JP4298061B2 - Solid-state imaging device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a solid-state imaging device, and more particularly to a solid-state imaging device such as a charge coupled device.
[0002]
[Prior art]
A solid-state imaging device, for example, a CCD (Charge Coupled Device) generally has an interline transfer method, a frame transfer method, and the like.
A plan view of the interline transfer type CCD is shown in FIG. For example, a light receiving surface 10 that has a photodiode structure and performs photoelectric conversion and vertically transfers the generated signal charge in a predetermined direction (the direction of the arrow in the drawing), and horizontal transfer that horizontally transfers the signal charge from the light receiving surface 10 Part (horizontal transfer register) 20 and an amplifier 21 for amplifying the obtained signal charge. The amplifier 21 is connected to a signal processing circuit (not shown).
The light receiving surface 10 is configured by a light receiving cell 12 serving as a unit pixel shown in FIG. In the interline transfer method, the light receiving cell 12 includes a light receiving unit (opening) 12a that generates signal charges by photoelectric conversion, and a light blocking unit that includes a transfer unit and a wiring unit that vertically transfer the signal charges generated by the light receiving unit 12a. 12b.
[0003]
On the other hand, a plan view of the frame transfer type CCD is shown in FIG. For example, a light receiving surface 10 that has a photodiode structure, performs photoelectric conversion, and vertically transfers a generated signal charge in a predetermined direction (the direction of the arrow in the drawing), and a function of temporarily holding the signal charge until it is read out And a horizontal transfer unit 20 that horizontally transfers signal charges from the vertical transfer unit, and an amplifier 21 that amplifies the obtained signal charges. The amplifier 21 is connected to a signal processing circuit (not shown).
The light receiving surface 10 is configured by a light receiving cell 12 serving as a unit pixel shown in FIG. The light receiving cell 12 is a so-called virtual gate type CCD light receiving cell having a transfer gate portion 12c and virtual gate portions (12d, 12e, 12f). An anti-blooming gate portion 12e is formed in a part of the virtual gate portions (12d, 12e, 12f).
[0004]
A CCD having a TDI (time delay integration) function has been developed using the interline transfer method or the frame transfer method.
The above-mentioned TDI sensor that can function as a confocal microscope has a configuration shown in the plan view of FIG. 18A, for example, has a photodiode structure, performs photoelectric conversion, and generates a signal charge that is predetermined. Direction (arrow OP on the drawing_VAnd a horizontal transfer unit 20 that horizontally transfers signal charges from the light receiving surface 10, and an amplifier 21 that amplifies the obtained signal charges. The amplifier 21 is connected to a signal processing circuit (not shown).
On the light receiving surface 10, the light receiving cells 12 as unit pixels are arranged in the horizontal direction every integer multiple of one pixel (every three pixels in the drawing), and shifted in the vertical direction by one pixel for each stage. Has been placed.
A region on the light receiving surface 10 excluding the light receiving cell 12 is constituted by a vertical transfer path 13, and the signal charge generated in the light receiving cell 12 is indicated by an arrow OP in the drawing._VForward in the direction of.
The vertical transfer path 13 has the same configuration as that of the light receiving cell 12, for example, and functions only for transfer by being shielded from light. Therefore, the light receiving surface 10 of the TDI sensor is 1 on the light receiving surface of the conventional interline transfer type or frame transfer type CCD in an integer multiple of one pixel in the horizontal direction and one step in the vertical direction. It can be configured by providing a light shielding film that is opened by shifting pixels.
[0005]
The operation of the TDI sensor will be described. As shown in FIG. 18A, when imaging the subject A, the subject A is placed on the stage and moved in a predetermined direction at a constant speed. At this time, the signal charge is transferred on the light receiving surface 10 in synchronization with the moving speed of the stage.
That is, when the subject A moves across the light receiving surface 10, a signal charge for the subject A is generated in the light receiving cell C1, and the obtained signal charge is indicated by an arrow OP._VWhen it reaches the light receiving cell C2, it is added to the signal charge of that portion.
The obtained signal charge is indicated by an arrow OP until the next vertical transfer._HAre transferred in the horizontal direction and taken out as an image signal through an amplifier. By repeating the above operation, continuous images can be taken.
[0006]
Accordingly, as shown in FIG. 18 (b), the signal charge is added to the charge of that portion every time it reaches the light receiving cell. Since this charge transfer is linked with the operation of the stage, images of the same subject portion are always added.
That is, the moving speed OP of the subject A_AAnd the vertical transfer speed OP of the signal charge A 'with respect to the subject A_VAre synchronized so that the subject A can be subjected to multiple exposure imaging.
[0007]
The TDI sensor can be configured by either an interline transfer type or a frame transfer type CCD, but the frame transfer type is more suitable for operation. In the case of the interline transfer method, the charge transfer from the light receiving portion (opening) to the transfer path and the charge transfer in the transfer path require different levels of clock voltage, which complicates the drive system and timing. Become. For this reason, the frame transfer system is advantageous in terms of structure.
[0008]
[Problems to be solved by the invention]
However, in the above-mentioned TDI sensor, it is necessary to complete horizontal transfer after performing vertical transfer once on the light receiving surface and before performing the next vertical transfer. There was a problem that the operating speed of the entire sensor had to be limited.
For example, when the vertical transfer is operated at 200 KHz, the horizontal transfer needs to be completed within 5 μsec. At this time, if the CCD has 2000 pixels horizontally and the duty is 50%, high-speed horizontal transfer of 800 MHz is required.
[0009]
In order to increase the horizontal transfer speed, for example, as shown in FIG. 19A, there is a method of providing a plurality of sets (two sets in the drawing) of horizontal transfer units 20, 20 'and amplifiers 21, 21'. By providing n sets of horizontal transfer units and amplifiers, the transfer rate of the entire horizontal transfer unit can be increased n times.
However, in this case, the pitch of the transfer cell of the horizontal transfer unit becomes n times longer. For example, when the configuration of the light receiving surface is 1000 horizontal pixels and 10 μm pitch, if two horizontal transfer units and an amplifier are provided as shown in FIG. 19A, 500 pixels per horizontal transfer unit and 20 μm pitch are provided. It becomes. When 10 sets of horizontal transfer units and amplifiers are provided, the horizontal transfer units have a pitch of 100 μm, and it is practically impossible to transfer data using transfer cells having a pitch of 100 μm. As described above, high-speed transfer becomes more difficult as the cell length becomes longer, and it is difficult to greatly increase the speed by this method.
[0010]
Further, for example, as shown in FIG. 19B, a method of forming n horizontal transfer units and amplifiers by dividing one horizontal transfer unit 20 into n parts and providing an amplifier 21 for each can be considered. Even by this method, the transfer rate of the entire horizontal transfer unit can be increased n times.
However, in the above method, there is no place for the amplifier, and it is difficult to divide the horizontal transfer unit into n groups.
[0011]
Increasing the horizontal transfer speed as described above is desired to be realized as a solid-state imaging device such as a CCD other than the TDI sensor in order to drive at high speed.
[0012]
The present invention has been made in view of the above problems, and an object of the present invention is to provide a solid-state imaging device such as a CCD capable of increasing the horizontal transfer speed.
[0013]
[Means for Solving the Problems]
In order to achieve the above object, a solid-state imaging device according to the present invention includes a light receiving surface in which a plurality of light receiving cells that generate signal charges corresponding to the amount of light to be absorbed are integrated, and a signal transferred from the light receiving surface. A first transfer unit that divides the charge into a plurality of regions and vertically transfers the region in a predetermined direction while narrowing the exclusive width of the region; and the divided signal charges transferred from the first transfer unit A second transfer unit that horizontally transfers the data in a predetermined direction for each region, and an amplifier that amplifies the signal charge transferred from the second transfer unit.
[0014]
In the solid-state imaging device of the present invention, preferably, the light receiving cells are discretely arranged at a predetermined distance on the light receiving surface, and the light receiving cells are disposed in a region excluding the light receiving cells on the light receiving surface. A third transfer unit that vertically transfers signal charges generated in the cells in a predetermined direction is formed, and the first transfer unit divides the signal charges transferred from the third transfer unit into a plurality of regions. Then, by narrowing the distance corresponding to the width of the light receiving cell on the most downstream side of the light receiving surface, the vertical transfer is performed in a predetermined direction while narrowing the exclusive width of the region.
[0015]
In the solid-state imaging device of the present invention, preferably, the first transfer unit transfers the first transfer path for transferring in the first direction and the second direction for transferring in the second direction different from the first direction. And is arranged so as to reduce the distance corresponding to the width of the light receiving cell on the most downstream side of the light receiving surface by a combination of the first transfer path and the second transfer path.
[0016]
In the solid-state imaging device according to the present invention, preferably, the first transfer unit includes a first transfer cell and a second transfer cell having a size different from that of the first transfer cell. According to the combination of the cell and the second transfer cell, the plurality of divided areas are arranged so as to be vertically transferred in a predetermined direction while narrowing the exclusive width.
[0017]
In the solid-state imaging device of the present invention described above, in the solid-state imaging device such as a CCD, the first transfer unit that connects the light receiving surface and the second transfer unit that performs horizontal transfer receives a plurality of signal charges transferred from the light receiving surface. It is arranged so as to perform vertical transfer in a predetermined direction while dividing the area and narrowing the exclusive width of the area.
Accordingly, a place where the amplifier is arranged in each of the divided second transfer units that perform horizontal transfer can be secured by the amount of narrowing of the width of each divided first transfer unit, and the horizontal position of a solid-state imaging device such as a CCD can be secured. The transfer speed can be increased.
[0018]
In order to achieve the above object, the solid-state imaging device of the present invention has a light receiving surface in which a plurality of light receiving cells that generate signal charges according to the amount of light to be absorbed are integrated and transferred from the light receiving surface. The signal charges are divided into a plurality of areas, and vertically transferred in a predetermined direction so that the vertical transfer distance monotonously changes from one end of the area in the horizontal direction to the other end. A first transfer unit, a second transfer unit that horizontally transfers a signal charge transferred from the first transfer unit in a predetermined direction for each of the plurality of divided areas, and a signal transferred from the second transfer unit And an amplifier for amplifying the electric charge.
[0019]
In the solid-state imaging device according to the present invention, preferably, the first transfer unit includes a first transfer cell and a second transfer cell having a size different from that of the first transfer cell. Depending on the combination of the cell and the second transfer cell, the transfer distance in the vertical direction monotonously changes from one horizontal end to the other end of the plurality of divided areas in a predetermined direction. Arranged for vertical transfer.
[0020]
In the solid-state imaging device of the present invention described above, in the solid-state imaging device such as a CCD, the first transfer unit that connects the light receiving surface and the second transfer unit that performs horizontal transfer receives a plurality of signal charges transferred from the light receiving surface. Divided for each area and arranged to perform vertical transfer in a predetermined direction so that the transfer distance in the vertical direction monotonously changes from one end of the area in the horizontal direction to the other end. Yes.
Therefore, the transfer direction of the second transfer unit that performs horizontal transfer can be shifted from the direction orthogonal to the vertical transfer direction of the first transfer unit, and thus the divided third transfer unit that performs horizontal transfer. Thus, it is possible to secure a place where an amplifier is disposed in each of them, and to increase the horizontal transfer speed of a solid-state imaging device such as a CCD.
[0021]
In order to achieve the above object, the solid-state imaging device of the present invention has a light receiving surface in which a plurality of light receiving cells that generate signal charges according to the amount of light to be absorbed are integrated and transferred from the light receiving surface. A transfer unit that divides the signal charge into a plurality of regions and horizontally transfers the signal charge in a predetermined direction while bending the transfer direction for each region, and an amplifier that amplifies the signal charge transferred from the transfer unit. .
[0022]
In the solid-state imaging device according to the present invention, preferably, the transfer unit includes a transfer cell that bends the transfer direction.
[0023]
In the solid-state imaging device of the present invention described above, in a solid-state imaging device such as a CCD, the transfer unit that performs horizontal transfer with the light receiving surface divides the signal charge transferred from the light receiving surface into a plurality of regions, and It is arranged to perform horizontal transfer in a predetermined direction while bending the transfer direction.
Therefore, it is possible to secure a place where the amplifier is disposed at the tip of the bent portion of the transfer unit that performs horizontal transfer, and it is possible to increase the horizontal transfer speed of a solid-state imaging device such as a CCD.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
[0025]
First embodiment
FIG. 1 is a plan view of a solid-state imaging device (CCD (Charge Coupled Device)) functioning as a TDI (time delay integration) sensor according to the present embodiment.
It has a photodiode structure and photoelectrically converts the generated signal charge in a predetermined direction (arrow OP on the drawing)._VA light receiving surface 10 that vertically transfers the signal charge from the light receiving surface 10, a vertical transfer portion 11 that vertically transfers the signal charge from the light receiving surface 10, and a horizontal transfer portion 20 that horizontally transfers the signal charge from the vertical transfer portion 11. And an amplifier 21 that amplifies the signal charge. The amplifier 21 is connected to a signal processing circuit (not shown).
In the present embodiment, the vertical transfer unit 11 divides the signal charge transferred from the light receiving surface into a plurality of regions, and performs vertical transfer in a predetermined direction while narrowing the width of the region. It is possible to increase the horizontal transfer speed by providing a plurality of horizontal transfer units 20 and a plurality of amplifiers 21 in the vertical transfer unit 11 divided for each area.
On the light receiving surface 10 described above, four light receiving cells 12 serving as unit pixels are arranged in a set of four arranged in a horizontal direction and two in a vertical direction, every integer multiple of one pixel (on the drawing, every four pixels in the drawing). ) In the horizontal direction, and in the vertical direction are shifted by one pixel at positions spaced apart by a predetermined number of rows (for example, 10 rows).
The region on the light receiving surface 10 excluding the light receiving cell 12 is constituted by a vertical transfer path 13, and the signal charge generated in the light receiving cell 12 as an entire light receiving surface 10 is indicated by an arrow OP in the drawing._VForward in the direction of.
[0026]
FIG. 2 shows an enlarged plan view of a part of the light receiving cell 12 and the vertical transfer path 13 of the CCD.
The light receiving cells 12 are arranged by shifting one pixel at a time at a predetermined number of rows (for example, 10 rows) in the vertical direction, with the four separated by the channel stop 14 as one set. In this manner, the arrangement of shifting the light receiving cell set downstream in the transfer direction by one light receiving cell from the immediately upstream light receiving cell set is repeated.
Accordingly, the four light receiving cells C1, C2, C3, and C4 in the figure are at the same position in the horizontal direction, and each image the same portion of the subject.
[0027]
In the vertical transfer path 13, one transfer cell is formed from the three phases of the first phase 13a, the second phase 13b, and the third phase 13c, and this transfer cell is indicated by an arrow OP._VAre repeatedly arranged in substantially the same direction.
The vertical transfer path 13 further has an arrow OP._VAn oblique vertical transfer path 13 ′ extending in an oblique direction different from the above direction is formed, and a transfer cell formed of three phases of a first phase 13a ′, a second phase 13b ′, and a third phase 13c ′ is formed. Arrow OP_VAre arranged repeatedly diagonally.
[0028]
In the above-described CCD layout, in order to design the light receiving cell 12 region as a 100% virtual gate region, an arrow OP is provided in the vertical transfer path 13._VAn obliquely extending vertical transfer path 13 'extending in an oblique direction different from the above direction is required.
In the layout in which the size of the light receiving cell 12 is X μm and the light receiving cell 12 is provided for every n columns, the gate pitch of the vertical transfer unit is (n columns−2 pixels) X / n columns.
For example, when X = 8 μm and the light receiving cells 12 are provided for every n columns, the gate pitch of the vertical transfer unit is 6.4 μm.
In addition, for confocal microscope use, a light receiving cell set including four light receiving cells as a set is shifted by one pixel at a position separated by a predetermined number of rows (for example, 10 rows) in the vertical direction. . Since the vertical transfer path 13 is aligned with the light receiving cells in the same column, the transfer direction is indicated by an arrow OP in the figure._VIs exactly the same direction as the arrow OP between the light receiving cells in the same column (for example, 10 rows)._VThe amount of shift in each row is X / (n columns / 2 pixels) / (m rows-2 pixels), where n = m = 10 and X = 8 μm Is 0.2 μm.
[0029]
The operation as the TDI sensor will be described.
For example, the subject is placed on the stage and moved in a predetermined direction at a constant speed, and on the light receiving surface, signal charges are transferred in synchronization with the moving speed of the stage.
That is, when the subject moves across the light receiving surface 10, a signal charge for the subject is generated in the light receiving cell C1, and the obtained signal charge is the arrow OP of the light receiving cell C1._VIs transferred to the vertical transfer path 13 from one direction orthogonal to the direction of_VIs transferred vertically in the direction of.
Next, when the subject is in the same set as the light receiving cell C1 and moves to the light receiving cell C2 adjacent to the light receiving cell C1 in the vertical direction, a signal charge for the subject is generated in the light receiving cell C2, and the obtained signal charge is obtained. Is the arrow OP of the light receiving cell C2._VThe signal charges are transferred to the vertical transfer path 13 from one direction orthogonal to the direction, and are added to the signal charges transferred from the light receiving cell C1 in synchronization with the movement of the subject.
Next, the signal charge is transferred by the oblique vertical transfer path 13 'to the arrow OP._VIs transferred in a direction having an angle with respect to the arrow OP again_VIs transferred by a vertical transfer path 13 extending in the direction of.
Next, signal charges for the subject are generated in the light receiving cells C3 and C4 of the light receiving cell set formed immediately downstream in the transfer direction with respect to the light receiving cell set of the light receiving cells C1 and C2, respectively. Arrow OP of cells C3 and C4_VIs transferred to the vertical transfer path 13 from the other direction orthogonal to this direction, and is added to the signal charges transferred from the light receiving cells C1 and C2 in synchronization with the movement of the subject.
The above operation is repeated until the vertical transfer unit 11 is reached, and the obtained signal charges are further vertically transferred by the vertical transfer unit 11 divided into a plurality of regions. The signal charge that has reached the horizontal transfer unit 20 is transferred in the horizontal direction until the next vertical transfer for each divided area, and is taken out as an image signal via the amplifier 21.
By repeating the above operation, continuous images can be taken.
[0030]
FIG. 3A is an enlarged view of a region B in FIG.
Formed by connecting the light receiving cell 12 separated by the channel stop 14 to the vertical transfer path 13 in which one transfer cell is formed from the three phases of the first phase 13a, the second phase 13b, and the third phase 13c. Has been.
Here, the light receiving cell 12 and the second phase 13b are connected with a width L.
[0031]
3B is a cross-sectional view taken along line X-X ′ in FIG. 3A, and FIG. 3C is a cross-sectional view taken along line Y-Y ′ in FIG.
An n-type semiconductor layer 31 made of silicon containing an n-type conductive impurity is formed in a region separated by the p-type element isolation layer 32 of the p-type semiconductor substrate 30 made of single crystal silicon, and an upper layer thereof is formed thereon. For example, a silicon oxide gate insulating film 40 is formed.
A first gate electrode 41 made of polysilicon, for example, is formed on the upper layer of the gate insulating film 40 in the region of the first phase 13a in the plan view. The first gate electrode 41 made of silicon oxide covers the first gate electrode. A covering film 42 is formed. A second gate electrode 43 is formed in the third phase 13c region in the plan view.
In the n-type semiconductor layer 31 below the first gate electrode 41 and the second gate electrode 43, a first n-type impurity high concentration region 33, which is a high concentration region of n-type conductive impurities, is formed. The region where the first gate electrode 41 is formed, that is, the first phase 13a becomes the first polywell PW1, and the region where the third gate electrode 43 is formed, that is, the third phase 13c becomes the second polywell PW2.
In the second phase 13b region, which is the gap between the first and second gate electrodes 41 and 43, a p-type first inversion layer 35 containing a p-type conductive impurity is formed in the n-type semiconductor layer 31. In the light receiving cell 12 region, a p-type second inversion layer 36 containing a higher concentration of p-type conductive impurities than the p-type first inversion layer 35 is formed.
Further, in the semiconductor layer 31 below the p-type first inversion layer 35 and the p-type second inversion layer 36, a second n-type impurity high-concentration region 34, which is a high-concentration region of n-type conductive impurities, is formed. And constitutes a virtual gate region. The region where the p-type first inversion layer 35 is formed, that is, the second phase 13b becomes the virtual well VW, and the region where the p-type second inversion layer 36 is formed, that is, the light receiving cell 12 region becomes the virtual barrier VB. .
[0032]
In the above configuration, it is preferable to provide a drain electrode (not shown) in a region adjacent to the light receiving cell 12 region. The drain electrode has a function of suppressing blooming and clearing a dark current generated during the standby time.
[0033]
In the transfer cell including the first phase 13a, the second phase 13b, and the third phase 13c, a predetermined clock voltage P1 is applied to the first gate electrode 41 formed in the upper layer of the first phase 13a. On the other hand, a voltage P2 of a clock different from the voltage P1 is applied to the second gate electrode 43 formed in the upper layer of the third phase 13c.
A gate electrode is not formed on the second phase 13b and the light receiving cell 12 region, and a virtual gate structure is obtained in which it can be considered that a gate to which a constant voltage is applied is formed.
[0034]
A method of transferring potentials and signal charges at the respective parts PW1, VW, PW2, and VB in the CCD will be described.
FIG. 4 is a potential diagram of the CCD. Here, each part of PW1, VW, and PW2, which are potentials continuous in one direction, is indicated by a solid line, and a potential of VB (light receiving cell) connected to VW is indicated by a wavy line.
The first gate electrode 41 and the second gate electrode 43 of each cell are supplied with different clock voltage pulses (high (High) and low (Low)), respectively, and PW1 and PW2 correspond to PWL and PWH respectively. Takes 2 levels.
On the other hand, in the virtual gate region, the p-type first inversion layer 35 and the p-type second inversion layer 36 are not affected by the adjacent gate electrodes and have a constant potential.
First, as shown in FIG. 4A, when the signal charges are transferred, if PW1, PW2 = PWL, VW becomes the lowest level, and the signal electrons generated in VB (light receiving cell) are transferred to VW.
Next, as shown in FIG. 4B, when PW1 = PWL and PW2 = PWH, signal charges are transferred from VW to PW2, which is the lowest level.
Next, as shown in FIG. 4C, when PW1, PW2 = PWH, PW1 of the adjacent transfer cell is at the same lowest level as PW2, and the signal charge is transferred to PW1 of the adjacent transfer cell. .
Next, as shown in FIG. 4D, when PW1 = PWH and PW2 = PWL, signal charges are transferred from PW2 to PW1 of the adjacent transfer cell that is at the lowest level. At this time, all signal charges have been transferred to adjacent transfer cells, and thereafter transfer is performed in adjacent transfer cells.
Next, as shown in FIG. 4E, when PW1, PW2 = PWL, the signal charge is transferred from PW1 to VW which is the lowest level.
By repeating the above steps, signal charges are transferred from one transfer cell to an adjacent transfer cell. In addition, the signal charge newly generated in the light receiving cell at each time point is immediately transferred to VW, and when there is a potential lower than VW, it is quickly transferred to a lower level, and the signal transferred earlier. It is added to the charge.
Although the above transfer method is like the interline transfer system in terms of the arrangement of the light receiving cells and the vertical transfer unit, the actual charge transfer operation can be performed in the same manner as the frame transfer system. The potential design of each part of PW1, VW, PW2, and VB can be the same as that of a conventionally known virtual gate structure CCD.
[0035]
An enlarged view of the vicinity of the vertical transfer unit 11 is shown in FIG.
On the light receiving surface 10, a set of four light receiving cells are arranged at a predetermined distance, and a vertical transfer path 13 is formed in the gap portion. Even on the most downstream side of the light receiving surface 10, four light receiving cells 12 are arranged.
Connected to the vertical transfer path 13 of the light receiving surface 10, a vertical transfer unit 11 composed of, for example, about 30 transfer cells is formed. In the entire vertical transfer unit 11, signal charges are transferred in a predetermined direction (arrow OP in the drawing)._VThe vertical transfer unit 11 uses the arrow OP._VThe first transfer path T that transfers in the direction of_vAnd arrow OP_VSecond transfer path T for transferring in an oblique direction with respect to_aAnd the first transfer path T_vAnd the second transfer path T_aAre arranged so as to reduce the distance corresponding to the width of the light receiving cell 12 on the most downstream side of the light receiving surface 10, thereby narrowing the exclusive width of each of the divided areas of the vertical transfer unit 11. However, it is possible to perform vertical transfer in a predetermined direction.
A channel stop 14 or a field oxide film is formed in a region that does not contribute to transfer, which is a portion immediately below the light receiving cell 12 on the most downstream side of the light receiving surface 10.
A horizontal transfer unit 20 is formed in connection with the vertical transfer unit 11, and an amplifier 21 is provided at the transfer destination of the horizontal transfer unit 20.
[0036]
In FIG. 5, the arrow OP_VThe first transfer path T that transfers in the direction of_vAnd arrow OP_VSecond transfer path T for transferring in an oblique direction with respect to_aFIG. 6 shows an enlarged view of a region D in which are formed close to each other.
Arrow OP_VThe first transfer path T that transfers in the direction of_vThe normal transfer cell 11a is indicated by an arrow OP._VIt is arranged side by side.
On the other hand, the arrow OP_VSecond transfer path T for transferring in an oblique direction with respect to_aThe transfer cells 11a are arranged, for example, so as to shift a distance of about 10% of the length of one cell for each cell.
[0037]
In the above structure, signal charges are not directly transferred from the light receiving cells 12 in the vertical direction. Therefore, when the horizontal transfer unit 20 is formed immediately below the light receiving surface 10, for example, every 10 cells using 8 μm cells. In the case of the light receiving cell array configuration, the signal charge of 16 μm is eliminated for every 80 μm of cells. In this way, there is no signal charge for every certain number of cells, which causes inconvenience as an image signal.
However, in this embodiment, a vertical transfer unit that vertically transfers in a predetermined direction while narrowing a distance corresponding to the width of the light receiving cell on the most downstream side of the light receiving surface 10 between the light receiving surface 10 and the horizontal transfer unit 20. 11 is formed, the above-mentioned inconvenience does not occur in the signal charge taken out from the horizontal transfer unit 20.
[0038]
According to the CCD of this embodiment, the vertical transfer unit 11 performs vertical transfer in a predetermined direction while narrowing the distance corresponding to the width of the light receiving cell on the most downstream side of the light receiving surface 10, so that the division is performed for horizontal transfer. Thus, it is possible to secure a place where the amplifier 21 is disposed in each of the horizontal transfer units 20 and to increase the horizontal transfer speed of a solid-state imaging device such as a CCD.
[0039]
In the present embodiment, the first transfer path T_vAnd the second transfer path T_aThere is no limitation on how to combine.
For example, as shown in FIG._vBy arrow OP_VAnd then the second transfer path T_aBy arrow OP_VIs transferred obliquely with respect to the direction of the first transfer path T_vBy arrow OP_VIt is also possible to adopt a configuration in which data is transferred in the direction.
[0040]
Second embodiment
FIG. 8 is a plan view of the solid-state imaging device (CCD) according to the present embodiment.
Unlike the first embodiment, the CCD according to the present embodiment is not limited to the TDI sensor, and can be configured as a normal frame transfer type CCD.
[0041]
It has a photodiode structure and photoelectrically converts the generated signal charge in a predetermined direction (arrow OP on the drawing)._VA light receiving surface 10 that vertically transfers the signal charge from the light receiving surface 10, a vertical transfer portion 11 that vertically transfers the signal charge from the light receiving surface 10, and a horizontal transfer portion 20 that horizontally transfers the signal charge from the vertical transfer portion 11. And an amplifier 21 that amplifies the signal charge. The amplifier 21 is connected to a signal processing circuit (not shown).
On the light receiving surface 10, for example, light receiving cells serving as unit pixels having a transfer function are arranged and arranged, and the signal charge generated in the light receiving cells as an entire light receiving surface 10 is indicated by an arrow OP in the drawing._VForward in the direction of.
[0042]
Connected to the light receiving surface 10, a vertical transfer unit 11 composed of, for example, about 30 transfer cells is formed. In the entire vertical transfer unit 11, signal charges are transferred in a predetermined direction (arrow OP in the drawing)._VThe vertical transfer unit 11 uses the arrow OP._VThe first transfer path T that transfers in the direction of_vAnd arrow OP_VSecond transfer path T for transferring in an oblique direction with respect to_aAnd the first transfer path T_vAnd the second transfer path T_aWith this combination, the vertical transfer unit 11 is arranged to perform vertical transfer in a predetermined direction while narrowing the width of each divided area.
A plurality of horizontal transfer units 20 and a plurality of amplifiers 21 are provided in connection with the vertical transfer unit 11 divided for each of the plurality of regions.
[0043]
In FIG. 8, the arrow OP_VThe first transfer path T that transfers in the direction of_vAnd arrow OP_VSecond transfer path T for transferring in an oblique direction with respect to_aFIG. 9 shows an enlarged view of the vertical transfer unit 11 composed of In order to simplify the explanation, the number of transfer cells is reduced to nine in the drawing.
Arrow OP_VThe first transfer path T that transfers in the direction of_vThe transfer cell 11a having a normal width is indicated by an arrow OP._VIt is arranged side by side.
On the other hand, the arrow OP_VSecond transfer path T for transferring in an oblique direction with respect to_aThe transfer cell 11b having a narrower width than the normal transfer cell 11a is arranged.
[0044]
According to the CCD of the present embodiment, the vertical transfer unit 11 performs vertical transfer in a predetermined direction while narrowing the width of each divided area, so the divided horizontal transfer unit 20 that performs horizontal transfer. Thus, it is possible to secure a place where the amplifier 21 is disposed, and it is possible to increase the horizontal transfer speed of a solid-state imaging device such as a CCD.
[0045]
In the present embodiment, the first transfer path T_vAnd the second transfer path T_aIt is also possible to change the size of the transfer cell.
As shown in FIG. 10, the arrow OP_VSecond transfer path T for transferring in an oblique direction with respect to_aIs constituted by a transfer cell 11a having a normal width, and an arrow OP_VThe first transfer path T that transfers in the direction of_vCan be constituted by the transfer cell 11b having a width narrower than that of the normal transfer cell 11a.
[0046]
The CCD of this embodiment can be applied to a CCD that functions as a TDI sensor.
In this case, on the light receiving surface, as in the first embodiment, for example, four light receiving cells are arranged with a predetermined distance apart from each other, and even on the most downstream side of the light receiving surface, A light receiving cell set is arranged. Here, since the signal charge is not directly transferred from the light receiving cell in the vertical direction, the width is further reduced while reducing the distance corresponding to the width of the light receiving cell on the most downstream side of the light receiving surface as in the first embodiment. It is preferable that the vertical transfer unit be arranged so as to narrow the exclusive width of each of the divided areas using different transfer cells.
[0047]
Third embodiment
FIG. 11 is a plan view of the solid-state imaging device (CCD) according to the present embodiment.
Unlike the first embodiment, the CCD according to the present embodiment is not limited to the TDI sensor, and can be configured as a normal frame transfer type CCD.
[0048]
It has a photodiode structure and photoelectrically converts the generated signal charge in a predetermined direction (arrow OP on the drawing)._VA light receiving surface 10 that vertically transfers the signal charge from the light receiving surface 10, a vertical transfer portion 11 that vertically transfers the signal charge from the light receiving surface 10, and a horizontal transfer portion 20 that horizontally transfers the signal charge from the vertical transfer portion 11. And an amplifier 21 that amplifies the signal charge. The amplifier 21 is connected to a signal processing circuit (not shown).
On the light receiving surface 10, for example, light receiving cells serving as unit pixels having a transfer function are arranged and arranged, and the signal charge generated in the light receiving cells as an entire light receiving surface 10 is indicated by an arrow OP in the drawing._VForward in the direction of.
[0049]
Connected to the light receiving surface 10, a vertical transfer unit 11 composed of, for example, about 30 transfer cells is formed.
The vertical transfer unit 11 divides the signal charge transferred from the light receiving surface 10 into a plurality of areas, and the transfer distance in the vertical direction is monotonous from one end in the horizontal direction to the other end of the area. The vertical transfer is performed in a predetermined direction so as to change.
A plurality of horizontal transfer units 20 and a plurality of amplifiers 21 are provided in connection with the vertical transfer unit 11 divided for each of the plurality of regions.
[0050]
In FIG. 11, the vertical transfer unit is divided into a plurality of regions and arranged so that the transfer distance in the vertical direction monotonously changes from one end in the horizontal direction to the other end in each region. An enlarged view of 11 is shown in FIG. In order to simplify the explanation, the number of transfer cells is reduced to 7 in the drawing.
Arrow OP_VThe vertical transfer unit 11 for transferring in the direction of the above is configured by combining a transfer cell 11a having a normal cell size and a transfer cell 11b having a cell size larger in the transfer direction than the transfer cell 11a.
Here, all the transfer cells at one end in the horizontal direction for each region of the vertical transfer unit 11 are configured using transfer cells 11a having a normal cell size, and the transfer cell 11a is directed toward the other end. Are transferred one by one to the transfer cell 11b whose cell size is enlarged in the transfer direction, so that the transfer distance in the vertical direction monotonously changes from one end in the horizontal direction to the other end. Is arranged.
[0051]
FIG. 13 shows an enlarged view of the transfer cell 11a having the normal cell size and the transfer cell 11b having the cell size enlarged in the transfer direction.
The transfer cell 11a is, for example, a polybarrier PB (L_PB), Polywell PW (L_PW), Virtual barrier VB (L_VB), Virtual well VW (L_VW). The parentheses above indicate the width in the transfer direction. The total of these four phases has a cell size of 8 μm, for example.
The transfer cell 11b is, for example, a polybarrier PB (L_PB), Polywell PW (L_PW′), Virtual barrier VB (L_VB), Virtual well VW (L_VW′). The parentheses above indicate the width in the transfer direction. That is, the width of the poly barrier PB and the virtual barrier VB is the same as that of the transfer cell 11a, and the width of the poly well PW and the virtual well VW is expanded in the transfer direction by, for example, 0.4 μm, respectively. The cell size is about 10% larger than the cell 11a in the transfer direction.
[0052]
According to the CCD of the present embodiment, the vertical transfer unit 11 monotonously changes the transfer distance in the vertical direction from one end in the horizontal direction to the other end in each of the divided areas. Since the vertical transfer is performed in a predetermined direction, it is possible to secure a place where the amplifier 21 is disposed in each of the divided horizontal transfer units 20 that perform the horizontal transfer, and the horizontal transfer speed of a solid-state imaging device such as a CCD can be secured. Can be increased.
[0053]
In this embodiment, when applied to a CCD functioning as a TDI sensor, for example, it can be realized by the configuration shown in FIG.
On the light receiving surface 10, as in the first embodiment, for example, four light receiving cells are arranged at a predetermined distance apart from each other, and the light receiving cell set is also located on the most downstream side of the light receiving surface. Has been placed. A vertical transfer path 13 is placed in the gap between the light receiving cells 12.
Here, since the signal charge is not directly transferred from the light receiving cell in the vertical direction, when the signal is read by horizontal transfer, in order to prevent the signal charge from being lost for every certain number of cells, It is preferable to provide a sub-vertical transfer unit 11 ′ that corrects a distance corresponding to the width of the light receiving cell on the most downstream side of the light receiving surface between the vertical transfer units 11.
In the sub-vertical transfer unit 11 ′, a distance corresponding to the width of the light receiving cell on the most downstream side of the light receiving surface is corrected by a combination of transfer cells 11a ′ and 11b ′ having different widths, and a signal is transmitted by horizontal transfer. It is possible to prevent the signal charge from being lost every certain number of cells when read out.
With respect to the sub-vertical transfer unit 11 ', the vertical transfer distance is monotonously changed from one end in the horizontal direction to the other end by being divided into a plurality of regions according to the present embodiment. The vertical transfer units 11 arranged in this way are connected, and a plurality of horizontal transfer units 20 and a plurality of amplifiers 21 are provided.
[0054]
Fourth embodiment
FIG. 15A is a plan view of a solid-state imaging device (CCD) according to the present embodiment. Unlike the first embodiment, the CCD according to the present embodiment is not limited to the TDI sensor, and can be configured as a normal frame transfer type CCD.
[0055]
It has a photodiode structure and photoelectrically converts the generated signal charge in a predetermined direction (arrow OP on the drawing)._VA light receiving surface 10 that vertically transfers the signal charge from the light receiving surface 10, a vertical transfer portion 11 that vertically transfers the signal charge from the light receiving surface 10, and a horizontal transfer portion 20 that horizontally transfers the signal charge from the vertical transfer portion 11. And an amplifier 21 that amplifies the signal charge. The amplifier 21 is connected to a signal processing circuit (not shown).
On the light receiving surface 10, for example, light receiving cells serving as unit pixels having a transfer function are arranged and arranged, and the signal charge generated in the light receiving cells as an entire light receiving surface 10 is indicated by an arrow OP in the drawing._VForward in the direction of.
[0056]
A horizontal transfer unit 20 is provided which is connected to the light receiving surface 10 and is divided into a plurality of regions and horizontally transferred in a predetermined direction while the transfer direction is bent at the bent portion C for each region.
An amplifier 21 is provided at the tip of the horizontal transfer unit 20 divided into each region.
[0057]
FIG. 15B is an enlarged view of a region near the bent portion C in the horizontal transfer unit 20.
Transfer gate G and well W are indicated by arrow OP_HIn the well W arranged in the bent portion C, the signal charge transfer direction is bent by 90 °. Thereafter, the transfer gate G and the well W are again indicated by the arrow OP._HThe arrow OP is the direction orthogonal to_VIt is repeatedly arranged in the direction of.
In the well W arranged in the bent portion C, in order to transfer the signal charge smoothly, the horizontal width L_HAnd vertical width L_VIs preferably set as close as possible.
[0058]
According to the CCD of this embodiment, the horizontal transfer unit is divided into a plurality of regions, and is arranged so as to transfer in a predetermined direction while bending the transfer direction at the bent portion C for each region. A place where the amplifier 21 is disposed in each of the divided horizontal transfer units 20 can be secured, and the horizontal transfer speed of a solid-state imaging device such as a CCD can be increased.
[0059]
The present invention is not limited to the above embodiment. For example, when a transfer cell having a plurality of widths and lengths is used, the difference between the widths and lengths can be selected according to the design.
In addition, the number of light receiving cells constituting one set of light receiving cell sets and the arrangement with respect to the vertical transfer unit can be appropriately selected.
Furthermore, it is possible to select the number of transfer cell phases constituting the vertical transfer unit as required.
In addition, various changes can be made without departing from the scope of the present invention.
[0060]
【The invention's effect】
According to the solid-state imaging device of the present invention, it is possible to provide a solid-state imaging device such as a CCD capable of increasing the horizontal transfer rate.
[Brief description of the drawings]
FIG. 1 is a plan view of a CCD according to a first embodiment of the present invention.
FIG. 2 is an enlarged plan view of a part of a light receiving cell and a vertical transfer path of a CCD according to the first embodiment.
3A is an enlarged plan view of a region B in FIG. 2, FIG. 3B is a cross-sectional view taken along line XX ′ in FIG. 3A, and FIG. 3C is YY in FIG. FIG.
FIG. 4 is a potential diagram for explaining signal charge transfer of the CCD according to the first embodiment;
FIG. 5 is a plan view showing a configuration of a vertical transfer unit.
FIG. 6 is an enlarged plan view showing a detailed configuration of a vertical transfer unit.
FIG. 7 is a plan view showing another configuration of the vertical transfer unit.
FIG. 8 is a plan view of a CCD according to a second embodiment of the present invention.
FIG. 9 is an enlarged plan view showing a detailed configuration of a vertical transfer unit of a CCD according to the second embodiment.
FIG. 10 is an enlarged plan view showing another detailed configuration of the vertical transfer unit of the CCD according to the second embodiment.
FIG. 11 is a plan view of a CCD according to a third embodiment of the present invention.
FIG. 12 is an enlarged plan view showing a detailed configuration of a vertical transfer unit of a CCD according to a third embodiment.
FIG. 13 is a plan view of a transfer cell used in a vertical transfer unit of a CCD according to a third embodiment.
FIG. 14 is an enlarged plan view showing another detailed configuration of the vertical transfer unit of the CCD according to the second embodiment.
FIG. 15A is a plan view of a CCD according to a third embodiment of the present invention, and FIG. 15B is an enlarged plan view showing a detailed configuration of a horizontal transfer unit.
16A is a plan view of a CCD according to a first conventional example, and FIG. 16B is a plan view of a light receiving cell.
FIG. 17A is a plan view of a CCD according to a second conventional example, and FIG. 17B is a plan view of a light receiving cell.
FIG. 18A is a plan view of a CCD according to a third conventional example, and FIG. 18B is a schematic diagram for explaining the operation.
19A is a plan view of a CCD according to a fourth conventional example, and FIG. 19B is a plan view of a CCD according to a fifth conventional example.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... Light-receiving surface, 11 ... Vertical transfer part, 12 ... Light receiving cell, 13 ... Vertical transfer part, 13 '... Oblique vertical transfer part, 14 ... Channel stop, 20 ... Horizontal transfer part, 21 ... Amplifier, 30 ... P-type Semiconductor substrate 31 ... n-type semiconductor layer 32 ... p-type element isolation layer 33 ... first n-type impurity high concentration region 34 ... second n-type impurity high concentration region 35 ... p-type first inversion layer 36 ... p Type second inversion layer, 40 ... gate insulating film, 41 ... first gate electrode, 42 ... gate electrode coating film, 43 ... second gate electrode, A ... subject, C1-C4 ... light receiving cell.

Claims (3)

A light receiving surface on which a plurality of light receiving cells that generate signal charges according to the amount of light to be absorbed are integrated;
A first transfer unit that divides the signal charge transferred from the light receiving surface into a plurality of regions and vertically transfers the signals in a predetermined direction while narrowing the width of the region;
A second transfer unit that horizontally transfers the signal charges transferred from the first transfer unit in a predetermined direction for each of the plurality of divided regions;
Possess an amplifier for amplifying the signal charge transferred from the second transfer unit,
The first transfer unit includes a first transfer cell and a second transfer cell having a size different from that of the first transfer cell;
A solid-state imaging device arranged so as to perform vertical transfer in a predetermined direction while narrowing a width occupied by the plurality of divided regions by a combination of the first transfer cell and the second transfer cell . A light receiving surface on which a plurality of light receiving cells that generate signal charges according to the amount of light to be absorbed are integrated;
The signal charge transferred from the light receiving surface is divided into a plurality of regions, and the vertical transfer distance is monotonously changed from one horizontal end to the other end of the region. A first transfer unit that performs vertical transfer in the direction of
A second transfer unit that horizontally transfers the signal charges transferred from the first transfer unit in a predetermined direction for each of the plurality of divided regions;
A solid-state imaging device comprising: an amplifier that amplifies the signal charge transferred from the second transfer unit. The first transfer unit includes a first transfer cell and a second transfer cell having a size different from that of the first transfer cell;
The combination of the first transfer cell and the second transfer cell is such that the vertical transfer distance monotonously changes from one horizontal end to the other end of the plurality of divided areas. The solid-state imaging device according to claim 2, wherein the solid-state imaging device is arranged to vertically transfer in a predetermined direction.

Images