scanning an object with an x-ray beam. As a reference system, a device is used, similar to the measuring part of the described installation, using radiation of the same source, where the illuminated object is a plate of known thickness from a reference substance.

 The physical essence of the operation of the device is based on the fact that for a mixture of substances having a thickness optimal for a single scattering of penetrating radiation, each of the substances will scatter independently, and the intensities of the radiation scattered by the object at separate angles will add up to scattering by each of the substances entering additively, and their contribution will be determined by the concentration of scattering centers of a certain kind. Therefore, by measuring the small-angle scattering of the studied object and comparing it with the normalized scattering of substances contained in the object, we can determine the contribution of each substance, i.e. its amount in the area of the transmission beam.

 As an example of such a device, we consider an installation for determining the quality of meat products on a conveyor, for example, the relative content of meat and fat in the studied object. When the object under study is X-rayed, the detector in the measuring system determines the intensity of the scattered radiation by the object at each moment in time and transfers the received data to the information processing unit. There they are compared with the scattering data of X-ray beam radiation by a model object in a reference system. A comparison of the intensities of the radiation scattered by the model and the studied object is carried out for each angle from the recorded range, and the number of scattering centers of each sort in the studied object is determined by their ratio. This allows you to determine the relative content of substances in the illuminated region of the investigated object. The use of a comparative measurement scheme, i.e., measuring and reference penetrating radiation beams, eliminates measurement errors caused by the instability of the source. In addition, such a device circuit allows the use of polychromatic penetrating radiation.

 Since the scattering curve of a substance changes with a change in the wavelength of the penetrating radiation of the source, in the case of using polychromatic penetrating radiation, the scattering curve will be a superposition of the scattering curves of radiation of each wavelength of the object under study. Using a reference beam, i.e. scattering of radiation from a model object, allows you to take into account the spectral composition of the radiation source during measurements.

 The number of angles from the small angle range at which intensity values are measured depends on the total number of substances entering the object. For objects consisting of two to three substances, it is enough to measure the values of the intensity of the scattered radiation at several different angles. More complex objects require measurements at dozens of different angles and increase the accuracy of determining the intensity of radiation scattered at each of the angles due to a set of measurement statistics.

 In FIG. 1 shows a schematic diagram of a device for mammography with a difference scheme for recording scattered radiation; in FIG. 2 - a device for small-angle topography with a rotating collimator; in FIG. 3 - a device for diagnosing an object with a spatially modulated radiation flux with a modulator, which is a block of opaque material with transparent slit-like channels; in FIG. 4 is a schematic diagram of a device for determining the relative content of known components in a test object.

 Figure 1 shows the first embodiment of the device, based on the principles of simultaneous registration of radiation transmitted through the object and scattered by it at small angles, which implements the method for determining the composition and structure of an inhomogeneous object as claimed in claim 1. This is a general setup for mammography research. From the source of x-ray radiation 1, the flow is directed to a stationary object 2, mounted in the holder 3. The collimator 4, made in the form of two slit diaphragms, input 5 and output 6, forms the radiation incident on the object 2 in the form of a dashed beam having an angular intensity distribution in one shape direction is close to the δ-function. The intensity distribution of the radiation transmitted through the object is recorded by a high-resolution two-coordinate detector 7. The dimensions of the individual elements of the detector 7 should be less than half the width of the X-ray beam intensity distribution in the registration plane, preferably by an order of magnitude. All optical elements of the device (source 1, collimator 4 and detector 7) are able to move around a stationary object 2, in order to scan it, to obtain a complete picture of the internal structure of the studied object. The presence of small-angle scattering in the object leads to a redistribution of the radiation intensity in the primary beam incident on the object. The distribution of the radiation intensity in the beam behind the object recorded by the detector 7 makes it possible, in comparison with the database, to determine the presence of structural changes in the illuminated region of the object 2, leading to this result. Moreover, at the same time, the detector registers the absorption of radiation by the object, i.e. for the entire time of scanning, he forms an image of the internal structure of the studied object in absorbing contrast.

 To increase the accuracy of measuring the distribution of radiation intensity in the zone of the primary beam 8 behind the object in the device, it is possible to change the distance of the detector-sample (slide 9) in order to increase the number of recording elements of the detector per unit angle of radiation scattering. This makes it possible to study weakly scattering objects, i.e. register small changes in the distribution of radiation intensity behind the object.

 Another way to increase the sensitivity of the device to detect radiation scattered at small angles is to use a dark-field registration scheme, which provides for separate registration of radiation transmitted through the object and radiation scattered by the object at small angles and extending beyond the boundaries of the primary beam. To this end, the installation provides the possibility of introducing into the channel of the primary beam 8 behind the object of the trap 10, which removes radiation transmitted in the direction of the primary beam from the registration zone. The introduction of the trap is carried out using a micromotor 11, at the command of the operator or in automatic mode. However, both methods lead to a significant decrease in the radiation flux density at the detector and an increase in the exposure dose of the object.

 Additionally, the device provides the ability to change the size of the input diaphragm 5 using a micromotor 12. Controlling the size of the diaphragm (penetrating radiation beam) allows you to change the irradiation mode of the object and the resolution of inhomogeneities in the object under study at the operator's command.

 Thus, the setup described above can operate in various modes: a high-intensity mode with a low exposure dose to the object, a high-resolution mode of the details of the object under study, and a mode highly sensitive to scattered radiation, requiring an increase in the radiation dose of the object. Switching from one mode to another can be carried out at the operator’s command, depending on the nature of the object being studied.

 As can be seen from FIG. 2, the described device can also be made with a collimator 4 rotating around its longitudinal axis. This installation option is designed to study objects that differ in the anisotropy of scattering (diffraction) properties, i.e. having a different distribution of electron density in different directions. The collimator 4 forms the incident radiation flux from the source 1 in the form of a dashed beam 13. When the collimator rotates, the beam plane intersects the object 14 at different azimuthal angles. At a position-sensitive detector 7, for each fixed position of the beam 13, the radiation transmitted through the object and the radiation scattered through it is recorded simultaneously according to the above-described scheme. For one revolution of the collimator 4, the detector 7 registers the total distribution of the absorbing and scattering properties of the studied object in the translucent region in a plane perpendicular to the direction of beam incidence. The sizes of the translucent region are determined by the longitudinal dimensions of the dashed beam at the object. This registration method allows you to more accurately identify the substances that make up the studied object, according to the scattered radiation, because there is an additional parameter (spatial distribution of electron density), which allows to distinguish between similar substances. In addition, the quality of the image obtained in the absorbing contrast is improved, since the use of a narrowly collimated beam reduces the spurious radiation scattering in the object.

 Another embodiment of the apparatus described, shown in FIG. 3, allows to distinguish substances by their scattering and absorbing properties when using a wide beam of penetrating radiation. The source 1 directs the penetrating radiation flux to the studied object 15. Between the object and the radiation source there is a collimator 16, which forms the incident penetrating radiation flux in the form of a wide beam modulated with a high spatial frequency. The collimator can be made in the form of a periodic structure, for example, a slit raster, the period and dimensions of the slits of which determine the spatial frequency and modulation depth of the transmission beam. Beams of penetrating radiation formed by the collimator can overlap in the registration plane. The two-coordinate position-sensitive detector 17 should provide a high spatial resolution such that the dimensions of the individual recording elements are less than the spatial modulation frequency of the transmission radiation in the registration plane, preferably by an order of magnitude. The intensity distribution of penetrating radiation recorded by the detector 17 in the presence and absence of an object makes it possible to obtain an image of the internal structure of the studied object in absorbing contrast, modulated with the appropriate frequency, and to determine the scattering function of the substances constituting the object by changing the depth of modulation of transmitted radiation. When comparing the obtained results with the existing database, these parameters allow us to identify the substances that make up the studied object. To obtain a complete picture of the internal structure of the object, it is necessary to ensure scanning of the object with a beam of penetrating radiation according to one of the schemes described above.

 In FIG. 4 is a general diagram of an apparatus for determining the percentage of known substances constituting an object under study that implements a method for determining the composition and structure of a heterogeneous object, as presented in paragraph 2 of the claims. The described device contains a source of penetrating radiation 18, a measuring system, a reference system, as well as a system for analyzing and processing information. The collimator 19 forms a radiation stream in the form of a narrow, slightly divergent dashed beam incident on the studied object 20, which is transported by means of a conveyor 21. As a collimator, for example, the Kratky collimator can be used. The beam size and the divergence in the direction of motion of the object must correspond to the conditions for detecting small-angle scattering of penetrating radiation in the required angular range, and in the perpendicular direction, overlap the entire controlled object as a whole. The radiation scattered by the object is detected by a two-coordinate position-sensitive detector 22. The small-angle scattering curve measured by the detector 22 from the studied object 20 will be a superposition of the scattering curves of each of the substances entering the object, and each substance will scatter independently, and the values of the intensities of the radiation scattered object at separate angles, will be added up from the scattering by each of the substances that make up the object, additively, and their contribution will be determined by concent walkie-talkie scattering centers of a certain variety. The data obtained are transmitted to the information processing unit 23, where they are compared with the normalized scattering curves of substances contained in the object, and the contribution of each substance is determined, i.e. its amount in the area of the transmission beam. The results of processing the measurement data are displayed on the screen of the video monitor 24. To obtain accurate quantitative results, it is necessary to constantly monitor the energy, and, in the case of using a polychromatic source, the spectral composition of the penetrating radiation. This implements a reference system.

 As such a reference system, a device similar to the measuring system of the described installation and using radiation of the same source is used. It consists of a collimator 25 and a position-sensitive detector 26. As a translucent object, a plate 27 of known thickness from a reference substance is used. Data on the scattering curve measured by the detector 26 is also supplied to the information processing unit, where it is used in processing the data obtained during transmission of the test object 20.

 The device can be calibrated so that the concentration of known substances in the test object is determined immediately from a comparison of the intensities of the radiation scattered by the test object 20 and the reference plate 27 at several different angles. The number of intensity measurements at various angles is determined by the complexity of the object under study, i.e. total number of substances contained in it. The greater the amount of substances contained, the larger the number of angles it is necessary to measure the values of the intensity of small-angle radiation scattering by the studied object, the higher should be the resolution of the detector 22.

Claims (6)

 1. A method for determining the composition and structure of an inhomogeneous object, which consists in irradiating a controlled object with a narrow low-dispersing beam of penetrating radiation, detecting radiation transmitted through the object using a high-resolution two-coordinate position-sensitive detector and identifying substances entering the controlled object by small-angle coherent scattering of radiation transmitted through the object and radiation absorbed in the object, characterized in that the intensity distribution from radiation over the beam cross section in the absence and presence of an object, the resulting intensity distributions in the presence and absence of an object are normalized to the total intensity of the incident and transmitted radiation, respectively, and to the change in the normalized spatial intensity distribution due to the scattering of radiation at small angles by the substances entering the object and comparing it with the reference values previously obtained under the same conditions, the substances entering the object are identified.  2. A method for determining the composition and structure of an inhomogeneous object, which consists in irradiating a controlled object with a narrow low-dispersing beam of penetrating radiation, detecting radiation transmitted through the object using a high-resolution two-coordinate position-sensitive detector and determining the content of substances entering the controlled object by small-angle coherent scattering of the transmitted through the object radiation, characterized in that they record the distribution of radiation intensity over the cross section of the past through the controlled beam object and simultaneously from the same radiation source, the distribution of the radiation intensity over the cross section of the beam passing through the standard sample is recorded, and from the comparison of the intensities scattered at the same non-angles for each beam, the substance content in the controlled object is determined.  3. A device for determining the composition and structure of an inhomogeneous object, containing a source of penetrating radiation, a collimator forming a narrow, slightly divergent beam of radiation in the direction of the object being studied, detecting a two-coordinate spatially sensitive detector transmitted through the object and an information processing unit connected to the detector, characterized in that the two-coordinate position-sensitive detector is installed from the object under study at a distance at which the dimensions of individual regis the detector’s trimming elements is less than the half-width of the intensity distribution in the beam in the registration plane, while the beam formed by the collimator in the projection of the object in at least one direction is already the area occupied by the controlled substance in the object and the device is equipped with a system that provides relative movements of the source, collimator and detector relative to the object .  4. The device according to claim 3, characterized in that the collimator forms a beam of penetrating radiation having a rectangular shape in cross section and is configured to rotate around its longitudinal axis.  5. The device according to claim 3 or 4, characterized in that the detector is equipped with a means of moving it along the beam of penetrating radiation.  6. A device for determining the composition and structure of an inhomogeneous object, containing a source of penetrating radiation, a collimator, which is a slit-like structure, forming a set of narrow, low-diverging radiation beams in the direction of the object under study, which records a two-coordinate spatially sensitive detector transmitted through the object and a block associated with the detector information processing, characterized in that the period of the multipurpose structure is selected from the condition of providing a period of spatial th modulation of radiation at least twice smaller than the region occupied by the controlled substance in an object, and the sizes of individual recording elements xy spatially sensitive detector shall be less than the spatial frequency of the radiation transmission modulation in the recording plane is preferably on the order.

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