DE102005005901A1 - Scintillator and photodiode array adjusting method, for computed tomography apparatus, involves stressing scintillator array`s pixel on side facing photodiode with X-ray, and adjusting arrays until high quality signal is adapted to diode - Google Patents

Abstract

Array adjusting method involves arranging pixels of scintillator and photodiode arrays (2, 3) one upon the other, such that a specific pixel of the array (2) is aligned approximately to a specific pixel of the array (3). The pixel of the array (2) is stressed on a side facing the array (3) using an X-ray (10). A signal adapting to the photodiode is measured, and the arrays are adjusted until a signal of high quality is adapted to the diode. An independent claim is also included for a device for adjusting a scintillator array and a photodiode array, comprising a retaining device.

Description

The The invention relates to a method and an apparatus for alignment a scintillator array and a photodiode array relative to each other.

detectors, in particular detectors for X-radiation, as used for example in computed tomography devices point usually a variety of detector modules. A detector module each comprises a scintillator array and a photodiode array, which one above the other arranged and aligned relative to each other. Encounters the scintillator array has passed through an examination subject X-radiation, like that this is converted by the scintillator array into light, which subsequently meets the photodiode array. The photodiodes of the photodiode array convert the light into electrical signals, which subsequently to the Generation of an image of the examination object to be evaluated. To obtain high quality signals from a detector module is It requires that the scintillator array and the photodiode array the detector module as accurate as possible are aligned relative to each other so that in one pixel of the Scintillator arrays generated by incident X-ray light ideally to the pixel associated with the pixel of the scintillator array of the photodiode array. In a relatively exact orientation of the scintillator array and the photodiode array relative to each other is then from the photodiode associated with the pixel of the photodiode array as a result of the incident light, an electrical signal higher Goodness or with good signal-to-noise ratio generated, which can be used for image generation.

to Alignment of the scintillator array and the photodiode array relative to each other, an optical system is currently being used by each of the two to be positioned to each other, initially perpendicular an array generated by each other and the images with Help of a radiation divider superimposed. These two pictures are made by adjusting one of the two arrays brought to cover. Subsequently The scintillator array is rotated by 90 ° above the Photodiode array arranged so that the two arrays parallel to each other lie. After setting the distance between the two arrays, which can be done with the help of a micrometer, for example, are the two arrays aligned relative to each other and can then with an adhesive permanently connected to each other.

adversely at such an orientation of the scintillator array and the photodiode array relative to each other is that the orientation is purely optical and only after the connection of the scintillator array to the photodiode array the goodness the orientation is determined by measurement.

Of the Invention is therefore the object of a method of the initially to specify type in which during the alignment of the scintillator and the photodiode array relative to each other already checked the quality of the alignment can. The invention also relates to a For this purpose, suitable device.

To The object of the invention is achieved by the problem relating to the method a method for aligning an X-ray sensitive Scintillator arrays and a photodiode array relative to each other, in which the alignment of the scintillator array and the photodiode array relative to each other using X-radiation. By the use of x-rays can already during The alignment can be measured, how well the two Arrays are aligned relative to each other by at least a photodiode of the photodiode array an adjusting electrical Signal is measured, which re verultiert that X-rays has hit on the scintillator array, which is the X-ray has converted to light and which light is on the photodiode of the Photodiode arrays has hit. If you get at the photodiode High quality signal or upon adjustment of the arrays relative to one another in an alignment the arrays relative to each other a signal maximum, it can be assumed be that the scintillator array and the photodiode array with high accuracy are aligned relative to each other. Thus, can already during the alignment and the irreversible connection of the arrays goodness with each other The orientation of the arrays are determined metrologically.

According to one variant of the invention, the pixel-bearing scintillator array and the pixel-comprising photodiode array are initially arranged one above the other such that at least one particular pixel of the scintillator array is roughly aligned with at least one specific pixel of the photodiode array. Subsequently, at least the particular pixel of the scintillator array is exposed to X-radiation on the side facing away from the photodiode array and measured at at least one signal adjusting the photodiode associated with the particular pixel of the photodiode array. The scintillator array and the photodiode array are then adjusted relative to each other until a signal maximum is established at the particular photodiode. The pixel of the photodiode array can be assigned one or more photodiodes, whose Signals are examined at a maximum signal level. Since the scintillator array and the photodiode array have initially been arranged in parallel one above the other, the adjustment of the scintillator array and / or the photodiode array takes place only in one plane. Preferably, the photodiode array remains stationary and only the scintillator array is moved relative to the photodiode array. After the alignment of the scintillator array and the photodiode array relative to one another, the distance between the two arrays can still be adjusted as far as necessary, and then the connection of the two arrays can be effected by means of a connection medium, which is generally an adhesive.

Around a high quality orientation of the scintillator array and the photodiode array relative to each other to reach, according to a variant of the invention, several pixels of the scintillator array and a number corresponding to these pixels Pixel of the photodiode array used. The alignment of the two Arrays is done when based on the pixel-pixel combinations each one at the different photodiodes possible setting high electrical signal.

The The object relating to the device is achieved by a device for Alignment of a scintillator array and a photodiode array relative to each other, comprising a holding device for the scintillator array, a holding device for the photodiode array, an x-ray source, a measuring and evaluation device, an adjusting device for Adjustment of the holding device for the scintillator array and / or an adjusting device for adjusting the holding device for the photodiode array. With the aid of this device, the method described above accomplished being, being x-ray used to align the two arrays.

To Variants of the invention are in the holding device for the Scintillator array around a holding frame and the holding device for the Photodiode array around a mounting plate. The holding frame for the scintillator array has the advantage that there is no shadowing of X-rays or of light generated by the scintillator array. The Storage plate is used for safe storage of the photodiode array.

One embodiment the invention is in the attached schematic drawings shown. Show it:

1 in a block diagram representation a side view of an apparatus for aligning a scintillator array and a photodiode array,

2 Partially the device off 1 in a view from above, and

3 schematically the structure of a computed tomography device.

In 1 is a device 1 for aligning a scintillator array 2 and a photodiode array 3 shown relative to each other. The photodiode array 3 is on a mounting plate 4 arranged for the process of alignment of the scintillator array 2 and the photodiode array 3 relative to each other, the temporarily stationary storage of the photodiode array 3 serves. The storage plate 4 is an adjustment device 5 associated with, as in 2 indicated by the arrows A to C, the storage plate 4 and thus the photodiode array 3 in a plane, in the case of the present embodiment, can be adjusted in a plane parallel to the xy plane. The adjusting device 5 , which in a manner not shown, preferably via electromotive drive means for adjusting the storage plate 4 is equipped with a measuring and evaluation device 6 connected, which the adjusting device 5 can control.

The scintillator array 2 is in the case of the present embodiment in a holding frame 7 trained holding device arranged. The support frame 7 is an adjustment device 8th assigned, which, as in 2 , is indicated by the arrows d to f, so with the holding frame 7 it works together that it can be adjusted in one plane, in this case in a plane parallel to the xy plane. The adjusting device 8th is like the adjustment device 5 with the measuring and evaluation device 6 connected so that the measuring and evaluation device 6 also the adjusting device 8th can control accordingly and thus the orientation of the scintillator 2 can influence. The adjusting device 8th Features as the adjusting device 5 not explicitly shown means for adjusting the holding frame 7 which are preferably electric motors.

Again 1 it can be seen, the device also comprises an X-ray source 9 , from whose focus F is an X-ray beam 10 towards the scintillator array 2 can be sent out. The X-ray source 9 is also with the measuring and evaluation device 6 connected, so that, controlled by the measuring and evaluation 6 , the generation of X-rays can be caused.

At the beginning of the alignment of the scintillator array 2 and the photodiode array 3 relative to one another they are initially arranged one above the other such that at least one particular pixel of the scintillator array 2 coarse to at least one particular pixel of the photodiode array 3 is aligned. As a rule, this coarse alignment initially takes place optically on the basis of the essentially corresponding transverse dimensions of the scintillator array 2 and the photodiode array 3 , The coarse alignment is performed by the measuring and evaluation device 6 which, by the way, is a commercially available computing device which has corresponding input means, for example a keyboard or a computer mouse. The measuring and evaluation device 6 has a corresponding computer program with which the adjustment 5 and 8th after appropriate inputs of a user or can be controlled automatically. The coarse alignment of the scintillator array 2 and the photodiode array 3 but can also be done automatically by means of known per se optical means, for example, by a match of edges is determined.

In the case of the present embodiment, the orientation of the scintillator array 2 and the photodiode array 3 relative to each other several pixels of the two arrays 2 . 3 used. In this case, pixel pairs are formed, preferably pixels in the edge regions of the arrays 2 . 3 to get voted. As in particular from 2 can be seen, in the case of the present embodiment, the pixels 2.1 to 2.6 of the scintillator array 2 as well as the underlying pixels 3.1 to 3.6 of the photodiode array 3 to align the two arrays 2 . 3 used relative to each other. After the coarse alignment, the pixel pairs ( 2.1 . 3.1 ) to ( 2.6 . 3.6 ) one above the other. However, it does not yet have any fine alignment of the pixels of the pixel pairs ( 2.1 . 3.1 ) to ( 2.6 . 3.6 ) found relative to each other instead. This is done, controlled by the measuring and evaluation 6 , the X-ray source 9 induced X-rays 10 towards the scintillator array 2 to be sent out, in particular in the pixels 2.1 to 2.6 of the scintillator array 2 the incident X-ray radiation is converted into light. The example of the pixel 2.6 of the scintillator array 2 Outgoing light then hits a the pixel 3.6 of the scintillator array 3 associated photodiode 36 which then emits an electrical signal. The same is true in the case of pixel pairs ( 2.1 . 3.1 ) to ( 2.5 . 3.5 ). That of the corresponding photodiodes ( 34 to 36 ) of the pixels 3.1 to 3.6 of the photodiode array 3 generated signals are by means of a signal line 11 to the measuring and evaluation device 6 transmitted, which determines the signal levels using a corresponding evaluation program and visible to a user on a display device 12 represents. The measuring and evaluation device 6 subsequently causes an adjustment of the scintillator array under preferably pulsed X-radiation 2 and the photodiode array 3 about their adjustment 5 and 8th relative to one another, all but the photodiodes of the pixels in an ideal manner 3.1 to 3.6 of the photodiode array 3 signals show a maximum signal level. If this can not be achieved, then the alignment of the scintillator array takes place 2 and the photodiode array 3 relative to each other such that as many signals of the photodiodes reach the highest possible signal level. If this is the case, then the orientation of the scintillator array 2 and the photodiode array 3 each completed in a plane parallel to the xy plane. Optionally, it is still necessary, the distance of the scintillator 2 and the photodiode array 3 set relative to each other in the z-direction before the two arrays are then connected together in a conventional manner by means of an adhesive. The adjustment of the distance between the two arrays 2 and 3 in z-direction can also be done via the measuring and evaluation 6 carried out, in a manner not shown z. B. a vertical adjustment of the holding frame 7 over the adjusting device 8th can cause. The height of the signals obtained by the photodiodes can also be used on the basis of empirical values of the distance of the arrays 2 . 3 are determined, wherein the higher the signals are, the smaller is the spacing of the arrays, as more of the pixels of the scintillator array emitted light quanta reach the photodiodes of the photodiode array due to lower scattering losses.

From the above it thus becomes clear that with the help of X-ray radiation, an alignment of a scintillator array 2 and a photodiode array 3 relative to each other, depending on one of photodiodes of the photodiode array 3 measured signal levels, the quality of the alignment can be controlled.

In the case of the present embodiment, the possibility was given both the photodiode array 3 as well as the scintillator array 2 each to be adjusted in a plane parallel to the xy plane. For the alignment of the two ar rays 2 . 3 relative to each other, however, it is sufficient if only the scintillator array 2 or just the photodiode array 3 can be adjusted in a plane parallel to the xy plane.

As described above, a pixel includes 3.1 to 3.6 of the photodiode array 3 one photodiode each. In contrast, however, also pixels of the photodiode array 3 be defined, which comprise more than one photodiode. For the alignment process, the signals of all photodiodes of a pixel are then evaluated.

Furthermore, in the case of the present embodiment, the entire scintillator array became 2 exposed to X-rays. However, it is also possible, with the help of diaphragms or a mask, only the parts of the scintillator array 2 or only the specific pixels of a scintillator array 2 to apply X-rays to the alignment of the two arrays 2 . 3 be used relative to each other.

In order to differ from the described embodiment, the two arrays 2 . 3 also have substantially the same longitudinal dimensions.

The transmission of the signals of the photodiodes from the photodiode array 3 to the measuring and evaluation device 6 It also does not necessarily have to be connected to the array 3 infected wire 11 respectively. Rather, the storage plate 4 via corresponding contacts for electrical contacting of the photodiodes of the photodiode array 3 feature. In this case, the storage plate 4 one with the measuring and evaluation device 6 connected line for transmitting the signals received from the photodiodes.

As already mentioned, are a Szintillatorarray 2 and a photodiode array 3 which are connected to each other, part of a detector module, from which an X-ray detector, as used in computed tomography, is formed. On from detector modules 13 built-up detector 14 is in 3 shown as part of a computed tomography device. This in 3 schematically illustrated computed tomography device comprises in a conventional manner an x-ray source 15 , That of the focus F of the X-ray source 15 outgoing X-ray beams 19 is doing with in 3 not shown, but known per se fan-shaped or pyramid-shaped. The x-ray beam 19 penetrates an object to be examined 16 and hits the one from the detector modules 13 constructed detector 14 on. The detector 14 comprises a multiplicity of detector rows lying next to each other and thus in the form of an arc in the φ-direction. The detector lines are arranged in the z-direction one behind the other. During operation of the computed tomography device, the X-ray source is rotating 15 and the detector 14 around the examination object 16 , wherein from different projection directions X-ray images of the examination subject 16 be won. Out of those with the detector 14 determined signals then calculates an image calculator 17 in a manner known per se, one or more two- or three-dimensional images of the examination subject 16 which is on a viewing device 18 are representable.

The computed tomography scanner by the way not necessarily a rotating X-ray source and a having rotating detector. If the detector, for example, as a ring detector is formed, this is fixed. Likewise, at the computed tomography device eg several X-ray sources be provided so that they do not need to be rotated.

Claims (7)

Method for aligning a scintillator array ( 2 ) and a photodiode array ( 3 ) relative to one another, in which the orientation of the scintillator array ( 2 ) and the photodiode array ( 3 ) relative to each other using X-radiation ( 10 ) he follows. Method according to claim 1, in which - the pixel ( 2.1 to 2.6 ) having scintillator array ( 2 ) and the pixel ( 3.1 to 3.6 ) having photodiode array ( 3 ) are arranged one above the other in such a way that at least one particular pixel ( 2.1 to 2.6 ) of the scintillator array ( 2 ) roughly to at least one particular pixel ( 3.1 to 3.6 ) of the photodiode array ( 3 ), - at least the particular pixel ( 2.1 to 2.6 ) of the scintillator array ( 2 ) on the photodiode array ( 3 ) opposite side with X-radiation ( 10 ) is applied to - at least one of the determined pixels ( 3.1 to 3.6 ) of the photodiode array associated photodiode ( 34 to 36 ) adjusting signal is measured and - the scintillator array ( 2 ) and the photodiode array ( 3 ) are adjusted relative to each other until a signal of the highest possible quality at the photodiode ( 34 to 36 ). Method according to Claim 2, in which a plurality of pixels ( 2.1 to 2.6 ) of the scintillator array ( 2 ) and several pixels ( 3.1 to 3.6 ) of the photodiode array ( 3 ) for aligning the arrays ( 2 . 3 ) are used relative to each other. Method according to Claim 2 or 3, in which the determined pixels ( 2.1 to 2.6 ) of the scintillator array ( 2 ) and the specific pixels ( 3.1 to 3.6 ) of the photodiode array ( 3 ) in each case in the edge regions of the arrays ( 2 . 3 ) lie. Device for aligning a pixel ( 2.1 to 2.6 ) having scintillator ( 2 ) and a pixel ( 3.1 to 3.6 ) having photodiode arrays ( 3 ) relative to each other, comprising a holding device ( 7 ) for the scintillator array ( 2 ), a holding device ( 4 ) for the photodiode array ( 3 ), an X-ray source ( 9 ), a measuring and evaluation device ( 6 ), an adjusting device ( 8th ) for adjusting the holding device ( 7 ) for the scintillator array ( 2 ) and / or an adjusting device ( 5 ) for adjusting the holding device ( 4 ) for the photodiode array ( 3 ). Device according to Claim 5, in which the holding device for the scintillator array ( 2 ) a holding frame ( 7 ). Apparatus according to claim 5 or 6, wherein the holding device for the photodiode array ( 3 ) a storage plate ( 4 ).