JP2009081443A - X-ray plane detector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an X-ray plane detector capable of obtaining a low-noise and high-quality image. <P>SOLUTION: The X-ray plane detector includes a detecting means consisting of a plurality of effective pixels for detecting X-ray and a plurality of dummy pixels arranged in the periphery of the effective pixel region while not depending on the X-ray, a signal line 26 for reading an electric signal out of respective pixels, a scanning line 27 for scanning respective pixels, a first wiring 291 for dispersing static electricity charged in the signal line 26 and a second wiring for static electricity charged in the scanning line 27. The plurality of dummy pixels are divided into a dummy pixel A region for removing noise superimposed on the signal line 26 and a dummy pixel B region for removing noise superimposed on the scanning line 27 while the first wiring 291 for static electricity and the second wiring 291 for static electricity are cut physically between the dummy pixel A region provided along the profile of the detecting means and the dummy pixel B region. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an X-ray flat panel detector used in an X-ray diagnostic system.

  An X-ray flat panel detector is an X-ray detector used in an X-ray diagnostic system that displays the intensity of X-rays transmitted through the body of a subject as a grayscale image. This X-ray flat panel detector is an I.D. I. In recent years, it has been commercialized as a replacement for (image intensifier) and imaging plate. X-ray flat panel detectors can be classified into a direct conversion system and an indirect conversion system according to the conversion system of incident X-rays. The configuration of X-ray detection and readout by each method is as follows.

  In the linear conversion method, incident X-rays are converted into electron-hole pairs by a photoelectric conversion film. The converted electron-hole pairs are carried as charges to the pixel electrodes arranged in a lattice pattern by a high electric field applied from the outside, and accumulated in the pixel electrodes. The accumulated electric charges are sequentially read out to the integrating amplifier as an electric signal through the signal line under the control of the switching element (TFT) (the scanning line is driven from the OFF potential to the ON potential). The read signal is converted into image data by A / D conversion, and is output to a subsequent processing system.

  On the other hand, in the indirect conversion method, incident X-rays are once converted into light by a phosphor, and the light is converted into electron-hole pairs by a photoelectric conversion film. The generated charges are carried to the pixel electrodes arranged in a lattice pattern by a high electric field applied from the outside. The charge carried to the pixel electrode is processed in the same manner as in the direct conversion method, and image data is generated.

  In general, this X-ray flat panel detector has a pixel group for removing a noise component from a signal detected by the effective pixel in addition to an effective pixel for collecting diagnostic image data. Each pixel constituting this pixel group is called a dummy pixel. This dummy pixel removes a noise component generated when a charge depending on the potential change flows into the signal line when the potential of the scanning line forming the signal line and the capacitance (parasitic capacitance) changes. used. In addition, a protective electrode for preventing dielectric breakdown caused by application of a high electric field is provided on each dummy pixel.

  Meanwhile, the protective electrode provided on the dummy pixel forms a capacitor with a signal line or a scanning line connected to the dummy pixel. Therefore, when the dummy pixel is driven, the potential of the protective electrode is distributed in the plane and becomes unstable. This instability of the protective electrode is transmitted to the signal line of the dummy pixel and is superimposed on the signal line as a noise component. On the other hand, the effective pixel region is not affected by instability due to the protective electrode. For this reason, a difference occurs between the output values of the effective pixel and the dummy pixel when the X-ray is not inserted, and this difference may become an offset in the output range of the AD converter.

  Further, the X-ray flat panel detector has a wiring for countermeasures against static electricity in the manufacturing process of the switching element array (TFT array) (hereinafter, the wiring for countermeasures against static electricity is referred to as “LC wiring”). This LC wiring is not necessary in the use of the X-ray flat panel detector, but is usually left as it is without being removed. However, the LC wiring is a scanning line for driving a dummy pixel → a component connected to the dummy pixel (for example, a device having high impedance) → LC wiring → a component connected to the effective pixel (for example, a device having high impedance). → A conductive path called a scanning line for driving an effective pixel is formed. Therefore, when a dummy pixel is driven in actual X-ray detection, a component due to fluctuation of the scanning line potential of the dummy pixel is superimposed on the potential of each scanning line of each effective pixel by the conductive path, and noise may increase.

  An object of the present invention is to provide an X-ray flat panel detector capable of acquiring a high-quality X-ray diagnostic image with less noise.

  In order to achieve the above object, the present invention takes the following measures.

  According to the first aspect of the present invention, there is provided an effective pixel array in which a plurality of pixel electrodes are arranged in a matrix and accumulates charges, and a photoconductor that covers the effective pixel array and generates charges based on incident X-rays A plurality of first signal lines for reading an electronic signal from the effective pixel array, a plurality of first scanning lines for scanning the effective pixel array, and the plurality of first signal lines Are connected to at least one of the plurality of first scanning lines and at least one of the plurality of first scanning lines directly or via a non-linear element, and the plurality of first signal lines or the plurality of first lines are connected. An electrostatic dispersion wiring that disperses static electricity charged to at least one of the scanning lines, wherein the electrostatic dispersion wiring includes at least one of the plurality of first signal lines. And a plurality of the plurality of connections In between the connection portion of the at least one line of the scanning line of an X-ray flat panel detector having a first auxiliary wiring for cutting the wire.

  According to a fourth aspect of the present invention, there is provided an effective pixel array in which a plurality of pixel electrodes are arranged in a matrix and accumulates charges, and a photoconductor that covers the effective pixel array and generates charges based on incident X-rays A plurality of first signal lines for reading an electronic signal from the effective pixel array, a plurality of first scanning lines for scanning the effective pixel array, and the plurality of first signal lines Are connected to at least one of the plurality of first scanning lines and at least one of the plurality of first scanning lines directly or via a non-linear element, and the plurality of first signal lines or the plurality of first lines are connected. Static electricity distribution wiring for dispersing static electricity charged on at least one of the scanning lines, a first dummy pixel for removing noise superimposed on the plurality of signal lines, and a plurality of scanning lines. First to remove noise A plurality of second signal lines for reading electronic signals from the first dummy pixels, and a second scanning line for scanning the second dummy pixels, The electrostatic distribution wiring includes a first wiring connected to at least one of the plurality of first signal lines and at least one of the plurality of second signal lines, and the plurality of first signals. An X-ray flat panel detector having a second wiring connected to at least one of the scanning lines and a third wiring connected to at least one of the plurality of second scanning lines. is there.

  As described above, according to the present invention, an X-ray flat panel detector capable of acquiring a high-quality X-ray diagnostic image with less noise can be realized.

  Hereinafter, first to third embodiments of the present invention will be described with reference to the drawings. In the following description, components having substantially the same function and configuration are denoted by the same reference numerals, and redundant description will be given only when necessary.

(First embodiment)
First, a schematic configuration of an X-ray flat panel detector according to an embodiment of the present invention will be described with reference to FIG. FIG. 1 is a diagram for explaining a schematic configuration of an X-ray flat panel detector 12 according to the present embodiment.

  The X-ray flat detector 12 has an X-ray sensor element 16 that detects incident X-rays, a gate scanning line driving circuit 18, an integrating amplifier circuit 20, a multiplexer 22, and an A / D converter 24.

  The X-ray sensor element 16 includes a plurality of photoelectric conversion films (not shown) that are arranged in a matrix and convert incident X-rays to charge information, and pixels that are provided for each pixel and collect charges from each photoelectric conversion film. A plurality of capacitors for accumulating charges collected by the electrodes, the pixel electrodes, and a switching element (for example, TFT :) that reads out the electric charges accumulated in each capacitor based on a control signal from the gate scanning line driving circuit 18 as an electric signal. A thin film transistor). A plurality of X-ray sensor elements 16 are arranged in a two-dimensional matrix, forming a sensor element array. As will be described later, each sensor element 16 is classified into an effective pixel, a dummy pixel A (hereinafter referred to as “DA”), and a dummy pixel B (hereinafter referred to as “DB”) (see FIG. 2).

  The gate scanning line driving circuit 18 is electrically connected to the gate terminal of each switching element of the X-ray sensor element 16 via the gate scanning line 27. The gate scanning line drive circuit 18 performs ON / OFF control of the switching element group for each gate scanning line 27 by supplying a control signal to the gate terminal of each switching element. Note that the gate scanning line driving circuit 18 may include a scanning line driving IC connected to each scanning line and having a function of supplying a potential to the protective electrode. FIG. 1 shows a configuration in which the gate scanning line driving circuit 18 is arranged only on one side. However, the gate scanning line driving circuit 18 is provided on both sides of the sensor element array so that the switching element is connected from both sides to each switching element. The configuration may be such that a drive signal is supplied.

  The integrating amplifier circuit 20 amplifies the electric signal for each pixel in the same column read out from the X-ray sensor element 16 via the signal line 26 at a predetermined timing in units of columns.

  The multiplexer 22 sequentially selects the signals amplified by the integrating amplifier 20 and sends them to the subsequent A / D converter 24.

  The A / D converter 24 converts the analog signal input from the multiplexer 22 into a digital signal.

  Although FIG. 1 shows a configuration in which the integrating amplifier circuit 20 and the multiplexer 22 are arranged only on one side, the integrating amplifier circuit 20 and the multiplexer 22 are provided on both sides of the sensor element array, and the sensor elements are arranged from both sides. The configuration may be such that the detection signal is read out.

  Next, the effective pixel, dummy pixel A (DA), and dummy pixel B (DB) included in the X-ray flat panel detector 12 will be described with reference to FIG.

  FIG. 2 is a diagram showing a pixel region formed by each pixel when the X-ray sensor element 16 is classified into an effective pixel, a dummy pixel A (DA), and a dummy pixel B (DB). The areas where the pixels are distributed are referred to as an effective pixel area, a dummy pixel A area, and a dummy pixel B area, respectively. As described above, each pixel constituting each pixel region is configured by the sensor element 16.

  An effective pixel is a pixel for detecting incident X-rays. The X-ray diagnostic image is generated based on the X-ray detected by the pixel.

  DA is used to cancel noise (NA) that flows into the signal line 26 and is superimposed on the detection signal of the effective pixel when the gate scanning line driving circuit 18 changes the potential of the scanning line 27 as shown in FIG. These pixels are arranged above and below the effective pixel region in the column direction (direction parallel to the signal line). The DA does not accumulate charge information based on X-rays (for example, the photoelectric conversion film and the capacitor are not electrically connected, or the surface (X-ray incident side) is covered with a shield). It has become. Therefore, when the TFT is turned from OFF to ON, the charge detected from the DA is obtained by extracting only noise (NA). The removal of noise (NA) from the effective pixel using the DA is performed by driving the DA scanning line in the opposite phase to the scanning line of the effective region when driving the scanning line of the effective pixel. This is executed by generating noise (NA) of the code and canceling the noise (NA) superimposed on the detection signal.

  DB removes noise (NB) generated by the fluctuation of the potential of the scanning line 27 in a steady state and superimposed on the detection signal of the effective pixel, as shown in FIG. The pixels are arranged on the left and right in the direction parallel to the horizontal direction. This DB has a structure that does not accumulate charge information based on X-rays (for example, the photoelectric conversion film and the capacitor are not electrically connected, or the surface (X-ray incident side) is covered with a shield). It has become. The method of removing noise (NB) by DB removes the fluctuation component of the scanning line potential by subtracting the output value of the dummy pixel (DB) on the same gate line from the output value of the effective pixel after X-ray irradiation. . This dummy pixel (DB) is designed so that its output value is the same as the output value when the effective pixel is not irradiated with X-rays.

(Function to prevent dielectric breakdown due to high electric field application)
Next, a function of the X-ray flat panel detector 12 for preventing dielectric breakdown due to application of a high electric field will be described.

  Usually, in the X-ray diagnosis, a high electric field is applied to the X-ray flat panel detector in order to collect charges generated in the photoelectric conversion film on the pixel electrode. The applied high electric field may cause dielectric breakdown in the effective pixel region and the peripheral region (dummy pixel A region, dummy pixel B region, scanning line region around the effective pixel, and signal line region around the effective pixel). Devised for each area.

  In the effective pixel region, since a high electric field is applied in the photoelectric conversion film, when a large dose of X-rays enters the photoelectric conversion film, a transient large current is generated and the potential of the pixel rises more than necessary. . At this time, there is a possibility that dielectric breakdown occurs between the effective pixel and the common electrode (capacitance is formed between them) or TFT. In order to prevent the dielectric breakdown in the effective pixel region, the pixel is provided with a function of releasing the charge to the outside when the charge is accumulated more than necessary. This function can be realized, for example, by providing a TFT with a diode function in the pixel.

  On the other hand, a high electric field is applied also in the peripheral region so that the characteristics of the photoelectric conversion film are sufficiently exhibited. Due to the application of this high electric field, dielectric breakdown may occur between the high electric field applying electrode and the dummy pixels, the scanning lines, and the signal lines. In order to prevent dielectric breakdown in this peripheral region, in this X-ray flat panel detector, a protective electrode (potential is GND) that shields charging by an insulating film between the scanning line, the signal line, and the high electric field applying electrode. Is provided. A material having electrical resistance is used for the protective electrode.

  FIGS. 3A and 3B are diagrams for explaining the protective electrode 30 of the X-ray detector 12, and are cross-sectional views taken along line DD in FIG. FIG. 4 is an enlarged view of the circle 3 (b). As shown in FIGS. 3A, 3 B, and 4, the protective electrode 30 is provided between the high voltage electrode 32 and the signal line layer 33. Since the protective electrode 30 is provided corresponding to the dummy pixel A or the dummy pixel B as described above, the protective electrode 30 is present around the effective pixel region.

  The protective electrode 30 is electrically separated between the effective pixel region and the dummy pixel A region and between the effective pixel region and the dummy pixel B region (see FIGS. 3A, 3B, and 4). ing. Further, the protective electrode 30 is also separated between the dummy pixel A region and the dummy pixel B region at G, H, I, and J. This is to prevent potential fluctuations generated when the DA is driven from being transmitted to the signal line 26 connected to DB.

  That is, due to the structure of the X-ray flat panel detector, the protective electrode 30 forms a capacitance with all the signal lines 26 connected to DA or DB. All the scanning lines 27 connected to DA or DB form a capacitance with the protective electrode 30. Accordingly, when DA is driven by the gate scanning line driving circuit 18, a transient current depending on the potential change flows through the protective electrode 30. At this time, since the protective electrode 30 is formed of a material having a resistance component, the potential of the protective electrode 30 becomes unstable. In particular, when the protective electrode 30 is not separated between the dummy pixel A region and the dummy pixel B region, the instability of the protective electrode 30 is transmitted to the DB signal line and is superimposed on the signal line as a noise component. On the other hand, the effective pixel region is not affected by such DA driving. This is because the protective electrode covers only the dummy pixel. For this reason, for example, a difference occurs between the output values of the effective pixel and the dummy pixel in dark image capturing. This difference becomes an offset in the output range of the AD converter and causes noise in the X-ray diagnostic image.

  On the other hand, the protective electrode 30 of the present X-ray flat panel detector has a configuration in which the dummy pixel A region and the dummy pixel B region are separated from each other, so that the occurrence of the noise wraparound can be prevented. This is because the transient current flowing through the protective electrode 30 covering DA in connection with the gate scanning line drive is not superimposed on the signal line via the protective electrode 30 covering DB.

  Each separated protective electrode needs to be supplied with a stable potential such as a GND potential. Four embodiments of the potential supply form to the protective electrode 30 are shown below. Each example can be applied to an X-ray flat panel detector according to any of the embodiments described later.

(Example 1-1)
An X-ray flat panel detector according to the first embodiment will be described.

  FIG. 5 is a diagram for explaining the X-ray flat panel detector 121 according to the first embodiment. The X-ray flat panel detector 121 shown in FIG. 5 drives the switching element from both sides, and reads out the signal readout from each pixel from both the upper and lower sides. Therefore, the scanning line from each sensor element of the sensor element array is drawn to the right side or the left side of the sensor element array. In addition, signal lines from the sensor elements of the sensor element array are drawn to the upper side or the lower side of the sensor element array.

  The gate scanning line driving circuits 18 disposed on the left and right sides of the sensor element array have ICs that are connected to the scanning lines and drive the switching elements. In the present X-ray flat panel detector 121, the IC is provided with a function of supplying a potential to the protective electrode, and is configured to supply several GND potentials from each side. Note that the configuration of the potential supply to the protective electrode is not limited to this, and a configuration may be provided in which a means for supplying several GND potentials is provided in a system different from the IC.

  The integrating amplifier circuit 20 arranged on the upper side and the lower side on one side in the row direction of the sensor element array has an amplifier IC connected to each signal line. In the X-ray flat panel detector 121, the IC is provided with a function of supplying a potential to the protective electrode, and a potential of several points is supplied from each side. Note that, as in the case of the gate scanning line driving circuit 18, the potential supply to the protective electrode may be a system different from the IC and may be a few points of GND potential supply.

(Example 1-2)
FIG. 6 is a diagram for explaining the X-ray flat panel detector 122 according to the second embodiment. The X-ray flat panel detector 122 shown in FIG. 6 drives the switching element from the right side or the left side of the sensor element array, and reads out signals from each pixel from the upper side and the lower side of the sensor element array. Therefore, the X-ray flat panel detector 121 includes the gate scanning line driving circuit 18 disposed on either the left or right side of the sensor element array, the integrating amplifier circuit 20 and the AD converter disposed on the upper side or the lower side of the sensor element array. It has composition which has.

  The gate scanning line driving circuit 18 disposed on either the left or right side of the sensor element array has a scanning line driving IC connected to each scanning line and having a function of supplying a potential to the protective electrode. Note that the configuration of supplying the potential to the protective electrode is not limited to this, and a configuration in which several GND potentials are supplied by a system different from the IC may be used. One or two GND potentials are supplied from the signal line side to the side to which the scanning line driving IC is not connected. In this case, since the protective electrode has a resistance component, the stability as GND is deteriorated, and an output difference appears between the left and right sides of the dummy pixel (DB). In order to prevent the occurrence of this output difference, it is preferable to strengthen GND by providing a low resistance material below the protective electrode and contacting the protective electrode and the low resistance material at several points.

  FIG. 7 shows a cross-sectional view taken along line EE of FIG. As shown in the figure, in order to eliminate the left-right difference in the dummy pixel (DB) output, a configuration in which a low resistance material is provided also on the lower layer of the protective electrode on the side to which the scanning line driving IC is connected may be employed. Alternatively, a portion 31 that can supply the GND potential may be provided on a side to which the scanning line driving IC is not connected so that the GND potential can be supplied from the scanning line itself.

  Note that on the signal line side, the GND potential can be supplied to the protective electrode by the potential supply function described in Embodiment 1.

(Example 1-3)
FIG. 8 is a diagram for explaining the X-ray flat panel detector 124 according to the third embodiment. The X-ray flat panel detector 124 shown in FIG. 8 drives the switching element from the right side and the left side of the sensor element array, and reads out the signal readout from each pixel from the upper side or the lower side of the sensor element array. Accordingly, the X-ray flat panel detector 124 includes the gate scanning line driving circuits 18 disposed on the left and right sides of the sensor element array, the integrating amplifier circuit 20 and the AD converter disposed on the upper side or the lower side of the sensor element array. It has a configuration.

  On the scanning line side, the GND potential can be supplied to the protective electrode by the potential supply function described in the first embodiment.

  On the other hand, on the signal line side, as in the first embodiment, the amplifier IC in the integrating amplifier circuit 20 connected to each signal line 26 has a function of supplying a potential to the protective electrode. It is configured to supply a potential. On the other hand, one or two GND potentials are supplied from the scanning line side to the signal line side to which the amplifier IC is not connected. Note that, as in the case of the gate scanning line driving circuit 18, the potential supply to the protection electrode may be a system different from the IC and may be a few points of GND potential supply. Further, a configuration may be provided in which means (for example, a pad or the like) capable of supplying the GND potential is provided from the signal line side to which the amplifier IC is not connected to the other signal line side to which the amplifier IC is not connected.

(Example 1-4)
FIG. 9 is a diagram for explaining the X-ray flat panel detector 126 according to the fourth embodiment. The X-ray flat panel detector 126 shown in FIG. 9 drives the switching element from the right side and the left side of the sensor element array, and reads out the signal readout from each pixel from the upper side or the lower side of the sensor element array. Therefore, the X-ray flat panel detector 124 includes the gate scanning line driving circuit 18 disposed on the right side or the left side of the sensor element array, the integrating amplifier circuit 20 and the AD converter disposed on the upper side or the lower side of the sensor element array. It is the composition which has.

  On the scanning line side, the GND potential can be supplied to the protective electrode by the potential supply function described in the second embodiment.

  On the signal line side, the GND potential can be supplied to the protective electrode by the potential supply function described in the third embodiment.

  According to the configuration described above, since the protective electrode 30 is separated between the dummy pixel A region and the dummy pixel B region, the signal line 26 connected to DB is not affected by potential fluctuation due to DA driving. Therefore, noise correction by DB can be performed appropriately, and as a result, a high-quality X-ray diagnostic image with reduced noise can be acquired.

  Further, since the LC wiring 291 is also separated between the dummy pixel A region and the dummy pixel B region, the effective pixel output is not affected by fluctuations in the scanning line potential of the DA in the steady state. Therefore, it is possible to eliminate the cause of noise (conductive path) itself, and as a result, it is possible to acquire a high-quality X-ray diagnostic image with reduced noise.

  Furthermore, since the LC wiring 291 has an auxiliary wiring 295 for cutting between the dummy pixel A region and the dummy pixel B region, the cutting can be easily performed even after the X-ray flat panel detector 12 is completed. Can be executed.

(Second Embodiment)
In the second embodiment, an X-ray flat panel detector having a configuration in which the protective electrode 30 does not form a capacitance with the signal line 26 or the scanning line 27 will be described.

  FIG. 10 is a diagram for explaining the configuration of the X-ray flat panel detector 12 according to the present embodiment. FIG. 11 is a cross-sectional view taken along the line PP in FIG. As shown in FIGS. 10 and 11, the X-ray flat panel detector 12 does not exist on DA or DB. With this configuration, the protective electrode 30 does not form a capacity with the DB and DA signal lines 26.

  That is, even when DA is driven by the gate scanning line driving circuit 18 and the potential of the protective electrode 30 becomes unstable, the instability of the protective electrode 30 is not transmitted to the DB signal line. Therefore, for example, even in dark image capturing, there is no difference between the output values of the effective pixels and the dummy pixels, and noise generation can be prevented.

  Next, two modified examples of the X-ray flat panel detector 12 according to the present embodiment will be shown. The X-ray flat panel detector according to each modification has the protective electrode 30 cut at least at one point from the viewpoint of removing the loop current flowing through the protective electrode 30 itself.

  FIG. 12 is a top view of the X-ray flat panel detector 12 having the C-type protective electrode 30 cut at the position Q. According to the X-ray flat panel detector 12 according to this example, the protective electrode 30 does not form a circuit. Therefore, the protective electrode 30 can block the path of the loop current generated when the detector 12 is driven.

  FIG. 13 is a top view of the X-ray flat panel detector 12 having the protective electrode 30 cut and separated at the position Q and the position R. FIG. In particular, in the example of the figure, the protective electrode 30 is line-symmetric with respect to the central axis of the X-ray flat detector 12. This corresponds to the array of the X-ray sensor elements 16 being arranged in line symmetry with respect to the central axis of the X-ray flat detector 12. That is, if the protective electrode 30 is axisymmetric with respect to the central axis of the X-ray flat detector 12 like the array of X-ray sensor elements 16, the noise superimposed on the image is also effectively canceled using the objectivity. Because it can.

(Third embodiment)
In general, in a TFT array manufacturing process or a detector assembly process in manufacturing an X-ray flat panel detector, scanning lines and signal lines are charged by static electricity. When the amount of static electricity increases, dielectric breakdown may occur between the scanning line, the signal line, and a conductor in the same layer or another layer as the scanning line. In the third embodiment, an X-ray flat panel detector that has a function of preventing dielectric breakdown due to static electricity and does not affect the potential of each scanning line of an effective pixel even when a dummy pixel is driven will be described. To do.

  That is, the X-ray flat panel detector 12 according to the present embodiment prevents this dielectric breakdown by the dielectric breakdown prevention unit 29 as shown in FIG. The dielectric breakdown prevention unit 29 is a component (for example, high resistance) 290 connected to each scanning line 27 and each signal line 26 outside all pixel regions (effective pixel region, dummy pixel A region, dummy pixel B region). And one of the electrodes connected to the component 290, and an LC wiring 291 that is bundled into one line and goes around the pixel region. Note that in the case where there are scanning lines that are not related to driving of the switching elements or signal lines that are not related to signal readout from each pixel, it is preferable to connect the component 290 to these scanning lines or signal lines.

  Further, the LC wiring 291 of the X-ray flat panel detector 12 according to the present embodiment is cut at a predetermined position and separated into the scanning line side and the signal line side. As for the cutting form of the LC wiring 291, the following five examples are shown. Each example can be applied to the X-ray flat panel detector according to any of the above-described embodiments.

(Example 3-1)
FIG. 14 is a diagram for explaining the cutting of the LC wiring 291 included in the X-ray flat panel detector 12 according to the present embodiment. As shown in FIG. 14, the X-ray flat panel detector 12 includes a second DA 296 for removing DB noise, and an LC wiring 291 cut at the position K to the scanning line side and the signal line side. is doing. Each of the cut LC wirings 291 is supplied with a potential (for example, an OFF potential of the scanning line, a signal line potential) that does not cause a problem with the array function.

  According to the dielectric breakdown prevention unit 29, the charges charged in the scanning lines and signal lines are dispersed by the component 290 in the LC wiring 291. Therefore, it is possible to prevent dielectric breakdown due to static electricity in the manufacturing process. Further, the LC wiring 291 is cut at the position K into the scanning line side and the signal line side.

(Example 3-2)
FIG. 15 is a diagram for explaining the cutting of the LC wiring 291 included in the X-ray flat panel detector 12 according to the present embodiment. As shown in the figure, the X-ray flat panel detector 12 has a position K that is a boundary between the scanning line side and the signal line side, and a position L that is a boundary between the dummy pixel A region and the dummy pixel B region. A cut LC wiring 291 is provided. In this way, cutting at the position L also completely separates the LC wiring 291 connected to the DA and the LC wiring 291 connected to the effective pixel, and the fluctuation of the scanning line potential of the DA in the steady state is This is because the effective pixel output is not affected.

  That is, when the DA is actually driven by using the X-ray flat panel detector 12, the fluctuation of the potential due to the driving is a component (for example, a component connected to the dummy pixel (DA) from the scanning line (dummy pixel (DA)) Device with high impedance) → Wiring (LC) → Component connected to effective pixel (for example, device with high impedance) → Scan line (effective pixel) . Thereby, a component due to DA fluctuation is superimposed on the potential of each scanning line, and noise (NB) increases. However, since the X-ray flat panel detector 12 has the divided LC wiring, the fluctuation of the scanning line potential connected to the DA through the above path affects the potential of the scanning line connected to the effective pixel. There is nothing. Therefore, it is possible to reduce the noise component superimposed on the scanning line connected to the effective pixel.

  In order to easily perform the cutting at the position L of the LC wiring 291, it is preferable to have a configuration having an auxiliary wiring 295 for cutting as shown in FIG. 16. According to such a configuration, it is possible to easily cut the LC wiring 291 between the dummy pixel A region and the dummy pixel B region.

  Further, in order to easily perform the cutting at the position K of the LC wiring 291, a configuration having the auxiliary wiring 295 for cutting similarly to the position L may be used.

(Example 3-3)
FIG. 17 is a diagram for explaining the structure of the LC wiring included in the X-ray flat panel detector 12 according to the present embodiment. As shown in the figure, the X-ray flat panel detector 12 includes a first LC wiring 292, a second LC wiring 293, and a third LC wiring 294. The first LC wiring 292 is connected to the scanning line connected to the DA and the second DA 291. The second LC wiring 293 is connected to a signal line connected to DB. The third LC wiring 294 is connected to the signal line of the second DA296.

  The first LC wiring 292, the second LC wiring 293, and the third LC wiring 294 are electrically disconnected from each other. Therefore, since the current path is interrupted, the potential fluctuation generated by driving the DA does not affect the potential of the scanning line connected to the effective pixel. As a result, it is possible to reduce the noise component superimposed on the scanning line connected to the effective pixel.

  In addition, the structure which cut | disconnects also in the position used as the boundary of the scanning line side and signal line side in each LC wiring, ie, position K1, K2, K3 may be sufficient. Moreover, as shown in FIG. 15, the structure cut | disconnected also in the position L may be sufficient. The same applies to the following Examples 3-4 and 3-5.

(Example 3-4)
FIG. 18 is a diagram for explaining the structure of the LC wiring 291 included in the X-ray flat panel detector 12 according to the present embodiment. The X-ray flat panel detector 12 shown in FIG. 18 includes a resistor 300 that connects the LC wirings in addition to the first LC wiring 292, the second LC wiring 293, and the third LC wiring 294. Yes. The resistor 300 has a resistance value enough to prevent dielectric breakdown due to static electricity.

  That is, the first LC wiring 292, the second LC wiring 293, and the third LC wiring 294 are connected to each other through the resistor 300. According to such a configuration, it is possible to further improve the dielectric breakdown prevention function in the manufacturing process or the like as compared with the case where each wiring is electrically cut completely. In addition, since the LC wirings are connected through the resistor 300, the influence on the scanning line potential connected to the effective pixel by driving the DA is reduced. As a result, it is possible to reduce the noise component superimposed on the scanning line connected to the effective pixel.

(Example 3-5)
FIG. 19 is a diagram for explaining the structure of the LC wiring 291 included in the X-ray flat panel detector 12 according to the present embodiment. The X-ray flat panel detector 12 shown in FIG. 18 includes an auxiliary wiring 301 for cutting connected to each LC wiring in addition to the first LC wiring 292, the second LC wiring 293, and the third LC wiring 294. Have

  That is, the first LC wiring 292, the second LC wiring 293, and the third LC wiring 294 are connected to each other through the auxiliary wiring 301. Therefore, it is possible to further improve the dielectric breakdown prevention function in the manufacturing process or the like as compared with the case where each wiring is electrically cut completely. In addition, when the actual X-ray flat panel detector 12 is used, the auxiliary wiring 301 is disconnected. Accordingly, since the current path is cut off and each LC wiring becomes electrically independent, the fluctuation of the potential generated by driving the DA does not propagate to the scanning line connected to the effective pixel. As a result, it is possible to reduce the noise component superimposed on the scanning line connected to the effective pixel.

   According to each embodiment described above, it is possible to realize an X-ray flat panel detector capable of preventing dielectric breakdown and providing a high-quality X-ray diagnostic image from which noise is removed.

  Although described based on the embodiments, those skilled in the art can come up with various changes and modifications within the scope of the idea of the present invention, and these modifications and modifications are also applicable to the present invention. It is understood that it belongs to the range, and various modifications can be made without changing the gist thereof.

  The above-described embodiments include inventions at various stages, and various inventions can be extracted by appropriately combining a plurality of disclosed constituent elements. For example, even if some constituent requirements are deleted from all the constituent requirements shown in the embodiment, the problem described in the column of the problem to be solved by the invention can be solved, and the effect described in the column of the effect of the invention If at least one of the following is obtained, a configuration in which this configuration requirement is deleted can be extracted as an invention.

  Based on the embodiment described above, the following X-ray flat panel detector can be obtained.

  (1) A plurality of pixel electrodes arranged in a matrix, an effective pixel array that accumulates charges, a photoconductor that covers the effective pixel array and generates charges based on incident X-rays, and the photoconductor A bias electrode that covers the pixel electrode region and applies a bias voltage between the photoconductor and the pixel electrode, and a plurality of electrodes for reading out an electronic signal from the effective pixel array. A plurality of scanning lines for scanning the effective pixel array, a first dummy pixel disposed adjacent to the effective pixel array and removing noise superimposed on the plurality of signal lines, A second dummy pixel that is disposed adjacent to the effective pixel array and removes noise superimposed on the plurality of scanning lines; and provided corresponding to the first dummy pixel; A first protection electrode that is electrically shielded between the signal line or the plurality of scanning lines, and provided corresponding to the second dummy pixel, and is electrically disconnected from the first protection electrode; and An X-ray flat panel detector comprising a bias electrode and a second protective electrode that electrically shields between the plurality of signal lines or the plurality of scanning lines can be provided.

  (2) The X-ray flat panel detector according to (1), wherein the first pad for supplying the GND potential to the first protective electrode and the GND potential for supplying the second protective electrode are provided. What has a 2nd pad can be provided.

(3) An effective pixel array in which a plurality of pixel electrodes are arranged in a matrix and accumulates charges, a photoconductor that covers the effective pixel array and generates charges based on incident X-rays, and the photoconductor A bias electrode that covers the pixel electrode region and applies a bias voltage between the photoconductor and the pixel electrode, and a plurality of electrodes for reading out an electronic signal from the effective pixel array. A plurality of scanning lines for scanning the effective pixel array, a protective electrode that electrically shields between the bias electrode and the plurality of signal lines or the plurality of scanning lines,
A first dummy pixel disposed around the protective electrode and removing noise superimposed on the plurality of signal lines; and a first dummy pixel disposed around the protective electrode and removing noise superimposed on the plurality of scanning lines. An X-ray flat panel detector comprising two dummy pixels can be provided.

  (4) The X-ray flat panel detector of (3) above, wherein at least two or more of the protective electrodes are provided.

  (5) The X-ray flat panel detector according to (3), wherein the protective electrodes are arranged in line symmetry with respect to the signal lines or the scanning lines. Can be provided.

  (6) The X-ray flat panel detector according to (3) can be provided having a pad for supplying a GND potential to the protective electrode.

  (7) The X-ray flat panel detector according to (3) above, wherein the protective electrode is supplied with the GND potential of a drive circuit that drives the effective pixel array.

  (8) The X-ray flat panel detector according to (3), wherein the protective electrode is supplied with the GND potential of a readout circuit that reads an electric signal from the effective pixel array via the signal line. Can be provided.

  (9) An effective pixel array in which a plurality of pixel electrodes are arranged in a matrix and accumulates charges; a photoconductor that covers the effective pixel array and generates charges based on incident X-rays; and the effective pixel array A plurality of first signal lines for reading electronic signals from the plurality of first scanning lines for scanning the effective pixel array, and at least one of the plurality of first signal lines; A direct or non-linear element is connected to at least one of the plurality of first scanning lines, and the plurality of first signal lines or the plurality of first scanning lines are Electrostatic dispersion wiring that disperses static electricity charged to at least one line, a first dummy pixel that removes noise superimposed on the plurality of signal lines, and a second that removes noise superimposed on the plurality of scanning lines. Dummy pixels of A plurality of second signal lines for reading an electronic signal from the first dummy pixel, and a second scanning line for scanning the second dummy pixel, A first wiring connected to at least one of the plurality of first signal lines and at least one of the plurality of second signal lines; and at least of the plurality of first scanning lines. An X-ray flat panel detector having a second wiring connected to one and a third wiring connected to at least one of the plurality of second scanning lines can be provided.

  (10) The X-ray flat panel detector according to (9) above, further comprising a resistor connecting the first wiring, the second wiring, and the third wiring can be provided.

  (11) In the X-ray flat panel detector according to (9), the resistor is caused by static electricity charged on at least one of the plurality of first signal lines or the plurality of first scanning lines. What has the resistance value which prevents a dielectric breakdown can be provided.

  (12) The X-ray flat panel detector according to (9), wherein the X-ray flat panel detector is connected to each of the first wiring, the second wiring, and the third wiring, and disconnects the electrical connection between the wirings. A device having a third auxiliary wiring can be provided.

  As described above, according to the present invention, an X-ray flat panel detector capable of acquiring a high-quality X-ray diagnostic image with less noise can be realized.

FIG. 1 is a diagram for explaining a schematic configuration of an X-ray flat panel detector 12 according to the embodiment. FIG. 2 is a diagram showing a pixel region formed by each pixel when the X-ray sensor element 16 is classified into an effective pixel, a dummy pixel A (DA), and a dummy pixel B (DB). FIG. 3A is a top view of the X-ray flat panel detector 12 for explaining the protective electrode 30. FIG. 3B is a cross-sectional view of the X-ray flat panel detector 12 for explaining the protective electrode 30. FIG. 4 is an enlarged view in the circle of FIGS. 3 (a) and 3 (b). FIG. 5 is a diagram for explaining an embodiment relating to a potential supply mode to the protective electrode 30. FIG. 6 is a diagram for explaining another embodiment relating to a potential supply form to the protective electrode 30. FIG. 7 is a diagram for explaining another embodiment relating to a potential supply form to the protective electrode 30. FIG. 8 is a diagram for explaining another embodiment relating to a potential supply form to the protective electrode 30. FIG. 9 is a diagram for explaining another embodiment relating to a potential supply form to the protective electrode 30. FIG. 10 is a diagram for explaining the configuration of the X-ray flat panel detector 12 according to the second embodiment. 11 is a cross-sectional view taken along the line PP in FIG. FIG. 12 is a top view of the X-ray flat panel detector 12 having the C-type protective electrode 30. FIG. 13 is a view for explaining the protective electrode 30 that is line-symmetric with respect to the central axis of the X-ray flat panel detector 12. FIG. 14 is a diagram for explaining an example of the LC wiring 291 included in the X-ray flat panel detector 12. FIG. 15 is a diagram for explaining another example of the LC wiring 291 included in the X-ray flat panel detector 12. FIG. 16 is a diagram for explaining the auxiliary wiring 295 included in the LC wiring 291. FIG. 17 is a diagram for explaining an example of an LC wiring structure included in the X-ray flat panel detector 12. FIG. 18 is a diagram for explaining another example of the LC wiring structure included in the X-ray flat panel detector 12. FIG. 19 is a diagram for explaining another example of the LC wiring structure included in the X-ray flat panel detector 12.

Explanation of symbols

DESCRIPTION OF SYMBOLS 12 ... X-ray plane detector 16 ... Sensor element 18 ... Gate scanning line drive circuit 20 ... Integration amplifier 22 ... Multiplexer 24 ... A / D converter 26 ... Signal line 27 ... Gate scanning line 27 ... Scan line 29 ... Dielectric breakdown prevention Part 30 ... Protective electrode 30 ... C-type protective electrode 31 ... Section 32 ... High voltage electrode 33 ... Signal line layer 121 ... X-ray flat detector 122 ... X-ray flat detector 124 ... X-ray flat detector 126 ... X-ray flat Detector 290 ... Component 291 ... LC wiring 291 ... Electrostatic wiring 292 ... First LC wiring 293 ... Second LC wiring 294 ... Third LC wiring 295 ... Auxiliary wiring 296 ... Second DA
300 ... resistor 301 ... auxiliary wiring

Claims (7)

An effective pixel array in which a plurality of pixel electrodes are arranged in a matrix and accumulates charges;
A photoconductor covering the effective pixel array and generating a charge based on incident X-rays;
A plurality of first signal lines for reading out an electronic signal from the effective pixel array;
A plurality of first scan lines for scanning the effective pixel array;
Connected to at least one line of the plurality of first signal lines and at least one line of the plurality of first scanning lines directly or via a non-linear element, and A static electricity dispersion wiring that disperses static electricity that is charged in at least one signal line or at least one of the plurality of first scanning lines;
Comprising
The electrostatic distribution wiring is between a connection portion with at least one of the plurality of first signal lines and a connection portion with at least one line of the plurality of first scanning lines. An X-ray flat panel detector having a first auxiliary wiring for cutting the wiring. A first dummy pixel for removing noise superimposed on the plurality of signal lines;
A second dummy pixel for removing noise superimposed on the plurality of scanning lines;
A second signal line for reading an electronic signal from the first and second dummy pixels;
A second scan line for scanning the first and second dummy pixels;
Further comprising
The static electricity distribution wiring includes at least one of the plurality of first signal lines and the second signal line, at least one of the plurality of first scanning lines, and the second signal line. To the scanning line, directly or via a non-linear element, and a connection portion between at least one of the plurality of first signal lines and a connection portion between the second signal lines Or a second auxiliary wiring for cutting the wiring between a connection portion with at least one of the plurality of first scanning lines and a connection portion with the second scanning line. The X-ray flat panel detector according to claim 1. A first dummy pixel for removing noise superimposed on the plurality of signal lines;
A second dummy pixel for removing noise superimposed on the plurality of scanning lines;
A plurality of second signal lines for reading out an electronic signal from the first dummy pixel;
A second scan line for scanning the second dummy pixel;
Further comprising
The electrostatic distribution wiring includes a first wiring connected to at least one of the plurality of first signal lines and at least one of the plurality of second signal lines;
A second wiring connected to at least one of the plurality of first scanning lines;
A third wiring connected to at least one of the plurality of second scanning lines;
The X-ray flat panel detector according to claim 1. An effective pixel array in which a plurality of pixel electrodes are arranged in a matrix and accumulates charges;
A photoconductor covering the effective pixel array and generating a charge based on incident X-rays;
A plurality of first signal lines for reading out an electronic signal from the effective pixel array;
A plurality of first scan lines for scanning the effective pixel array;
Connected to at least one line of the plurality of first signal lines and at least one line of the plurality of first scanning lines directly or via a non-linear element, and A static electricity dispersion wiring that disperses static electricity that is charged in at least one signal line or at least one of the plurality of first scanning lines;
A first dummy pixel for removing noise superimposed on the plurality of signal lines;
A second dummy pixel for removing noise superimposed on the plurality of scanning lines;
A plurality of second signal lines for reading out an electronic signal from the first dummy pixel;
A second scan line for scanning the second dummy pixel;
Comprising
The electrostatic distribution wiring includes a first wiring connected to at least one of the plurality of first signal lines and at least one of the plurality of second signal lines;
A second wiring connected to at least one of the plurality of first scanning lines;
A third wiring connected to at least one of the plurality of second scanning lines;
X-ray flat panel detector.   The X-ray flat panel detector according to claim 1, further comprising a resistor connecting the first wiring, the second wiring, and the third wiring.   5. The X according to claim 1, wherein the resistor has a resistance value that prevents a dielectric breakdown due to static electricity charged on at least one of the plurality of first signal lines or the plurality of first scanning lines. Line plane detector.   5. The X-ray plane according to claim 1, further comprising a third auxiliary wiring connected to each of the first wiring, the second wiring, and the third wiring for cutting an electrical connection between the wirings. Detector.

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