JP2016096362A - Solid-state imaging apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a solid-state imaging apparatus capable of making an output property or noise level of a pixel adjacent to a dummy photodiode closer to that of another pixel.SOLUTION: A solid-state imaging apparatus 1A includes a light-receiving part 20, an unwanted carrier capturing part 30 and a vertical shift register 60. The unwanted carrier capturing part 30 includes carrier capturing areas DAto DAwhich are disposed for each row in an area between the light-receiving part 20 and the vertical shift register 60. Each of the carrier capturing areas DAto DAincludes a transistor and a photodiode. One end of the transistor is connected to the photodiode and the other end is connected to electric charge discharging wiring R. The electric charge discharging wiring Ris short-circuited to a reference potential line GND.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a solid-state imaging device.

  Patent Document 1 describes a technique related to a radiation imaging apparatus. This apparatus includes a sensor array in which a plurality of pixels including a conversion element that converts radiation from a subject into an electric signal and a transfer switch that transfers the electric signal to the outside are two-dimensionally arranged. In addition, the device includes a plurality of gate lines that connect the pixels of the sensor array in the row direction, and a gate driving device that drives the gate lines to read out electrical signals of the pixels connected to the gate lines. And a plurality of signal lines connecting the pixels of the sensor array in the column direction, and a plurality of amplifiers provided corresponding to the signal lines and amplifying and reading out the electric signals transferred from the transfer switches. .

JP 2007-50053 A

  The solid-state imaging device has a light receiving unit in which a plurality of pixels are two-dimensionally arranged over a plurality of rows and a plurality of columns. Each pixel is provided with a photodiode for converting incident light into electrons. The photodiode of each pixel is connected to the readout wiring arranged for each column via a switch circuit (for example, a transistor), and the charge accumulated in the photodiode becomes conductive. This flows out to the readout wiring. The electric charge reaches the integrating circuit through the readout wiring and is converted into a voltage signal in the integrating circuit. A control terminal (for example, a gate terminal) for controlling the conduction state of the switch circuit of each pixel is connected to a row selection wiring arranged for each row. Then, a signal from the shift register is supplied to the control terminal of each switch circuit via the row selection wiring, whereby the charge is read from each pixel for each row.

  In a solid-state imaging device having such a configuration, light enters not only the light receiving unit but also a region around the light receiving unit. For example, when a solid-state imaging device is used as an X-ray imaging device, X-rays transmitted through the scintillator and scintillation light from the scintillator are transmitted to Incident into the surrounding area. As a result, unnecessary charges (carriers) are generated in the region around the light receiving unit. In particular, since the shift register arranged alongside the light receiving portion has a certain area, many unnecessary carriers are generated in the region where the shift register is formed.

  When unnecessary carriers generated in the shift register flow into the light receiving unit, noise is superimposed on an output from a pixel adjacent to the shift register. In order to avoid such a phenomenon, a photodiode (dummy photodiode) for absorbing unnecessary carriers is arranged in a region between the shift register and the light receiving unit, and this dummy photodiode is connected to a reference potential line (ground wiring). ).

  However, this method has the following problems. Usually, crosstalk caused by coupling capacitance or the like generated between these photodiodes exists between pixels adjacent to each other in the light receiving section. In each pixel, a parasitic capacitance exists between the photodiode and the row selection wiring connected to each other via the switch circuit, and this parasitic capacitance also affects the crosstalk. However, since the dummy photodiode described above is not provided with a switch circuit, such a parasitic capacitance does not occur. For this reason, the pixel adjacent to the dummy photodiode has a different degree of crosstalk compared to the other pixels, and the output characteristics and noise level from the pixel adjacent to the dummy photodiode are different from those of the other pixels. End up.

  The present invention has been made in view of such problems, and provides a solid-state imaging device capable of bringing the output characteristics and noise magnitude of pixels adjacent to a dummy photodiode closer to other pixels. With the goal.

  In order to solve the above-described problem, a solid-state imaging device according to the present invention includes a first photodiode and a first switch circuit having one end connected to the first photodiode, and includes M rows and N columns ( M, N are integers of 2 or more), and M × N pixels are two-dimensionally arranged. The light receiving portions are formed on the single crystal silicon substrate, and are arranged for each column. N readout wirings connected to the other end of the first switch circuit included in the pixel, and N pieces of output voltage values corresponding to the amounts of electric charges input through the N readout wirings, respectively. An integration circuit, a shift register that is arranged in the row direction with respect to the light receiving unit, and that controls the open / close state of the first switch circuit for each row, and a dummy that is disposed in a region between the shift register and the light receiving unit One end connected to photodiode and dummy photodiode A second switch circuit, characterized in that it comprises a shorted charge drain wiring to the reference potential line is connected to the other end of the second switch circuit.

  In this solid-state imaging device, a dummy photodiode is disposed in a region between the shift register and the light receiving unit. Unnecessary carriers generated in the shift register are absorbed by the dummy photodiode. As a result, it is possible to effectively prevent noise caused by unnecessary carriers generated in the shift register from being superimposed on the output from the pixels of the light receiving unit.

  Further, in this solid-state imaging device, the dummy photodiode and the charge discharging wiring are connected via the second switch circuit, and when the second switch circuit is turned on, the unnecessary carrier is a dummy photo. It is discharged from the diode to the reference potential line through the charge discharging wiring. As described above, in the solid-state imaging device, the second switch circuit is provided in the dummy photodiode as well as the first switch circuit in each pixel in the light receiving unit. Therefore, according to the above-described solid-state imaging device, the magnitude of the crosstalk in the pixels adjacent to the dummy photodiode can be made closer to the magnitude of the crosstalk in the other pixels, It becomes possible to bring the output characteristics and the magnitude of noise close to those of other pixels.

  The solid-state imaging device may be characterized in that the width of the dummy photodiode in the row direction is shorter than the width of the first photodiode in the direction. In the solid-state imaging device described above, the size of the dummy photodiode is not necessarily equal to that of the first photodiode. Therefore, by making the width of the dummy photodiode shorter than the width of the first photodiode in this way, the area around the light receiving unit is narrowed, and for example, when arranging a plurality of solid-state imaging devices side by side, the solid-state imaging device The insensitive area generated between them can be narrowed.

  The solid-state imaging device may be characterized in that the shift register and the light receiving unit are formed on a common substrate. In such a case, unnecessary carriers generated in the shift register easily flow into the light receiving unit, but according to the solid-state imaging device, it is possible to effectively prevent the unnecessary carriers from flowing into the light receiving unit.

  According to the solid-state imaging device according to the present invention, the output characteristics and noise magnitude of the pixels adjacent to the dummy photodiode can be brought close to other pixels.

It is a top view which shows a solid-state imaging device. It is the top view to which a part of solid-state imaging device was expanded. It is a figure which shows the internal structure of a solid-state imaging device. It is a figure which shows the detailed circuit structural example of a pixel, an integration circuit, a holding circuit, and a carrier capture area | region. It is a timing chart of each signal. It is a top view which shows the example which has arrange | positioned the dummy photodiode for absorbing an unnecessary carrier in the area | region between a shift register and a light-receiving part. (A) It is a top view of a light-receiving part, Comprising: An example of the boundary line of joint exposure is shown. (B) An example of a boundary line for joint exposure in the vicinity of the carrier capturing portion is shown. (A) It is a top view of a light-receiving part, Comprising: Another example of the boundary line of joint exposure is shown. (B) Another example of the boundary line of the joint exposure near the carrier capturing portion is shown. It is a top view which shows roughly the example which arranged two glass substrates side by side.

  Embodiments of a solid-state imaging device according to the present invention will be described below in detail with reference to the accompanying drawings. In the description of the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted.

  The solid-state imaging device according to the present embodiment is used in, for example, a medical X-ray imaging system. 1 and 2 are diagrams showing a configuration of a solid-state imaging device 1A according to the present embodiment. FIG. 1 is a plan view showing the solid-state imaging device 1A, and FIG. 2 is an enlarged plan view of a part of the solid-state imaging device 1A. 1 and 2 also show the XYZ orthogonal coordinate system for easy understanding.

  As shown in FIG. 1, the solid-state imaging device 1 </ b> A includes a light receiving unit 20, an unnecessary carrier capturing unit 30, a reading circuit unit 40, and a vertical shift register 60. The light receiving unit 20, the unnecessary carrier capturing unit 30, the reading circuit unit 40, and the vertical shift register 60 are fabricated on the main surface of the substrate 12. The vertical shift register 60 is arranged side by side with respect to the light receiving unit 20 in the X-axis direction. A part of the unnecessary carrier capturing unit 30 is disposed in a region between the light receiving unit 20 and the vertical shift register 60, and the remaining part of the unnecessary carrier capturing unit 30 is aligned with the light receiving unit 20 in the Y-axis direction. And is located in a region between the light receiving unit 20 and the readout circuit unit 40.

  The readout circuit unit 40 includes a plurality of integration circuits provided corresponding to each of the plurality of columns of the light receiving unit 20, and the plurality of integration circuits correspond to the amount of charge output from the pixels in the corresponding column. Each voltage value is generated. The read circuit unit 40 holds the voltage value output from each integrating circuit, and sequentially outputs the held voltage value.

The light receiving unit 20 is configured by two-dimensionally arranging a plurality of pixels P _{1,1 to} P _{M, N} over M rows and N columns (M and N are integers of 2 or more). In FIG. 2, a plurality of pixels _P 1, 1 _{to P M,} on behalf of _N, 4 each pixel _{P m, N-1, P} m, N, is _{P m + 1, N-1} , and _{P m + 1, N} It is shown. For example, the pixel P _{m, N} is a pixel located in the m-th row and the N-th column (m is an integer of 1 to M). 1 and 2, the column direction matches the Y-axis direction, and the row direction matches the X-axis direction. Each of the pixels P _{1,1 to} PM _{, N} included in the light receiving unit 20 includes a transistor 21 and a photodiode 22. The transistor 21 included in each of the pixels P _{1,1 to} P _{M, N} is a first switch circuit in the present embodiment. The transistor 21 is preferably a field effect transistor (FET), but may be a bipolar transistor. In the following description, it is assumed that the transistor 21 is an FET. In this case, the control terminal means a gate. When the transistor 21 is a bipolar transistor, the control terminal means a base.

In addition, the photodiode 22 included in each of the pixels P _{1,1 to} PM _{, N} is the first photodiode in the present embodiment. The photodiode 22 is constituted by a semiconductor region including a pn junction or a pin junction, generates an amount of electric charge corresponding to the incident light intensity, and accumulates the generated electric charge in the junction capacitance portion. One end (for example, a source region) of the transistor 21 is electrically connected to the photodiode 22. A scintillator (not shown) is provided on the light receiving unit 20. The scintillator generates scintillation light according to the incident X-rays, converts the X-ray image into an optical image, and outputs this optical image to the photodiode 22.

The solid-state imaging device 1A is provided with a plurality of row selection wirings Q _{1 to} Q _M (represented by Q _m and Q _{m + 1} in FIG. 2) arranged for each row and for each column. A plurality of readout wirings R _{1 to} R _N (representing _RN and _RN-1 as representative in FIG. 2) are further provided. The m-th row selection wiring Q _m includes a control terminal (for example, a gate terminal) for controlling the open / close state of the transistors 21 included in the pixels P _{m, 1 to} P _{m, N} of the corresponding row, and the transistor 21. Are vertically connected to a vertical shift register 60 that controls the open / close state of each row. Further, the readout wiring R _n in the n-th column (n is an integer of 1 to N) is the other end (for example, drain region) of the transistor 21 included in the pixels P _{1, n to} P _{M, n} of the corresponding column. And are electrically connected. A plurality of row selecting wirings _Q 1 to Q _M, and a plurality of readout wiring _R 1 to R _N, for example made of metal.

Unnecessary carrier capturing portion 30 has M carrier capturing regions _DA 1 to DA _M. Carrier capturing regions _DA 1 to DA _M is in the region between the light receiving portion 20 and the vertical shift register 60, it is arranged in each row. In FIG. 2, on behalf of the carrier capturing regions _DA 1 to DA _M, 2 one carrier capture region DA _m and _{DA m + 1} is shown. For example, the carrier trap region DA _m is a carrier trap region located in the m-th row. The M number of carrier capturing regions _DA 1 to DA _M respectively, the pixel _P 1, 1 _{to P M} as described _above, similarly to the _N, and a transistor 21 and a photodiode 22. Incidentally, M number of transistors 21 having carrier capturing regions _DA 1 to DA _M each is a second switch circuit in this embodiment. Further, M-number of photodiodes 22 having carrier capturing regions DA ₁ to DA _M each is a dummy photodiode in this embodiment, is constituted by a semiconductor region including a pn junction or pin junction, the light receiving portion 20 and the vertical It is arranged for each row in the area between the shift register 60. One end (for example, a source region) of the transistor 21 is electrically connected to the photodiode 22.

Carrier control terminal for controlling the opening and closing states of the capture region transistor 21 included in the DA _m (for example, the gate terminal) is the corresponding row selecting wiring Q _m and electrically connected to the line. Further, the solid-state imaging device 1A further includes a charge discharging wiring _Rd . Charge discharging wire _{R d} is, the other end of the transistor 21 included in the carrier capture region _DA 1 to DA _M (e.g. drain region) and are electrically connected. The charge discharging wiring _Rd is made of metal. Incidentally, the carrier capturing regions _DA 1 to DA _M not been blocked, the carrier capture region _DA 1 to DA _M normal pixels _P 1, 1 _{to P M,} is _N like the light incident. However, part or all of the carrier capturing regions _DA 1 to DA _M may be shielded.

Unnecessary carrier capturing portion 30 further has a disposed in each column (N + 1) pieces of carrier capturing regions _{DB 1 ~DB N +} 1. The configurations of the carrier capture regions DB _{1 to} DB _{N + 1} are the same as those of the pixels P _{1,1 to} P _{M, N} described above. That is, each of the carrier trap regions DB _{1 to} DB _{N + 1} includes a transistor 21 and a photodiode 22. One end (for example, a source region) of the transistor 21 is electrically connected to the photodiode 22. The control terminals of the transistors 21 included in the carrier trap regions DB _{1 to} DB _{N + 1} are electrically connected to a row selection wiring Q _d described later. The other end (e.g. the drain region) of the transistor 21 included in the carrier capture region _DB 1 to DB _N is electrically connected to the readout wiring _R 1 to R _N of each column. Note that the other end of the transistor 21 included in the carrier capture region DB _{N + 1} in the (N + 1) th column is electrically connected to the charge discharging wiring _Rd .

Next, the circuit configuration of the solid-state imaging device 1A will be described in detail. FIG. 3 is a diagram illustrating an internal configuration of the solid-state imaging device 1A. As described above, the light receiving unit 20 includes M × N pixels P _{1,1 to} P _{M, N} two-dimensionally arranged in M rows and N columns. Moreover, unnecessary carrier capturing portion 30 includes and M carrier capturing regions _DA 1 to DA _M, and (N + 1) pieces of carrier capturing regions _{DB 1 ~DB N +} 1. N pixels of the m-th row _P m, 1 _{to P m, N} and m-th row selecting wiring _{Q m} that is connected to the carrier capturing region DA _m is connected to a vertical shift register 60. Further, the row selection wiring Q _d connected to the carrier capture regions DB _{1 to} DB _{N + 1} is also connected to the vertical shift register 60.

The read circuit unit 40 is a circuit for sequentially outputting an electrical signal corresponding to the amount of charge output for each column via the read wirings R _{1 to} R _N. The read circuit unit 40 includes N integration circuits 42 provided for each column and N holding circuits 44. The integrating circuit 42 and the holding circuit 44 are connected to each other in series for each column. The N integration circuits 42 have a common configuration. The N holding circuits 44 have a common configuration.

The N is the integration circuit 42 each have an input terminal connected to the respective readout wiring R ₁ to R _N, accumulates charges input from the readout wiring R ₁ to R _N, the accumulated charge A voltage value corresponding to the amount is output from the output terminal to each of the N holding circuits 44. However, the integration circuit is not provided in the charge drain wire R _d, is short-circuited to GND (connected to a ground potential voltage line in the present embodiment) charge drain wire R _d is the reference potential line . Accordingly, the charge which has passed through the charge discharging wire R _d is discharged to the reference potential line GND. Thus, the signal output from the dummy photodiode 22 of the carrier capturing regions _DA 1 to DA _M is the pixel _P 1, 1 _{to P M} that is input to the read circuit section _40, is output from the photodiode 22 of the _N Unlike the signal, it is not output from the solid-state imaging device 1A.

Each of the N integration circuits 42 is connected to a reset wiring 46 provided in common to the N integration circuits 42. Each of the N holding circuits 44 has an input terminal connected to the output terminal of the integrating circuit 42, holds a voltage value input to this input terminal, and uses the held voltage value for voltage output from the output terminal. Output to the wiring 48. Each of the N holding circuits 44 is connected to a holding wiring 45 provided in common to the N holding circuits 44. Also, each of the N holding circuits 44 are connected to a horizontal shift register 61 through the respective first row selection wiring U _{1 ~} N-th column selection wiring U _N.

The vertical shift register 60 provides the m-th row selection control signal VS _m to each of the N pixels P _{m, 1 to} P _{m, N in} the m-th row via the m-th row selection wiring Q _m . In addition, the vertical shift register 60 provides a row select control signal VS _d, via the row selecting wiring _{Q d} (N + 1) pieces of the carrier capturing regions _{DB 1 ~DB N +} 1. In the vertical shift register 60, the row selection control signals VS _d and VS _{1 to} VS _M are sequentially set to significant values. The horizontal shift register 61, the column selection control signal _HS 1 _{~HS n,} provided to each of the N holding circuits 44 via line _U 1 ~U _n for the column selection. The column selection control signals HS _{1 to} HS _n are sequentially set to significant values. Each of the N integrating circuits 42 is provided with a reset control signal RE via a reset wiring 46. A holding control signal Hd is provided to each of the N holding circuits 44 via the holding wiring 45.

FIG. 4 is a diagram illustrating a detailed circuit configuration example of the pixel P _{m, n} , the integration circuit 42, the holding circuit 44, and the carrier capture region DA _m . Here, a circuit diagram of the pixel P _{m, n in} the _m- th row and the n-th column is shown on behalf of the M × N pixels P _{1,1 to} P _{M, N} , and M carrier capture regions DA ₁ are shown. On behalf of the to DA _M and shows a circuit diagram of a carrier capturing region DA _m of the m-th row.

As shown in FIG. 4, the anode terminal of the photodiode 22 of the pixel P _{m, n} is grounded, and the cathode terminal is connected to the readout wiring R _n via the transistor 21. Similarly, the anode terminal of the photodiode 22 of the carrier capturing region DA _m is grounded, the cathode terminal is connected to the charge discharging wire R _d via the transistor 21. The m-th row selection control signal VS _m is provided from the vertical shift register 60 to the transistor 21 in the pixel P _{m, n} and the carrier trap region DA _m via the m-th row selection wiring Q _m . The m-th row selection control signal VS _m instructs the opening / closing operation of the transistors 21 included in the N pixels P _{m, 1 to} P _{m, n} and the carrier capture region DA _m of the m-th row. For example, when the m-th row selection control signal VS _m is an insignificant value (the off voltage of the control terminal of the transistor 21), the transistor 21 is turned off. At this time, the charge generated in the photodiode 22 is accumulated in the junction capacitance portion of the photodiode 22 without being output to the readout wiring R _n (or the charge discharging wiring R _d ). On the other hand, when the m-th row selection control signal VS _m is a significant value (the ON voltage of the control terminal of the transistor 21), the transistor 21 is connected. At this time, the electric charge accumulated in the junction capacitance portion of the photodiode 22 is output to the reading wiring R _n (or the charge discharging wiring R _d ) via the transistor 21. The charges output from the photodiode 22 of the pixel P _{m, n} are sent to the integration circuit 42 through the readout wiring R _n . Meanwhile, the charge output from the photodiode 22 of the carrier capturing region DA _m is sent to the reference potential line GND through the charge discharging wire R _d.

The integration circuit 42 has a so-called charge integration type configuration including an amplifier 42a, a capacitive element 42b, and a discharge switch 42c. The capacitive element 42b and the discharge switch 42c are connected in parallel to each other and are connected between the input terminal and the output terminal of the amplifier 42a. Input terminal of the amplifier 42a is connected to the readout wiring line R _n. A reset control signal RE is provided to the discharge switch 42 c via the reset wiring 46.

  The reset control signal RE instructs the opening / closing operation of the discharge switch 42c of each of the N integration circuits 42. For example, when the reset control signal RE is an insignificant value (for example, high level), the discharging switch 42c is closed, the capacitive element 42b is discharged, and the output voltage value of the integrating circuit 42 is initialized. When the reset control signal RE is a significant value (for example, low level), the discharge switch 42c is opened, and the charge input to the integration circuit 42 is accumulated in the capacitive element 42b. The voltage value is output from the integration circuit 42.

The holding circuit 44 includes an input switch 44a, an output switch 44b, and a capacitive element 44c. One end of the capacitive element 44c is grounded. The other end of the capacitive element 44c is connected to the output end of the integrating circuit 42 through the input switch 44a, and is connected to the voltage output wiring 48 through the output switch 44b. A holding control signal Hd is given to the input switch 44 a via the holding wiring 45. The holding control signal Hd instructs the opening / closing operation of the input switch 44 a of each of the N holding circuits 44. The output switch 44b of the holding circuit 44, the n-th column selection control signal HS _n via the n-th column selecting wiring U _n is given. The selection control signal HS _n instructs the opening / closing operation of the output switch 44b of the holding circuit 44.

For example, when the holding control signal Hd changes from the high level to the low level, the input switch 44a changes from the closed state to the open state, and the voltage value input to the holding circuit 44 at that time is held in the capacitive element 44c. The When the n-th column selection control signal HS _n changes from the low level to the high level, the output switch 44b is closed and the voltage value held in the capacitive element 44c is output to the voltage output wiring 48.

FIG. 5 is a timing chart of each signal. In FIG. 5, in order from the top, (a) reset control signal RE, (b) row selection control signal VS _d , (c) first row selection control signal VS ₁ , (d) second row selection control signal VS _2. (E) third row selection control signal VS ₃ , (f) fourth row selection control signal VS ₄ , (g) Mth row selection control signal VS _M , (h) holding control signal Hd, and (i) A first column selection control signal HS ₁ to an Nth column selection control signal HS _N are shown.

First, a period of from the time _{t 10} to the time _{t 11,} the reset control signal RE is set to the high level. As a result, in each of the N integration circuits 42, the discharge switch 42c is closed, and the capacitive element 42b is discharged.

During a period from time t ₁₂ to time t ₁₃ after time t ₁₁ , the vertical shift register 60 sets the row selection control signal VS _d to the high level. Thus, the transistor 21 becomes the connected state in the carrier capture region _{DB 1 ~DB N +} 1, the carrier capture region _{DB 1 ~DB N +} 1 charges accumulated in the photodiodes 22 through the readout wiring line _R 1 to R _N It is output to the integrating circuit 42 and stored in the capacitive element 42b. Then, the period from the time _{t 14} after the time _{t 13} to the time _{t 15,} the reset control signal RE is set to the high level. Thereby, in each of the N integration circuits 42, the discharge switch 42c is closed, and the charge accumulated in the capacitive element 42b is released.

Subsequently, the first row selection control signal VS _{1 is set} to the high level during a period from time t ₁₆ to time t ₁₇ after time t ₁₅ . As a result, the transistors 21 are connected in the pixels P _{1,1 to} P _{1, N} and the carrier trap region DA ₁ in the first row. Pixels _P 1, 1 _{to P 1, N} charges accumulated in the photodiodes 22 is outputted to the integration circuit 42 through the readout wiring line _R 1 to R _N, it is accumulated in the capacitor 42b. The integration circuit 42 outputs a voltage value having a magnitude corresponding to the amount of charge accumulated in the capacitive element 42b. On the other hand, a photodiode and the charge stored in the 22 of the carrier capturing regions DA ₁ is discharged to the reference potential line GND through the charge discharging wire R _d.

Then, during a period from time t ₁₈ to time t ₁₉ after time t ₁₇ , the holding control signal Hd is set to the high level, whereby the input switch 44 a is connected in each of the N holding circuits 44. The voltage value output from the integrating circuit 42 is held by the capacitive element 44c.

Then, the period from the time _{t 20} after the time _{t 19} to time _{t 21,} the horizontal shift register 61 to the first column selection control signal HS ₁ ~ N-th column selection control signal HS _N the high level sequentially. As a result, the output switches 44b of the N holding circuits 44 are sequentially closed, and the voltage value held in the capacitive element 44c is sequentially output to the voltage output wiring 48. During this time, the reset control signal RE is set to the high level, and the capacitive element 42b of the integrating circuit 42 is discharged.

Then, the period from the time _{t 22} after the time _{t 21} to time _{t 23,} the vertical shift register 60 is the second row selection control signal VS ₂ to high level. As a result, the transistors 21 are connected in the pixels P _{2,1 to} P _{2, N} and the carrier trap region DA ₂ in the second row. Pixels _P 2,1 _{to P 2, N} charges accumulated in the photodiodes 22 is outputted to the integration circuit 42 through the readout wiring line _R 1 to R _N, it is accumulated in the capacitor 42b. On the other hand, a photodiode and the charge stored in the 22 of the carrier capturing region DA ₂ is discharged to the reference potential line GND through the charge discharging wire R _d. Thereafter, by the same operation as in the first row, a voltage value having a magnitude corresponding to the amount of charge accumulated in the capacitor element 42 b is sequentially output from the N holding circuits 44 to the voltage output wiring 48. The charges accumulated in the pixels in the third to Mth rows are also converted into voltage values by the same operation as in the first row, and sequentially output to the voltage output wiring 48. Thus, reading of image data for one imaging frame from the light receiving unit 20 is completed.

  The effect which 1A of solid-state imaging devices by this embodiment demonstrated above show | plays is demonstrated. In the solid-state imaging device 1A of the present embodiment, light is incident not only on the light receiving unit 20 but also on a region around the light receiving unit 20. Further, although the solid-state imaging device 1A is used as an X-ray imaging device, X-rays transmitted through the scintillator and scintillation light from the scintillator are transmitted to the light receiving unit 20 even if the area around the light receiving unit 20 is covered with the scintillator. Incident into the surrounding area. As a result, unnecessary charges (unnecessary carriers) are generated in the region around the light receiving unit 20. In particular, since the vertical shift register 60 arranged side by side with the light receiving unit 20 has a certain area, many unnecessary carriers are generated in the region where the vertical shift register 60 is formed.

When unnecessary carriers generated in the vertical shift register 60 flow into the light receiving unit 20, noise is superimposed on the outputs from the pixels P _{1, N to} P _{M, N} adjacent to the vertical shift register 60. FIG. 6 is a plan view showing an example in which a photodiode (dummy photodiode) 81 for absorbing unnecessary carriers is arranged in a region between the vertical shift register 60 and the light receiving unit 20 in order to avoid such a phenomenon. FIG. The dummy photodiodes 81 are formed over a plurality of rows, and are continuously formed from the first row to the Mth row (that is, connected in the column direction). By short-circuiting the dummy photodiode 81 to the reference potential line (ground wiring) GND, unnecessary carriers generated in the vertical shift register 60 can be discharged to the reference potential line GND and can be prevented from flowing into the light receiving unit 20.

However, this method has the following problems. Normally, crosstalk caused by coupling capacitance or the like generated between the photodiodes 22 exists between pixels adjacent to each other in the light receiving unit 20. Further, in each pixel, parasitic capacitance is present between the wiring Q _m photodiode 22 and the row selection are connected to each other through the transistor 21, the parasitic capacitance also affects the crosstalk. However, since the above-described dummy photodiode 81 is not provided with a transistor, such parasitic capacitance does not occur. For this reason, the pixels P _{1, N to} P _{M, N} adjacent to the dummy photodiode 81 have different degrees of crosstalk compared to other pixels, and the pixels P _{1, N to} P adjacent to the dummy photodiode 81 are different. The output characteristics from _{M and N} and the magnitude of noise are different from those of other pixels.

In view of such problems, the solid-state imaging device 1A of the present embodiment, in the carrier capture region DA ₁ to DA _M between the vertical shift register 60 and the light receiving portion 20, M-number of photodiodes (dummy photodiode) 22 Is arranged for each row. Unnecessary carriers generated in the vertical shift register 60 are absorbed by these photodiodes 22. Thereby, it is possible to effectively prevent noise caused by unnecessary carriers generated in the vertical shift register 60 from being superimposed on the output from the pixels of the light receiving unit 20.

Further, in the solid-state imaging device 1A, and the photodiode 22 of the carrier capturing regions DA ₁ to DA _M and the charge drain wire R _d is connected via the transistor 21, when the transistor 21 becomes a conductive state , unnecessary carriers are discharged to the reference potential line GND via the charge discharging wire R _d from the photodiode 22. Thus, the solid-state imaging device 1A, the pixel _P 1, 1 _{to P M} in the light receiving portion _20, similarly to the _N, the transistor 21 is also provided on the photodiode 22 of the carrier capturing regions _DA 1 to DA _M Yes. Moreover, since the photodiode 22 is provided on the carrier capture region _DA 1 to DA _M each row, the photodiode 22 of the carrier capturing regions _DA 1 to DA _M which are adjacent in the column direction are spaced apart from each other. Thus, in this embodiment according to the solid-state imaging device 1A, the pixel _P 1, N _{to P M} adjacent to the carrier capturing regions _DA 1 to DA _M, the size of the crosstalk in _N, crosstalk in the other pixels Since it can be made close to the size _, the output characteristics from the pixels P1 _{, N to} PM _{, N} and the magnitude of noise can be made close to those of other pixels. Also, when the carrier capturing regions _DA 1 to DA _M is either not blocked, or is partially shielded only, other pixels _P 1, 1 _{to P M, N} as well as the carrier capture region _DA 1 ~ the light to the photodiode 22 of the DA _M carriers are generated by incident, the amount of accumulated carriers also can be made closer to the other pixels.

  Further, as in the present embodiment, the vertical shift register 60 and the light receiving unit 20 may be formed on a common substrate 12. In such a case, unnecessary carriers generated in the vertical shift register 60 tend to flow into the light receiving unit 20. However, according to the solid-state imaging device 1 </ b> A of the present embodiment, it is effective for the unnecessary carriers to flow into the light receiving unit 20. Can be prevented.

Also, as in the present embodiment, the control terminals of the carrier capturing regions _DA 1 to DA _M of the transistor 21, for common row selection and the control terminals of the transistors 21 of the pixels _P 1, 1 _{to P M, N} It is preferable that they are connected to the wirings Q _{1 to} Q _M. Thus, the parasitic capacitance between the carrier capture region _DA 1 to DA photodiode 22 and the row selecting wiring of _{M Q} 1 to Q _M, each pixel _P 1, 1 _{to P M,} the photodiode 22 of the _N The parasitic capacitance value between the row selection wirings Q _{1 to} Q _M can be approached. Thus, the pixel _P 1, N _{to P M} adjacent to the carrier capturing regions _DA 1 to DA _M, the size of the crosstalk in _N, can be further closer to the magnitude of the crosstalk in the other pixel.

Here, an exposure method in the manufacturing process of the solid-state imaging device 1A according to the present embodiment will be described. When manufacturing a solid-state image pickup device 1A includes a plurality of pixels _{P 1, N ~P M,} N and carrier capturing regions _DA 1 _{to DA M,} the _{DB 1} ~DB _{N +} 1, while using a reticle containing a predetermined pattern Photo It is produced by lithography technology. At this time, since each of the pixels P1 _{, N to} PM _{, N} has a common configuration, so-called joint exposure is performed in which exposure is performed a plurality of times while moving the position of the reticle including the predetermined pattern. FIG. 7A is a plan view of the light receiving unit 20 and shows an example of a boundary line (seam) LA for joint exposure. In the example shown in FIG. 7A, the lines passing through the center of the rectangular photodiode 22 are defined as the boundary lines LA and LB. In this case, as shown in FIG. 7B, the size of the photodiodes 22 in the carrier capture regions DA _{1 to} DA _M and DB _{1 to} DB _{N + 1} is equal to the photodiodes of the pixels P _{1, N to} P _{M, N.} The size of 22 is almost the same.

FIG. 8A is a plan view of the light receiving unit 20 and shows another example of the boundary line LA for joint exposure. In the example shown in FIG. 8 (a), the column direction of the boundary line LA is, is closer to the left side (i.e. the side away from the carrier capturing regions DA ₁ to DA _M) with respect to the center of the rectangular photodiode 22, the row direction of the border line LB has shifted to the upper side (i.e. the side away from the carrier capturing regions DB ₁ to DB _N) with respect to the center of the rectangular photodiode 22. In this case, as shown in FIG. 8B, the size of the photodiodes 22 in the carrier capture regions DA _{1 to} DA _M , DB _{1 to} DB _{N + 1 is set to} the photodiodes of the pixels P _{1, N to} P _{M, N.} The size can be smaller than 22. Specifically, the width of the carrier capturing regions _DA 1 to DA _M of photodiodes 22 in the row direction, the pixel _P 1, N _{to P M} in said direction _can be made shorter than the width of the _N photodiodes 22 . Further, it is possible to shorten the width of the carrier capturing regions _DB 1 to DB _N photodiode 22, the pixel _P 1 in the direction, N _{to P M,} than the width of the _N photodiodes 22 in the row direction. Therefore, the area required around the light receiving unit 20 can be narrowed.

Carrier capture region as described above _DA 1 _{to DA M,} to reduce the photodiode 22 of the _{DB 1} ~DB _{N +} 1 has the following advantages. FIG. 9 is a plan view schematically showing an example in which two glass substrates 12 are arranged side by side. These glass substrate 12, pixel _P 1, N _{to P M} of the light receiving portion _20, and the _N, and a carrier capturing regions _DA 1 to DA _M and _{DB 1 ~DB N +} 1 is formed. In order to further increase the area of the light receiving portion in the entire solid-state imaging device, it is effective to arrange a plurality of glass substrates 12 side by side in this manner. At this time, the pixel _P 1 in the two glass substrates 12 on, N _{to P M, N,} if the arrangement of the carrier capturing regions _DA 1 to DA _M and _DB 1 to DB _N identical to common parts and manufacturing Cost can be kept low. However, in that case, it becomes the carrier capture region DA ₁ to DA _M between the two light receiving portion 20 is located, the region becomes a dead zone can not be obtained image (dead areas). In this case, the width of the carrier capturing regions _DA 1 to DA _M of photodiodes 22 in the row direction, the pixel _P 1 in the direction N _{to P M,} by less than the width of the _N photodiodes 22, The insensitive area can be narrowed.

Further, referring to FIG. 8A, in a normal pixel P _{m + 1, n} , a transistor is formed on the side closer to P _{m + 1, n + 1} . The pixel _{P m + 1, n} seams (boundaries LA) is present on the side close to the pixel _{P m + 1, n-1} . That is, with respect to the center of the pixel P _{m + 1, n} , a transistor is present on one side of the pixel and a seam (boundary line LA) is present on the other side, and the distance between the seam and the transistor is increased in the row direction. In this way, since the seam and the transistor can be physically separated, manufacturing defects can be reduced.

  The solid-state imaging device according to the present invention is not limited to the above-described embodiment, and various other modifications are possible. For example, the light receiving unit shown in the above embodiment may have a configuration in which amorphous silicon or polycrystalline silicon is formed on a glass substrate. In this case, the transistor 21 is preferably realized by a thin film transistor. Alternatively, the light receiving portion may be fabricated on a single crystal silicon substrate.

  In the above embodiment, the present invention is applied to a so-called passive pixel sensor (PPS) in which each pixel does not have an amplifier circuit and an integration circuit is provided for each readout wiring in each column. The present invention may be applied to a so-called active pixel sensor (APS) having an amplifier circuit for each pixel.

In the above embodiment, the carrier capture regions DB _{1 to} DB _{N + 1} are provided side by side in the column direction with respect to the light receiving unit, but the carrier capture regions DB _{1 to} DB _{N + 1} may be omitted.

DESCRIPTION OF SYMBOLS 1A ... Solid-state imaging device, 12 ... Board | substrate, 20 ... Light-receiving part, 21 ... Transistor, 22 ... Photodiode, 30 ... Unnecessary carrier capture part, 40 ... Read-out circuit part, 42 ... Integration circuit, 44 ... Holding circuit, 45 ... Holding use wire, 46 ... reset wiring 48 ... voltage output wiring 51 ... bonding wire, 60 ... vertical shift register, 61 ... horizontal shift _{register, DA 1 ~DA M, DB 1} ~DB N + 1 ... carrier capturing regions, GND ... reference potential line, LA, LB ... boundary line _{(seam), P 1,1 ~P M, N} ... _{pixel, Q 1 ~Q M, Q d} ... row selecting _{wiring, R} 1 to R N _... readout wiring , R _d ... charge discharging wiring, R _n ... reading wiring, R _n ... column reading wiring.

Claims (3)

The M × M array includes a first photodiode and a first switch circuit having one end connected to the first photodiode, and is two-dimensionally arranged in M rows and N columns (M and N are integers of 2 or more). A light receiving portion having N pixels and formed on a single crystal silicon substrate;
N readout wirings arranged for each column and connected to the other end of the first switch circuit included in the pixel of the corresponding column;
A readout circuit unit connected to the N readout wirings;
A shift register that is arranged side by side in the row direction with respect to the light receiving unit, and controls the open / close state of the first switch circuit for each row;
A dummy photodiode disposed in a region between the shift register and the light receiving unit;
A second switch circuit having one end connected to the dummy photodiode;
A solid-state imaging device comprising: a charge discharging wiring connected to the other end of the second switch circuit and short-circuited to a reference potential line.   The solid-state imaging device according to claim 1, wherein a width of the dummy photodiode in a row direction is shorter than a width of the first photodiode in the direction.   The solid-state imaging device according to claim 1, wherein the shift register and the light receiving unit are formed on a common substrate.

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