WO2013176007A1 - 撮像素子、駆動方法、および電子装置 - Google Patents
撮像素子、駆動方法、および電子装置 Download PDFInfo
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Definitions
- the present technology relates to an imaging device, a driving method, and an electronic device, and more particularly, to an imaging device, a driving method, and an electronic device that can realize a global shutter.
- CMOS Complementary Metal Oxide Semiconductor
- CIS Complementary Metal Oxide Semiconductor
- Some CISs have a function called a global shutter that ensures the synchronism of exposure time of images to be captured.
- MOSFET Metal Oxide Semiconductor Semiconductor Field Field Effect Transistor
- a relatively high voltage is applied to the gate provided in the pixel of the CMOS image sensor, initialization of each element in the pixel, signal transfer from the photoelectric conversion unit to the charge voltage conversion unit in the pixel, etc. Has been done.
- a photodiode PD21 and a floating diffusion FD22 are provided in a P well region W11 formed in a silicon substrate.
- the photodiode PD21 is composed of a P + layer (charge separation region) and an n layer (charge storage region) that accumulates charges, and the charge accumulated in the photodiode PD21 has a voltage applied to the transfer gate part GT23. When applied, it is transferred to the floating diffusion FD22 and read out as signal charges.
- a voltage is applied to the gate of the transfer gate part GT23 during transfer of charges from the photodiode PD21 to the floating diffusion FD22, but if the voltage is insufficient, the left broken line PO11 in the figure. As shown in FIG. 1, a voltage is applied to the gate of the transfer gate part GT23 during transfer of charges from the photodiode PD21 to the floating diffusion FD22, but if the voltage is insufficient, the left broken line PO11 in the figure. As shown in FIG.
- a polygonal line PO11 indicates the potential of each part of the solid-state imaging device, that is, the potential at each position of the photodiode PD21, the transfer gate part GT23, the floating diffusion FD22, and the reset transistor RT24.
- the downward direction in the figure is the positive direction of the potential.
- the potential indicated by the arrow A11 that is, the potential immediately below the transfer gate portion GT23 is higher than the potential of the photodiode PD21 portion. Therefore, a part of the charge of the photodiode PD21 remains in the photodiode PD21 without being transferred to the floating diffusion FD22.
- this solid-state imaging device by applying a negative voltage (negative bias) to the P well region W11, the potential of the photodiode PD21 portion is transferred to the transfer gate portion GT23 as shown by the right broken line PO12 in the figure. It is made higher than the potential of the region immediately below.
- the potential of the photodiode PD21 portion is higher than the potential immediately below the transfer gate portion GT23, and assists in reading out the signal charge. As a result, more charge is transferred to the floating diffusion FD22.
- the present technology has been made in view of such a situation, and is intended to reduce the voltage and increase the saturation signal amount.
- the imaging device is an imaging device including a pixel unit including a large number of pixels arranged in a matrix and a driving unit that drives the pixel unit.
- a conversion unit that converts a physical quantity into an electric charge; a charge holding unit that accumulates the electric charge converted by the conversion unit in the conversion period; and that holds the electric charge transferred from the conversion unit after the end of the conversion period;
- a readout unit that reads out the charge held in the charge holding unit during a period, and the driving unit equally divides the plurality of pixels of the pixel unit into two groups of a first group and a second group When one of the first group and the second group of the pixel portion is set as the readout period, the other is set as the conversion period.
- the driving unit can simultaneously set the pixels belonging to the first group or the second group as a conversion period for each group.
- the imaging device may further include a generation unit that generates an image signal based on the read electric charge.
- the generation unit generates an odd-frame image signal based on the charges read from the first group, and generates an even-frame image signal based on the charges read from the second group. be able to.
- the conversion unit can convert incident light as the physical quantity into electric charge.
- a driving method is a driving method of an imaging element including a pixel unit including a large number of pixels arranged in a matrix and a driving unit that drives the pixel unit.
- a conversion unit that converts a physical quantity into an electric charge during the conversion period, and a charge holding unit that accumulates the electric charge converted by the conversion unit during the conversion period and holds the electric charge transferred from the conversion unit after the conversion period ends
- a readout unit that reads out the electric charge held in the electric charge holding unit during a readout period, and the driving unit converts the plurality of pixels of the pixel unit into two groups of a first group and a second group
- the method includes a step of equally dividing, and setting one of the first group and the second group of the pixel portion as the reading period and the other as the conversion period.
- a large number of pixels of the pixel unit are equally divided into two groups of a first group and a second group, and one of the first group or the second group of the pixel unit is read out When a period is set, the other is set as a conversion period.
- An electronic device is an electronic device having an imaging function, in which an imaging element including a pixel unit including a plurality of pixels arranged in a matrix and a driving unit that drives the pixel unit is provided.
- the pixel is mounted, the conversion unit converts a physical quantity into an electric charge during a conversion period, and accumulates the electric charge converted by the conversion unit during the conversion period, and is transferred from the conversion unit after the conversion period ends A charge holding unit for holding charge; and a reading unit for reading out the charge held in the charge holding unit during a reading period, wherein the driving unit includes the plurality of pixels of the pixel unit as a first group.
- the second group is equally divided into two groups, and when one of the first group and the second group of the pixel portion is set as the readout period, the other is set as the conversion period.
- a large number of pixels of the pixel portion of the mounted image sensor are equally divided into two groups of a first group and a second group, and the first group or the first group of the pixel unit is divided.
- one of the two groups is a readout period
- the other is a conversion period.
- An imaging device includes a photoelectric conversion unit that photoelectrically converts incident light, a charge storage unit that stores charges obtained by photoelectric conversion, the charge storage unit, and at least one or more gates. And an initialization unit that initializes the charge storage unit and a well region in which the photoelectric conversion unit, the charge storage unit, and the initialization unit are provided when the charge storage unit is initialized.
- the voltage application control part which applies the voltage of this is provided.
- the voltage application control unit can apply a positive voltage to the well region at the time of initialization of the charge storage unit for reading the reset level and at the time of reading the signal level.
- the charge storage unit can be a capacitor.
- the capacity can be any of MIM structure, PIM structure, or PIP structure.
- the photoelectric conversion unit, the charge storage unit, and the initialization unit are provided for each of a plurality of pixels that constitute a pixel array unit that captures an image, and the voltage application control unit includes all pixels on the pixel array unit. Can simultaneously apply the positive voltage.
- the well regions of all the pixels on the pixel array portion can be formed electrically integrally.
- the photoelectric conversion unit, the charge storage unit, and the initialization unit are provided for each of a plurality of pixels that form a pixel array unit that captures an image, and the voltage application control unit has a horizontal direction on the pixel array unit.
- the positive voltage can be applied to each pixel row composed of pixels arranged in a row.
- the well regions of the pixels in the pixel row on the pixel array unit may be electrically integrated so that the well regions of the pixel rows are electrically separated.
- the photoelectric conversion unit, the charge storage unit, and the initialization unit are provided for each of a plurality of pixels that form a pixel array unit that captures an image, and the voltage application control unit includes some of the pixels on the pixel array unit.
- the positive voltage can be applied to each pixel block composed of the pixels.
- the well regions of the pixels of the pixel block on the pixel array unit can be electrically integrated so that the well regions of the pixel blocks can be electrically separated.
- the photoelectric conversion unit, the charge storage unit, and the initialization unit are provided for each of a plurality of pixels constituting a pixel array unit that captures an image, and the well region of each pixel on the pixel array unit is electrically connected Can be separated.
- the imaging device is further provided with a charge-voltage conversion unit that is provided between the initialization unit and the charge storage unit and converts a charge into a voltage signal, and the charge stored in the charge storage unit is greater than or equal to the one or more. It can be transferred to the charge-voltage converter through a gate.
- a driving method includes a photoelectric conversion unit that photoelectrically converts incident light, a charge storage unit that stores charges obtained by photoelectric conversion, the charge storage unit, and at least one gate. And an initialization unit that initializes the charge storage unit, wherein the photoelectric conversion unit, the charge storage unit, and the initializing unit are initialized when the charge storage unit is initialized. Applying a positive voltage to the well region provided with the conversion portion.
- a photoelectric conversion unit that photoelectrically converts incident light, a charge storage unit that stores charges obtained by photoelectric conversion, and the charge storage unit and at least one or more gates
- an imaging device that is connected and includes an initialization unit that initializes the charge storage unit, the well in which the photoelectric conversion unit, the charge storage unit, and the initialization unit are provided when the charge storage unit is initialized A positive voltage is applied to the region.
- the first aspect of the present technology it is possible to realize a global shutter having a large handling charge amount without providing a non-exposure period for the entire screen.
- the second aspect of the present technology it is possible to realize a global shutter having a large handling charge amount without providing a non-exposure period for the entire screen.
- the second aspect of the present technology it is possible to capture a moving image with a high frame rate and an image that captures an instantaneous state of a fast-moving subject, and the sensitivity is high at the same frame rate.
- the voltage can be lowered and the saturation signal amount can be increased.
- FIG. 2 is a diagram illustrating a configuration example of an embodiment of a solid-state imaging device to which the present technology is applied.
- the solid-state image sensor 11 is composed of, for example, a CMOS image sensor and receives a light from a subject, performs photoelectric conversion, and generates an image signal to capture an image.
- the solid-state imaging device 11 includes a pixel array unit 21, a vertical drive unit 22, a column processing unit 23, a horizontal drive unit 24, a system control unit 25, a pixel drive line 26, a vertical signal line 27, a signal processing unit 28, and a data storage unit. 29.
- a pixel array unit 21 is formed on a semiconductor substrate (chip) (not shown), and a vertical drive unit 22 to a system control unit 25 are integrated on the semiconductor substrate.
- the pixel array unit 21 includes pixels having a photoelectric conversion unit that generates and accumulates charges according to the amount of light incident from a subject.
- the pixels constituting the pixel array unit 21 are illustrated in the horizontal direction (row direction) in the figure. ) And the vertical direction (column direction).
- pixel drive lines 26 are wired along the row direction for each pixel row composed of pixels arranged in the row direction, and each pixel column composed of pixels arranged in the column direction is vertically aligned.
- Signal lines 27 are wired along the column direction.
- the vertical drive unit 22 includes a shift register, an address decoder, and the like, and supplies signals to each pixel via a plurality of pixel drive lines 26 so that each pixel of the pixel array unit 21 can be simultaneously or all row-wise. Etc. to drive.
- the column processing unit 23 reads a signal from each pixel for each pixel column of the pixel array unit 21 via the vertical signal line 27, and performs noise removal processing, correlated double sampling processing, A / D (Analog to Digital) conversion processing. Etc. to generate a pixel signal.
- the horizontal driving unit 24 includes a shift register, an address decoder, and the like, and selects unit circuits corresponding to the pixel columns of the column processing unit 23 in order. By the selective scanning by the horizontal driving unit 24, the pixel signals subjected to signal processing for each unit circuit in the column processing unit 23 are sequentially output to the signal processing unit 28.
- the system control unit 25 includes a timing generator that generates various timing signals, and performs drive control of the vertical drive unit 22, the column processing unit 23, and the horizontal drive unit 24 based on the timing signals generated by the timing generator. Do.
- the signal processing unit 28 performs signal processing such as arithmetic processing on the pixel signal supplied from the column processing unit 23 while temporarily storing data in the data storage unit 29 as necessary, and from each pixel signal Output an image signal.
- a solid-state imaging device 11 for example, global exposure, that is, exposure start and exposure end are performed at the same timing for all the pixels of the pixel array unit 21.
- the global shutter function that realizes such global exposure is suitable for use in sensing applications that require high-speed imaging of a moving subject and synchronization of captured images.
- FIG. 3 is a circuit diagram illustrating a configuration example of one pixel provided in the pixel array unit 21.
- the pixels of the pixel array unit 21 include a photodiode 61, a charge discharge gate unit 62, a first transfer gate unit 63, a first charge storage unit 64, a second transfer gate unit 65, and a second charge.
- the storage unit 66, the third transfer gate unit 67, the charge voltage conversion unit 68, the reset gate unit 69, the amplification transistor 70, and the selection transistor 71 are configured.
- the photodiode 61 is a PN junction photodiode, receives light from the subject, generates electric charge corresponding to the amount of received light, and accumulates it.
- the charge discharge gate unit 62 is connected between the photodiode 61 and a power source (not shown), and is stored in the photodiode 61 in accordance with a drive signal PG applied to the gate electrode of the charge discharge gate unit 62. The discharged electric charge is discharged to the outside.
- the charge discharge gate unit 62, the first transfer gate unit 63, the second transfer gate unit 65, the third transfer gate unit 67, the reset gate unit 69, and the selection transistor 71 are N-channel MOS transistors. It is composed of transistors.
- the drive signals PG, TG, CG, FG, RST, and SEL are supplied to the gate electrodes of the charge discharge gate unit 62 to the selection transistor 71.
- These drive signals are pulse signals in which a high level (for example, power supply voltage VDD) is in an active state (on state) and a low level (for example, negative potential) is in an inactive state (off state). .
- the charge discharge gate portion 62 when the drive signal PG supplied to the gate electrode of the charge discharge gate portion 62 becomes active and the charge discharge gate portion 62 is turned on, the charge discharge gate portion 62 becomes conductive. The charge accumulated in the photodiode 61 is discharged. In the charge discharge gate unit 62, the photodiode 61 is saturated with charge during a period in which charge is not accumulated, and charges exceeding the saturation charge amount are transferred to the first charge accumulation unit 64, the second charge accumulation unit 66, It is provided to prevent overflowing to peripheral pixels.
- the first transfer gate unit 63 is provided between the photodiode 61 and the first charge storage unit 64.
- the first transfer gate unit 63 converts the charge stored in the photodiode 61 into the first charge storage unit. 64.
- the first charge storage unit 64 is provided as an embedded MOS capacitor (capacitance), and stores the charge transferred from the photodiode 61 via the first transfer gate unit 63.
- the drive signal SG is applied to the gate electrode of the first charge accumulation unit 64 and the drive signal SG is in an active state, that is, in a high level state, the potential of the first charge accumulation unit 64 is lowered. A lot of charge can be accumulated.
- the second transfer gate unit 65 is provided between the first charge storage unit 64 and the second charge storage unit 66.
- the second transfer gate portion 65 When the drive signal CG supplied to the gate electrode of the second transfer gate portion 65 is in an active state (high level), the second transfer gate portion 65 becomes conductive, and thus the first charge accumulation portion 64. Are combined with the potential of the second charge storage section 66.
- the second transfer gate unit 65 when the drive signal CG supplied to the gate electrode of the second transfer gate unit 65 is in an inactive state (low level), the second transfer gate unit 65 is in a non-conducting state.
- the potentials of the charge storage unit 64 and the second charge storage unit 66 are divided.
- the second charge storage unit 66 is configured by a capacitor having a larger capacitance value per unit area than the first charge storage unit 64, and the second charge storage unit 66 is LOFIC.
- the third transfer gate unit 67 is connected to a charge-voltage conversion unit 68 to which the gate electrode of the amplification transistor 70 is connected, and a drive signal FG is transferred to the gate electrode of the third transfer gate unit 67 as a transfer signal. Applied.
- the third transfer gate unit 67 becomes conductive when the drive signal FG is in an active state, that is, when the drive signal FG is at a high level, and converts the charge accumulated in the first charge accumulation unit 64 into a charge voltage.
- the data is transferred to the unit 68.
- the charge-voltage conversion unit 68 is a floating diffusion region that converts the charge transferred from the first charge storage unit 64 into an electric signal, for example, a voltage signal and outputs the electric signal.
- the reset gate unit 69 is an element that appropriately initializes (resets) each region from the charge-voltage conversion unit 68 to the second charge storage unit 66, the drain is connected to the power supply of the reset voltage VR, and the source is the charge voltage.
- the converter 68 is connected.
- a drive signal RST is applied as a reset signal to the gate electrode of the reset gate unit 69.
- the reset gate unit 69 becomes conductive, and the potential of the charge voltage conversion unit 68 and the like is reset to the level of the reset voltage VR. That is, the charge voltage conversion unit 68 and the like are initialized.
- the amplification transistor 70 has a gate electrode connected to the charge-voltage conversion unit 68 and a drain connected to a power supply of a power supply voltage.
- the amplification transistor 70 reads a charge obtained by photoelectric conversion at the photodiode 61, that is, a so-called source follower. It becomes the input part of the circuit. That is, the amplifying transistor 70 is connected to the vertical signal line 27 via the selection transistor 71, thereby forming a constant current source and a source follower circuit connected to one end of the vertical signal line 27.
- the selection transistor 71 is connected between the source of the amplification transistor 70 and the vertical signal line 27, and a drive signal SEL is supplied to the gate electrode of the selection transistor 71 as a selection signal.
- the drive signal SEL is activated, the selection transistor 71 is turned on, and the pixel provided with the selection transistor 71 is selected.
- the signal output from the amplification transistor 70 is read out to the column processing unit 23 via the vertical signal line 27.
- each pixel a plurality of drive lines are wired for each pixel row, for example, as the pixel drive lines 26 in FIG. Then, drive signals PG, TG, SG, CG, FG, RST, and SEL are supplied into the pixel through a plurality of drive lines as the pixel drive line 26 from the vertical drive unit 22 of FIG.
- the pixel of FIG. 3 is connected to a power source (not shown) and a connection line 72 for applying a voltage V well to a well constituting the pixel via a contact (not shown).
- the vertical drive unit 22 controls the application of the voltage V well to the well of each pixel via the connection line 72.
- Control of voltage application to the pixel wells is not limited to the vertical drive unit 22, and may be performed by another block of the solid-state imaging device 11 shown in FIG. 2, or a block that only controls voltage application.
- the solid-state image sensor 11 may be provided.
- solid-state imaging device 11 cannot read out the charges of all the pixels at the same time and reads them out in units of one row, for the global shutter, while waiting for the reading in the light-shielded charge accumulation region in the pixels. It is necessary to hold the signal.
- Some solid-state imaging devices 11 having a global shutter function increase the amount of charge handled by accumulating a part of a signal in the above-described charge accumulation region not only during waiting for reading but also during exposure. It has been. (For example, refer to JP2011-199816A or JP2009-268083A)
- FIG. 4 shows drive timing when a conventional global shutter with an increased handling charge amount is performed.
- the solid-state imaging device 11 exposure is performed after all pixels are first reset at once. During this exposure period, photoelectric conversion by PD (photodiode) is performed in each pixel, and charges obtained by the PD are accumulated in the PD and the charge accumulation unit. When the exposure time ends, the charges remaining in the PDs of all the pixels are collectively transferred to the charge storage unit, and thereafter, the charges in the charge storage unit are sequentially read out in units of one row. Therefore, the charge storage unit of each pixel has a standby time to wait while holding the stored charge until the stored charge is read out.
- PD photoelectric conversion by PD
- a large number of pixels constituting the pixel array unit 21 are divided into two groups, a first group and a second group, and the driving timings of the first group and the second group are controlled independently. Then, for example, odd frames are generated from image signals from the first group of pixels, and even frames are generated from image signals from the second group of pixels. Although odd frames and even frames have different sampling points (pixel positions), odd frames and even frames in which sampling points appear to be the same may be generated by interpolation or image size reduction.
- FIG. 5 shows two examples of the method of segmenting the pixel array unit 21 when the solid-state imaging device 11 outputs a monochrome image.
- FIG. 5A shows a large number of pixels forming the pixel array unit 21 are alternately divided into horizontal stripes for each predetermined number of rows (one row in the case of A in FIG. 5). Shows how.
- FIG. 5B shows a method of dividing the first group and the second group into a checkered pattern by setting the upper, lower, left and right pixels of the first group of pixels as the second group.
- FIG. 6 shows three examples of the method of segmenting the pixel array unit 21 when the solid-state imaging device 11 outputs a color image.
- FIG. 6A shows a method of dividing the first group and the second group into horizontal stripes alternately for each row of a large number of pixels constituting the pixel array unit 21.
- FIG. 6B shows a method of dividing the first group and the second group into horizontal stripes alternately every two rows for a large number of pixels forming the pixel array unit 21.
- FIG. 6C shows a method of dividing the first group and the second group into a checkered pattern by setting the upper, lower, left, and right pixels of the first group of pixels as the second group.
- R, G, and B in the solid-state imaging device 11 is not limited to the arrangement example of FIG. Further, the way of dividing the first group and the second group is not limited to the example of FIG. 6, and it is sufficient that the first group and the second group are equally divided. Further, instead of dividing into two groups, it may be divided into three or more groups.
- FIG. 7 is a flowchart for explaining the operation of the pixel array unit 21.
- This pixel unit control process is started when the solid-state imaging device 11 starts outputting an image signal to the subsequent stage.
- step S1 all the pixels (that is, the first group and the second group) constituting the pixel array unit 21 are collectively reset.
- step S2 the pixel (photodiode 61) belonging to the first group is set to the exposure period after the collective reset. Thereby, accumulation of the photoelectrically converted charge is started.
- the read electric charges are output as an electric signal to the column processing unit 23 to be an odd frame image signal.
- the charge remaining in the photodiode 61 is collectively transferred to the subsequent stage, and thereafter, the charge is sequentially read out for each row.
- the second group is not yet in the exposure period, so the process for the second group may be omitted.
- step S3 in the pixels belonging to the first group, the charge remaining in the photodiode 61 is collectively transferred to the subsequent stage, and thereafter, the charge is sequentially read out for each row.
- the read charge is output as an electric signal to the column processing unit 23 to be an image signal of an even frame.
- the pixel (photodiode 61) belonging to the second group is set to the exposure period after the batch reset. Thereby, accumulation of the photoelectrically converted charge is started.
- step S4 it is determined whether or not the output of the image signal from the solid-state imaging device 11 is to be ended, and the processing is returned to step S2 until the determination is completed, and steps S2 and S3 are repeated.
- description of a pixel part control process is complete
- 8 and 9 show the driving timings of the first group and the second group of the pixel array unit 21 by the pixel unit control process described above. 8 shows an example in which part of the exposure period overlaps between the first group and the second group, and FIG. 9 shows an example in which the exposure period does not overlap between the first group and the second group. Is shown.
- the solid-state imaging device 11 can be used for shooting applications that capture a smooth moving image with a high frame rate that requires continuous exposure without interruption, or capture an instantaneous state of a fast-moving subject. Further, it is possible to prevent a decrease in sensitivity due to the existence of a non-exposure period.
- the frame rate is halved when the conventional operation shown in FIG. 4 is performed. Furthermore, the frame rate is reduced by the additional exposure period.
- the number of pixels read out in one frame is halved, so that the frame rate is not halved even if read out twice. Furthermore, since the other readout is performed during the exposure period of one pixel group, there is no decrease in the frame rate due to the exposure time.
- the batch reset timing can be adjusted, or a batch reset can be performed a plurality of times between the exposure time and the next exposure time. That is, the substantial exposure time can be adjusted without changing the frame rate.
- FIG. 10 is a diagram showing the structure of the pixel shown in FIG. 3.
- FIG. 10 shows a plane pattern showing the pixel layout, a cross section taken along the line AA ′, and a cross section taken along the line BB ′ in the plane pattern. It is shown.
- the same reference numerals are given to the portions corresponding to those in FIG. 3, and the description thereof will be omitted as appropriate.
- the photodiode 61 has a PN junction diode configuration in which an N-type semiconductor region 101 is formed in a P-type well 52 on a semiconductor substrate 51, as shown in the cross section taken along the line B-B '.
- the photodiode 61 is a buried photodiode in which a depletion end is separated from the interface by forming a P-type semiconductor region 102 in a surface layer portion thereof.
- the first transfer gate portion 63 includes a gate electrode 103 disposed on a substrate surface via a gate insulating film (not shown), and a P ⁇ type semiconductor region 104 formed on the substrate surface layer portion. It has become.
- the P ⁇ type semiconductor region 104 slightly deepens the potential immediately below the gate electrode 103 as compared with the case where the P ⁇ type semiconductor region 104 is not formed.
- the P ⁇ type semiconductor region 104 becomes an overflow path for transferring a predetermined amount or more of the charges overflowing from the photodiode 61 to the first charge storage unit 64.
- the charge of a predetermined amount or more is specifically the charge that exceeds the saturation charge amount of the photodiode 61.
- the first charge storage section 64 has a gate electrode 105 disposed on a substrate surface via a gate insulating film (not shown), and is formed as an embedded MOS capacitor under the gate electrode 105. That is, the first charge storage portion 64 includes a gate electrode 105, an N-type semiconductor region 106 formed in the P-type well 52 immediately below the gate electrode 105, and a P-type semiconductor region 107 formed in the surface layer portion thereof. An embedded MOS capacitor is used.
- the third transfer gate portion 67 has a gate electrode 108 disposed on the substrate surface via a gate insulating film (not shown).
- the third transfer gate unit 67 uses the N-type semiconductor region 106 of the first charge storage unit 64 as one source / drain region, and the N + type semiconductor region 109 serving as the charge-voltage conversion unit 68 as the other source / drain region. It is said.
- the first charge storage unit 64 is buried under the gate electrode 105 of the first charge storage unit 64 formed adjacent to the first transfer gate unit 63 and the third transfer gate unit 67.
- the pixel structure is formed as a type MOS capacitor.
- the second transfer gate unit 65 includes a gate electrode 110 disposed on a substrate surface via a gate insulating film (not shown), and the N-type semiconductor region 106 of the first charge storage unit 64 is connected to one of the gate electrodes. Source / drain regions are used. One end of the second charge accumulation unit 66 is connected to the other source / drain region of the second transfer gate unit 65.
- the second transfer gate portion 65 has a structure in which an N ⁇ type semiconductor region 111 is formed in the P type well 52 immediately below the gate electrode 110.
- This N ⁇ type semiconductor region 111 makes the potential just below the gate electrode 110 slightly deeper than when the N ⁇ type semiconductor region 111 is not formed.
- the N ⁇ type semiconductor region 111 serves as an overflow path for transferring a predetermined amount or more of the charges overflowing from the first charge accumulation unit 64 to the second charge accumulation unit 66 via the N + type semiconductor region 112.
- a P + type semiconductor region 113 is formed in the P type well 52, that is, in the substrate surface layer portion, and a connection line 72 is connected to the P + type semiconductor region 113.
- the gate electrode 105, the second transfer gate unit 65, and the third transfer gate unit 67 of the first charge storage unit 64 include the charge voltage conversion unit 68, the first charge storage unit 64, The potentials of the second charge storage unit 66 are combined or divided.
- the voltage V well is applied to each pixel provided in the pixel array unit 21 via the connection line 72 or the contact, and the connection line 72 and the pixel (P-type well 52) are connected.
- the contacts may be provided in units of rows or may be provided for each pixel.
- each pixel row G11-1 through pixel rows is placed in an N ⁇ type semiconductor region 141 provided on the substrate of the pixel array unit 21.
- G11-5 is provided.
- each of the pixel rows G11-1 to G11-5 is separated by the N ⁇ type semiconductor region 141 and electrically separated.
- the pixel row G11-1 to the pixel row G11-5 are also simply referred to as a pixel row G11 when it is not necessary to distinguish them.
- a plurality of pixels arranged in the horizontal direction (row direction) in the figure are provided in one P-type well 52 partitioned by the N ⁇ type semiconductor region 141. That is, the region of the P-type well 5 is electrically isolated for each pixel row.
- the P-type well 52 of each pixel of the pixel row is integrally formed, and the P-type well 52 of each pixel row is electrically isolated.
- one square in the pixel row G11 represents one pixel.
- the connection line 72 is connected to one of the pixels constituting the pixel row G11 through a contact. That is, the voltage V well is applied to the P-type well 52 of the pixel row G11 through one connection line 72.
- connection line 72 When the voltage V well is applied to each pixel by the connection line 72, for example, as shown in the upper side of FIG. 12, each pixel is provided in the N ⁇ type semiconductor region 142 so as to be electrically separated.
- a connection line 72 is connected to the P-type well 52 via a contact. That is, the region of the P-type well 52 is electrically isolated for each pixel.
- the voltage V well is applied to the P-type well 52 for each pixel.
- the pixel array section 21 shown on the upper side of FIG. 12 one square with hatching represents one pixel.
- the pixel array unit 21 can be driven at high speed. Note that one contact may be provided for several pixels as shown in FIG. 11 using the electrical conduction of the P-type well 52 itself without providing a contact for each pixel.
- one P-type is provided for the N ⁇ type semiconductor region 143 provided on the substrate of the pixel array unit 21.
- a type well 52 may be provided, and all the pixels may be formed in the P type well 52. That is, the region of the P-type well 52 is electrically integrated with all the pixels.
- a hatched area represents a pixel area, and one square in the area represents one pixel.
- a plurality of block regions each composed of a plurality of pixels are provided in the N ⁇ type semiconductor region 144 provided on the substrate of the pixel array unit 21. You may be made to do.
- the region of the P-type well 52 may be electrically separated in units of blocks composed of arbitrary M ⁇ N pixels.
- connection line 72 is connected to the P-type well 52 in each block region via a contact, and the voltage V well is applied to the P-type well 52 for each block region.
- a hatched rectangular area represents one block area, and one square in each block area represents one pixel.
- adjacent P-type wells 52 must be separated from each other by a fixed distance. Therefore, if a pixel region is divided in units of blocks and contacts are provided in units of blocks, the area efficiency is improved. Can do.
- the pixel is provided when the charge storage element is initialized. Assume that a negative bias is applied to the well region.
- the polygonal line PO21 and the polygonal line PO22 indicate the potential in each region from the N + type semiconductor region 112 to the region immediately below the reset gate portion 69.
- the voltage applied to the gate electrode 110 of the second transfer gate portion 65 and the gate electrode 108 of the third transfer gate portion 67 is insufficient.
- the potential in the region immediately below is high.
- the potentials of the second charge storage unit 66, the first charge storage unit 64, and the charge-voltage conversion unit 68 are not coupled, and charges are transferred from the first charge storage unit 64 to the second charge storage unit 66. I can no longer inject. That is, the second charge accumulation unit 66 cannot be reset.
- the reset voltage VR is high, the drive signal CG or the drive
- the region from the reset gate unit 69 to the second charge storage unit 66 is not electrically connected.
- the broken line PO31 indicates the potential in each region from the second charge accumulation unit 66 to the reset gate unit 69, and the downward direction in the figure is the positive direction of the potential.
- the shaded area on the upper side or the lower side of the polygonal line PO31 represents the charge accumulated in each area.
- the region from the reset gate unit 69 to the second charge storage unit 66 is electrically connected, the second charge storage unit 66 is initialized, and the potential of each region becomes the same height.
- the reset level is increased by the increase in potential, so that the dynamic range of the pixel is lowered, which is not desirable.
- the positive voltage V well is applied to the P-type well 52 as necessary, so that the gate electrode 110 and the gate that are insufficient.
- the voltage of the electrode 108 is supplemented.
- the saturation signal amount of the pixel can be increased as compared with the conventional case.
- the first charge accumulation unit 64 and the second charge accumulation unit 66 connected to the reset gate unit 69 via one or more gates such as the third transfer gate unit 67 are to be initialized.
- the voltage applied to the gate is insufficient, the potential of each region may not be reset to the level of the reset voltage VR. Therefore, according to the present technology, a positive voltage is applied to the P-type well 52 at the time of initialization to compensate for the gate voltage, and the initialization is appropriately performed while ensuring a sufficient saturation signal amount.
- the timing at which the positive voltage V well is applied to the P-type well 52 is global driving, that is, when all pixels are reset at the same time, when all pixels are simultaneously reset, and when rolling reading is performed to reset the pixels for each pixel row. Is preferably performed for each pixel row. In addition, when performing rolling readout, it is desirable that the region of the P-type well 52 is divided in units of pixel rows.
- the power supply voltage used in the solid-state imaging device is also reduced, which leads to a reduction in the number of saturation signal charges that can be secured in the pixel.
- a pixel that has a storage capacitor for expanding the dynamic range in the pixel, represented by the LOFIC structure, is reset to initialize the storage capacitor. It must be in a potential state where the gate from the voltage terminal to the storage capacitor is electrically connected.
- a positive bias (voltage) is applied to the well region of the pixel, and the voltage required for the gate is assisted to appropriately Initialization is performed and the saturation signal amount can be expanded.
- FIG. 15 shows a state at each time of a signal supplied to the pixel. That is, in the figure, the horizontal direction indicates time, and the vertical direction indicates the level (voltage) of each signal.
- the broken lines SL11 to SL18 represent the driving signals SEL, RST, TG, PG, CG, SG, FG, and the pulse P well for applying the positive voltage V well to the P-type well 52, respectively.
- the drive signal PG is on, that is, an active state, and the other drive signals SEL, RST, TG, CG, SG, and FG are off, that is, inactive.
- the pulse P well is also turned off (inactive state), and a predetermined voltage as a reference is applied to the P-type well 52.
- the drive signals RST, CG, SG, and FG are turned on, the pulse P well is turned on (becomes active), and the P-type well 52 has a positive voltage higher than a predetermined voltage serving as a reference.
- a voltage V well is applied. For example, on / off control of the pulse P well is performed by the vertical drive unit 22.
- the second charge storage unit 66, the first charge storage unit 64, and the charge-voltage conversion unit 68 are electrically connected.
- some of the charges accumulated in each region are discharged to the outside through the reset gate unit 69, or charges are injected into each region from the outside through the reset gate unit 69, and the first Each region from the second charge storage unit 66 to the charge-voltage conversion unit 68 is initialized (reset).
- the potential of the first charge storage unit 64 increases, so that the charge stored in the first charge storage unit 64 remains electrically connected. Is transferred to the second charge storage section 66.
- the second charge accumulation unit 66 is initialized (reset), more specifically, the second charge accumulation unit 66, the first charge accumulation unit 64, and The charge voltage conversion unit 68 is initialized. For example, the initialization of the second charge storage unit 66 is performed in order for each pixel row.
- the pulse P well is turned off at time t3, and the voltage applied to the P-type well 52 is changed from the voltage V well to a predetermined reference voltage. .
- the drive signal PG is turned off, the discharge of the charge from the charge discharge gate 62 is stopped, so that the charge obtained by the photoelectric conversion by the photodiode 61 is changed to the photodiode 61. Will be accumulated. That is, exposure for all pixels is started.
- an overflow path is formed between the first charge storage unit 64 and the second charge storage unit 66. Therefore, when the amount of charges accumulated in the first charge accumulation unit 64 reaches the saturation signal amount, the charges transferred beyond the saturation signal amount are further transferred to the second charge accumulation unit 66, The charge is accumulated in the second charge accumulation unit 66.
- the drive signal CG When the drive signal CG is turned on at time t5, the potential immediately below the second transfer gate unit 65 is lowered, so that the charge accumulated in the first charge accumulation unit 64 so far is changed to the second charge accumulation unit. 66. Thereafter, the drive signal CG is turned off.
- the drive signal TG and the drive signal SG are turned on.
- the potential of the first charge storage unit 64 decreases and the potential immediately below the first transfer gate unit 63 decreases, so that the charge accumulated in the photodiode 61 so far is transferred to the first charge storage unit 64.
- the charge obtained during the exposure period is in a state of being accumulated in the first charge accumulation unit 64 and the second charge accumulation unit 66.
- the drive signal TG is turned off and the drive signal PG is turned on.
- the transfer of charges from the photodiode 61 to the first charge storage section 64 is stopped, and the charges of the photodiode 61 are discharged to the outside.
- the period T2 from the time t4 to the time t7 is the exposure period, and in the exposure period, all the pixels are exposed simultaneously for the same period.
- the drive signal SG is turned off, and the potential of the first charge storage unit 64 is increased. Further, the drive signal SEL is turned on to select a pixel, and the drive signal RST is turned on to reset the potential of the charge voltage conversion unit 68 to the level of the reset voltage VR.
- the first reset level is read. That is, the potential of the charge-voltage conversion unit 68 is read as the first reset level N1 to the column processing unit 23 via the amplification transistor 70, the selection transistor 71, and the vertical signal line 27.
- the drive signal FG is turned on, the potential immediately below the third transfer gate unit 67 is lowered, and the first charge storage unit 64 and the charge voltage conversion unit 68 are electrically connected.
- the charge in the first charge storage unit 64 is transferred to the charge-voltage conversion unit 68 via the third transfer gate unit 67. That is, charges are transferred by the third transfer gate unit 67 and the transferred charges are accumulated in the charge-voltage conversion unit 68.
- a period T3 from time t8 to time t9 is a first reset level reading period in which the first reset level N1 is read.
- the potential of the charge voltage conversion unit 68 is read as the first signal level S1 to the column processing unit 23 via the amplification transistor 70, the selection transistor 71, and the vertical signal line 27.
- the difference between the first reset level N1 and the first signal level S1 is the value of the first pixel signal. That is, the potential difference that varies in accordance with the charge transferred from the first charge accumulation unit 64 to the charge-voltage conversion unit 68 is set as the value of the first pixel signal.
- the drive signals CG, SG, and FG are turned on, the pulse P well is turned on (becomes active), and the positive voltage V well is applied to the P-type well 52.
- the potential immediately below the second transfer gate unit 65 and the third transfer gate unit 67 is lowered, and the potentials of the first charge storage unit 64, the second charge storage unit 66, and the charge voltage conversion unit 68 are reduced.
- the first charge storage unit 64, the second charge storage unit 66, and the charge voltage conversion unit 68 are electrically connected.
- the application of the positive voltage V well to the P-type well 52 assists the voltage application to the gate electrodes of the second transfer gate portion 65 and the third transfer gate portion 67.
- a period T4 from time t10 to time t11 is a first signal level reading period in which the first signal level S1 is read.
- the second charge accumulation unit 66 and the charge-voltage conversion unit 68 are thus far processed.
- the charge accumulated in the first charge accumulation unit 64, the second charge accumulation unit 66, and the charge-voltage conversion unit 68 is accumulated. That is, charges are accumulated over the entire region of the first charge accumulation unit 64, the second charge accumulation unit 66, and the charge-voltage conversion unit 68 to which the potential is coupled.
- the potential of the charge-voltage conversion unit 68 is read as the second signal level S2 to the column processing unit 23 via the amplification transistor 70, the selection transistor 71, and the vertical signal line 27. That is, the second signal level reading is performed.
- a period T5 from time t11 to time t12 is a second signal level reading period in which the second signal level S2 is read.
- the second reset level is read. That is, the potential of the charge-voltage conversion unit 68 is read as the second reset level N2 to the column processing unit 23 via the amplification transistor 70, the selection transistor 71, and the vertical signal line 27.
- the drive signal SEL is turned off to cancel the selection of the pixel, and the drive signal FG is turned off to increase the potential immediately below the third transfer gate portion 67, so that the first charge accumulation portion 64 and the charge are charged.
- the potential of the voltage converter 68 is divided. That is, the first charge storage unit 64 and the charge voltage conversion unit 68 are electrically disconnected.
- the period T6 from time t13 to time t14 is a second reset level reading period in which the second reset level N2 is read.
- the difference between the second reset level N2 and the second signal level S2 read out in this way is used as the value of the second pixel signal. That is, the first charge accumulation unit 64, the second charge accumulation unit 66, and the charge-voltage conversion unit 68 are electrically connected, and those regions are reset from the state where charges are accumulated in all the regions. The difference in potential that is changed at this time is taken as the value of the second pixel signal.
- the final pixel value of the pixel that is, the value of the pixel signal is determined based on the read first pixel signal and second pixel signal. For example, when the value of the first pixel signal is less than a predetermined threshold, that is, when signal saturation does not occur at low illuminance, the first pixel signal is directly used as the final pixel signal.
- the value of the first pixel signal is greater than or equal to a predetermined threshold, that is, when signal saturation occurs at high illuminance, the gain obtained from the first pixel signal and the second pixel signal And the product value of the second pixel signal is the final pixel signal.
- the drive signal SEL and the drive signal FG are turned off at time t14, the drive signal SG is turned off. Then, since the potential of the first charge storage unit 64 is increased, the charge stored in the first charge storage unit 64 is transferred to the second charge storage unit 66 that remains electrically connected. Transferred.
- the pulse P well is turned off, and the voltage applied to the P-type well 52 is changed from the voltage V well to a predetermined reference voltage.
- processing performed thereafter is processing performed for each pixel row.
- the solid-state imaging device 11 captures an image by receiving light from a subject and performing photoelectric conversion.
- the second charge accumulation unit 66 is initialized in the period T1
- the second signal level is read in the period T5
- the second reset level is read in the period T6
- the P-type well 52 is read.
- the solid-state imaging device 11 is electrically connected to the reset gate unit 69 that discharges or injects charges by one or more gates such as the third transfer gate unit 67 by applying a positive voltage to the P-type well 52.
- the gate voltage necessary for initializing the semiconductor elements such as the first charge storage portion 64 and the second charge storage portion 66 that are separated from each other is relaxed. Thereby, even when the voltage for driving the solid-state imaging device 11 is low, a sufficient saturation signal amount can be secured and the semiconductor device can be initialized (reset).
- the node having the lowest voltage in the pixel is the vertical signal line 27 serving as the source of the selection transistor 71. Therefore, when the positive voltage V well is applied to the P-type well 52, the positive voltage lower than the voltage value applied to the vertical signal line 27 is set as the voltage V well at the timing of applying the voltage V well. That's fine.
- timing of applying the positive voltage V well to the P-type well 52 may be the same for all the pixels, or may be different for each of several pixels, such as for each pixel row or each pixel block. Good.
- a positive voltage may be applied to each P-type well 52 in which each pixel is formed, or a positive voltage is applied to the P-type well 52 for each pixel row or for each block unit composed of several pixels. May be applied.
- the first charge accumulation unit 64 and the second charge accumulation unit 66 as the semiconductor elements to be initialized are described as capacitors. However, when the semiconductor elements are capacitors.
- the capacity may be of any structure.
- the capacitance of the semiconductor element may be an MIM structure (metal-insulating layer-metal) in which an insulating layer (insulator) is sandwiched between metals, or the insulating layer is sandwiched between polysilicon and metal. It may be of PIM structure (polysilicon-insulating layer-metal). Further, the capacity of the semiconductor element may be a PIP structure (polysilicon-insulating layer-polysilicon) in which an insulating layer is sandwiched between polysilicon.
- MIM structure metal-insulating layer-metal
- PIP structure polysilicon-insulating layer-polysilicon
- the solid-state imaging device 11 may be a sensor that has a capacitance provided in the vicinity of the charge-voltage conversion unit 68 in the pixel of the pixel array unit 21 and makes the gain of the charge-voltage conversion unit 68 variable.
- the pixels constituting the pixel array unit 21 are configured as shown in FIG. 16, for example.
- portions corresponding to those in FIG. 3 are denoted by the same reference numerals, and description thereof will be omitted as appropriate.
- the pixels of the pixel array unit 21 include a photodiode 61, a first transfer gate unit 63, a gain control gate unit 201, a charge storage unit 202, a charge / voltage conversion unit 68, a reset gate unit 69, an amplification transistor 70, And a selection transistor 71.
- a connection line 72 that is connected to a power source (not shown) and applies a positive voltage V well to the P-type well 52 of the pixel is connected to the pixel via a contact (not shown).
- the photodiode 61 is connected to the charge voltage conversion unit 68 via the first transfer gate unit 63.
- a reset gate unit 69 is connected to the charge voltage conversion unit 68, and a vertical signal line 27 is also connected via an amplification transistor 70 and a selection transistor 71.
- a charge storage unit 202 which is a capacitor (capacitor) for storing charges is also connected to the charge voltage conversion unit 68 via a gain control gate unit 201.
- a drive signal GC is supplied to the gate electrode constituting the gain control gate unit 201.
- the drive signal GC is in an active state (on state) when in a high level, and in an inactive state (off state) in a low level. In this state, the pulse signal is
- the drive signal GC when the drive signal GC is turned on, the potential immediately below the gain control gate unit 201 is lowered, and the potentials of the charge voltage conversion unit 68 and the charge storage unit 202 are coupled. That is, the charge voltage conversion unit 68 and the charge storage unit 202 are electrically connected.
- the capacitance value of the charge-voltage conversion unit 68 is C FD and the capacitance value of the charge storage unit 202 is C CAP , in the state of the pixel where the signal level is read out when the drive signal GC is on.
- the capacitance value C is C FD + C CAP .
- the capacitance value C changes to CFD , so that the sensitivity of the voltage (the amount of change in voltage) with respect to the amount of change in charge increases.
- the sensitivity of the pixel is appropriately changed by turning on and off the drive signal GC.
- the charge storage unit 202 is electrically connected to the charge voltage conversion unit 68.
- the charge storage unit 202 includes the photodiode 61 to the charge voltage conversion unit 68. A part of the transferred charge is accumulated.
- the solid-state image sensor 11 is driven, and initialization (reset) of the charge storage unit 202 is assisted at the time of reading a signal that reduces the conversion efficiency in the pixel.
- initialization (reset) of the charge storage unit 202 is assisted at the time of reading a signal that reduces the conversion efficiency in the pixel.
- a positive voltage V well is applied to the P-type well 52.
- FIG. 17 shows the state of signals supplied to the pixels at each time. That is, in the figure, the horizontal direction indicates time, and the vertical direction indicates the level (voltage) of each signal. Further, the broken lines SL31 to SL35 represent the drive signals SEL, TG, RST, the pulse P well , and the drive signal GC, respectively.
- the drive signals SEL, TG, RST, and GC are turned off.
- the pulse P well is also turned off (inactive state), and a predetermined voltage as a reference is applied to the P-type well 52.
- the drive signal SEL is turned on to select a pixel, and the drive signal GC is turned on to electrically connect the charge storage unit 202 and the charge-voltage conversion unit 68.
- the drive signal RST is turned on, the charge storage unit 202 and the charge voltage conversion unit 68 are reset, and the pulse P well is turned on.
- the reset level is read out. That is, the potential of the charge-voltage conversion unit 68 is read as a reset level to the column processing unit 23 via the amplification transistor 70, the selection transistor 71, and the vertical signal line 27.
- the drive signal TG is turned on.
- the potential immediately below the first transfer gate portion 63 is lowered, and the charges accumulated in the photodiode 61 so far are transferred to the charge-voltage conversion portion 68 and the charge accumulation portion 202.
- the drive signal TG is turned off, and the transfer of charges from the photodiode 61 to the charge voltage conversion unit 68 is stopped.
- the signal level is read out thereafter. That is, the potential of the charge-voltage conversion unit 68 is read as a signal level to the column processing unit 23 via the amplification transistor 70, the selection transistor 71, and the vertical signal line 27. In the column processing unit 23, the difference between the reset level and the signal level read in this way is used as the value of the pixel signal.
- the drive signal SEL is turned off to cancel the selection of the pixel, and the drive signal GC is turned off to electrically disconnect the charge voltage conversion unit 68 and the charge storage unit 202. Furthermore, the pulse P well is turned off, and the voltage applied to the P-type well 52 is changed from the voltage V well to a predetermined reference voltage.
- a period from time t31 to time t35 is one horizontal readout period in which a pixel signal is read from each pixel constituting the pixel row.
- the solid-state imaging device 11 assists initialization of the charge storage unit 202 by applying a positive voltage to the P-type well 52 in the horizontal readout period in which the pixel signal is read.
- the gate voltage necessary for driving the gain control gate unit 201 and the reset gate unit 69 that is, the voltages of the drive signals GC and RST can be relaxed, and even when the voltage for driving the solid-state imaging device 11 is low. A sufficient saturation signal amount can be ensured.
- the pulse P well is controlled to be turned on only during the horizontal readout period and the positive voltage V well is applied to the P-type well 52, but the pulse P well is always turned on. You may make it do.
- FIG. 18 shows the state of signals supplied to the pixels at each time. That is, in the figure, the horizontal direction indicates time, and the vertical direction indicates the level (voltage) of each signal.
- the broken lines SL41 to SL45 represent the drive signals SEL, TG, RST, the pulse P well and the drive signal GC, respectively.
- the operation from the start of the image capturing operation to immediately before time t43 is the same as the operation until immediately before time t33 in FIG. That is, at time t41, the drive signals SEL, RST, GC are turned on, and the pulse P well is turned on. At time t42, the drive signal RST is turned off and the reset level is read out.
- the drive signal TG is turned on, the pulse P well is set to a level lower than off, and a negative voltage lower than a predetermined voltage serving as a reference is applied to the P-type well 52.
- the application of a negative voltage to the P-type well 52 by the pulse P well is performed by the vertical drive unit 22 via the connection line 72.
- the drive signal TG is turned off to stop the charge transfer from the photodiode 61 to the charge-voltage converter 68, and the pulse P well is turned on to stop the charge transfer assistance. Thereafter, the same operation as that after time t34 in FIG. 17 is performed.
- the drive signals SEL and GC are turned off and the pulse P well is turned off, so that the voltage applied to the P-type well 52 is changed.
- the voltage V well is changed to a predetermined reference voltage.
- the solid-state imaging device 11 assists initialization by applying a positive voltage to the P-type well 52 when the charge storage unit 202 is initialized, and transfers the charge to the charge-voltage conversion unit 68.
- a negative voltage is applied to the P-type well 52 to assist transfer. Thereby, it is possible to reduce the voltage of the pixel and further increase the saturation signal amount.
- the broken line PO51 indicates the potential in each region of the pixel, and the two dotted lines PT11 indicate the same position, specifically, the position of the N + type semiconductor region 109 serving as the charge-voltage conversion unit 68. .
- the charge voltage conversion unit 68 For example, in the drawing, on the right side of the dotted line PT11 on the right side, the charge voltage conversion unit 68, the region of the reset gate unit 69 connected to the charge voltage conversion unit 68, and the potential of the region are shown. . Further, in the drawing, on the right side of the dotted line PT11 on the left side, the charge voltage conversion unit 68, the region of the charge storage unit 202 connected to the charge voltage conversion unit 68, and the potential of the region are shown. .
- a capacitor serving as the charge storage unit 202 is connected to the right side of the gain control gate unit 201 in the P-type well 52 via an N + type semiconductor region 241 constituting the charge storage unit 202.
- the reset gate portion 69 is connected to the reset power source VR via the N + type semiconductor region 242.
- Such a potential state shown in FIG. 19 is each region of the pixel in a state before time t41 in FIG. 18, that is, in a state where the drive signals SEL, TG, RST, GC are turned off and the pulse P well is also turned off. Shows the potential.
- the photodiode 61 and the N + type semiconductor region 109 that becomes the charge-voltage conversion unit 68 are electrically separated. Further, the N + type semiconductor region 109 and the N + type semiconductor region 241, and the N + type semiconductor region 109 and the N + type semiconductor region 242 are also electrically isolated.
- the potential immediately below the gain control gate portion 201 is lowered from the potential state indicated by the dotted line to become the potential indicated by the broken line PO61. That is, the potential level immediately below the gain control gate portion 201 becomes the same level as the potential levels of the N + type semiconductor region 109 and the N + type semiconductor region 241 by applying a positive voltage to the P type well 52.
- the potential levels of the N + type semiconductor region 109, the region immediately below the reset gate portion 69, and the N + type semiconductor region 242 are the same.
- the charge-voltage conversion unit 68 and the charge storage unit 202 are electrically connected, the charge-voltage conversion unit 68 and the charge storage unit 202 are initialized. At this time, the potential levels of the charge voltage conversion unit 68, the region immediately below the gain control gate unit 201, and the regions of the charge storage unit 202 are the same. Therefore, the charge of the charge storage unit 202 is not discharged without remaining, or the charge required for the charge storage unit 202 is not injected.
- the potential in the region immediately below the photodiode 61 and the first transfer gate 63 rises from the potential state indicated by the dotted line and becomes the potential indicated by the broken line PO71. Further, the potential immediately below the gain control gate portion 201 also rises from the potential state indicated by the dotted line and becomes the potential indicated by the broken line PO71.
- the potential of the region immediately below the first transfer gate portion 63 is higher than the potential of the photodiode 61. This is because the potential of the photodiode 61 becomes higher than the potential of the region immediately below the first transfer gate portion 63 by the transfer assistance. As a result, all charges accumulated in the photodiode 61 are transferred to the charge-voltage converter 68.
- the potential directly under the gain control gate unit 201 is increased by applying a negative voltage (negative bias) to the P-type well 52.
- a negative voltage negative bias
- the potential to the P-type well 52 is positive.
- the potential is lowered by the bias.
- the potential directly below the gain control gate unit 201 is the level at the time of initialization, that is, the potential directly below the gain control gate unit 201 shown in FIG. Become a level.
- imaging device is applied to an image capturing unit (photoelectric conversion unit) such as an imaging device such as a digital still camera or a video camera, a portable terminal device having an imaging function, or a copying machine using a solid-state imaging device for an image reading unit.
- an image capturing unit photoelectric conversion unit
- the present invention can be applied to all electronic devices using a solid-state image sensor.
- the solid-state imaging device may be formed as a one-chip, or may be in a module shape having an imaging function in which an imaging unit and a signal processing unit or an optical system are packaged together.
- FIG. 22 is a diagram illustrating a configuration example of an imaging apparatus as an electronic apparatus to which the present technology is applied.
- the 22 includes an optical unit 311 including a lens group, a solid-state imaging device (imaging device) 312, and a DSP (Digital Signal Processor) circuit 313 that is a camera signal processing circuit.
- the imaging device 301 also includes a frame memory 314, a display unit 315, a recording unit 316, an operation unit 317, and a power supply unit 318.
- the DSP circuit 313, the frame memory 314, the display unit 315, the recording unit 316, the operation unit 317, and the power supply unit 318 are connected to each other via a bus line 319.
- the optical unit 311 takes in incident light (image light) from a subject and forms an image on the imaging surface of the solid-state imaging device 312.
- the solid-state imaging device 312 converts the amount of incident light imaged on the imaging surface by the optical unit 311 into an electrical signal in units of pixels and outputs it as a pixel signal.
- the solid-state image sensor 312 corresponds to the solid-state image sensor 11 described above.
- the display unit 315 includes a panel type display device such as a liquid crystal panel or an organic EL (electroluminescence) panel, and displays a moving image or a still image captured by the solid-state imaging device 312.
- the recording unit 316 records a moving image or a still image captured by the solid-state imaging device 312 on a recording medium such as a video tape or a DVD (Digital Versatile Disk).
- the operation unit 317 issues operation commands for various functions of the imaging apparatus 301 under the operation of the user.
- the power source unit 318 appropriately supplies various power sources serving as operation power sources for the DSP circuit 313, the frame memory 314, the display unit 315, the recording unit 316, and the operation unit 317 to these supply targets.
- the present invention is applied to a CMOS image sensor in which pixels that detect signal charges corresponding to the amount of visible light as physical quantities are arranged in a matrix has been described as an example.
- the present technology is not limited to application to a CMOS image sensor, and can be applied to all solid-state imaging devices.
- the present technology is not limited to application to a solid-state imaging device that senses the distribution of the amount of incident light of visible light and captures it as an image. It can be applied to an image sensor.
- the present technology can be configured as follows.
- a pixel portion composed of a large number of pixels arranged in a matrix;
- an imaging device comprising: a drive unit that drives the pixel unit;
- the pixel is A conversion unit for converting a physical quantity into an electric charge during the conversion period;
- a charge holding unit for accumulating the charge converted by the conversion unit in the conversion period and holding a charge transferred from the conversion unit after the conversion period ends;
- a readout unit for reading out the electric charge held in the electric charge holding unit in a readout period;
- the drive unit is When the plurality of pixels of the pixel portion are equally divided into two groups of a first group and a second group, and one of the first group and the second group of the pixel portion is set as the readout period, the other An imaging device having the conversion period as the imaging element.
- the imaging device according to [1], wherein the driving unit sets the pixels belonging to the first group or the second group to a conversion period simultaneously for each group.
- the imaging device according to [1] or [2], further including a generation unit that generates an image signal based on the read electric charge.
- the generation unit generates an odd-frame image signal based on the charges read from the first group, and generates an even-frame image signal based on the charges read from the second group.
- the imaging device according to [3].
- a pixel portion composed of a large number of pixels arranged in a matrix;
- a driving method of an image sensor comprising: a driving unit that drives the pixel unit;
- the pixel is A conversion unit for converting a physical quantity into an electric charge during the conversion period;
- a charge holding unit for accumulating the charge converted by the conversion unit in the conversion period and holding a charge transferred from the conversion unit after the conversion period ends;
- a readout unit for reading out the electric charge held in the electric charge holding unit in a readout period;
- An image sensor including a pixel unit composed of a large number of pixels arranged in a matrix and a drive unit that drives the pixel unit is mounted.
- the pixel is A conversion unit for converting a physical quantity into an electric charge during the conversion period;
- a charge holding unit for accumulating the charge converted by the conversion unit in the conversion period and holding a charge transferred from the conversion unit after the conversion period ends;
- a readout unit for reading out the electric charge held in the electric charge holding unit in a readout period;
- the drive unit is When the plurality of pixels of the pixel portion are equally divided into two groups of a first group and a second group, and one of the first group and the second group of the pixel portion is set as the readout period, the other An electronic device having the conversion period.
- a photoelectric conversion unit that photoelectrically converts incident light; and A charge accumulating unit for accumulating charges obtained by photoelectric conversion;
- An initialization unit connected to the charge storage unit via at least one or more gates to initialize the charge storage unit;
- An image pickup device comprising: a voltage application control unit configured to apply a positive voltage to a well region provided with the photoelectric conversion unit, the charge storage unit, and the initialization unit when the charge storage unit is initialized.
- the voltage application control unit applies a positive voltage to the well region at the time of initialization of the charge storage unit for reset level reading and at the time of signal level reading.
- the imaging device has any one of an MIM structure, a PIM structure, and a PIP structure.
- the photoelectric conversion unit, the charge storage unit, and the initialization unit are provided for each of a plurality of pixels constituting a pixel array unit that captures an image, The imaging device according to any one of [8] to [11], wherein the voltage application control unit applies the positive voltage simultaneously to all the pixels on the pixel array unit.
- the imaging device according to [12], wherein the well regions of all the pixels on the pixel array unit are electrically integrated.
- the photoelectric conversion unit, the charge storage unit, and the initialization unit are provided for each of a plurality of pixels constituting a pixel array unit that captures an image
- the imaging device according to any one of [8] to [11], wherein the voltage application control unit applies the positive voltage for each pixel row including pixels arranged in a horizontal direction on the pixel array unit.
- the imaging element according to [14], wherein the well regions of the pixels in the pixel row on the pixel array unit are electrically integrated, and the well regions of the pixel rows are electrically separated.
- the photoelectric conversion unit, the charge storage unit, and the initialization unit are provided for each of a plurality of pixels constituting a pixel array unit that captures an image,
- the imaging device according to any one of [8] to [11], wherein the voltage application control unit applies the positive voltage to each pixel block including a plurality of pixels on the pixel array unit.
- the imaging device according to [16], wherein the well regions of the pixels of the pixel block on the pixel array unit are electrically integrated, and the well regions of the pixel blocks are electrically separated.
- the photoelectric conversion unit, the charge storage unit, and the initialization unit are provided for each of a plurality of pixels constituting a pixel array unit that captures an image, and the well region of each pixel on the pixel array unit includes The image sensor according to any one of [8] to [11], which is electrically separated.
- a charge-voltage conversion unit that is provided between the initialization unit and the charge storage unit and converts a charge into a voltage signal; The image sensor according to any one of [8] to [18], wherein the charge accumulated in the charge accumulation unit is transferred to the charge voltage conversion unit via the one or more gates.
- 11 solid-state imaging device 21 pixel array unit, 61 photodiode, 63 first transfer gate unit, 64 first charge storage unit, 65 second transfer gate unit, 66 second charge storage unit, 67 third Transfer gate section, 68 charge voltage conversion section, 69 reset gate section, 72 connection lines, 201 gain control gate section, 202 charge storage section
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Abstract
Description
[固体撮像素子の構成例]
まず、本技術を適用した固体撮像素子の構成例について説明する。図2は、本技術を適用した固体撮像素子の一実施の形態の構成例を示す図である。
次に、上述した画素アレイ部21の各画素の構成について説明する。図3は、画素アレイ部21に設けられた1つの画素の構成例を示す回路図である。
画素アレイ部21を成す多数の画素は、第1群と第2群の2群に区分けし、第1群と第2群の駆動タイミングを独立して制御するようにする。そして、例えば第1群の画素からの画像信号により奇数フレームを生成し、第2群の画素からの画像信号により偶数フレームを生成する。なお、奇数フレームと偶数フレームはサンプリングポイント(画素の位置)が異なるが、補間や画像サイズの縮小によりサンプリングポイントが同一に見える奇数フレームと偶数フレームを生成するようにしてもよい。
次に、画素アレイ部21の動作について説明する。図7は、画素アレイ部21の動作を説明するフローチャートである。
[各画素の構造について]
さらに、図3に示した画素の構造について説明する。図10は、図3に示した画素の構造を示す図であり、図10には、画素レイアウトを示す平面パターン、その平面パターンにおけるA―A’矢視断面、およびB―B’矢視断面が示されている。なお、図10において、図3における場合と対応する部分には同一の符号を付してあり、その説明は適宜省略する。
上述したように、画素アレイ部21に設けられた各画素には、接続線72やコンタクトを介して電圧Vwellが印加されるが、接続線72と画素(P型ウェル52)とを接続するコンタクトは、行単位で設けられてもよいし、画素ごとに設けられてもよい。
次に、本技術の概要について説明する。
以下、図15を参照して、本技術を適用した固体撮像素子11の具体的な動作について説明する。図15は、画素に供給される信号の各時刻における状態を示している。すなわち、図中、横方向は時間を示しており、縦方向は各信号のレベル(電圧)を示している。
[画素の構成例]
さらに、固体撮像素子11は、画素アレイ部21の画素内の電荷電圧変換部68近傍に容量が設けられた、電荷電圧変換部68のゲインを可変にするセンサとされてもよい。
ところで、図16に示した画素では、画像の撮像時には少なくとも1つ以上のゲートを介して電荷蓄積部202をリセット(初期化)する必要がある。具体的には、ここではリセットゲート部69の駆動信号RSTと、ゲインコントロールゲート部201の駆動信号GCとをオンにして、電荷蓄積部202と電荷電圧変換部68を電気的に接続させ、初期状態にする必要がある。
[固体撮像素子の動作について]
また、例えば図18に示すように、フォトダイオード61から電荷電圧変換部68への電荷の転送時においてP型ウェル52に負の電圧が印加されて、電荷転送の補助が行なわれるようにしてもよい。
さらに、本技術は、デジタルスチルカメラやビデオカメラ等の撮像装置や、撮像機能を有する携帯端末装置や、画像読取部に固体撮像素子を用いる複写機など、画像取込部(光電変換部)に固体撮像素子を用いる電子機器全般に対して適用可能である。固体撮像素子は、ワンチップとして形成された形態であってもよいし、撮像部と信号処理部または光学系とがまとめてパッケージングされた撮像機能を有するモジュール状の形態であってもよい。
行列状に配置された多数の画素から成る画素部と、
前記画素部を駆動する駆動部と
を備える撮像素子において、
前記画素は、
変換期間において物理量を電荷に変換する変換部と、
前記変換期間において前記変換部により変換された前記電荷を蓄積するとともに、前記変換期間終了後に前記変換部から転送された電荷を保持する電荷保持部と、
読み出し期間において前記電荷保持部に保持されている前記電荷を読み出す読み出し部とを有し、
前記駆動部は、
前記画素部の前記多数の画素を第1群と第2群の2群に均等に区分し、前記画素部の前記第1群または前記第2群の一方を前記読み出し期間としたときに、他方を前記変換期間とする
撮像素子。
[2]
前記駆動部は、前記第1群または前記第2群にそれぞれ属する前記画素を、群毎に同時に変換期間とする
[1]に記載の撮像素子。
[3]
読み出された前記電荷に基づいて画像信号を生成する生成部を
さらに備える
[1]または[2]に記載の撮像素子。
[4]
前記生成部は、前記第1群から読み出された前記電荷に基づいて奇数フレームの画像信号を生成し、前記第2群から読み出された前記電荷に基づいて偶数フレームの画像信号を生成する
[3]に記載の撮像素子。
[5]
前記変換部は、前記物理量としての入射光を電荷に変換する
[1]乃至[4]の何れかに記載の撮像素子。
[6]
行列状に配置された多数の画素から成る画素部と、
前記画素部を駆動する駆動部と
を備える撮像素子の駆動方法において、
前記画素は、
変換期間において物理量を電荷に変換する変換部と、
前記変換期間において前記変換部により変換された前記電荷を蓄積するとともに、前記変換期間終了後に前記変換部から転送された電荷を保持する電荷保持部と、
読み出し期間において前記電荷保持部に保持されている前記電荷を読み出す読み出し部とを有し、
前記駆動部による、
前記画素部の前記多数の画素を第1群と第2群の2群に均等に区分し、前記画素部の前記第1群または前記第2群の一方を前記読み出し期間としたときに、他方を前記変換期間とするステップを
含む駆動方法。
[7]
撮像機能を有する電子装置において、
行列状に配置された多数の画素から成る画素部と、前記画素部を駆動する駆動部とを備える撮像素子が搭載され、
前記画素は、
変換期間において物理量を電荷に変換する変換部と、
前記変換期間において前記変換部により変換された前記電荷を蓄積するとともに、前記変換期間終了後に前記変換部から転送された電荷を保持する電荷保持部と、
読み出し期間において前記電荷保持部に保持されている前記電荷を読み出す読み出し部とを有し、
前記駆動部は、
前記画素部の前記多数の画素を第1群と第2群の2群に均等に区分し、前記画素部の前記第1群または前記第2群の一方を前記読み出し期間としたときに、他方を前記変換期間とする
電子装置。
[8]
入射した光を光電変換する光電変換部と、
光電変換により得られた電荷を蓄積する電荷蓄積部と、
前記電荷蓄積部と少なくとも1以上のゲートを介して接続され、前記電荷蓄積部を初期化する初期化部と、
前記電荷蓄積部の初期化時に、前記光電変換部、前記電荷蓄積部、および前記初期化部が設けられたウェル領域に正の電圧を印加する電圧印加制御部と
を備える撮像素子。
[9]
前記電圧印加制御部は、リセットレベル読み出しのための前記電荷蓄積部の初期化時、および信号レベル読み出し時に前記ウェル領域に正の電圧を印加する
[8]に記載の撮像素子。
[10]
前記電荷蓄積部は容量である
[8]または[9]に記載の撮像素子。
[11]
前記容量はMIM構造、PIM構造、またはPIP構造の何れかである
[10]に記載の撮像素子。
[12]
画像を撮像する画素アレイ部を構成する複数の画素ごとに、前記光電変換部、前記電荷蓄積部、および前記初期化部が設けられており、
前記電圧印加制御部は、前記画素アレイ部上の全画素に対して同時に前記正の電圧を印加する
[8]乃至[11]に記載の撮像素子。
[13]
前記画素アレイ部上の全画素の前記ウェル領域が電気的に一体に形成されている
[12]に記載の撮像素子。
[14]
画像を撮像する画素アレイ部を構成する複数の画素ごとに、前記光電変換部、前記電荷蓄積部、および前記初期化部が設けられており、
前記電圧印加制御部は、前記画素アレイ部上の水平方向に並ぶ画素からなる画素行ごとに、前記正の電圧を印加する
[8]乃至[11]に記載の撮像素子。
[15]
前記画素アレイ部上の前記画素行の画素の前記ウェル領域が電気的に一体に形成され、各前記画素行の前記ウェル領域は電気的に分離されている
[14]に記載の撮像素子。
[16]
画像を撮像する画素アレイ部を構成する複数の画素ごとに、前記光電変換部、前記電荷蓄積部、および前記初期化部が設けられており、
前記電圧印加制御部は、前記画素アレイ部上のいくつかの画素からなる画素ブロックごとに、前記正の電圧を印加する
[8]乃至[11]に記載の撮像素子。
[17]
前記画素アレイ部上の前記画素ブロックの画素の前記ウェル領域が電気的に一体に形成され、各前記画素ブロックの前記ウェル領域は電気的に分離されている
[16]に記載の撮像素子。
[18]
画像を撮像する画素アレイ部を構成する複数の画素ごとに、前記光電変換部、前記電荷蓄積部、および前記初期化部が設けられており、前記画素アレイ部上の各画素の前記ウェル領域が電気的に分離されている
[8]乃至[11]に記載の撮像素子。
[19]
前記初期化部と前記電荷蓄積部の間に設けられ、電荷を電圧信号に変換する電荷電圧変換部をさらに備え、
前記電荷蓄積部に蓄積された電荷は、前記1以上のゲートを介して前記電荷電圧変換部に転送される
[8]乃至[18]に記載の撮像素子。
Claims (20)
- 行列状に配置された多数の画素から成る画素部と、
前記画素部を駆動する駆動部と
を備える撮像素子において、
前記画素は、
変換期間において物理量を電荷に変換する変換部と、
前記変換期間において前記変換部により変換された前記電荷を蓄積するとともに、前記変換期間終了後に前記変換部から転送された電荷を保持する電荷保持部と、
読み出し期間において前記電荷保持部に保持されている前記電荷を読み出す読み出し部とを有し、
前記駆動部は、
前記画素部の前記多数の画素を第1群と第2群の2群に均等に区分し、前記画素部の前記第1群または前記第2群の一方を前記読み出し期間としたときに、他方を前記変換期間とする
撮像素子。 - 前記駆動部は、前記第1群または前記第2群にそれぞれ属する前記画素を、群毎に同時に変換期間とする
請求項1に記載の撮像素子。 - 読み出された前記電荷に基づいて画像信号を生成する生成部を
さらに備える
請求項2に記載の撮像素子。 - 前記生成部は、前記第1群から読み出された前記電荷に基づいて奇数フレームの画像信号を生成し、前記第2群から読み出された前記電荷に基づいて偶数フレームの画像信号を生成する
請求項3に記載の撮像素子。 - 前記変換部は、前記物理量としての入射光を電荷に変換する
請求項2に記載の撮像素子。 - 行列状に配置された多数の画素から成る画素部と、
前記画素部を駆動する駆動部と
を備える撮像素子の駆動方法において、
前記画素は、
変換期間において物理量を電荷に変換する変換部と、
前記変換期間において前記変換部により変換された前記電荷を蓄積するとともに、前記変換期間終了後に前記変換部から転送された電荷を保持する電荷保持部と、
読み出し期間において前記電荷保持部に保持されている前記電荷を読み出す読み出し部とを有し、
前記駆動部による、
前記画素部の前記多数の画素を第1群と第2群の2群に均等に区分し、前記画素部の前記第1群または前記第2群の一方を前記読み出し期間としたときに、他方を前記変換期間とするステップを
含む駆動方法。 - 撮像機能を有する電子装置において、
行列状に配置された多数の画素から成る画素部と、前記画素部を駆動する駆動部とを備える撮像素子が搭載され、
前記画素は、
変換期間において物理量を電荷に変換する変換部と、
前記変換期間において前記変換部により変換された前記電荷を蓄積するとともに、前記変換期間終了後に前記変換部から転送された電荷を保持する電荷保持部と、
読み出し期間において前記電荷保持部に保持されている前記電荷を読み出す読み出し部とを有し、
前記駆動部は、
前記画素部の前記多数の画素を第1群と第2群の2群に均等に区分し、前記画素部の前記第1群または前記第2群の一方を前記読み出し期間としたときに、他方を前記変換期間とする
電子装置。 - 入射した光を光電変換する光電変換部と、
光電変換により得られた電荷を蓄積する電荷蓄積部と、
前記電荷蓄積部と少なくとも1以上のゲートを介して接続され、前記電荷蓄積部を初期化する初期化部と、
前記電荷蓄積部の初期化時に、前記光電変換部、前記電荷蓄積部、および前記初期化部が設けられたウェル領域に正の電圧を印加する電圧印加制御部と
を備える撮像素子。 - 前記電圧印加制御部は、リセットレベル読み出しのための前記電荷蓄積部の初期化時、および信号レベル読み出し時に前記ウェル領域に正の電圧を印加する
請求項8に記載の撮像素子。 - 前記電荷蓄積部は容量である
請求項9に記載の撮像素子。 - 前記容量はMIM構造、PIM構造、またはPIP構造の何れかである
請求項10に記載の撮像素子。 - 画像を撮像する画素アレイ部を構成する複数の画素ごとに、前記光電変換部、前記電荷蓄積部、および前記初期化部が設けられており、
前記電圧印加制御部は、前記画素アレイ部上の全画素に対して同時に前記正の電圧を印加する
請求項9に記載の撮像素子。 - 前記画素アレイ部上の全画素の前記ウェル領域が電気的に一体に形成されている
請求項12に記載の撮像素子。 - 画像を撮像する画素アレイ部を構成する複数の画素ごとに、前記光電変換部、前記電荷蓄積部、および前記初期化部が設けられており、
前記電圧印加制御部は、前記画素アレイ部上の水平方向に並ぶ画素からなる画素行ごとに、前記正の電圧を印加する
請求項9に記載の撮像素子。 - 前記画素アレイ部上の前記画素行の画素の前記ウェル領域が電気的に一体に形成され、各前記画素行の前記ウェル領域は電気的に分離されている
請求項14に記載の撮像素子。 - 画像を撮像する画素アレイ部を構成する複数の画素ごとに、前記光電変換部、前記電荷蓄積部、および前記初期化部が設けられており、
前記電圧印加制御部は、前記画素アレイ部上のいくつかの画素からなる画素ブロックごとに、前記正の電圧を印加する
請求項9に記載の撮像素子。 - 前記画素アレイ部上の前記画素ブロックの画素の前記ウェル領域が電気的に一体に形成され、各前記画素ブロックの前記ウェル領域は電気的に分離されている
請求項16に記載の撮像素子。 - 画像を撮像する画素アレイ部を構成する複数の画素ごとに、前記光電変換部、前記電荷蓄積部、および前記初期化部が設けられており、前記画素アレイ部上の各画素の前記ウェル領域が電気的に分離されている
請求項9に記載の撮像素子。 - 前記初期化部と前記電荷蓄積部の間に設けられ、電荷を電圧信号に変換する電荷電圧変換部をさらに備え、
前記電荷蓄積部に蓄積された電荷は、前記1以上のゲートを介して前記電荷電圧変換部に転送される
請求項9に記載の撮像素子。 - 入射した光を光電変換する光電変換部と、
光電変換により得られた電荷を蓄積する電荷蓄積部と、
前記電荷蓄積部と少なくとも1以上のゲートを介して接続され、前記電荷蓄積部を初期化する初期化部と
を備える撮像素子の駆動方法であって、
前記電荷蓄積部の初期化時に、前記光電変換部、前記電荷蓄積部、および前記初期化部が設けられたウェル領域に正の電圧を印加する
ステップを含む駆動方法。
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JPWO2013176007A1 (ja) | 2016-01-12 |
US20150124132A1 (en) | 2015-05-07 |
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