DE102011089595A1 - X-ray detector used for diagnostic investigation in e.g. surgery, has active matrix layers that include pixel elements which have electrical switching element for converting light into image information - Google Patents

Abstract

The X-ray detector has two detection layers (14, 15) which have scintillator layers (10,11) for converting X-radiation (16) into light (17), and active matrix layers (12,13). Each active matrix layer includes equally large pixel elements (18). The pixel elements have photodiode (20) and an electrical switching element (21) for converting light into image information. The two active matrix layers are different according to pixel sizes of pixel elements. An independent claim is included for a method for generating X-ray image.

Description

The invention relates to an X-ray detector according to claim 1 and to a method for generating an overall X-ray image according to claim 8.

In digital X-ray imaging, X-ray detectors in the form of flat-panel detectors with active read-out matrices with direct or indirect conversion of the X-ray radiation are known today. Such an X-ray detector is based on an active matrix layer of pixel elements, which matrix layer is assigned an X-ray converter layer or scintillator layer, generally pre-laminated. In a scintillator layer, incident X-ray quanta are first converted into visible light. The active matrix, e.g. made of amorphous silicon, is divided into a plurality of pixel elements each having a photodiode and one or more switching elements. In the photodiode, the light is converted into electrical charge, then by means of the switching elements e.g. stored spatially resolved and read using a drive and readout electronics.

The technical background of a flat panel detector is also on M. Spahn, "Flat detectors and their clinical applications", Eur. Radiol. (2005), Volume 15, pages 1934 to 1947 , referenced. Today's integrating flat-panel detectors produce a gray-scale X-ray image per shot, eg with a grayscale resolution of 14 or 16 bits. The gray scale x-ray image contains no information about the energy of the x-ray quanta converted in the x-ray detector. For energy-resolving X-ray imaging, recently-mentioned X-ray detectors based on CdTe and CMOS are known; However, these are very complex in the production and development.

The arrangement of several detector layers, each comprising a scintillator layer and an active matrix layer, one behind the other (normal to the x-ray source), allows the natural x-ray spectrum hardening process to be utilized as it passes through matter, and the input x-ray spectrum at the x-ray detector to be divided into its spectral regions, thereby spectral imaging to enable. This is achieved as follows: X-radiation hits a first detection layer. A portion of the X-ray quanta is absorbed in the first scintillator layer, converted into the photodiodes of the first active matrix layer, and e.g. by means of line-by-line control of TFTs (thin-film transistors) in the pixel elements. The result is a first x-ray image (i.a., a gray scale X-ray image). The remaining, e.g. Higher energy X-ray quanta are absorbed in the second scintillator layer of the second detection layer and generate a second X-ray image (i.a., gray scale X-ray image) using the same processes.

It is the object of the present invention to provide an X-ray detector with spectral X-ray imaging with high image quality or to provide a method for generating an overall X-ray image by means of such an X-ray detector.

The object is achieved by an X-ray detector according to claim 1 and by a method for generating a total X-ray image according to claim 8. Advantageous embodiments of the invention are the subject of the dependent claims.

In the X-ray detector according to the invention for converting X-radiation into image information, comprising at least two detection layers, each detection layer comprising a scintillator layer for converting X-ray quanta into light and an active matrix layer, each matrix layer comprising a plurality of pixel elements of equal size, each pixel element a photodiode and have an electrical switching element for converting light into image information, at least two of the at least two matrix layers differ in terms of the pixel sizes of their pixel elements. This means that at least two matrix layers have a different pixel resolution. The two or more detection layers can realize a dual or multiple energy resolution and thus high quality dual and multi-energy imaging and colorimaging. The different spectral components of the X-ray spectrum can be detected simultaneously and no special X-ray sources or a change in the image frequencies of the X-ray detector are necessary. By means of a lower pixel resolution in at least one matrix layer, the X-ray detector can be produced more simply and more cost-effectively than known X-ray detectors with a plurality of matrix layers with the same pixel resolution. In the case of the at least one matrix layer with a lower resolution, moreover, the defect pixel susceptibility is markedly lower and the number of read-out electronic channels required is lower.

By clever choice of the pixel resolutions of the different matrix layers, it is also possible to ensure adaptation to the physical processes (scattering, eg Compton or Rayleigh scattering in each further absorbing layer), so that in turn the image quality is particularly high due to low scattering. The X-ray detector according to the invention is also for various applications, such as those where a high pixel resolution, and those where a lower pixel resolution is desirable, suitable, for example, in the presentation of different types of tissue. A multilayer structure of an X-ray detector also produces a higher spatial resolution because two or more scintillator layers of small thickness reduce optical scattering processes compared to a thicker scintillator layer. The X-ray detector is suitable for many different applications, it can also be used eg for non-energy-resolved imaging. In this case, for example, it is only possible to measure with the first detection layer.

According to one embodiment of the invention, the at least two scintillator layers have at least two different scintillator thicknesses. The scintillator thicknesses may e.g. be adapted to different X-ray energies, so that the image quality and the relative absorption probabilities in the different scintillator layers are particularly good. For this purpose, e.g. the scintillator layer arranged above with respect to the direction of incidence of the X-ray radiation is thinner than the lower scintillator layer (s). This is particularly advantageous due to the hardening of the X-radiation. In addition, it can be advantageously provided that the at least two scintillator layers have different materials. Again, the materials can be selected adapted to the x-ray energies to be absorbed, so that a particularly good energy resolution and thus image quality is possible. For example, scintillator layers with patterned material and those with unstructured material can also be used in an X-ray detector.

According to one embodiment of the invention, each matrix layer has a pixel size of the pixel elements which is different from the pixel size of each other matrix layer, in particular in the case of a structure having three or more detection layers. Alternatively, however, e.g. two have the same pixel size in three detection layers and the third has a larger or smaller pixel size.

The uppermost matrix layer with respect to the direction of incidence of the X-ray radiation advantageously has the smallest pixel size (and thus the highest pixel resolution) and the lowermost matrix layer has the largest pixel size (and thus the lowest pixel resolution). The lowest energy X-ray that is already absorbed in the top scintillator layer is then used for imaging at the highest pixel resolution, high energy X-ray that is first absorbed in the bottom most scintillator layer is imaged with the lowest pixel resolution.

Suitably, each scintillator layer is arranged with respect to the direction of incidence of the X-radiation over the respective associated matrix layer. Alternatively, at least one scintillator layer is arranged below the respective associated matrix layer with respect to the direction of incidence of the X-ray radiation; This arrangement is referred to as back-to-back, because here then two matrix layers abut separately at most by the substrate.

Also provided according to the invention is a method for generating an overall X-ray image of an X-ray detector according to the invention having at least two detection layers, wherein X-ray image data are read from each detection layer and a single X-ray image is generated, and from the individual X-ray images, e.g. Grayscale images, an overall x-ray image, e.g. Color X-ray image is generated, which is a function of the individual X-ray images. The function may in this case be e.g. be a linear combination.

For a high-quality energy-resolution X-ray imaging, the individual X-ray images are formed by gray value images and a color X-ray image is generated during the combination.

Prior to generation of the overall x-ray image, processing, e.g. in the form of a resizing method, at least one of the individual X-ray images necessary, since they have a different pixel resolution due to the different pixel sizes. There are two alternatives for this: According to a first embodiment of the invention, at least the X-ray image with the largest pixel size (lowest resolution) is processed by a remapping method so that a processed X-ray image with a smaller pixel size (larger resolution) is created from the X-ray image. According to a second embodiment of the invention, at least the X-ray image with the smallest pixel size (largest resolution) is processed by a binning process, so that a processed X-ray image with a larger pixel size (smaller resolution) is created from the X-ray image.

The invention and further advantageous embodiments according to features of the subclaims are explained in more detail below with reference to schematically illustrated embodiments in the drawing, without thereby limiting the invention to these embodiments. Show it:

1 a side view of a known spectral X-ray detector with two detection layers,

2 1 is a side view of a spectral X-ray detector according to the invention with two detection layers with different matrix size and different scintillator thickness,

3 3 is a side view of a spectral X-ray detector according to the invention with two detection layers with different matrix size,

4 a side view of another spectral X-ray detector according to the invention with two detection layers with different matrix size and different scintillator thickness,

5 3 a side view of another spectral X-ray detector according to the invention with three detection layers with different matrix size and different scintillator thickness,

6 3 shows a side view of another spectral X-ray detector according to the invention with two detection layers with different matrix size,

7 a side view of another spectral X-ray detector according to the invention with two detection layers with different matrix size and different scintillator thickness,

8th 3 shows a side view of another spectral X-ray detector according to the invention with two detection layers with different matrix size,

9 3 shows a side view of another spectral X-ray detector according to the invention with two detection layers with different matrix size,

10 a side view of a spectral X-ray detector according to the invention with two detection layers of different surface,

11 a processing sequence according to the invention for generating a total X-ray image from a plurality of single X-ray images and

12 a processing sequence according to the invention for generating a total X-ray image of two single radiographs.

In the 1 is a view of a known X-ray spectral detector with two detection layers 14 . 15 shown whose function is already described in the introduction. The first detection layer 14 has a first scintillator layer 10 and a first matrix layer 12 on, the second detection layer 15 a second scintillator layer 11 and a second matrix layer 13 , The two matrix layers each have a multiplicity of pixel elements 18 on, each pixel element each having a photodiode 20 and at least one switching element 21 having. The pixel size of the pixel elements 18 the first matrix layer 14 and the second matrix layer 15 are the same, so that a direct superimposition of the X-ray images can be performed. The detection layers each still have a glass substrate 19 on. To read laterally on the active matrix layers are electronic elements in the form of chips 22 Arranged (chip on glass or chip on flex); In addition, there are flexible cables 23 available. X-rays 16 lower energy is absorbed, for example, in the first scintillator layer and in light quanta 17 transformed; those with higher energy radiate through the first detection layer 14 and only in the second scintillator layer 11 absorbed. This results in the spectral resolution.

In the 2 an inventive X-ray detector is shown, wherein the pixel size of the pixel elements of the first matrix layer 12 differ from the pixel size of the pixel elements of the second matrix layer. In this case, the pixel elements of the first matrix layer 12 on which the X-ray radiation first impinges (that is to say the uppermost matrix layer in relation to the direction of incidence of the X-ray radiation) is smaller than the pixel elements of the second matrix layer 13 ; the first matrix layer thus has a higher pixel resolution than the second matrix layer. As a result, the scattering processes (Compton and Rayleigh scattering), which worsen the resulting resolution in X-ray imaging, are taken into account, thus improving the quality of the X-ray images.

The pixel size of the pixel elements within a matrix layer is generally the same, possibly with the exception of a few pixel elements arranged at the edge of the matrix layer. The matrix layers are each formed of a-Si and, for example, on glass substrates 19 applied. Alternatively, the matrix layers may also be formed of organic materials and have no additional substrate. In the X-ray detector of the invention 2 the scintillator layers have different scintillator thicknesses. The first (top) scintillator layer 10 is relative to the second scintillator layer 11 thinner. The scintillator layers are made of, for example, acicular cesium iodide (CSJ).

Low energy X-rays will be in the first scintillator layer 10 absorbed, in light quanta 17 converted and from the photodiodes 20 the first matrix layer 12 converted into electrical charge with the high pixel resolution and using the TFTs (thin film transistors) 21 saved and read. From the X-ray image data obtained therefrom, a first gray value image is obtained generated. Higher-energy x-rays radiate through the first scintillator layer and only in the thicker second scintillator layer 11 absorbed. From this X-ray image data, a second gray value image is then generated. From the two gray value images, a color X-ray image can be generated using image processing methods, for example as a linear combination.

The reading out of the X-ray image data from the matrix layers takes place with the aid of chips 22 (Chip on glass or chip on flex) and via leads 23 , Plug 24 and an electronics board 25 (PCB). Not in the 2 Shown are other components of the X-ray detector such as housings, cooling, interface electronics components and encapsulation of the scintillator layers, etc.

The X-ray detector according to the invention, as an integrating X-ray detector with commercial technology with regard to the production of scintillator layers, matrix layers and commercial X-ray sources with a broad X-ray spectrum, can ensure particularly good dual or multi-energy imaging and justify the production of color X-ray images of high quality and with low noise.

Further alternatives of an inventive X-ray detector are in the 3 to 10 shown.

In the 3 For example, an X-ray detector is shown in which the matrix layers are formed of organic material so that no glass substrate is necessary. Such matrix layers are thinner and have a lower absorption. The two scintillator layers are for example the same thickness. It is also possible to form a matrix layer of organic material and the other of a-Si with a glass substrate.

In the 4 For example, an X-ray detector with two detection layers is shown in which the first, upper scintillator layer is thinner than the second scintillator layer and where both non-structured material scintillator layers, eg Gd ₂ O ₂ S (GOS), CuJ, Bi ₄ Ge ₃ O ₁₂ (BGO ) or CsJ. The unstructured layers can be formed, for example, from tiny crystals introduced into a plastic film. By using such materials, the cost and complexity of manufacturing the X-ray detector can be significantly reduced. The use of at least two scintillator layers reduces optical scattering processes.

In the 5 an X-ray detector with three detection layers is shown, wherein in addition to the first and the second detection layer still a third detection layer 28 with a third scintillator layer 26 and a third matrix layer 27 are provided. The first and the second scintillator layer are the same thickness and generally thinner than the third scintillator. They may be formed of unstructured material, but alternatively also of structured material such as structured CsJ. In addition, the first and the second matrix layer have a same, higher resolution than the third matrix layer 27 ,

In the 6 and the 7 In each case, an X-ray detector with two detection layers is shown, in which the first matrix layer 12 with the higher resolution of the first detection layer and the second matrix layer 13 with the lower detection layer of the second detection layer only by a substrate 19 are separated from each other (back-to-back Anodnung). In the case of the second detection layer, therefore, the second scintillator layer is in relation to the direction of incidence of the X-ray radiation 16 arranged under the second matrix layer. The scintillator layers in the 6 are formed, for example, of structured CsJ. In the 7 The first scintillator layer is made of unstructured material and the second one is made of structured CsJ.

In the 8th For example, an X-ray detector with two detection layers is shown in which the scintillator layers are formed of different materials but of the same thickness. For example, the first, upper scintillator layer associated with the higher resolution matrix layer is formed of patterned CsJ, and the second lower scintillator layer assigned to the lower resolution matrix layer is formed of an unstructured material.

In the 9 an X-ray detector is shown which is comparable to that in the 2 shown X-ray detector is with the exception that the two scintillator layers are formed of different materials. The two matrix layers are made of a-Si, each with a substrate 19 educated.

In the 10 An X-ray detector is shown in which the surfaces of the matrix layers and of the detection layers differ. For example, the lower, second detection layer has a smaller area than the upper, first detection layer. It can be provided, for example, to arrange the second detection layer only in the central image area, since there is generally the "region of interest" (eg stent, foreign body, tumor, etc.). This also saves costs.

The 11 and 12 In each case, the processing of the X-ray image data obtained from an X-ray detector according to the invention is shown in FIG 11 an inventive X-ray detector with N> 3 (N is the total number of Detection layers) detection layers and in 12 an inventive X-ray detector with two detection layers is used. In the 11 the gray value images obtained from the respective X-ray image data, in particular the gray scale image data, are shown. From the first detection layer, a first gray value image G ₁ , from the second detection layer a second gray level image G ₂ , from further detection layers further gray level images G _i (1≤i≤N; i is variable for the detection layer) and from the last detection layer an N gray scale image G ₂ t gray value image G _N read out. The first matrix layer of the first detection layer has the highest resolution, the second and the remaining matrix layers have a lower (eg, mutually equal) resolution. Subsequently, all gray value images G _{i are processed} in an image processing step B _i for the respective gray value image, for example by means of noise correction. From the first gray scale image G ₁ with the highest resolution, the first processed gray scale image G ₁ 'is obtained by an image processing step B ₁ for the first gray scale image. Remaining steps R _i are subsequently also carried out in the case of the remaining gray value images G ₂ to G _N according to a known remapping method (division of a pixel into several) in order to adapt the resolution to the first processed gray value image G ₁ '. Thus, for example, the second gray value image G _{2 is processed} in a remapping step R _{2 in} such a way that a second processed gray level image G ₂ 'is produced which has the same resolution as the first processed gray value image G ₁ '. In a combination step K0, all acquired, processed gray value images G _i ', that is to say G ₁ ', G ₂ 'to G _N ', are then combined to form a color overall X-ray image C _k . This can be done for example by a linear combination or by any non-linear combination. It is also possible to create multiple color x-ray images.

Assuming that the ith matrix layer P _{i has} pixel elements in the x direction (x is the first direction of the pixel axis of the pixel elements) and M _i pixel elements in the y direction (y is the second direction of the pixel axis of the pixel elements), the processed Gray value images as G _i '(x _pi , y _mi ) with 1 ≤ i ≤ N and 1 ≤ pi ≤ Pi (Pi is the total number of pixel elements in the x direction, pi is the variable) and 1 ≤ mi ≤ Mi (Mi is the total number the pixel elements in the y direction, with the variable to it). Color X-ray images are now generated from the various processed gray scale images G _i '(x _pi , y _mi ). In this case, i is the i-th detector layer of a total of N detector layers. The color X-ray images C _k (x, y) are generally a function of the gray value images: C _k (x, y) = fct _k (G ₁ '(x _p1, y _m1), G _2' (x _p2, y _m2), ..., G _M '(x _PN, y _MN)

In this case, differently sized arrays pi x mi can be used in each detection layer i. The functions fct _k with 1 ≤ k ≤ K (K is the total number of color X-ray images, k the variable) can be linear combinations as well as arbitrary non-linear functions.

In the 12 the gray value images obtained from the respective X-ray image data, in particular the gray value image data, are likewise shown. From a first detection layer, a first gray-scale image G ₁ and from the second detection layer a second gray-scale image G _{2 are} read out. The first matrix layer of the first detection layer again has the highest resolution and the second matrix layer has a lower resolution. Subsequently, the gray value image G _{1 is processed} in an image processing step B ₁ for the first gray value image and the second gray value image in an image processing step B ₂ for the second gray value image.

From the second gray scale image G ₂ with the lower resolution, the second processed gray value image G ₂ 'is obtained by the image processing step B ₂ for the second gray scale image. In the higher-resolution gray-scale image G ₁ a Binningschritt V ₁ by a known Binningverfahren (combining of pixels) is then carried out yet, to adjust the resolution to the second processed gray-level image G ₂ '. In a combination step K0, the two acquired, processed gray value images G ₁ 'and G ₂ ' are then combined to form one or more color overall X-ray images C _k with 1 ≦ _k ≦ _K. This can be done for example by linear combinations or by any non-linear combination.

• a) Ein Röntgendetektor mit zwei Detektionsschichten, wobei die Pixelgröße (Achse eines Pixelelements bei quadratischer Form des Pixelelements) 150 μm in der ersten Detektionsschicht und 225 μm in der zweiten Detektionsschicht ist.
• b) Ein Röntgendetektor mit zwei Detektionsschichten, wobei die Pixelgröße (Achse eines Pixelelements bei quadratischem Pixelelement) 125 μm in der ersten Detektionsschicht und 250 μm in der zweiten Detektionsschicht ist (doppelte Pixelgröße; kann auch dreifach verwendet werden).
• c) Ein Röntgendetektor mit drei Detektionsschichten, wobei die Pixelgröße 150 μm in der ersten und zweiten Detektionsschicht und 300 μm in der dritten Detektionsschicht ist.
• d) Ein Röntgendetektor mit drei Detektionsschichten, wobei die Pixelgröße 150 μm in der ersten Detektionsschicht und 225 μm in der zweiten und dritten Detektionsschicht ist und
• e) ein Röntgendetektor mit drei Detektionsschichten, wobei die Pixelgröße 100 μm in der ersten Detektionsschicht und 200 μm in der zweiten und dritten Detektionsschicht ist. Andere Kombinationen, Materialien für Szintillatorschichten und Matrixschichten sowie Pixelgrößen, weitere Detektionsschichten etc. sind ebenfalls möglich.

Due to the lower resolution of the "lower" matrix layers in comparison to the upper, that of the X-ray tube closest detection layer significant cost savings can be achieved. In addition, this distribution is adapted to the physical processes (scattering (Compton or Rayleigh scattering) in each further detection layer or associated scintillator layer.) Some advantageous embodiments for resolutions of the pixel elements in two or more detection layers are described below:

• a) An X-ray detector with two detection layers, wherein the pixel size (axis of a pixel element with square shape of the pixel element) is 150 μm in the first detection layer and 225 μm in the second detection layer.
• b) An X-ray detector with two detection layers, wherein the pixel size (axis of a pixel element in square pixel element) is 125 μm in the first detection layer and 250 μm in the second detection layer (double pixel size, can also be used in triplicate).
• c) An X-ray detector with three detection layers, the pixel size being 150 μm in the first and second detection layers and 300 μm in the third detection layer.
• d) An X-ray detector having three detection layers, wherein the pixel size is 150 μm in the first detection layer and 225 μm in the second and third detection layers, and
• e) an X-ray detector with three detection layers, the pixel size being 100 μm in the first detection layer and 200 μm in the second and third detection layers. Other combinations, materials for scintillator layers and matrix layers as well as pixel sizes, further detection layers, etc. are also possible.

The use of the first high resolution detection layer may also be applicable to non-energy resolved imaging (ie, conventional gray level resolution). In a case where high resolution is needed without energy-sensitive imaging, only the first detection layer is used for imaging (e.g., to display stent struts, microcatheters, coils, or the like).

By means of the X-ray detector according to the invention, a simultaneous detection of the different spectral components of the X-ray spectrum can be achieved. The method does not require a new X-ray tube or other provisions for radiation generation or higher image frequencies of the detector / system. In addition, the method does not lead to temporal asynchrony of the various spectral images.

Use of unstructured scintillator layers, e.g. GOS reduces the costs for the scintillator layer and compensates in part for the additional costs due to the need for several active matrix layers and corresponding readout electronics. Instead of GOS, e.g. also CuJ, BGO (Bi4Ge3O12), unstructured CsJ, etc. are used. Here microscopic crystals are introduced into a plastic film.

The design with two or more detection layers leads to higher spatial resolutions, since reduced Szintiallatordicken the optical scattering processes are reduced. Adjustment of the scintillator calibers and possibly even the materials (e.g., mix of GOS and CsJ) can optimize image quality and relative absorption probabilities in the different layers.

An arbitrarily reduced resolution of the matrix layers (eg reduced by 30% or 70% in comparison to the upper matrix layer), for example also adapted to the resolution of the associated scintillator layer, can be used in the lower detection layers. The overlay is realized by resizing (binning or remapping) the different resolutions of the matrix layers to each other. In the US patent publication US 2010/0278451 A1 In general, the method of resizing is described.

An X-ray detector according to the invention can be used in all areas of X-ray imaging, e.g. for diagnostic examination and for interventional procedures e.g. in cardiology, radiology and surgery. X-ray systems in which the X-ray detector can be incorporated have e.g. a C-arm on which an X-ray tube and the X-ray detector are mounted, a high voltage generator for generating a tube voltage, an imaging system including at least one monitor, a system control unit and a patient table. Two-level (2 C-arcs) systems are also used in interventional radiology.

The invention may be briefly summarized as follows: For improved dual or multi-energy imaging, an X-ray detector is for converting X-radiation into image information comprising at least two detection layers, each detection layer comprising a scintillator layer for converting X-ray quanta into light and an active matrix layer wherein each matrix layer comprises a plurality of pixel elements of equal size, each pixel element having a photodiode and an electrical switching element for converting light into image information, at least two of the at least two matrix layers being different in pixel sizes of their pixel elements.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 2010/0278451 A1 [0053]

Cited non-patent literature

• M. Spahn, "Flat detectors and their clinical applications", Eur. Radiol. (2005), Volume 15, pages 1934 to 1947 [0003]

Claims (12)

X-ray detector for converting X-radiation into image information, comprising at least two detection layers ( 14 . 15 . 28 ), each detection layer ( 14 . 15 . 28 ) a scintillator layer ( 10 . 11 . 26 ) for the conversion of X-radiation ( 16 ) in light ( 17 ) and an active matrix layer ( 12 . 13 . 27 ), each matrix layer ( 12 . 13 . 27 ) a plurality of pixel elements of equal size ( 18 ), which pixel elements ( 18 ) each have a photodiode ( 20 ) and an electrical switching element ( 21 ) for converting light into image information, wherein at least two of the at least two matrix layers ( 12 . 13 . 27 ) with regard to the pixel sizes of their pixel elements ( 18 ). An X-ray detector according to claim 1, wherein the at least two scintillator layers ( 10 . 11 . 26 ) have at least two different scintillator thicknesses. An X-ray detector according to claim 1, wherein each matrix layer ( 12 . 13 . 27 ) one of the pixel size of each other matrix layer ( 12 . 13 . 27 ) different pixel size of the pixel elements ( 18 ) having. An X-ray detector according to claim 3, wherein, with respect to the direction of incidence, the X-ray radiation ( 16 ) uppermost matrix layer ( 12 ) the smallest pixel size and the lowest matrix layer ( 13 . 27 ) has the largest pixel size. X-ray detector according to one of the preceding claims, wherein the at least two scintillator layers ( 10 . 11 . 26 ) with regard to their materials. X-ray detector according to one of the preceding claims, wherein each scintillator layer ( 10 . 11 . 26 ) with respect to the direction of incidence of the X-radiation ( 16 ) above the respective assigned matrix layer ( 12 . 13 . 27 ) is arranged. X-ray detector according to one of the preceding claims, wherein at least one scintillator layer ( 11 ) with respect to the direction of incidence of the X-ray radiation under the respective associated matrix layer ( 13 ) is arranged. Method for producing an overall x-ray image of an x-ray detector according to one of Claims 1 to 7, having at least two detection layers ( 14 . 15 . 28 ), wherein - from each detection layer ( 14 . 15 . 28 ) X-ray image data are read out and a single X-ray image is generated in each case, and - an overall X-ray image is generated from the individual X-ray images, which is a function of the individual X-ray images. The method of claim 8, wherein the function is a linear combination. Method according to claim 8 or 9, wherein the individual X-ray images are formed by gray scale images (G _i ) and the overall X-ray image is formed by a color X-ray image (C _k ). Method according to one of claims 8 to 10, wherein at least the X-ray image with the largest pixel size is processed by a Remappingverfahren, so that from the X-ray image, a processed X-ray image is created with a smaller pixel size. Method according to one of claims 8 to 10, wherein at least the X-ray image with the smallest pixel size is processed by a Binningverfahren, so that from the X-ray image, a processed X-ray image is created with a larger pixel size.

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