The technical field of the invention is the analysis of an object by spectrometric analysis of ionizing radiation diffracted by said object. The invention applies equally well to analysis of biological tissues for diagnostic purposes and to non-destructive testing in the industrial field or for applications linked to security.
Energy Dispersive X Ray Diffraction (EDXRD) spectrometry is a nondestructive analysis technique used for the identification of materials constituting an object. This technique is based on the elastic scattering of an ionizing electromagnetic radiation, also termed Rayleigh scattering. It has already been applied in the detection of explosives or other elicit substances. Generally speaking, this technique consists in irradiating an object with poly-energetic X rays and determining the energy spectrum of radiation scattered by the object at low scattering angles, typically between 1° and 20° inclusive, relative to the trajectory of the X rays incident on the object. The analysis of this spectrum makes it possible to identify the materials constituting the object. In fact, most materials have a particular spectral signature, depending on their atomic or molecular structure. Comparison of the measured scattering spectra with signatures of known materials makes it possible to determine the composition of the object.
In devices known until now, a source of irradiation produces poly-energetic X rays propagating toward an object, a primary collimator or pre-collimator being disposed between the source and the object so as to form a finely collimated beam of X rays toward the object. A second collimator is then placed between the analyzed object and a detector adapted to acquire an energy spectrum of the radiation scattered by the object.
The volume of the analyzed object corresponds to an intersection between said beam, propagating through the object, and an observation field of the detector, that field being defined, among other things, by the aperture of the second collimator and the size of the detector. Accordingly, for the same detector, the observation field is proportional in size to the aperture of the second collimator. This makes it possible to increase the volume of the observed object and to increase the quantity of scattered radiation detected.
However, if the observation field is increased, the detector may detect photons scattered by different parts of the object with different scattering angles. Now, the scattering angle is a key parameter because it makes it possible to convert the measured data, taking the form of energy spectra, into spectral signatures representative of the material constituting the examined object, the latter generally being expressed in the form of a magnitude termed the momentum transfer. Moreover, the analyzed object may not be homogeneous and comprise different parts, each of these having its own spectral signature. It is therefore of interest to be able to divide the object spatially into different elementary volumes and to determine a spectral signature, termed the scattering signature, associated with each of these elementary volumes.
Because of this, an angular and/or spatial dispersion function of the measuring device must be determined during a calibration procedure. The inventors have established an experimental method making it possible to obtain a dispersion function of this kind.
One object of the invention is a method of calibrating a device for analyzing an object, said analysis device including:
The term “peak parameter” means an intensity (or amplitude) of the peak, that is to say a parameter representing the area or the height of that peak, and/or an energy associated with that peak, that is to say a parameter representing the energy with which that peak is detected.
According to an embodiment,
According to an embodiment,
In this embodiment, step f) may include determining a mean scattering angle for said pixel.
According to an embodiment:
The calibration object is an object the composition of which is known.
According to one embodiment, the detector includes a plurality of pixels and the method includes a determination of said dispersion function for each pixel. The pixels can be virtual pixels produced by sub-pixelization of physical pixels of the detector.
Another object of the invention is an information storage medium readable by a processor including instructions for the execution of the steps c) to e) of the calibration method described above using acquisition spectra acquired by a pixel of a detector, the spectrum being acquired according to the steps a) and b) of the calibration method described above, those instructions being executable by the processor.
The device includes a first collimator or pre-collimator 30 adapted to collimate the radiation emitted by the irradiation source 11 to form an incident collimated beam 12cpropagating towards the object along a propagation axis 12z The device also includes a detector 20 including pixels 20k, each pixel being adapted to detect radiation 14□scattered by the object 10 in a direction at a scattering angle θ relative to the propagation axis 12z This radiation results for example from elastic scattering of radiation forming the incident collimated beam 12c.
The analysis device 1 includes a second collimator 40 disposed between the object 10 and the detector 20. The second collimator 40 makes it possible to direct selectively scattering radiation 14θ scattered by the object 10 at a scattering angle θ relative to the propagation axis 12z in an angular range Δθ. By directing selectively is meant that radiation scattered at an angle not included in this angular range Δθ is attenuated by the second collimator.
The analysis device 1 is placed in a frame of reference to which is tied an orthogonal frame of reference X, Y, Z as represented in
The term ionizing electromagnetic radiation designates electromagnetic radiation consisting of photons with an energy greater than 1 keV and preferably less than 5 MeV. The energy range of the ionizing radiation may be between 1 keV and 2 MeV inclusive, but most often lies between 1 keV and 150 keV or 300 keV. The ionizing radiation may be X radiation or γ radiation The ionizing radiation source is preferably poly-energetic, the incident radiation being emitted in an energy range generally extending over several tens or even hundreds of keV. It is notably a tube emitting X rays.
The irradiation source 11 is an X ray tube with a tungsten anode at a voltage, generally between 40 and 170 kV inclusive, that can be varied in order to modify the energy range of the incident radiation 12. The detector includes pixels distributed along a line or in a two-dimensional matrix, each pixel extending over an area of 2.5*2.5 mm2, its thickness being 5 mm. The material constituting each pixel is a semiconductor, for example CdTe or CdZnTe or any other material adapted to produce spectrometric measurements, preferably at room temperature. It could equally be a scintillator type material, with sufficient energy resolution. The detector is energy resolved and each pixel makes it possible to obtain spectra with energy channels of the order of 1 keV. The irradiation source 11 may include a screen made of metal, for example copper, to block the propagation toward the pre-collimator 30 of radiation with an energy less than 20 keV. When this screen is made of copper, its thickness is equal to 0.2 mm, for example.
The first collimator or pre-collimator 30 includes a block of dense material 31, including tungsten, for example, adapted to absorb virtually all of the radiation 12 emitted by the irradiation source 11. It includes a narrow opening 32 extending along a so-called propagation axis 12z allowing the passage of a narrow collimated beam 12c. By narrow opening is meant an opening the diameter or the largest diagonal of which is less than 2 cm, or even less than 1 cm. In this example, the opening is a cylinder of 1 mm diameter.
The object 10 may be an industrial component the quality or the composition of which it is wished to determine. It may equally well be luggage to be checked. The device 1 is then used for nondestructive testing purposes. It may equally be living biological tissue, for example a part of the body of an animal or of a human being. The device is then a medical analysis device used to assist diagnosis. The body part may in particular be an organ in which, following a first examination, for example an X ray or a scan, the presence of an anomaly is suspected, in particular a cancerous tumour.
The second collimator 40 includes walls 41 made from a dense material adapted to absorb virtually all of the radiation 14θ scattered by the object outside the angular range previously referred to. An opening in said dense material defines a channel 42 extending along a median axis 45. By median axis is meant an axis extending along the channel equidistantly from the walls delimiting the channel. This median axis 45 is inclined relative to the propagation axis 12z of the incident collimated beam 12c. The angle Θ between the median axis 45 of the channel 42 and the propagation axis 12z, termed the collimation angle, is strictly greater than 0° and less than 20°. The collimator is then able to transmit toward the detector 20 scattered radiation 14θ propagating at an angle, termed the scattering angle θ, in a defined angular range Δθ around the collimation angle Θ.
In the embodiment represented in
The radiation detector is a detector comprising pixels 20k arranged in a plane P20 termed the detection plane. The index k designates a coordinate of each pixel in the detection plane P20. The pixels may extend along a line but generally extend in a two-dimensional regular matrix. In the example described in this application, the detection plane P20 extends in a direction at an angle a strictly less than 90° relative to the propagation axis 12z of the collimated incident radiation 12c. This angle α is preferably between 70° and 88° or 89°. The detection plane P20 is preferably orthogonal to the median axis 45 of the channel 42 of the second collimator 40.
Each pixel 20k constituting the radiation detector 20 includes:
Each pixel 20k is therefore adapted to produce a spectrum SkE of the radiation 14θ scattered by the object.
The term energy spectrum designates a histogram of the amplitude A of the signals detected during a period of acquisition of the spectrum. A relation between the amplitude A of a signal and the radiation energy E can be obtained by means an energy calibration function g such as E=g(A), according to principles known to the person skilled in the art. An energy spectrum SkE, can therefore take the form of a vector, each term SkE(E) of which represents a quantity of radiation detected by the pixel 20k in an energy range
where ∂E is the spectral width of an energy discretization increment of the spectrum.
The device also includes a calculation unit or processor 22, for example a microprocessor, adapted to process each spectrum SkE acquired by the pixels 20k of the detector 20. In particular, the processor is a microprocessor connected to a programmable memory 23 in which is stored a sequence of instructions for effecting the spectrum processing and calculation operations described in the present description. These instructions may be saved on a storage medium that can be read by the processor, of the hard disk, CDROM or other memory type. The processor may be connected to a display unit 24, for example a screen.
Each pixel 20k is connected to an electronic circuit 21 for collecting signals representative of the energy of scattering radiation transmitted by the collimator 40. The detector 20 may be connected to the processor 22 described above, making possible a first stage of processing consisting in analyzing the signals emitted by a plurality of adjacent pixels so as to locate the point of impact of the detected radiation with a spatial resolution less than the increment at which these pixels are distributed. This kind of processing, known to the person skilled in the art as sub-pixelization or super-pixelization, amounts to forming so-called virtual pixels 20′k, the area of each virtual pixel being less than 1 mm * 1 mm or even 0.5 mm by 0.5 mm, for example. In the present example, the size of the virtual pixels is 150 μm by 150 μm. This increases the spatial resolution of the detector 20. This kind of decomposition of the virtual pixels is known to the person skilled in the art. It has already been described in Warburton W. K., “An approach to sub-pixel spatial resolution in room temperature X-ray detector arrays with good energy resolution” and Montemont et al. “Studying spatial resolution of CZT detectors using sub-pixel positioning for SPECT”, IEEE transactions on nuclear science, Vol. 61, N°5, October 2014.
In the remainder of the text, references to pixels 20k may refer interchangeably to physical or virtual pixels. This preferably means virtual pixels because of the improved spatial resolution of the detector this achieves.
The device 1 preferably includes a so-called auxiliary detector 200 in a so-called transmission configuration adapted to detect not radiation scattered by the object retained on the support but instead radiation 140 transmitted by the object 10 in the direction 12z of the incident beam 12c. This so-called transmission radiation is transmitted by the object 10 without having interacted with it. The auxiliary detector 200 makes it possible to establish a spectrum S0E of the radiation 140 transmitted by the object 10 along the propagation axis 12z of the incident collimated beam 12c. This kind of spectrum can be used to determine an attenuation spectral function Att of the object, as described later.
During the analysis, the object 10 is irradiated by the incident poly-energetic beam 12c.
Because of the effect of the Rayleigh scattering, a portion of the incident radiation 12c is scattered in a plurality of directions, the scattering radiation intensity being higher or lower according to the combination of the energy of the photons and the scattering direction. This variation of intensity as a function of the scattering angle θ form a scattering signature specific to each material. In the case of a crystal, the scattering intensity is non-zero only in precise incident photon energy/scattering angle pair configurations defined by the Bragg equation:
where:
It is common to express a magnitude designated by the term momentum transfer and represented by the letter χ, expressed in nm−1, as follows:
To each pixel or virtual pixel 20k of the detector 20 there corresponds a so-called mean scattering angle θk representing the most probable angle at which scattering radiation 14θ detected by the pixel propagates. The benefit of super-pixelization is to end up with small pixels, which reduces the angular range of the scattering radiation likely to reach one of them.
The main steps of the analysis of an object are described next with reference to
During a first step 100, the object 10 is irradiated by the irradiation source 11 and each pixel 20k of the detector 20 acquires a spectrum SkE of the scattering radiation 14θ to which it is exposed. In this example, the collimation angle Θ may be between 1° and 20° inclusive. The exponent E represents the fact that here the spectrum is a function of energy. Knowing the scattering angle θk associated with each pixel 20k, it is possible to express a scattering spectrum not as a function of energy but as a function of the momentum transfer χ by proceeding to a change of variable according to equation (2), in which case the spectrum is designated Skχ.
The energy spectrum may be expressed according to the following equation:
SkE=Dk·(Sinc×Att×(Ak·fkχ)) (3)
where:
where θk represents a mean scattering angle associated with the pixel 20k concerned. The determination of this mean scattering angle θk will be explained hereinafter;
Moreover, in this example, it is considered that the energy resolution of the detector is good enough for the response matrix Dk of each pixel 20k to be considered as being the identity matrix.
Equation (3) becomes:
SkE=Sinc×Att×fkE (5)
where fkE is the scattering function measured by each pixel 20k as a function of energy. From this scattering function, expressed as a function of the energy E, it is possible to establish a scattering function fkχ estimated as a function of the momentum transfer χ, the passage between the vectors fkE and fkχ being established by applying the aforementionned matrix Ak, with fkE=Ak·fkχ
In steps 120 and 140, a reference scattering spectrum Sk,refE, obtained for each pixel 20k, by placing a reference object 10ref made of a known material instead of the object 10, is considered. The scattering properties of the reference object are known. It is then possible to establish a reference scattering function fk,refE, fk,refχ associated with each pixel 20k. Obtaining this reference scattering function will be described in detail hereinafter. Considering that the spectrum Sinc of the incident collimated beam 12c does not change between the measurement of the scattering spectrum Sk,refE of the reference object and the measurement of the scattering spectrum SkE of the object to be analyzed, the spectrum of the radiation scattered by each pixel 20k may be expressed as follows:
Sk,refE=Sinc×Attref×fk,refE (6)
where Attref is an attenuation spectral function of the reference object 10ref.
It is then possible to form a scattering spectrum denoted S′kE normalized by said reference scattering spectrum Sk,refE and such that:
This normalization constitutes the step 120. It is possible to determine from this normalized spectrum a scattering function fkχ of each pixel 20k, which constitutes the step 140, according to the expression:
Thus,
where fk,refχ is the reference scattering function associated with the pixel, expressed as a function of the momentum transfer.
Accordingly, knowing Attref, fk,refχ, Att and having measured SkE, it is possible to estimate fkχ using expression (8).
The aim of step 160 is to obtain a scattering signature representative of each elementary volume of the object from the respective scattering functions fkχ obtained by each pixel 20k. In fact, given the angular aperture of the collimator, the same pixel 20k can detect different scattered radiations from respective different elementary volumes.
This spatial dispersion is characterized by an intensity spatial dispersion function gk, each term gk(z) of which representing an intensity of the radiation scattered by an elementary volume Vz centred on a coordinate z and reaching a pixel 20k. This dispersion function gk is established for each pixel 20k. Establishing this dispersion function gk will be described hereinafter.
An intensity spatial dispersion matrix G can be constituted, each row of which is formed by the various values of the intensity spatial dispersion function gk associated with a pixel 20k as a function of z. Each term G(k,z) of the matrix G represents the intensity of the signal detected by a pixel 20k and coming from an elementary volume Vz centred at z. In other words, G(k,z)=gk(z).
The step 160 amounts to taking account of this dispersion matrix in constituting a matrix Fk each row of which represents a scattering function fkχ obtained by a pixel 20k. Each term Fk(k,χ) of this matrix represents a value of the scattering function fkχ measured, at the value χ, by a pixel 20k. The dimension of this matrix is (Nk, Nχ), where Nk is the number of pixels.
The aim is to constitute a matrix Fz of scattering signatures of the object 10 each row of which representing a spectral signature fzχ relating to an elementary volume Vz centred at z. Each term Fz (z,χ) of this matrix represents a value of the scattering signature (or form factor) at the value χ of an elementary volume Vz. The dimension of this matrix is (Na, Nχ), where Nz is the number of elementary volumes Vz concerned.
The intensity spatial dispersion matrix G establishes a connection between the scattering functions of each pixel forming the matrix Fk and the signatures of each elementary volume forming the matrix Fz such that: Fk=G.Fz (9).
It is then a question of obtaining information characterizing the radiation scattered by each elementary volume on the basis of measurements collected at the level of each pixel.
Having determined the intensity spatial dispersion matrix G and having formed from the measurements the matrix of the scattering functions Fk, it is possible to obtain an estimate of the matrix of the scattering signatures Fz using an inversion algorithm. The iterative inversion algorithms commonly used include a maximum likelihood expectation maximization (MLEM) type algorithm. According to an algorithm of this kind, the value of each term of the matrix Fz may be estimated using the following expression:
the exponent n designating the rank of each iteration. Each iteration then makes it possible to obtain an estimate {circumflex over (F)}Zn of the matrix Fz.
The iterations continue until a convergence criterion is reached, which may be a predetermined number of iterations or a low variation between the values estimated during two successive iterations. The use of this algorithm assumes a step of initialization of the matrix Fz. For example, this initialization is such that:
At the end of step 160, an estimate of the matrix Fz is obtained, each row of which represents a scattering signature fzχ of a material constituting an elementary volume Vz of the object 10.
During a step 180, the material constituting each elementary volume Vz is identified from the associated scattering signature fiχ. For this purpose standard scattering spectral signatures fiχ of various known standard materials 10i are provided. These calibration scattering signatures are either established experimentally or obtained from the literature. The proportions γz(i) of the material 10i in the elementary volume Vz may be determined from the expression:
(γz(i=1) . . . γz(i=Ni))=Argmin(∥fzχ−Σiγz(i)fiχ∥2)
where Ni is the number of known calibration materials 10i.
A vector γz is obtained each term γz(i) of which represents a proportion of the material 10i in the elementary volume Vz.
The method described above assumes the prior establishment of calibration parameters of the measuring system. To be more precise, the method uses for each pixel dispersion functions representing a dispersion of the intensity and/or the scattering angles of scattered radiation detected by said pixel as a function of the positions in the object from which said scattered radiation is emitted. Thus each pixel 20k can be associated to:
One object of the invention is to establish at least one of these dispersion functions, in particular experimentally, the inventors considering that this kind of determination is more reliable than modelling based on calculation codes.
Obtaining the Intensity Spatial Dispersion Functions gk
The passage between the scattering functions fkχ measured by a pixel and the scattering signatures fzχ of the radiation emitted by an elementary volume Vz requires the use of intensity spatial dispersion functions gk associated with each pixel 20k from which it is possible to establish the intensity spatial dispersion matrix G described above with reference to the step 160. These intensity spatial dispersion functions gk can be obtained experimentally, using a calibration object 10c consisting of a known material taking the form of a thin plate that can be moved successively along the propagation axis 12z of the incident collimated beam 12c. By thin plate is meant a width in the order of that of an elementary volume, i.e. in the order of the spatial resolution that it is required to obtain.
The calibration object 10c is chosen so that its scattering signature, i.e. the momentum transfer spectrum of the scattered radiation during the irradiation of this object, features characteristic peaks. There may for example be chosen aluminium, 3 mm thick, having a characteristic peak at 2.0248 Å. This corresponds to a momentum transfer χ=2.469 nm−1. The thickness of the calibration object must be consistent with the required spatial resolution. It may be between 1 mm and 1 cm inclusive if a spatial resolution better than 1 cm is required, for example.
Let us consider for example a pixel 20k configured essentially to receive scattering radiation emitted at an angle θ of 2.5°.
Intensity values Ik,c,z are then available representing a quantity of photons detected by a pixel 20k in a representative peak of the calibration object 10c when the latter occupies a position z in the object.
It is then possible to establish the intensity spatial dispersion matrix G as represented in
The determination of the spatial dispersion matrix G therefore comprises the following steps:
At some positions z of the calibration object 10c, the calibration spectrum Sk,c,zE measured by a pixel 20k may not include an identifiable calibration peak. In this case, this calibration spectrum is not taken into account to determine the dispersion function associated with the pixel.
Obtaining the Scattering Angles Spatial Dispersion Function hk
Refer again to
On each calibration spectrum Sk,c,zE acquired by a pixel 20k, and preferably normalized by the transmission spectrum S0,cE the energy Ek,c,z is determined corresponding to a representative calibration peak of a material constituting the calibration peak. This material being known, the momentum transfer corresponding to the energy of the calibration peak is also known, for example χ=2.469 nm−1 for aluminium. The step 230 determines the energy Ek,c,z of the calibration peak.
The scattering angle θk,c,z associated with this peak can be obtained using expression (2), knowing the energy Ek,c,z. Accordingly, with each position z for which the calibration spectrum Sk,c,zE has an identifiable calibration peak, there may be associated a scattering angle θk,c,z of the scattering radiations detected by the pixel 20k. The step 235 determines this scattering angle. If the calibration material occupies certain positions z, a pixel may collect no scattering radiation. In this case, the calibration spectrum Sk,c,zE does not cause any meaningful peak to appear and there is no therefore scattering angle associated with the pixel at this position.
The distribution of the scattering angles θk,c,z of the scattered radiation detected by a pixel 20k as a function of the position z constitutes a spatial dispersion function of the scattering angles hk of said pixel such that hk(z)=θk,c,z, where θk,c,z is one of the scattering angles determined at a position z of the calibration object. This function is determined in the step 260. Each row k in
Moreover, for each pixel 20k/position z pair there may be established an intensity Ik,c,z of a calibration peak, as described with reference to the determination of the intensity spatial dispersion function gk.
A mean scattering angle θk for a pixel 20k can be determined by producing a mean of each scattering angle θk,c,z corresponding to a position z weighted by the intensity Ik,c,z of the calibration peak corresponding to that same position.
In other words,
θk representing the mean scattering angle associated with the pixel 20k. The spectra recalibrated in this way, denoted Skχ because they depend on the momentum transfer, have been summed so as to constitute a cumulative spectrum Sχ of the momentum transfer. This spectrum is represented in
Obtaining Intensity Angular Dispersion Functions jk
For each pixel 20k it is possible to establish both the intensity Ik,c,z and the scattering angle θk,c,z of a calibration peak obtained over a calibration spectrum Sk,c,zE when the calibration object 10c is placed at each position z. An intensity angular dispersion function, jk, can then be obtained for said pixel. It is then expressed in the form jk(θ)=Ik,c,z when θ=θk,c,z. Referring to
Each intensity angular dispersion function jk can be interpolated in order to obtain a continuous distribution between the various angles θk,c,z. A so-called interpolated intensity angular dispersion function jki is then obtained, the exponent i designating the fact that the angular dispersion function is interpolated.
For each pixel 20k, the interpolated intensity angular dispersion function jki associated with a pixel 20k makes it possible to establish the angular response matrix Ak associated with said pixel mentioned above. Each row (or column) of said angular response matrix Ak is associated with an energy E and represents a probability distribution of the momentum transfer χ when said pixel detects radiation with said energy E.
Using small pixels physical or virtual pixels makes it possible to limit the observation field of each pixel. Because of this, in the present example the angular dispersion matrix Ak can be considered as being the diagonal matrix, with Ak(E,χ)=1 if
this diagonal matrix represented in
Thus the determination of an intensity angular dispersion function, whether discrete or interpolated, makes it possible to establish an angular dispersion matrix for each pixel of the detector.
Obtaining the Scattering Function fk,refχ of the Reference Material for Each Pixel 20k.
The step 160 requires a knowledge of a scattering function fk,refχ of each pixel 20k when it detects scattering radiation coming from the reference material 10ref. In the presence of such a material, occupying all the elementary volumes Vz in the observation field of the second collimator 40, the scattering signature fZ,refχ of each elementary volume Vz corresponds to a scattering signature frefχ of the reference material, which is known and common to all the elementary volumes. The scattering function fk,refχ of each pixel is obtained from expression (9), constituting a matrix FZ,ref each row of which corresponds to the scattering signature frefχ of the reference material. There is obtained a matrix Fk,ref=G.FZ,ref (16), each row of the matrix Fk,ref representing the scattering function fk,refχ associated with each pixel 20k of the reference object 10ref.
Obtaining Attenuation Spectral Functions
The method described above preferably assumes the use of attenuation spectral functions Att and Attref respectively representing the attenuation of the incident collimated beam 12c by the object 10 and by the reference object 10ref. These functions are respectively obtained using the auxiliary detector 200 in transmission mode, the latter measuring:
Having acquired these spectra, it is possible to define an attenuation spectral function by a comparison of those spectra, generally in the form of a ratio. Thus the attenuation Att of the object 10 is obtained by a ratio between Sinc and S0E and the attenuation Attref of the reference object is obtained by a ratio between Sinc and S0,refE. This corresponds to the following equations:
Experimental Trial
An experimental trial was carried out using a test object 10test consisting of a copper plate 10test-1 1 cm thick and an aluminium plate 10test-2 1 cm thick, these two plates being spaced by 2 cm. Here the collimation angle Θ is equal to 5°. The experimental set up is represented in
The reference measurements fk,refE and Attref making it possible to obtain scattering functions fkE of each pixel (cf. step 140) are effected using a block of PMMA 10 cm thick.
The PMMA block was placed first, before determining a transmission spectrum S0,refE, using the auxiliary detector 200. That auxiliary detector also makes it possible to measure a spectrum Sinc of the incident collimated beam 12c with no object disposed between the auxiliary detector 200 and the first collimator 30. A spectral function Attref was determined in this way for the attenuation of the reference material on the basis of a ratio between S0,refE and Sinc according to equation (21).
There was also determined the spectrum Sk,refE of the scattering radiation of the reference material, in this instance PMMA, for various virtual pixels 20k.
The attenuation spectral function Att of the test object 10test was then determined by carrying out a measurement of a spectrum by the auxiliary detector 200 with and without the test object so as to acquire the respective spectra S0E and Sinc, the ratio of which makes it possible to establish this attenuation spectral function Att according to expression (20).
There were then acquired the scattering spectra SkE of the test object by various virtual pixels 20k, those spectra being represented in
Each scattering spectrum was then normalized according to equation (7) using the spectra Sk,refE so as to obtain for each pixel g a normalized spectrum S′kE.
From each normalized spectrum S′kE there were obtained the spectral signatures fkχ of each pixel 20k expressed as a function of the momentum transfer χ (cf. equation 8) using a scattering function fk,refχ of the reference material 10ref established using equation 16.
Knowing the spatial dispersion matrix G, the scattering signature fzχ was obtained of various elementary volumes distributed in the object along the propagation axis 12z by applying equations (9) and (10). These scattering signatures are given in
The invention could be used in nondestructive testing type applications or medical diagnostic aid type applications, using a collimator including only one channel, as described in the above detailed description, or a collimator including a plurality of channels.
Moreover, although described in connection with a second collimator 40 having a single channel 42, the method of establishing dispersion functions, whether that means an angular dispersion function or a spatial dispersion function, can be applied to other types of collimation, for example collimators having a plurality of channels, for example channels disposed parallel to one another, or coded mask type collimation, by virtue of which the same pixel sees the object via different channels.
Number | Date | Country | Kind |
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15 63318 | Dec 2015 | FR | national |
Number | Name | Date | Kind |
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20040109531 | Yokhin et al. | Jun 2004 | A1 |
20100124315 | Harding | May 2010 | A1 |
20170184518 | Barbes | Jun 2017 | A1 |
Number | Date | Country |
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WO 2014045045 | Mar 2014 | WO |
Entry |
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French Preliminary Search Report (with Written Opinion) dated Sep. 23, 2016 in French Application 15 63318 filed on Dec. 24, 2015 (with English Translation of Categories of Cited Documents). |
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20170184739 A1 | Jun 2017 | US |