WO2012034401A1 - 辐射探测器及其成像装置、电极结构和获取图像的方法 - Google Patents

辐射探测器及其成像装置、电极结构和获取图像的方法 Download PDF

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WO2012034401A1
WO2012034401A1 PCT/CN2011/073669 CN2011073669W WO2012034401A1 WO 2012034401 A1 WO2012034401 A1 WO 2012034401A1 CN 2011073669 W CN2011073669 W CN 2011073669W WO 2012034401 A1 WO2012034401 A1 WO 2012034401A1
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pixel
electrode
signal
column
transistor
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PCT/CN2011/073669
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English (en)
French (fr)
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张岚
陈志强
赵自然
吴万龙
李元景
邓智
郑晓翠
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同方威视技术股份有限公司
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Priority to EP11735762.4A priority Critical patent/EP2518530A4/en
Priority to US13/170,821 priority patent/US20120068078A1/en
Priority to US13/174,174 priority patent/US8785867B2/en
Publication of WO2012034401A1 publication Critical patent/WO2012034401A1/zh

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    • GPHYSICS
    • G01MEASURING; TESTING
    • G01TMEASUREMENT OF NUCLEAR OR X-RADIATION
    • G01T1/00Measuring X-radiation, gamma radiation, corpuscular radiation, or cosmic radiation
    • G01T1/16Measuring radiation intensity
    • G01T1/24Measuring radiation intensity with semiconductor detectors
    • G01T1/247Detector read-out circuitry
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01TMEASUREMENT OF NUCLEAR OR X-RADIATION
    • G01T1/00Measuring X-radiation, gamma radiation, corpuscular radiation, or cosmic radiation
    • G01T1/16Measuring radiation intensity
    • G01T1/24Measuring radiation intensity with semiconductor detectors
    • G01T1/241Electrode arrangements, e.g. continuous or parallel strips or the like
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L27/00Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate
    • H01L27/14Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate including semiconductor components sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation
    • H01L27/144Devices controlled by radiation
    • H01L27/146Imager structures
    • H01L27/14601Structural or functional details thereof
    • H01L27/14609Pixel-elements with integrated switching, control, storage or amplification elements
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L27/00Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate
    • H01L27/14Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate including semiconductor components sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation
    • H01L27/144Devices controlled by radiation
    • H01L27/146Imager structures
    • H01L27/14601Structural or functional details thereof
    • H01L27/14632Wafer-level processed structures
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L27/00Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate
    • H01L27/14Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate including semiconductor components sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation
    • H01L27/144Devices controlled by radiation
    • H01L27/146Imager structures
    • H01L27/14643Photodiode arrays; MOS imagers
    • H01L27/14658X-ray, gamma-ray or corpuscular radiation imagers
    • H01L27/14659Direct radiation imagers structures
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L27/00Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate
    • H01L27/14Devices consisting of a plurality of semiconductor or other solid-state components formed in or on a common substrate including semiconductor components sensitive to infrared radiation, light, electromagnetic radiation of shorter wavelength or corpuscular radiation and specially adapted either for the conversion of the energy of such radiation into electrical energy or for the control of electrical energy by such radiation
    • H01L27/144Devices controlled by radiation
    • H01L27/146Imager structures
    • H01L27/14665Imagers using a photoconductor layer
    • H01L27/14676X-ray, gamma-ray or corpuscular radiation imagers

Definitions

  • the present invention relates to a radiation detector and an imaging device therefor, an electrode structure, and a method of acquiring an image, and more particularly to, for example, an X-ray digital image flat panel detector and an imaging device . Background technique
  • the products of the digital image flat panel detector can realize a large area of thousands of square centimeters, a spatial resolution of several tens of micrometers, and a reading speed of hundreds of frames per second.
  • the first known technique for digital image flat panel detectors is to combine amorphous silicon diodes with TFTs.
  • the amorphous silicon diode absorbs the radiation and generates electron-hole pairs. Under the action of the electric field, the charged particles of a certain polarity drift onto the TFT pixel array, and the pixel signals are sequentially read by the switching scan of the TFT.
  • Amorphous silicon has a very low ionization energy (about 5 eV), which can generate a large number of electron-hole pairs under radiation, and still obtain a good signal-to-noise ratio at low doses.
  • a second known technique for digital image flat panel detectors is to combine an amorphous selenium film with a TFT.
  • Amorphous selenium absorbs radiation, generates electron-hole pairs, and the charged particles of a certain polarity drift to TFT pixels under the action of an electric field.
  • On the array, each pixel signal is sequentially read by a switch scan of the TFT.
  • the atomic number of selenium is 34.
  • the barrier ability of amorphous selenium to radiation is stronger than that of amorphous silicon, but it is still only suitable for detecting radiation within 50KeV, which limits the main application field of amorphous selenium flat panel detector to low energy field. (such as breast imaging).
  • the ionization energy of amorphous selenium varies with the applied field strength and the incident ray energy.
  • the ionization energy in the field strength and ray energy region commonly used in medical diagnosis is about 50 eV, which limits the minimum dose of the ray and the output signal. Amplitude.
  • amorphous selenium has poor temperature stability, deliquescent and crystallization, and has a shorter service life than flat-plate detectors of other structures.
  • a third known technique for digital image flat panel detectors is to use a scintillator in combination with a photodiode and a TFT.
  • the scintillator converts the ray into an optical signal
  • the photodiode receives the optical signal, converts it into an electrical signal, and sequentially scans each pixel signal through a switch scan of the TFT.
  • the scintillator absorbs ray energy and emits a range of visible light, and the number of emitted photons is proportional to the absorbed energy.
  • the scintillator material generally has a relatively high atomic number and a strong ability to absorb radiation.
  • the scintillator may be a fluorescent film material (such as certain rare earth materials) or a scintillation crystal (such as cesium iodide, cadmium tungstate, etc.).
  • the atomic number of yttrium iodide crystal is larger than that of amorphous silicon and amorphous selenium, and has good barrier and absorption ability to radiation.
  • the emission peak of ytterbium iodide crystal with ytterbium is 565 nm, and amorphous silicon photoelectric
  • the absorption peaks of the diodes are basically consistent, and the combination of the two has the highest quantum efficiency among the same type of products.
  • the scintillator is a uniform thin film material, in order to increase the detectable energy range and the detection efficiency, it is necessary to increase the thickness of the thin film, and as the thickness of the thin film increases, the influence of the scattering of the visible light on the spatial resolution of the detector increases. .
  • the scintillator is a cesium iodide crystal, it is possible to suppress photon scattering by growing the crystal into a high-density needle array (a needle of 10-20 ⁇ m size).
  • the aspect ratio of the needle tube increases, and the collection efficiency of photons in the tube is greatly reduced, thereby reducing the quantum efficiency of the detector.
  • the proportion of the dead zone of this type of detector will be too large.
  • Each generation of a visible light in the scintillator requires about 20-50 eV of energy. Considering the quantum efficiency of the photodiode in the visible range, the detector of this structure requires about 100 eV or more of energy for each pair of electron-hole pairs. Performance determines that using a scintillator as a radiation-sensitive film will result in a poor letter. Noise ratio.
  • a fourth known technique for digital image flat panel detectors is the use of scintillators in combination with CMOS.
  • the scintillator can be directly overlaid on the CMOS, or a large area of the scintillator can be combined with a small area of CMOS through a fiber of different diameters at both ends.
  • CMOS process replaces the traditional silicon process, which can greatly improve the integration of the system.
  • the spatial resolution, duty cycle and acquisition speed of the detector are greatly improved.
  • Each pixel unit is integrated independently.
  • the charge-voltage conversion circuit and the amplifying circuit can obtain a better signal-to-noise ratio.
  • this type of flat panel detector is not easy to obtain a large sensitive area at a lower cost, but in the field of small area detection, such as dental CT, small animal CT, etc., the advantage is very obvious. .
  • the main ray conversion method is to use a high density needle.
  • the cesium iodide scintillator converts the ray into a visible light and converts the visible light into an electrical signal through a photodiode.
  • the reading of the electrical signal is mainly performed by TFT reading or CMOS reading, and one of TFT and CMOS is selected according to actual required area, spatial resolution, acquisition speed, integration degree, cost and the like. Summary of the invention
  • the invention provides a digital image flat panel detector and an imaging device with simple structure and high quantum efficiency, in which it is not necessary to use a scintillator and a photoelectric conversion device.
  • a radiation detector comprising a radiation sensitive film, a top electrode on the radiation sensitive film, and an array of pixel cells electrically coupled to the radiation sensitive film, wherein each pixel unit comprises; a pixel electrode And a storage capacitor for collecting a charge signal in a pixel region of the radiation sensitive film; a storage capacitor connected to the pixel electrode for storing the charge signal collected by the pixel electrode; and a reset transistor connected to the pixel electrode for emptying the storage capacitor a charge transistor; connected to the pixel electrode, configured to convert a charge signal on the pixel electrode into a voltage signal and transmitted to the signal line; a column gate transistor for selecting a pixel electrode of a predetermined column; and a row gate transistor, a pixel electrode for selecting a predetermined row, wherein the column strobe transistor and the row strobe transistor are connected in series between the buffer transistor and the signal line, and transmit the voltage signal of the corresponding pixel unit in response to the column strobe signal and the row strobe
  • a digital imaging apparatus includes: a radiation source that generates radiation; a radiation detector that detects a radiation dose after passing through an object to be measured; and a data acquisition system that performs radiation detection The analog signal output by the detector is converted into a digital signal; the image processor processes the digital signal into an image.
  • an electrode structure for a radiation detector comprising: a pixel electrode; and a grid-shaped guiding electrode surrounding the at least one pixel electrode, and the pixel electrode and the guiding electrode are electrically insulated from each other.
  • a method of acquiring an image using the aforementioned radiation detector comprising the steps of:
  • the reset transistor, the column strobe transistor, the row strobe transistor of all the pixel units are turned off, and the pixel electrode collects the charge signal and accumulates on the storage capacitor;
  • the reset transistor of the first column of pixel cells is turned off, applying a column strobe signal to the first column of pixel cells, and then sequentially applying a row strobe signal to the corresponding pixel cells of the column, such that the column strobe transistors of the corresponding pixel cell And the row strobe transistor is turned on, so that the potentials of the pixel electrodes of the first column of pixel units are read one by one as a background signal;
  • the detector and the imaging device thereof provided by the invention directly convert the radiation into an electrical signal by using a radiation sensitive film (such as a mercury iodide film) on the premise of ensuring detection efficiency, detection energy range, signal to noise ratio and spatial resolution.
  • a radiation sensitive film such as a mercury iodide film
  • the step of converting the ray into a visible light and then converting it into an electrical signal is eliminated, which simplifies the structure of the detector, reduces the loss of the effective signal in the intermediate process, and improves the quantum efficiency of the detector.
  • the detector is more sensitive to changes in the irradiation dose, and the scanning speed can be further improved.
  • the acquisition, output, and data processing of electrical signals are realized by pixel units including four transistors (4T), and can be implemented as a TFT pixel array, a CMOS pixel array, a circuit board, and a signal processing ic.
  • 4T the 4T pixel unit directly outputs the voltage signal, the interference of the external circuit to the analog signal can be reduced, the signal-to-noise ratio of the system can be improved, and the complexity of the subsequent ASIC design can be reduced, and the reliability of the device can be improved.
  • CMOS pixel arrays or TFT pixel arrays containing 4T pixel cells increases system integration to meet higher spatial resolution requirements in small areas.
  • a signal processing IC including a 4T pixel unit
  • a pixel array is formed together with the circuit board, and the pixel electrode of a certain area is led to a signal processing IC to collect and process the electrical signal, thereby reducing the design scale of the signal processing IC, and maximizing Reduce costs.
  • a grid-shaped guide electrode with a certain structure is arranged between pixels or between pixel regions and on the periphery of the pixel array, and the leakage current of the detector surface can be collected to reduce the noise of the detector.
  • the potential of the guiding electrode is slightly different from the potential of the pixel electrode (the potential of the guiding electrode is slightly lower than that of the pixel electrode when collecting electrons, and the potential of the guiding electrode is slightly higher than that of the pixel electrode when collecting holes), and there is a weak electric field between the guiding electrode and the pixel electrode. It can effectively prevent charge accumulation, improve charge collection rate, reduce the dead zone of the detector, and reduce the polarization effect of the detector. The performance of the detector is further optimized.
  • Figures la to lc show schematic configurations of three digital image flat panel detectors according to the prior art, respectively.
  • Figures 2a to 2b respectively show schematic structures of two digital imaging devices according to the prior art.
  • Figures 3a to 3b show a more detailed structure of a digital image flat panel detector according to the prior art.
  • Figure 4 shows a TFT pixel array of a digital image flat panel detector according to the prior art.
  • Figure 5 shows a pixel array of a digital image flat panel detector in accordance with the present invention.
  • Figure 6 shows a top view of a pixel electrode in a digital image flat panel detector in accordance with the prior art.
  • Figure 7 shows a top view of a pixel electrode in a digital image flat panel detector in accordance with the present invention.
  • Figures 8a and 8b show, respectively, cross-sectional views of pixel electrodes in a digital image flat panel detector in accordance with the present invention.
  • Figures 9a and 9b respectively show cross-sectional views of pixel electrodes in a digital image flat panel detector in accordance with the present invention.
  • BEST MODE FOR CARRYING OUT THE INVENTION will be described in more detail with reference to the accompanying drawings, in which: FIG. However, the present invention may be embodied in many different forms, and the present invention should not be construed as being limited thereto. The resulting embodiment.
  • FIGS la to lc show three digital image flat panel detectors according to the prior art, respectively.
  • the mercury iodide (Hgl 2 ) film 1 is a continuous film or patterned into discrete pixel regions corresponding to the pixel electrodes, and the digital images are provided by the electrode arrays of the CMOS pixel array 2, the TFT pixel array 3, and the circuit board (PCB) 6, respectively.
  • the pixel signals obtained by the detector are transmitted via cable 8 to an image processor 9 (e.g., a computer) to form a digital image for display on the display.
  • an image processor 9 e.g., a computer
  • a mercury iodide film 1 is placed over the CMOS pixel array 2, for example, by evaporation directly on top of the CMOS pixel array 2 as part of an integrated circuit. Access to each pixel region in the mercury iodide film 1 is achieved using the CMOS pixel array 2.
  • a mercury iodide film 1 is placed over the TFT pixel array 3, for example, by evaporation directly on top of the TFT pixel array 3 as part of an integrated circuit. Access to each of the pixel regions in the mercury iodide film 1 is achieved via the electrodes 4 and 5.
  • the mercury iodide film 1 is located on one side of the circuit board 6, and the signal processing IC 7 is provided on the other side of the circuit board.
  • the mercury iodide film 1 and the signal processing IC 7 are connected via wiring and via holes on the circuit board.
  • the signal processing IC 7 is connected to the image processor 9. Access to each of the pixel regions in the mercury iodide film 1 is achieved using an array of electrodes (not shown) formed on the circuit board.
  • the atomic number of mercury iodide is higher than that of cesium iodide, the density is larger than that of cesium iodide, and the ray blocking ability is stronger.
  • the radiation sensitive film used as a ray can obtain higher detection efficiency.
  • the mercury iodide detector can detect higher ray energies (upper dynamic range).
  • the interaction between photons and mercury iodide in the range of 500KeV is mainly photoelectric effect, and the proportion of Compton scattering is small. Under a certain electric field, in such a short migration distance, carriers The lateral offset is negligible, and the positional information of the ray-substance interaction can be more accurately measured.
  • mercury iodide is a semiconductor material, its ionization energy is of the same order of magnitude as that of amorphous silicon ( ⁇ 10 eV), and the ray energy required to obtain an electron-hole pair is much smaller than that of cesium iodide or amorphous selenium, at the same energy/dose. Under the irradiation of radiation, the number of electron-hole pairs generated is of the same order of magnitude as that of amorphous silicon, far more than that of cesium iodide or amorphous selenium.
  • the forbidden band width of mercury iodide is about twice that of silicon, and the resistivity can reach 10 14 Q . cm .
  • the inventors have recognized that superior mercury image quality can be obtained by using mercury iodide as the radiation sensitive film at the same irradiation dose.
  • lead iodide Pbl 2
  • cadmium zinc cadmium CdZnTe
  • cadmium telluride CdTe
  • gallium arsenide GaAs
  • Barium bromide TlBr
  • indium phosphide InP
  • CdSe cadmium selenide
  • CdS cadmium sulfide
  • InAs indium arsenide
  • PbS lead sulfide
  • InSb indium antimonide
  • lead telluride Other semiconductor materials such as (PbTe) and mercury selenide (HgSe) are substituted for mercury iodide.
  • one of TFT and CMOS is selected depending on actual required area, spatial resolution, acquisition speed, integration, cost, and the like. For example, in the field of small area imaging (dental), CMOS is most preferred.
  • PCB circuit board
  • FIG. 2a A schematic structure of a planar imaging digital imaging device according to the prior art is shown in Figure 2a.
  • Radiation from the radiation source 200 passes through the object 300 to be measured and then reaches the detector 100.
  • the detector 100 includes a two-dimensional array of pixels, which may be an integral two-dimensional array of pixels or a plurality of one- or two-dimensional arrays of pixels.
  • Each pixel signal is associated with the radiation dose of the pixel area and then converted to a digital signal by a subsequent data acquisition system (DAQ) 400 for transmission to image processor 900.
  • DAQ data acquisition system
  • a digital imaging device that utilizes linear scanning imaging is shown in Figure 2b.
  • the radiation from the point source 200 is shaped into a linear beam of radiation via the collimator 201, then passes through the object 300 to be reached, reaches the detector 100, and is then converted to a digital signal by a subsequent data acquisition system (DAQ) 400.
  • DAQ data acquisition system
  • the digital imaging in FIG. 2b uses a relative movement of the measured object 300 relative to the radiation source 200, the collimator 201, and the detector 100 to linearly scan the object 300 to be measured.
  • a two-dimensional digital image that expands in the scanning direction is formed.
  • the radiation source 200, the collimator 201, and the detector 100 move synchronously in the scanning direction, and the object to be measured 300 is fixed.
  • the radiation source 200, the collimator 201, and the detector 100 are both fixed, and only the object 300 to be measured moves in the scanning direction.
  • the digital image forming apparatus can planarly image the larger-sized object 300 to be measured by the detector 100 of a smaller size, thereby reducing the manufacturing cost of the digital image forming apparatus.
  • the detector 100 includes a pixel array 110, a mercury iodide film ⁇ located above the pixel array 110, a top electrode iii on the mercury iodide film 101, a protective layer surrounding the mercury iodide film 101 and the top electrode 111. 112, and an outer casing 113 surrounding the protective layer.
  • the pixel array 110 can be a TFT Array, CMOS array or board.
  • the top electrode 11 1 may be metal palladium (Pd ), indium tin oxide alloy (IT0), carbon film, indium oxide (1 0 3 ), tin oxide (Sn0 2 ), tungsten titanium (TiW), and other non-iodine A suitable conductive material that reacts with mercury.
  • the protective layer 112 is a stable moisture-proof and anti-static insulating material and does not chemically react with mercury iodide. It may be a silicone rubber, a resin material, or other thermoplastic materials such as parylene.
  • the outer casing 113 is an insulating, light-shielding, anti-static material.
  • Radiation can pass through the outer casing 113, the protective layer 12 and the top electrode 111 to reach the mercury iodide film 101.
  • the interaction of the radiation with the mercury iodide film produces electron-hole pairs that drift to the pixel array 110 and the top electrode 111 under the action of an electric field and are collected directly by the electrodes and processed by the signal processing circuit.
  • a first intermediate protective layer 14 between the mercury iodide film 101 and the pixel array 110 and a first portion between the mercury iodide film 101 and the top electrode 111 are further included.
  • the first intermediate protective layer 114 and the second intermediate protective layer 115 are formed of a dielectric and may be the same as or different from the material of the protective layer 112 described above.
  • the detector 100 shown in Figures 3a and 3b preferably, by applying a reverse electric field to the pixel region periodically (e.g., between each frame or per multi-frame signal), neutralizing the mercury iodide film 101
  • the residual charge allows the detector 100 to operate stably for a long period of time.
  • FIG. 4 shows a TFT pixel array of sensor components in a digital image flat panel detector in accordance with the prior art.
  • Each pixel unit is composed of a pixel electrode 311, a transistor Q10, and a storage capacitor C1.
  • the drain of the transistor Q10 is connected to the pixel electrode 311, and the pixel electrode 311 is grounded via the storage capacitor C1.
  • the pixel electrode 311 is electrically connected to a pixel region of the mercury iodide film for collecting a charge signal.
  • the mercury iodide film acts as a radiation-sensitive film, deposits ray energy upon exposure to radiation, generates a charge signal, and is then collected by the pixel electrode 311.
  • the storage capacitor C1 is used to store the charge.
  • the charge collected via the pixel electrode 311 is stored in the storage capacitor C1.
  • the charge signal Signal in the storage capacitor C1 can be read.
  • the gate of transistor Q1 is coupled to an external control signal V eat6 and the source is coupled to a read circuit (eg, an integrating amplifier circuit).
  • the control signal V eat6 can be provided by a programmable logic chip to implement the associated logic control in the following manner:
  • the pixel electrode 311 collects a charge signal and accumulates on the storage capacitor C1; b) after reaching a predetermined integration time, applying a strobe signal V e to the first column of pixel units, the first column of transistors Q10 is turned on, and the storage capacitor C1 of each unit of the first column is discharged, thereby reading the charge signal;
  • step b) Repeat step b), for other columns, read the charge signal collected on the pixel electrode column by column.
  • FIG. 5 shows a pixel array of sensor components in a digital image flat panel detector in accordance with the present invention.
  • Each of the pixel units includes a pixel electrode 311, four transistors (Q21, Q22, Q23, Q24) and a storage capacitor Cl.
  • the pixel electrode 311 is electrically coupled to a pixel region of the mercury iodide film for collecting a charge signal.
  • the mercury iodide film acts as a radiation-sensitive film, deposits ray energy upon exposure to radiation, generates a charge signal, and is then collected by the pixel electrode 311.
  • the storage capacitor C1 is used to store the charge.
  • the potential of the pixel electrode 311 changes.
  • the amount of change in potential is proportional to the amount of charge accumulated, that is, proportional to the amount of ray energy deposited in the pixel region.
  • Transistor Q21 is used for reset and its gate is connected to the reset control signal (V R6S6t ).
  • V R6S6t the reset control signal
  • the transistor Q22 is used for buffering to drive a subsequent circuit whose gate is connected to the pixel electrode 311. Applying a fixed bias level on the drain 2 V, so that transistor Q22 operates in following state. Q22 due to changes stateless during operation, and therefore, fixed level V 2 is always applied to the drain of transistor Q22.
  • Transistor Q23 is used for column strobe, its gate is connected to the column strobe signal (V Col ), and the order of reading and the integration time of each column and the read time are controlled; transistor Q24 is used for row strobe, and its gate is The row strobe signal (V Row ) is connected to select the row to be output.
  • Transistors Q23 and 24 are connected in series. If the transistors Q23 and Q24 are gated at the same time, the charge signal stored in the storage capacitor is sequentially transmitted to the signal line Signal via the pixel electrode 311, the buffer transistor Q21, the column strobe transistor Q23, and the row strobe transistor Q24, so that the signal can be read.
  • the gate of transistor Q21 of the same column of pixel cells is connected to the same reset signal (V R6S6t ); the gate of transistor Q23 of the same column of pixel cells is connected to the same column strobe signal (V); The gate of transistor Q24 is connected to the same row strobe signal (V Row ); the same row of pixel cells
  • the source of transistor Q24 is connected to the same follower circuit (for example, multiplexer, level shifting, or ADC).
  • the energy of the radiation deposited in the pixel region can be calculated, thereby obtaining image information of the pixel.
  • the reading method outputs a voltage value, which is stronger than the conventional transistor reading method, and the data processing circuit is simpler.
  • the transistors Q21, Q23, Q24 of all the pixel cells are turned off, and the pixel electrode 31 1 collects the charge signal and accumulates on the storage capacitor C1;
  • V is applied to the column strobe signal to the first column of the pixel unit, and then sequentially applied to the row column strobe signal V R. W , the transistors Q23, Q24 of the corresponding pixel unit are turned on, so that the potential of the pixel electrode 311 of the first column of pixel units is read one by one as a sensing signal;
  • the first column of pixel cell transistors Q21 is turned off, the column strobe signal is applied to the first column of V Col pixel units, then successively to the respective pixel columns of the row strobe unit to apply V R. W , the transistors Q23, Q24 of the corresponding pixel unit are turned on, thereby reading the potential of the pixel electrode 311 of the first column of pixel units one by one as a background signal;
  • a constant bias can be applied to the top electrode on the radiation sensitive film to create a collection field of sufficient strength in the sensitive region of the radiation detector.
  • the bias voltage is a negative bias.
  • the bias voltage is a positive bias.
  • the pixel unit of the digital image flat panel detector of the present invention has a 4T structure (SP, including four transistors), compared to the prior art digital image flat panel detector shown in FIG. 4 (where the pixel unit is a 1T structure),
  • the inventive digital image flat panel detector can read signals either column by column or by pixel.
  • the object to be measured has a small area, it is possible to selectively read only the pixel region corresponding to the object to be measured, thereby reducing the effective imaging area of the detector, thereby reducing data redundancy and improving data processing. speed.
  • the deadger can be masked by the row strobe and column strobe functions.
  • the bad point will output a large voltage, which has a great influence on the subsequent circuit.
  • the line strobe function disconnects the dead pixel from the subsequent circuit, which does not affect the subsequent circuit or affect any surrounding pixels.
  • the pixel array shown in FIG. 5 can be implemented as any of the combination of the CMOS pixel array 2 shown in FIG. 1A, the TFT pixel array 3 shown in FIG. 1b, and the circuit board 6 and the signal processing IC 7 shown in FIG. . Further, the detector constructed thereby can be used for any of the planar imaging digital imaging device shown in Fig. 2a and the linear scanning digital imaging device shown in Fig. 2b.
  • Figure 6 shows a top view of a pixel electrode in a digital image flat panel detector in accordance with the prior art.
  • An array of pixel electrodes 311 is formed, for example, on the circuit board 210.
  • Each of the pixel electrodes 311 is a part of one pixel unit shown in Fig. 5, and is electrically coupled to one pixel region of the mercury iodide film.
  • Each of the pixel electrodes 311 is electrically insulated from each other.
  • Figure 7 shows a top view of a pixel electrode in a digital image flat panel detector in accordance with the present invention.
  • the pixel electrode shown in Fig. 6 is different.
  • the electrode structure shown in Fig. 7 includes a pixel electrode 31 1 and a grid-like guide electrode 314 around each pixel electrode 311.
  • the pixel electrodes 31 1 and between the pixel electrodes 311 and the guiding electrodes 314 are electrically insulated.
  • Figure 8a shows a cross-sectional view of a pixel electrode in a digital image flat panel detector in accordance with the present invention.
  • a transistor of each of the CMOS pixel array or the TFT pixel array is formed in the active layer 212 on the upper side of the substrate 211.
  • the interlayer insulating layer 213 is located between the pixel electrode 311, the guiding electrode 314, and the active layer 212.
  • the pixel electrode 311 and the guiding electrode 314 are electrically connected to transistors in the active layer 212 via vias (not shown) in the interlayer insulating layer 213.
  • the pixel electrode 311 and the guiding electrode 314 may be formed of the same or different metal layers. Typically, the two are on the same plane and are formed from the same metal layer.
  • Fig. 8b shows a modification of the above pixel electrode, in which each grid of the grid-shaped guide electrodes 314 At least two pixel electrodes 311 are included.
  • Figure 9a shows a cross-sectional view of a pixel electrode in a digital image flat panel detector in accordance with the present invention.
  • a pixel electrode 31 1 and a guiding electrode 314 are formed on one side of the circuit board 214, and a signal processing IC (not shown) is provided on the other side of the circuit board, and the pixel electrode 311 and the guiding electrode are connected via wiring and via holes on the circuit board. 314 is connected to the signal processing IC.
  • the signal processing IC includes a transistor Q21-24 and a storage capacitor Cl in the pixel unit.
  • the pixel electrode 311 and the guiding electrode 314 may be formed of the same or different metal layers. Typically, the two are on the same plane and are formed from the same metal layer.
  • Fig. 9b shows a modification of the above-described pixel electrode in which each of the mesh-shaped guiding electrodes 314 includes at least two pixel electrodes 311.
  • the shape of the pixel electrode 311 is not limited to a rectangle, and may be a circle, a diamond, a hexagon, or the like.
  • the electrode structure shown in Figs. 7 to 9 can be realized as a pixel electrode in the CMOS pixel array 2 shown in Fig. 2, the TFT pixel array 3 shown in Fig. 1b, and the circuit board shown in Fig. lc. Further, the detector constructed thereby can be used for any of the planar imaging digital imaging device shown in Fig. 2a and the linear scanning digital imaging device shown in Fig. 2b.
  • a grid-shaped guiding electrode 314 surrounding each pixel electrode 31 1 is used, which can effectively collect the leakage current of the detector surface, reduce the influence of leakage current on the pixel electrode 311, and reduce the detection. Noise.
  • the potential of the guiding electrode 314 is slightly different from the potential of the pixel electrode 31 1 (the potential of the guiding electrode 314 is slightly lower than that of the pixel electrode 311 when electrons are collected, and the potential of the guiding electrode 314 is slightly higher than the pixel electrode 311 when collecting holes)
  • the guiding electrode 314 can effectively prevent the charge from being accumulated in the blank area between the electrodes without the electrode, and thereby prevent the electric field generated by the accumulated electric charge from weakening the applied electric charge collecting electric field intensity, reducing the dead zone of the detector, and reducing the polarization of the detector. effect.
  • the bias potential applied to the guiding electrode 314 provides a shaped electric field for each pixel region, further improving the charge collection efficiency.
  • a shaped electric field of a desired shape can be obtained.
  • the shape of the pixel electrode may be selected from any one of a circle, an ellipse, and a polygon.
  • the shape of the pixel electrode is square.
  • the mesh shape of the grid-like conductive electrode is substantially the same as the shape of the pixel electrode.

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Description

辐射探测器及其成像装置、 电极结构和获取图像的方法 技术领域 本发明涉及辐射探测器及其成像装置、 电极结构和获取图像的方法, 具体地涉及 例如 X射线数字影像平板探测器及成像装置。 背景技术
在过去, 人们利用对辐射敏感的闪烁层将射线转换成光信号, 用电视摄像机 接收光信号, 并经显示屏显示出来, 从而实现射线辐射透视时的实时成像。 随着 技术的发展, CCD的出现使得这一实时成像方式更加优化。 CCD在稳定性、 集成 度、 一致性以及高速采集上有着非常优越的性能。 但是由于 CCD本身的耐辐射损 伤问题, 这一实时成像方式有着一个不可避免的缺点, 那便是需要足够厚度的辐 射敏感薄膜或者传输光路的装置, 常用的转换、 传输装置有影像增强器、 透镜、 光纤等, 这些转换、传输装置在工作流程中位于 CCD前面, 所引入的不一致、 噪 声等因素使得 CCD的诸多优势无法充分的显现出来, 同时也增加了成像系统的复 杂程度, 降低了系统的可靠性。
从 20世纪九十年代开始,从事辐射成像领域的技术人员开始着眼于研究如何 在辐射成像探测器上将高速、 高图像质量、 高集成度、 高可靠性、 大面积以及操 作的简易性等优点结合起来, 由此发展出了大面积的数字影像平板探测器。
目前数字影像平板探测器的产品可以实现上千平方厘米级的大面积, 几十微 米级的空间分辨以及每秒上百帧的读取速度。
数字影像平板探测器的第一种已知技术是采用非晶硅二极管与 TFT结合。 非 晶硅二极管吸收射线, 产生电子空穴对, 在电场作用下某种极性的带电粒子漂移 到 TFT像素阵列上, 通过 TFT的开关扫描依次读取各像素信号。
非晶硅的电离能很低 (约 5eV), 在射线照射下能够产生大量的电子空穴对, 能够在低剂量下仍然得到很好的信噪比。
然而, 硅的原子序数很小 (Z=14 ), 对射线的阻挡能力非常弱, 需要很厚的硅 层才能将射线有效阻挡, 这使得该方法在工艺上不易实现, 且成本很高。
数字影像平板探测器的第二种已知技术是用非晶硒薄膜与 TFT结合。 非晶硒 吸收射线, 产生电子空穴对, 在电场作用下某种极性的带电粒子漂移到 TFT像素 阵列上, 通过 TFT的开关扫描依次读取各像素信号。
硒的原子序数为 34, 非晶硒对射线的阻挡能力相对非晶硅较强, 但仍然只适 应于探测 50KeV以内的射线, 这限制了非晶硒平板探测器的主要应用领域为低能 量领域 (如乳腺成像)。
非晶硒的电离能随所加场强以及入射的射线能量变化而改变, 在医学诊断常 用的场强以及射线能量区域, 其电离能约为 50eV, 由此限制了射线的最低剂量以 及输出的信号幅度。
另外, 非晶硒温度稳定性差, 易潮解和晶化, 使用寿命不如其他结构的平板 探测器。
数字影像平板探测器的第三种已知技术是采用闪烁体与光电二极管以及 TFT 结合。 闪烁体将射线转换成光信号, 光电二极管接收光信号, 转换为电信号, 再 通过 TFT的开关扫描依次读取各像素信号。
闪烁体可以吸收射线能量并发射出一定波长范围的可见光子, 发射出的光子 数与吸收的能量成正比。 闪烁体材料的原子序数一般比较高, 对射线吸收能力较 强。 闪烁体可以是荧光薄膜材料 (比如某些稀土材料) 或者是闪烁晶体 (比如碘 化铯、 钨酸镉等)。
碘化铯晶体的原子序数比非晶硅和非晶硒都大, 对射线有很好的阻挡、 吸收 能力; 同时掺杂铊的碘化铯晶体发射光谱峰位为 565nm, 与非晶硅光电二极管的 吸收光谱峰位基本吻合, 两者的结合在同种类型产品中具有最高的量子效率。 这 些优点使得目前数字影像平板探测器中最常见的都是由碘化铯晶体与硅光电二 极管以及 TFT结合的结构。
当闪烁体为均匀薄膜材料时, 为了增大可探测的能量范围以及探测效率, 需 要增加薄膜的厚度, 而随着薄膜厚度的增加, 可见光子的散射对探测器空间分辨 率的影响会增大。 当闪烁体为碘化铯晶体时, 可以通过将晶体生长为高密度针状 阵列 (10-20 μ πι尺寸的针管), 以抑制光子的散射。
然而, 随着碘化铯薄膜厚度的增加, 针管深宽比增大, 管内光子的收集效率 会大大降低, 从而降低了探测器的量子效率。 同时由于针管与光电二极管之间的 尺寸配合问题, 这种类型的探测器死区所占的比例会偏大。
闪烁体内每产生一个可见光子需要约 20-50eV的能量, 再考虑光电二极管对 可见光波段的量子效率, 这种结构的探测器每产生一对电子空穴对需要约 lOOeV 甚至更多的能量, 这个性能决定了采用闪烁体作为辐射敏感薄膜会得到较差的信 噪比。
数字影像平板探测器的第四种已知技术是采用闪烁体与 CMOS 结合。 可以将 闪烁体直接覆盖在 CMOS 上, 也可以通过两端直径不一样的光纤将大面积的闪烁 体与小面积的 CMOS结合。
采用 CMOS 工艺取代传统的硅工艺, 能够更大程度的提高系统的集成度, 探 测器的空间分辨率、 占空比、 采集速度等都有很大的提高, 每个像素单元都集成 了独立的电荷-电压转化电路和放大电路, 能够获得更好的信噪比。
然而, 受到 CMOS 工艺的限制, 这种类型的平板探测器不易在较低的成本下 得到大的灵敏面积, 但在小面积探测领域, 比如牙科 CT、 小动物 CT等, 其优势 是非常明显的。
综上所述, 在现有技术的数字影像平板探测器中, 考虑动态范围 (可探测的 能量范围)、 探测效率、 信噪比、 空间分辨等因素, 主要的射线转换方式是使用 高密度针状的碘化铯闪烁体, 将射线先转换为可见光子, 再通过光电二极管将可 见光子转换为电信号。
电信号的读取主要采用 TFT读取或者 CMOS读取, 根据实际需要的面积、 空 间分辨率、 采集速度、 集成度、 成本等因素进行选择 TFT和 CMOS之一。 发明内容
本发明提出一种结构简单、 高量子效率的数字影像平板探测器及成像装置, 其中不必使用闪烁体和光电转换器件。
根据本发明的一方面, 提供一种辐射探测器, 包括辐射敏感薄膜、 位于辐射 敏感薄膜上的顶部电极、 以及与辐射敏感薄膜电耦合的像素单元的阵列, 其中每 一个像素单元包括; 像素电极, 用于收集辐射敏感薄膜的一个像素区域中的电荷 信号; 储存电容, 与像素电极连接, 用于储存像素电极所收集的电荷信号; 复位 晶体管, 与像素电极连接, 用于清空储存电容中的电荷; 缓冲晶体管, 与像素电 极连接, 用于将像素电极上的电荷信号转换成电压信号并传送到信号线上; 列选 通晶体管, 用于选择预定列的像素电极; 以及行选通晶体管, 用于选择预定行的 像素电极, 其中, 列选通晶体管和行选通晶体管串联连接在缓冲晶体管和信号线 之间, 并响应列选通信号和行选通信号传送相应的像素单元的电压信号。
根据本发明的又一方面, 提供一种数字成像装置, 包括: 辐射源, 产生辐射; 前述的辐射探测器, 检测穿过被测物体后的辐射剂量; 数据获取系统, 将辐射探 测器输出的模拟信号转换成数字信号; 图像处理器, 将数字信号处理成图像。 根据本发明的又一方面, 提供一种用于辐射探测器的电极结构, 包括: 像素 电极; 以及网格状的导向电极, 围绕至少一个像素电极, 并且像素电极与导向电 极彼此电绝缘。
根据本发明的又一方面, 提供一种利用前述的辐射探测器获取图像的方法, 包括以下步骤:
a)向各列像素单元施加复位信号, 使得所有像素单元复位;
b)所有像素单元的复位晶体管、 列选通晶体管、 行选通晶体管截止, 像素电 极收集电荷信号, 积累在储存电容上;
c)达到预定的积分时间后, 向第一列像素单元施加列选通信号, 然后依次向 该列的相应的像素单元施加行选通信号, 使得相应的像素单元的列选通晶体管和 行选通晶体管导通, 从而逐个地读取第一列像素单元的像素电极的电位, 作为传 感信号;
d)第一列像素单元的列选通晶体管和行选通晶体管截止, 并向第一列施加复 位信号, 使得第一列像素单元的复位晶体管导通, 即第一列像素单元复位;
e)第一列像素单元的复位晶体管截止, 向第一列像素单元施加列选通信号, 然后依次向该列的相应的像素单元施加行选通信号, 使得相应的像素单元的列选 通晶体管和行选通晶体管导通, 从而逐个地读取第一列像素单元的像素电极的电 位, 作为背景信号;
f)重复步骤 c)至 e),针对其他列,逐像素地读取像素电极上收集的电荷信号。 g)在所有像素读取完毕后, 经过数据处理获得一帧图像。
本发明提出的探测器及其成像装置一方面在保证探测效率、 探测能量范围、 信噪比以及空间分辨率的前提下, 利用辐射敏感薄膜 (如碘化汞薄膜) 直接将射 线转换为电信号, 去掉了把射线转换为可见光子再由可见光子转化为电信号的步 骤, 简化了探测器的结构, 减少了中间过程有效信号的损失, 提高了探测器的量 子效率。 而且, 没有闪烁体的余晖问题, 探测器对辐照剂量的变化会更加敏感, 扫描速度可以进一步提高。
另一方面, 通过包含四个晶体管 (4T ) 的像素单元, 实现电信号的采集、 输 出和数据处理, 并可以实现为 TFT像素阵列、 CMOS像素阵列、 电路板和信号处理 ic。 这提高了系统的集成度, 使之在性能指标上更加优越, 与实际应用领域更加 适应。 由于 4T 像素单元直接输出电压信号, 可以减少外电路对模拟信号的干扰, 提高系统的信噪比, 同时降低后继 ASIC设计的复杂程度, 提高设备的可靠性。
利用包含 4T像素单元的 CMOS像素阵列或 TFT像素阵列,提高系统的集成度, 以满足小区域内更高空间分辨的要求。
利用包含 4T像素单元的信号处理 IC, 与电路板一起形成像素阵列, 将某一 区域的像素电极引至一个信号处理 IC 收集电信号并进行处理, 可以减小信号处 理 IC的设计规模, 最大程度地降低成本。
在像素之间或者像素区域之间以及像素阵列外围设置一定结构的网格状的 导向电极, 可以收集探测器表面漏电流, 降低探测器的噪声。 同时, 使得导向电 极电位与像素电极电位略有不同 (收集电子时导向电极电位略低于像素电极, 收 集空穴时导向电极电位略高于像素电极), 导向电极与像素电极之间存在弱电场, 可以有效的防止电荷堆积, 提高电荷收集率, 减少探测器的死区, 减轻探测器的 极化效应。 进一步优化了探测器的性能。 附图说明
图 la至 lc分别示出了根据现有技术的三种数字影像平板探测器的示意性结 构。
图 2a至 2b分别示出了根据现有技术的两种数字成像装置的示意性结构。 图 3a至 3b示出了根据现有技术的数字影像平板探测器的更详细的结构。 图 4示出了根据现有技术的数字影像平板探测器的 TFT像素阵列。
图 5示出了根据本发明的数字影像平板探测器的像素阵列。
图 6示出了根据现有技术的数字影像平板探测器中的像素电极的俯视图。 图 7示出了根据本发明的数字影像平板探测器中的像素电极的俯视图。
图 8a和 8b分别示出了根据本发明的数字影像平板探测器中的像素电极的截 面图。
图 9a和 9b分别示出了根据本发明的数字影像平板探测器中的像素电极的截 面图。 具体实施方式 以下参照附图, 更加详细地描述本发明, 附图中示出了本发明的实施例。 但 是本发明可以采用多种不同的形式具体实现, 而不应该认为本发明仅限于在此提 出的实施例。
图 la 至 lc 分别示出了根据现有技术的三种数字影像平板探测器。 碘化汞 ( Hgl2 ) 薄膜 1是连续的薄膜或者图案化成与像素电极相对应的分立像素区域, 分别利用 CMOS像素阵列 2、 TFT像素阵列 3和电路板(PCB) 6的电极阵列提供数 字影像的像素单元。 通过探测器获得的像素信号经由电缆 8传送至图像处理器 9 (例如计算机), 形成数字影像, 并在显示器上进行显示。
如图 la所示, 碘化汞薄膜 1位于 CMOS像素阵列 2上方, 例如通过蒸镀直接 在 CMOS像素阵列 2的顶部形成, 作为集成电路的一部分。 利用 CMOS像素阵列 2 实现对碘化汞薄膜 1中的每一个像素区域的访问。
如图 lb所示, 碘化汞薄膜 1位于 TFT像素阵列 3上方, 例如通过蒸镀直接 在 TFT像素阵列 3的顶部形成, 作为集成电路的一部分。 经由电极 4和 5实现对 碘化汞薄膜 1中的每一个像素区域的访问。
如图 lc所示, 碘化汞薄膜 1位于电路板 6的一面, 在电路板的另一面提供 信号处理 IC 7, 经由电路板上的布线和过孔连接碘化汞薄膜 1和信号处理 IC 7。 进一步地,信号处理 IC 7连接至图像处理器 9。利用电路板上形成的电极阵列(未 示出) 实现对碘化汞薄膜 1中的每一个像素区域的访问。
碘化汞的原子序数比碘化铯要高,密度比碘化铯大,对射线的阻挡能力更强, 用来作为射线的辐射敏感薄膜可以得到更高的探测效率。 同样的辐射敏感薄膜厚 度下, 碘化汞探测器能探测到的射线能量也更高 (动态范围上限)。 同时由于其 原子序数高, 500KeV范围内的光子与碘化汞的相互作用主要为光电效应, 发生康 普顿散射的比例很小, 在一定电场作用下, 这么短的迁移距离里, 载流子的横向 偏移可以忽略不计, 射线与物质相互作用的位置信息可以得到更精确的测量。
由于碘化汞是半导体材料, 其电离能与非晶硅在同一数量级 (〈10eV), 其得 到一个电子空穴对所需的射线能量远小于碘化铯或者非晶硒, 在同样能量 /剂量 的射线照射下, 产生的电子空穴对数量与非晶硅在同一数量级, 远多于碘化铯或 者非晶硒。 碘化汞禁带宽度约为硅的 2倍, 同时电阻率可达 1014 Q . cm, 因此其室 温下的漏电流非常小, 噪声性能远优于硅光二极管, 因此采用碘化汞作为辐射敏 感薄膜可以得到更好的信噪比, 能够测量到更低能量的射线 (动态范围下限)。
本发明人认识到, 在相同的辐照剂量下, 采用碘化汞作为辐射敏感薄膜可以 得到更优的图像质量。
可以采用真空物理气相沉积、 溅射、 喷涂、 热压、 丝印等方法, 在像素阵列 上覆盖碘化汞薄膜。
然而, 根据实际应用领域 (例如射线能量、 探测效率、 工艺要求等), 可以 用碘化铅 (Pbl2 )、 碲锌镉 (CdZnTe )、 碲化镉 (CdTe )、 砷化镓 (GaAs )、 溴化铊 ( TlBr )、 磷化铟 (InP)、 硒化镉 ( CdSe )、 硫化镉 ( CdS)、 砷化铟 ( InAs )、 硫 化铅 (PbS )、 锑化铟 (InSb )、 碲化铅 (PbTe )、 硒化汞 (HgSe ) 等其他半导体材 料来代替碘化汞。
此外, 正如在现有技术中已知的那样, 根据实际需要的面积、 空间分辨率、 采集速度、 集成度、 成本等因素选择 TFT和 CMOS之一。 例如, 在小面积成像领域 (牙科), CMOS是最优选的。
此外, 在对空间分辨率的要求不高的情形下, 甚至可以用电路板 (PCB ) 来 代替 TFT阵列。
在图 2a 中示出了根据现有技术的平面成像的数字成像装置的示意性结构。 来自辐射源 200的辐射穿过被测物体 300, 然后到达探测器 100。 探测器 100包 括二维的像素阵列, 这可以是一个整体的二维的像素阵列, 也可以由多个一维或 二维的像素阵列拼接而成。 每一个像素信号与像素区域的辐射剂量相关, 然后经 过后继数据获取系统 (DAQ) 400转换成数字信号, 传送至图像处理器 900。
在图 2b 中示出了利用线性扫描成像的数字成像装置。 来自点状辐射源 200 的辐射经由准直器 201整形为线状的辐射束, 然后穿过被测物体 300, 到达探测 器 100, 然后经过后继数据获取系统 (DAQ) 400转换成数字信号, 传送至图像处 理器 900。
与图 2a所示的数字成像装置不同, 图 2b中的数字成像利用被测物体 300相 对于辐射源 200、 准直器 201和探测器 100的相对移动, 对被测物体 300进行线 性扫描, 以形成在扫描方向上扩展的二维的数字图像。
例如辐射源 200、 准直器 201和探测器 100沿扫描方向同步地移动, 而被测 物体 300固定。 替代地, 辐射源 200、 准直器 201和探测器 100均固定, 而仅仅 被测物体 300沿扫描方向移动。
结果, 该数字成像装置可以利用较小尺寸的探测器 100对较大尺寸的被测物 体 300进行平面成像, 从而降低了数字成像装置的制造成本。
参见图 3a, 探测器 100包括像素阵列 110, 位于像素阵列 1 10上方的碘化汞 薄膜 ιοι、 位于碘化汞薄膜 101上 的顶部电极 iii、 包围碘化汞薄膜 101和顶部 电极 111 的保护层 112、 以及包围保护层的外壳 113。 像素阵列 110可以是 TFT 阵列、 CMOS阵列或电路板。
顶部电极 11 1可以是金属钯(Pd )、氧化铟锡合金(IT0)、 碳膜、氧化铟(1 03 )、 氧化锡(Sn02 )、钨钛(TiW), 以及其它的不与碘化汞发生反应的合适的导电材料。 保护层 112是稳定的防潮防静电的绝缘材料, 与碘化汞不发生化学反应, 可以是 硅橡胶, 树脂材料, 也可以是其他的热塑性材料 (如聚对二甲苯)。 外壳 113 是 绝缘、 遮光、 防静电材料。
辐射可以穿过外壳 113、 保护层 1 12和顶部电极 111到达碘化汞薄膜 101。 辐射与碘化汞薄膜的相互作用产生电子空穴对, 在电场作用下分别向像素阵列 110和顶部电极 111漂移, 并直接由电极收集, 由信号处理电路进行处理。
在图 3b所示的探测器 100的变型中, 进一步包括位于碘化汞薄膜 101和像 素阵列 110之间的第一中间保护层 1 14以及位于碘化汞薄膜 101和顶部电极 111 之间的第二中间保护层 1 15, 以实现探测器的长期稳定性。 第一中间保护层 114、 第二中间保护层 115由电介质形成,可以与前述的保护层 112的材料相同或不同。
对于图 3a和图 3b所示的探测器 100, 优选的, 通过周期性地 (例如在每帧 或每多帧信号之间) 对像素区域施加反向电场, 中和碘化汞薄膜 101中的残留电 荷, 使得探测器 100可以长期稳定的工作。
图 4示出了根据现有技术的数字影像平板探测器中的传感器部件的 TFT像素 阵列。 每个像素单元由一个像素电极 311、 一个晶体管 Q10 和一个储存电容 C1 组成。 晶体管 Q10 的漏极与像素电极 311相连, 像素电极 311经由储存电容 C1 接地。
像素电极 311与碘化汞薄膜的一个像素区域电连接, 用于收集电荷信号。 如 上所述, 碘化汞薄膜作为辐射敏感薄膜, 在经受辐射时沉积射线能量, 产生电荷 信号, 然后由像素电极 311收集。
储存电容 C1用于储存电荷。 当晶体管 Q10截止时, 经由像素电极 311收集 的电荷储存在储存电容 C1中。 当晶体管 Q10导通时, 可以读取储存电容 C1中的 电荷信号 Signal。
晶体管 Q1的栅极连接到外部的控制信号 Veat6, 而源极连接到读取电路(例如 积分放大电路)。 控制信号 Veat6可由可编程逻辑芯片提供, 按照以下的方式实现 有关的逻辑控制:
a)在晶体管 Q10 截止时, 像素电极 311 收集电荷信号, 积累在储存电容 C1 上; b)达到预定的积分时间后, 向第一列像素单元施加选通信号 V e, 第一列晶 体管 Q10导通, 第一列各单元的储存电容 C1放电, 从而读取电荷信号;
c)重复步骤 b), 针对其他列, 逐列读取像素电极上收集的电荷信号。
d)所有列读取完毕后, 经过数据处理可以获得一帧图像。
通常由于第一帧图像内各列积分时间不一致, 第一帧图像数据舍弃, 以后各 帧图像均为有效数据。
图 5示出了根据本发明的数字影像平板探测器中的传感器部件的像素阵列。 每个像素单元包括像素电极 311、 四个晶体管 (Q21、 Q22、 Q23、 Q24 ) 和储存电 容 Cl。
像素电极 311与碘化汞薄膜的一个像素区域电耦合, 用于收集电荷信号。 如 上所述, 碘化汞薄膜作为辐射敏感薄膜, 在经受辐射时沉积射线能量, 产生电荷 信号, 然后由像素电极 311收集。
储存电容 C1用于储存电荷。 当电荷在储存电容 C1上积累时, 像素电极 311 的电位会发生变化。 电位的变化量与累计的电荷量成正比, 即与像素区域中沉积 的射线能量成正比。
晶体管 Q21用于复位, 其栅极与复位控制信号 (VR6S6t ) 相连。 当晶体管 Q21 导通时, 储存电容 C1上积累的电荷被清空, 像素电极 311恢复到固定的初始电 平 探测器恢复初始状态。
晶体管 Q22用于缓冲, 以驱动后继的电路, 其栅极与像素电极 311相连。 在 漏极上施加固定的偏置电平 V2, 使得晶体管 Q22工作于跟随状态。 由于 Q22在工 作过程中无状态变化, 因此, 固定的电平 V2始终施加到晶体管 Q22的漏极上。
晶体管 Q23用于列选通, 其栅极与列选通信号 ( VCol )相连, 控制读取的顺序 和每列的积分时间以及读取时间; 晶体管 Q24用于行选通, 其栅极与行选通信号 ( VRow) 相连, 用来选择需要输出的行。
晶体管 Q23和 24串联连接。 如果同时选通晶体管 Q23和 Q24时, 则储存电 容中储存的电荷信号依次经由像素电极 311、缓冲晶体管 Q21、列选通晶体管 Q23、 行选通晶体管 Q24传送到信号线 Signal上, 使得可以读取对应的像素单元的像 素电极 311的电位。
同一列像素单元的晶体管 Q21的栅极连接到同一个复位信号 (VR6S6t ) 上; 同 一列像素单元的晶体管 Q23的栅极连接到同一个列选通信号 (V ) 上; 同一行像 素单元的晶体管 Q24的栅极连接到同一个行选通信号 ( VRow)上; 同一行像素单元 的晶体管 Q24 的源极连接到同一路后继电路 (例如, 多路开关、 电平转换或者 ADC)。
通过测量复位前 (传感信号) 和复位后 (背景信号) 像素电极 31 1电位的变 化量, 可以计算出在该像素区域内沉积的射线的能量, 从而得到该像素的图像信 息。
该读取方法输出的是电压值, 与传统的晶体管读取方式相比, 抗干扰能力会 更强, 同时数据处理电路会更简单。
按照以下的方式实现有关的逻辑控制:
a)向各列像素单元施加复位信号 VR6S6t, 使得所有像素单元复位;
b)所有像素单元的晶体管 Q21、 Q23、 Q24截止, 像素电极 31 1收集电荷信 号, 积累在储存电容 C1上;
c)达到预定的积分时间后, 向第一列像素单元施加列选通信号 V , 然后依 次向该列的相应的像素单元施加行选通信号 VRW, 使得相应的像素单元的晶体管 Q23、 Q24导通, 从而逐个地读取第一列像素单元的像素电极 311的电位, 作为传 感信号;
d)第一列像素单元的晶体管 Q23、 Q24截止, 并向第一列施加复位信号 VR6S6t, 使得第一列像素单元的晶体管 Q21导通, 即第一列像素单元复位;
e)第一列像素单元的晶体管 Q21 截止, 向第一列像素单元施加列选通信号 VCol, 然后依次向该列的相应的像素单元施加行选通信号 VRW, 使得相应的像素单 元的晶体管 Q23、 Q24导通, 从而逐个地读取第一列像素单元的像素电极 311 的 电位, 作为背景信号;
f)重复步骤 c)至 e),针对其他列,逐像素地读取像素电极上收集的电荷信号。 g)在所有像素读取完毕后, 经过一定的数据处理 (例如, 从传感信号中减去 背景信号), 可以获得一帧图像。
通常由于第一帧图像内各列积分时间不一致, 第一帧图像数据舍弃, 以后各 帧图像均为有效数据。
在步骤 a ) 至 g) 期间, 可以向辐射敏感薄膜上的顶部电极施加恒定的偏压, 使得辐射探测器灵敏区内形成足够强度的收集电场。 在像素区域中产生的电荷信 号由电子产生时,该偏压为负偏压。在像素区域中产生的电荷信号由空穴产生时, 该偏压为正偏压。
根据探测器的极化程度和残留电荷量, 在每帧或每数帧图像之间, 进一步包 括周期性改变顶部电极的偏压极性 (反向偏压), 在探测器灵敏区内形成方向相 反的电场, 以消除探测器在工作过程中的极化现象, 中和残留电荷。
本发明的数字影像平板探测器的像素单元为 4T结构(SP,包括四个晶体管), 相对于图 4所示的现有技术的数字影像平板探测器(其中,像素单元为 1T结构), 本发明的数字影像平板探测器既可以逐列读取信号, 也可以逐个像素读取信号。
而且, 当被测物体面积很小时, 可以选择性地仅对被测物体相对应的像素区 域读取信号, 以减小探测器的有效成像面积, 从而减小数据的冗余, 提高数据处 理的速度。
在探测器出现坏点的时候, 可以通过行选通和列选通功能屏蔽该坏点。 特别 是某些情况下坏点会输出较大电压, 对后继的电路影响很大, 通过行选通功能将 坏点与后继电路断开, 既不影响后继电路, 也不影响周边任何像素。
图 5所示的像素阵列可以实现为图 la所示的 CMOS像素阵列 2、图 lb所示的 TFT像素阵列 3以及图 l c所示的电路板 6与信号处理 IC 7的组合中的任一实例。 进一步地, 由此构成的探测器可以用于图 2a所示的平面成像的数字成像装置以 及图 2b所示的线性扫描的数字成像装置中的任一实例。
图 6示出了根据现有技术的数字影像平板探测器中的像素电极的俯视图。 例 如在电路板 210上形成像素电极 311的阵列。 每一个像素电极 311作为图 5所示 的一个像素单元的一部分, 并且电耦合至碘化汞薄膜的一个像素区域。 各个像素 电极 311之间电绝缘。
图 7示出了根据本发明的数字影像平板探测器中的像素电极的俯视图。 与图
6所示的像素电极不同, 图 7所示的电极结构包括像素电极 31 1和在每一个像素 电极 311周围的网格状的导向电极 314。 各个像素电极 31 1之间、 以及像素电极 311与导向电极 314之间电绝缘。
图 8a 示出了根据本发明的数字影像平板探测器中的像素电极的截面图。 在 衬底 211上方面的有源层 212中形成了 CMOS像素阵列或 TFT像素阵列中的每一 个像素单元的晶体管。 层间绝缘层 213位于像素电极 311、 导向电极 314和有源 层 212之间。 像素电极 311和导向电极 314经由层间绝缘层 213中的通道 (via) (未示出) 与有源层 212中的晶体管电连接。
像素电极 311和导向电极 314可以由相同或不同的金属层形成。 通常, 二者 位于同一平面上并由相同的金属层形成。
图 8b示出了上述像素电极的变型, 其中网格状的导向电极 314的每个网格 包括至少两个像素电极 311。
图 9a 示出了根据本发明的数字影像平板探测器中的像素电极的截面图。 在 电路板 214的一面上形成了像素电极 31 1和导向电极 314, 在电路板的另一面提 供信号处理 IC (未示出), 经由电路板上的布线和过孔将像素电极 311和导向电 极 314连接至信号处理 IC。
信号处理 IC包含像素单元中的晶体管 Q21-24和储存电容 Cl。
像素电极 311和导向电极 314可以由相同或不同的金属层形成。 通常, 二者 位于同一平面上并由相同的金属层形成。
图 9b示出了上述像素电极的变型, 其中网格状的导向电极 314的每个网格 状包括至少两个像素电极 311。
应当注意, 像素电极 311的形状不限于矩形, 还可以是圆形、 菱形、 六边形 等。
图 7至 9所示的电极结构可以实现为图 la所示的 CMOS像素阵列 2、图 lb所 示的 TFT像素阵列 3 以及图 l c所示的电路板中任一实例中的像素电极。 进一步 地, 由此构成的探测器可以用于图 2a所示的平面成像的数字成像装置以及图 2b 所示的线性扫描的数字成像装置中的任一实例。
已经知道, 大面积的平板探测器存在着严重的表面漏电流。 在本发明的探测 器中, 采用了包围每一个像素电极 31 1的网格状的导向电极 314, 可以有效地收 集探测器表面的漏电流,减小漏电流对像素电极 311的影响,降低探测器的噪声。
优选地, 导向电极 314的电位与像素电极 31 1的电位略有不同 (收集电子时 导向电极 314的电位略低于像素电极 311, 收集空穴时导向电极 314的电位略高 于像素电极 311 ), 从而在导向电极 314与像素电极 311之间存在弱电场。 导向电 极 314能够有效地防止电荷在像素之间没有电极的空白地带堆积, 并进而防止堆 积的电荷产生的电场削弱外加的电荷收集电场强度, 减少探测器的死区, 以及减 轻探测器的极化效应。
更优选地, 向导向电极 314施加的偏置电位为每一个像素区域提供了成形电 场, 进一步提高电荷的收集效率。 通过改变像素电极和导向电极的形状, 可以获 得理想形状的成形电场。 例如, 像素电极的形状可以选自圆形、 椭圆形、 多边形 中的任意一种。 优选地, 像素电极的形状为方形。 网格状导电电极的网格形状与 像素电极的形状大致相同。
在上文中已描述了若干实施例, 本领域的技术人员将认识到, 在不偏离本发 明的权利要求的精神的情况下, 可以使用各种不同的变型、 替代的结构以及等同 物。 因此, 上面的描述不应用来限制本发明的范围。

Claims

权 利 要 求
1. 一种辐射探测器, 包括辐射敏感薄膜、 位于辐射敏感薄膜上的顶部 电极、 以及与辐射敏感薄膜电耦合的像素单元的阵列, 其中每一个像素单元 包括;
像素电极, 用于收集辐射敏感薄膜的一个像素区域中的电荷信号; 储存电容, 与像素电极连接, 用于储存像素电极所收集的电荷信号; 复位晶体管, 与像素电极连接, 用于清空储存电容中的电荷; 缓冲晶体管, 与像素电极连接, 用于将像素电极上的电荷信号转换成电 压信号并传送到信号线上;
列选通晶体管, 用于选择预定列的像素电极; 以及
行选通晶体管, 用于选择预定行的像素电极,
其中, 列选通晶体管和行选通晶体管串联连接在缓冲晶体管和信号线之 间, 并响应列选通信号和行选通信号传送相应的像素单元的电压信号。
2. 根据权利要求 1 所述的辐射探测器, 其中所述辐射敏感薄膜由选自 碘化汞、 碘化铅、 碲锌镉、 碲化镉、 砷化镓、 溴化铊、 磷化铟、 硒化镉、 硫化镉、 砷化铟、 硫化铅、 锑化铟、 碲化铅、 硒化汞构成的组中的一种材料 形成。
3. 根据权利要求 1 所述的辐射探测器, 其中所述辐射敏感薄膜是图案 化的,包括与每一个像素电极相对应的像素区域,并且像素区域彼此电绝缘。
4. 根据权利要求 1 所述的辐射探测器, 其中所述复位晶体管响应复位 信号而将像素电极连接到固定的初始电平上。
5. 根据权利要求 1 所述的辐射探测器, 其中所述缓冲晶体管的栅极与 像素电极连接,漏极与固定的偏置电平连接, 以及源极与列选通晶体管连接。
6. 根据权利要求 1 所述的辐射探测器, 其中辐射探测器由集成有辐射 敏感薄膜的单片 CMOS集成电路构成。
7. 根据权利要求 1 所述的辐射探测器, 其中辐射探测器由集成有辐射 敏感薄膜的单片 TFT集成电路构成。
8. 根据权利要求 1 所述的辐射探测器, 其中辐射敏感薄膜和像素电极 位于电路板的一面上, 储存电容、 复位晶体管、 缓冲晶体管、 列选通晶体管 和行选通晶体管的至少一部分集成在集成电路中, 并且所述集成电路安装在 电路板的另一面上。
9. 根据权利要求 1所述的辐射探测器, 其中像素电极的形状选自圆形、 椭圆形、 多边形中的一种。
10. 根据权利要求 1至 9中任一项所述的辐射探测器, 还包括围绕至少 一个像素电极的网格状的导向电极, 其中像素电极与导向电极彼此电绝缘。
11. 根据权利要求 10 所述的辐射探测器, 其中网格状导电电极的网格 形状与像素电极的形状相同。
12. 根据权利要求 1所述的辐射探测器, 进一步包括包围辐射敏感薄膜 和顶部电极的保护层、 以及包围保护层的外壳。
13. 根据权利要求 12 所述的辐射探测器, 进一步包括位于辐射敏感薄 膜和像素单元的阵列之间的第一中间保护层以及位于辐射敏感薄膜和顶部 电极之间的第二中间保护层。
14. 根据权利要求 1所述的辐射探测器,采用真空物理气相沉积、溅射、 喷涂、 热压、 丝印等方法, 在像素单元的阵列上覆盖辐射敏感薄膜。
15. 一种数字成像装置, 包括:
辐射源, 产生辐射;
根据前述任意一项权利要求所述的辐射探测器, 用于检测穿过被测物体 后的辐射剂量;
数据获取系统, 将辐射探测器输出的模拟信号转换成数字信号; 图像处理器, 将数字信号处理成图像。
16. 根据权利要求 15 所述的数字成像装置, 还包括准直器, 其中辐射 源、 准直器和探测器相对于被测物体移动, 从而对被测物体进行线性扫描。
17. 根据权利要求 16 所述的数字成像装置, 其中所述辐射源、 准直器 和探测器沿扫描方向同步地移动。
18. 一种用于辐射探测器的电极结构, 包括:
像素电极; 以及
网格状的导向电极, 围绕至少一个像素电极, 并且像素电极与导向电极 彼此电绝缘。
19. 根据权利要求 18所述的电极结构, 其中像素电极的形状选自圆形、 椭圆形、 多边形中的一种。
20. 根据权利要求 19 所述的电极结构, 其中网格状导电电极的网格形 状与像素电极的形状相同。
21. 根据权利要求 18 所述的电极结构, 其中导向电极与像素电极由相 同或不同的金属层形成。
22. 根据权利要求 21 所述的电极结构, 其中导向电极与像素电极位于 同一平面上并由相同的金属层形成。
23. 根据权利要求 18至 22中任一项所述的电极结构, 其中所述电极结 构位于集成电路内或电路板的一面上。
24. 根据权利要求 18至 22中任一项所述的电极结构, 其中导向电极的 电位与像素电极的电位相同或不同。
25. 根据权利要求 24 所述的电极结构, 其中在像素区域中产生的电荷 信号由电子产生时, 导向电极的电位低于像素电极。
26. 根据权利要求 24 所述的电极结构, 其中在像素区域中产生的电荷 信号由空穴产生时, 导向电极的电位高于像素电极。
27. 一种利用权利要求 1 至 14 中任一项所述的辐射探测器获取图像的 方法, 包括以下步骤:
a)向各列像素单元施加复位信号, 使得所有像素单元复位;
b)所有像素单元的复位晶体管、 列选通晶体管、 行选通晶体管截止, 像 素电极收集电荷信号, 积累在储存电容上;
C)达到预定的积分时间后, 向第一列像素单元施加列选通信号, 然后依 次向该列的相应的像素单元施加行选通信号, 使得相应的像素单元的列选通 晶体管和行选通晶体管导通, 从而逐个地读取第一列像素单元的像素电极的 电位, 作为传感信号;
d)第一列像素单元的列选通晶体管和行选通晶体管截止, 并向第一列施 加复位信号, 使得第一列像素单元的复位晶体管导通, 即第一列像素单元复 位;
e)第一列像素单元的复位晶体管截止, 向第一列像素单元施加列选通信 号, 然后依次向该列的相应的像素单元施加行选通信号, 使得相应的像素单 元的列选通晶体管和行选通晶体管导通, 从而逐个地读取第一列像素单元的 像素电极的电位, 作为背景信号;
f)重复步骤 c)至 e),针对其他列, 逐像素地读取像素电极上收集的电荷 信号。
g)在所有像素读取完毕后, 经过数据处理获得一帧图像。
28. 根据权利要求 27所述的方法, 其中, 所述步骤 g )包括从传感信号 中减去背景信号。
29. 根据权利要求 27所述的方法, 其中在步骤 a ) 至 g ) 期间, 向辐射 敏感薄膜上的顶部电极施加恒定的第一偏压, 使得辐射探测器灵敏区内形成 足够强度的收集电场。
30. 根据权利要求 29所述的方法,其中在像素区域中产生的电荷信号由 电子产生时, 第一偏压为负偏压。
31. 根据权利要求 29 所述的方法, 其中在像素区域中产生的电荷信号 由空穴产生时, 第一偏压为正偏压。
32. 根据权利要求 27至 31任一项所述的方法, 其中重复步骤 c)至 g), 以获取连续的多帧图像。
33. 根据权利要求 32所述的方法, 还包括在每帧或每数帧图像之间, 向辐 射敏感薄膜上的顶部电极施加恒定的第二偏压,以消除探测器在工作过程中的极 化现象, 第二偏压与第一偏压极性相反。
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