JP4269431B2 - Solid-state imaging device, driving method thereof, and image input device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a solid-state imaging device, a driving method thereof, and an image input device that alternately transfer and output charges taken in a plurality of columns or transfer and output only a single column of charges.
[0002]
[Prior art]
In an image input device applied to a scanner, a copying machine, and the like, a solid-state imaging device including a linear sensor is used, and an image is input by scanning a reading position by the solid-state imaging device.
[0003]
In recent years, there has been a strong demand for improvement in reading resolution and reduction in reading speed, and a linear sensor that uses a plurality of sensor arrays has been developed. FIG. 5 is a schematic diagram for explaining a conventional solid-state imaging device, in which a plurality of sensor arrays are provided.
[0004]
That is, this solid-state imaging device includes a first light receiving pixel column 10 including pixels D1, D2,..., A second light receiving pixel column 20 including pixels D1 ′, D2 ′,. 10, the first charge transfer column 12 that transfers the charge captured by the second light receiving pixel column 20, the second charge transfer column 22 that transfers the charge captured by the second light receiving pixel column 20, the first charge transfer column 12 and the second charge transfer column 12. And a multiplexer unit 30 for alternately transferring the charges transferred by the charge transfer train 22. Further, an output gate 31, a floating diffusion amplifier 32, a reset gate 33 and a reset drain 34 are provided at the subsequent stage of the multiplexer unit 30.
[0005]
Among these, the pixels D1, D2,... Constituting the first light receiving pixel column 10 and the pixels D1 ′, D2 ′,. The resolution is improved as compared with the case of capturing in a single row.
[0006]
FIG. 6 is an operation timing chart in the conventional solid-state imaging device. Among these, φ1 and φ2 are alternately applied to the first charge transfer train 12 and the second charge transfer train 22 shown in FIG. Φ3 and φ4 are applied to the multiplex unit 30. Due to these φ 1 and φ 2, the charges are sequentially transferred alternately in the first charge transfer train 12 and the second charge transfer train 22, and the charges are alternately sent from the final stage of each transfer train to the multiplex unit 30. It is done. The charges sent to the multiplex unit 30 are sequentially sent to the floating diffusion amplifier 32 via the output gate 31 by φ3 and φ4 each having a frequency twice that of φ1 and φ2. _out It becomes. The reset pulse φRS is applied to the reset gate 33 in synchronization with the falling of φ3 and the rising of φ4, and the charge transferred to the floating diffusion amplifier 32 is discharged to the reset drain 34.
[0007]
By such an operation, the electric charge taken in by the first light receiving pixel column 10 and the electric charge taken in by the second light receiving pixel column 20 are alternately outputted to the output circuit as a predetermined voltage.
[0008]
[Problems to be solved by the invention]
However, such a solid-state imaging device has the following problems. In other words, although it is possible to improve the resolution by alternately reading the pixels captured by the plurality of light receiving pixel columns, the number of pixels to be read increases compared to the case of reading the pixels captured by the single light receiving pixel column. For this reason, there is a problem that the reading time becomes long and is not suitable for high-speed reading. In addition, if signal output is performed at the same speed as in the case of one light receiving pixel column, it is necessary to increase the charge transfer frequency, and the signal data area is shortened, making it difficult to handle external signal processing. End up.
[0009]
[Means for Solving the Problems]
The present invention is a solid-state imaging device, a driving method thereof, and an image input device, which have been made to solve such problems. That is, in the solid-state imaging device of the present invention, the first charge transfer column that sequentially transfers the charges captured by the first light receiving pixel column and the second charge that sequentially transfers the charges captured by the second light receiving pixel column. A transfer sequence, a final stage of the first charge transfer sequence, and a final stage of the second charge transfer sequence, In the case of the alternate output mode, each charge transferred in the first charge transfer column and the second charge transfer column is alternately transferred in the case of the single column output mode. Transfer the charges transferred in the first charge transfer train Multiplex and alternate output mode , Transfer potentials having opposite phases are applied to the final stage of the first charge transfer train and the final stage of the second charge transfer train, respectively, and in the single-column output mode, the transfer potential is applied to the final stage of the first charge transfer train. And a transfer potential generating means for supplying a constant potential to the final stage of the second charge transfer train.
[0010]
In the present invention, in the alternate output mode, the respective charges transferred in the first charge transfer train and the second charge transfer train are alternately transferred in the multiplex unit, and signals corresponding to the respective charges are transferred. Outputs can be obtained sequentially. In the single column output mode, the charges transferred in the second charge transfer column are stopped at the final stage, and are not transferred to the multiplex unit. That is, only the charges transferred by the first charge transfer train can be transferred by the multiplex unit, and only the output corresponding to the charges transferred by the first charge transfer train can be obtained.
[0011]
In the solid-state imaging device of the present invention, a first charge transfer column that sequentially transfers charges taken in by the first light receiving pixel row and a second charge that sequentially transfers charges taken in by the second light receiving pixel row. Each charge transferred adjacent to the transfer column and the last stage of the first charge transfer column and the last stage of the second charge transfer column and transferred in the first charge transfer column and the second charge transfer column A multiplex unit that alternately transfers, a charge-voltage conversion unit that is connected to the subsequent stage of the multiplex unit via an output gate, a reset drain that is connected to the charge-voltage conversion unit via a reset gate, and an alternate output mode In the case of the single column output mode, a signal for discharging each charge, which is alternately transferred in the multiplex part and converted into a voltage by the charge voltage conversion means, to the reset drain is given to the reset gate. The reset gate outputs a signal for discharging the charge transferred to the reset voltage drain in synchronization with the timing at which the charge transferred in the second charge transfer column is transferred to the charge-voltage conversion means. It is also provided with a potential generating means for applying to the voltage.
[0012]
In the present invention, in the alternate output mode, the respective charges transferred in the first charge transfer train and the second charge transfer train are alternately transferred in the multiplex section, and each charge voltage conversion means transfers each charge. Signal outputs corresponding to the charges can be obtained sequentially. In the single-column output mode, the charges transferred in the first charge transfer string and the second charge transfer string are alternately transferred in the multiplex unit and sequentially transferred to the charge voltage conversion unit. A signal is given to the reset gate in synchronization with the timing at which the charge transferred in the second charge transfer train is transferred to the charge voltage conversion means, and the charge is discharged to the reset drain. As a result, the charge voltage conversion means does not convert the charge transferred in the second charge transfer string into a voltage, but converts only the charge transferred in the first charge transfer string into a voltage. become. That is, it is possible to obtain only an output for the charges transferred by the first charge transfer train.
[0013]
In the solid-state imaging device driving method according to the present invention, the first charge transfer column that sequentially transfers charges taken in by the first light receiving pixel row and the first charge transfer that sequentially transfers charges taken in by the second light receiving pixel row. Two charge transfer columns, a final stage of the first charge transfer column, and a final stage of the second charge transfer column, Provided between charge voltage conversion means In a driving method of a solid-state imaging device including a multiplex unit, in an alternate output mode , In the case of single column output mode, transfer potentials having opposite phases are applied to the final stage of the first charge transfer string and the final stage of the second charge transfer string, In order to transfer each charge transferred in the first charge transfer train in the multiplex part, A transfer potential is applied to the final stage of the first charge transfer train and a constant potential is applied to the final stage of the second charge transfer train.
[0014]
In the present invention, in the alternate output mode, the respective charges transferred in the first charge transfer train and the second charge transfer train are alternately transferred in the multiplex unit, and signals corresponding to the respective charges are transferred. Outputs can be obtained sequentially. In the single column output mode, by applying a constant potential to the final stage of the second charge transfer column, the charges transferred in the second charge transfer column are stopped at the final stage. It is not transferred to the department. That is, only the charges transferred by the first charge transfer train can be transferred by the multiplex unit, and only the output corresponding to the charges transferred by the first charge transfer train can be obtained.
[0015]
In the solid-state imaging device driving method according to the present invention, the first charge transfer column that sequentially transfers charges taken in by the first light receiving pixel row and the first charge transfer that sequentially transfers charges taken in by the second light receiving pixel row. 2 charge transfer columns are connected adjacent to the last stage of the first charge transfer string and the last stage of the second charge transfer string, and transferred by the first charge transfer string and the second charge transfer string. A multiplex unit that alternately transfers each charge, a charge-voltage conversion unit connected to the subsequent stage of the multiplex unit via an output gate, and a reset drain connected to the charge-voltage conversion unit via a reset gate In the driving method of the solid-state imaging device provided, in the alternate output mode, a signal for transferring each charge after being alternately transferred by the multiplex unit and converted to a voltage by the charge voltage conversion means to the reset drain is sent to the reset drain. In the single-column output mode, in synchronization with the timing at which the charges transferred in the second charge transfer column among the charges transferred alternately in the multiplex unit are transferred to the charge voltage conversion means A signal for discharging the electric charge to the reset drain is also given to the reset gate.
[0016]
In the present invention, in the alternate output mode, the respective charges transferred in the first charge transfer train and the second charge transfer train are alternately transferred in the multiplex section, and each charge voltage conversion means transfers each charge. Signal outputs corresponding to the charges can be obtained sequentially. In the single-column output mode, the charges transferred in the first charge transfer string and the second charge transfer string are alternately transferred in the multiplex unit and sequentially transferred to the charge voltage conversion unit. A signal is given to the reset gate in synchronization with the timing at which the charge transferred in the second charge transfer train is transferred to the charge voltage conversion means, and the charge is discharged to the reset drain. As a result, the charge voltage conversion means does not convert the charge transferred in the second charge transfer string into a voltage, but converts only the charge transferred in the first charge transfer string into a voltage. become. That is, it is possible to obtain only an output for the charges transferred by the first charge transfer train.
[0017]
In the image input device of the present invention, a first charge transfer column that sequentially transfers charges taken in by the first light receiving pixel row and a second charge that sequentially transfers charges taken in by the second light receiving pixel row. A transfer sequence, a final stage of the first charge transfer sequence, and a final stage of the second charge transfer sequence, In the case of the alternate output mode, each charge transferred in the first charge transfer column and the second charge transfer column is alternately transferred in the case of the single column output mode. Transfer the charges transferred in the first charge transfer train Multiplex and alternate output mode , Transfer potentials having opposite phases are applied to the final stage of the first charge transfer train and the final stage of the second charge transfer train, respectively, and in the single-column output mode, the transfer potential is applied to the final stage of the first charge transfer train. And a solid-state imaging device that includes a potential generating means for applying a constant potential to the final stage of the second charge transfer train.
[0018]
In the present invention, in the alternate output mode, the respective charges transferred in the first charge transfer train and the second charge transfer train are alternately transferred in the multiplex unit, and the high charges corresponding to the respective charges are transferred. The resolution signal output can be obtained sequentially. In the single column output mode, the charges transferred in the second charge transfer column are stopped at the final stage, and are not transferred to the multiplex unit. That is, only the charges transferred by the first charge transfer train can be transferred by the multiplex unit, and only the output corresponding to the charges transferred by the first charge transfer train can be obtained at high speed.
[0019]
In the image input device of the present invention, a first charge transfer column that sequentially transfers charges taken in by the first light receiving pixel row and a second charge that sequentially transfers charges taken in by the second light receiving pixel row. Each charge transferred adjacent to the transfer column and the last stage of the first charge transfer column and the last stage of the second charge transfer column and transferred in the first charge transfer column and the second charge transfer column A multiplex unit that alternately transfers, a charge-voltage conversion unit that is connected to the subsequent stage of the multiplex unit via an output gate, a reset drain that is connected to the charge-voltage conversion unit via a reset gate, and an alternate output mode In the case of the single column output mode, a signal for discharging each charge, which is alternately transferred in the multiplex part and converted into a voltage by the charge voltage conversion means, to the reset drain is given to the reset gate. The reset gate outputs a signal for discharging the charge transferred to the reset voltage drain in synchronization with the timing at which the charge transferred in the second charge transfer column is transferred to the charge-voltage conversion means. In addition, a solid-state imaging device including a potential generating means for applying to the device is used.
[0020]
In the present invention, in the alternate output mode, the respective charges transferred in the first charge transfer train and the second charge transfer train are alternately transferred in the multiplex section, and each charge voltage conversion means transfers each charge. A high-resolution signal output corresponding to the charge can be sequentially obtained. In the single-column output mode, the charges transferred in the first charge transfer string and the second charge transfer string are alternately transferred in the multiplex unit and sequentially transferred to the charge voltage conversion unit. A signal is given to the reset gate in synchronization with the timing at which the charge transferred in the second charge transfer train is transferred to the charge voltage conversion means, and the charge is discharged to the reset drain. As a result, the charge voltage conversion means does not convert the charge transferred in the second charge transfer string into a voltage, but converts only the charge transferred in the first charge transfer string into a voltage. become. That is, only the output for the charges transferred in the first charge transfer train can be obtained at high speed.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the solid-state imaging device, the driving method thereof, and the image input device of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic diagram for explaining the solid-state imaging device of the present embodiment. That is, the solid-state imaging device includes the first sensor array 10 (pixel D ₁ ... D _n , S ₁ , S ₂ ... S _n , D _{n + 1} ... D _m ) And the second sensor row 20 and the two light receiving pixel rows (pixel D). ₁ ', ..., D _n ', S ₁ ', S ₂ '... S _n ', D _{n + 1} ', ..., D _m ') Is used to transfer the electric charge, and the first CC register 12 via the readout gate 11 parallel to the first sensor row 10 and the second CC via the readout gate 21 parallel to the second sensor row 20 are transferred. And a register 22. The first sensor array 10 and the second sensor array 20 are arranged in a state (staggered) that is shifted by a half pitch (1 / 2P) with respect to the pitch P of each pixel to obtain a high-resolution signal output. It can be done.
[0022]
Also, a multiplex unit 30 for transferring the respective charges transferred by the first CCD register 12 and the second CCD register 22 in accordance with the output mode, an output gate 31 connected to the subsequent stage of the multiplex unit 30, and a charge voltage conversion means A floating diffusion amplifier 32, a reset gate 33, and a reset drain 34. Further, a potential generator (not shown) for generating pulses to be supplied to the first CCD register 12 and the second CCD register 22, the multiplex unit 30, the output gate 31, and the reset gate 33 is also provided.
[0023]
Here, the output mode includes an alternate output mode and a single column output mode. In the alternate output mode, output signals corresponding to the charges taken in by the pixels of the first sensor array 10 and the second sensor array 20 are sequentially output from the floating diffusion amplifier 32 alternately. In the single array mode, the first sensor array 10 Only the output signal corresponding to the electric charge taken in each pixel is sequentially output from the floating diffusion amplifier 32.
[0024]
For example, when you want to obtain a high-resolution output signal, such as when capturing a fine image, operate in the alternate output mode, and when performing a pre-scan of image capture (reading that determines the image size, etc.) If you want to perform signal processing, operate in single-row output mode.
[0025]
FIG. 2 is a schematic diagram for explaining the vicinity of the multiplex unit in the solid-state imaging device of the present embodiment. Transfer pulses of φ1 and φ2 are alternately applied to the first CCD register 12 corresponding to the first sensor array 10, and the charges taken in by the first sensor array 10 are sequentially transferred in the direction of the multiplexing unit 30. . In addition, φ2 and φ1 that are opposite in phase to φ1 and φ2 applied to the first CCD register 12 are alternately applied to the second CCD register 22 corresponding to the second sensor row 20 and are captured by the second sensor row 20. The charges are sequentially transferred in the direction of the multiplex unit 30.
[0026]
Next, a method for driving the solid-state imaging device will be described. First, the case of the alternate output mode will be described. In the alternate output mode, transfer pulses φ 1 and φ 2 are applied to the first CCD register 12, and transfer pulses φ 2 and φ 1 are applied to the second CCD register 22. The same pulse as φ2 is applied as the pulse φ2 ′ applied to the final stage 12a of the first CCD register 12, and the same pulse as φ1 is applied as the pulse φ1 ′ applied to the final stage 22a of the second CCD register 22. To do. As a result, the charge taken in by the first sensor row 10 and the charge taken in by the second sensor row 20 by the first CCD register 12 and the second CCD register 22 are alternately transferred, and the charge is alternately transferred from each final stage to the multiplex unit 30. Forward.
[0027]
Clocks φ3 and φ4 having a frequency twice that of φ1 and φ2 are alternately applied to the multiplex unit 30. As a result, the charge of the first sensor array 10 and the charge of the second sensor array 20 that are alternately transferred to the first stage of the multiplex unit 30 are sequentially transferred toward the output gate 31. Then, each charge is sent to the floating diffusion amplifier 32 according to the timing of the pulse applied to the output gate 31, and is sent to the output circuit as a voltage corresponding to the amount of charge. Further, before the next charge is sent to the floating diffusion amplifier 32, a reset pulse φRS is applied to the reset gate 33, and the charge remaining in the floating diffusion amplifier 32 is discharged to the reset drain 34. As a result, signals corresponding to the charges taken in by the first sensor array 10 and the second sensor array 20 are alternately output.
[0028]
Next, the case of the single column output mode will be described. In the single column output mode, only a signal corresponding to the electric charge taken in by the first sensor column 10 is output. In the present embodiment, there are two driving methods corresponding to this single column output mode. First, the first driving method will be described. FIG. 3 is a timing chart for explaining the first driving method.
[0029]
That is, in this driving method, φ1 and φ2 are applied to the first CCD register 12, and φ2 and φ1 are applied to the second CCD register 22. The same pulse as φ2 is applied as the pulse φ2 ′ applied to the final stage 12a of the first CCD register 12. On the other hand, as the pulse φ1 ′ applied to the final stage 22a of the second CCD register 22, for example, a voltage having a low level is applied.
[0030]
By applying such a pulse, the first CCD register 12 sequentially transfers the charge of each pixel taken in by the first sensor array 10 to the multiplexing unit 30, but in the second CCD register 22, the second sensor array 20 The charge of each pixel taken in is transferred up to the front of the final stage 22a and is not transferred beyond that.
[0031]
Then, the charges of the first sensor array 10 transferred by the first CCD register 12 are sequentially transferred toward the output gate 31 by φ3 and φ4 applied to the multiplex unit 30, converted into a voltage by the floating diffusion amplifier 32, and output. Will be.
[0032]
On the other hand, the electric charge taken in by the second sensor array 20 is transferred by the second CCD register 22 up to the last stage 22a, but is not transferred beyond that. As a result, only the signals (S1, S2, S3,... Shown in FIG. 3) corresponding to the charges taken in by the first sensor array 10 are output from the floating diffusion amplifier 32.
[0033]
Since the charges transferred up to the last stage 22a before the second CCD register 22 are accumulated here, they are discharged at a predetermined timing. For example, a discharge drain is provided adjacent to the charge transfer region before the final stage 22a of the second CCD register 22, and charge is transferred from the front of the final stage 22a of the second CCD register 22 each time the charge for one column is transferred. Try to drain. Thereby, overflow due to charge accumulation can be prevented.
[0034]
Next, the second driving method will be described. FIG. 4 is a timing chart for explaining the first driving method. That is, in this driving method, φ1 and φ2 are applied to the first CCD register 12, and φ2 and φ1 are applied to the second CCD register 22. The same pulse as φ2 is applied as the pulse φ2 ′ applied to the final stage 12a of the first CCD register 12, and the same pulse as φ1 is applied as the pulse φ1 ′ applied to the final stage 22a of the second CCD register 22. To do. That is, the first CCD register 12 and the second CCD register 22 transfer the charges taken in by the first sensor array 10 and the second sensor array 20, respectively, in the direction of the multiplex unit 30 alternately.
[0035]
Next, clocks φ3 and φ4 having a frequency twice that of φ1 and φ2 are alternately applied to the multiplex unit 30. As a result, the charge of the first sensor array 10 and the charge of the second sensor array 20 that are alternately transferred to the first stage of the multiplex unit 30 are sequentially transferred toward the output gate 31. Then, each charge is sent to the floating diffusion amplifier 32 in accordance with the timing of the pulse applied to the output gate 31. Here, the reset is performed in synchronization with the transfer timing of the charge taken in by the second sensor array 20. A reset pulse φRS to be applied to the gate 33 is applied. As a result, the charge taken in by the second sensor array 20 is transferred to the floating diffusion amplifier 32, and at the same time, the charge is discharged to the reset drain 34 and is not output.
[0036]
On the other hand, when the charge taken in by the first sensor array 10 is transferred to the floating diffusion amplifier 32, the reset pulse φRS is not applied to the reset gate 33, and a voltage corresponding to the amount of charge is output from the floating diffusion amplifier 32. It will be. That is, by such driving, an output signal corresponding to the charge taken in by the first sensor array 10 is obtained while the reset pulse φRS is not applied.
[0037]
In the second driving method, an output signal is obtained for one cycle of φ3 and φ4, so that there is a time margin in signal processing in the output circuit in the subsequent stage so that reliable signal processing can be performed. Become.
[0038]
The above-described solid-state imaging device and the driving method thereof are mainly applied to an image input device such as a scanner or a copying machine. In this case, when high resolution is required, such as when capturing a fine image, the output of each pixel captured by the first sensor array 10 and the second sensor array 20 is obtained by the alternate output mode described above. If you need to perform high-speed signal processing within a limited amount of time, such as pre-scanning when scanning images (reading that determines image size, area, etc.) Only the output of each pixel of the first sensor array 10 is obtained depending on the mode. This makes it possible to meet the demands for both high resolution and high speed processing with a single solid-state imaging device.
[0039]
In the above-described embodiment, the case of a line sensor in which a plurality of pixels are arranged in a row has been described. However, the present invention is also applicable to an area sensor in which a plurality of pixels are arranged in an area (matrix). .
[0040]
【The invention's effect】
As described above, the solid-state imaging device, the driving method thereof, and the image input device of the present invention have the following effects. That is, a single solid-state imaging device can cope with both high resolution and high-speed signal processing, and can respond to various needs. Further, since switching to the output mode can be performed only by changing one pulse, it is possible to cope with mode switching without causing complication of circuit wiring or the like. As a result, it is possible to reduce the manufacturing cost of a solid-state imaging device that can support both high resolution and high-speed signal processing.
[Brief description of the drawings]
FIG. 1 is a schematic diagram illustrating a solid-state imaging device according to an embodiment.
FIG. 2 is a schematic diagram illustrating the vicinity of a multiplex unit in the solid-state imaging device according to the present embodiment.
FIG. 3 is a timing chart illustrating a first driving method according to the present embodiment.
FIG. 4 is a timing chart illustrating a second driving method according to the present embodiment.
FIG. 5 is a schematic diagram illustrating the periphery of a multiplex unit of a conventional solid-state imaging device.
FIG. 6 is a timing chart illustrating a conventional driving method.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... 1st sensor row | line | column, 11 ... Lead-out gate, 12 ... 1st CCD register, 20 ... 2nd sensor row | line | column, 21 ... Lead-out gate, 22 ... 2nd CCD register, 30 ... Multiplex part, 31 ... Output gate, 32 ... Floating diffusion amplifier, 33 ... Reset gate, 34 ... Reset drain

Claims (9)

A first charge transfer column that sequentially transfers charges taken in by the first light receiving pixel column;
A second charge transfer column for sequentially transferring charges taken in by the second light receiving pixel column;
Provided between the last stage of the first charge transfer string and the last stage of the second charge transfer string and the charge voltage conversion means, and in the alternate output mode, the first charge transfer string and the second charge transfer string. Each of the charges transferred in the first charge transfer sequence is alternately transferred, and in the single-column output mode, a multiplex unit that transfers the charges transferred in the first charge transfer sequence ;
If the alternate output mode, giving each transfer potential opposite phases at the final stage and the final stage of the second charge transfer row of said first charge transfer column, the case of the single column output mode, the first And a potential generating means for applying a transfer potential to the last stage of the second charge transfer train and applying a constant potential to the last stage of the second charge transfer train. The solid-state imaging device according to claim 1, wherein a charge discharging unit is provided adjacent to a final stage of the second charge transfer train. A first charge transfer column that sequentially transfers charges taken in by the first light receiving pixel column;
A second charge transfer column for sequentially transferring charges taken in by the second light receiving pixel column;
Each charge transferred adjacent to the last stage of the first charge transfer string and the last stage of the second charge transfer string and transferred by the first charge transfer string and the second charge transfer string A multiplex part that alternately transfers
Charge voltage conversion means connected to the subsequent stage of the multiplex part via an output gate;
A reset drain connected to the charge-voltage conversion means via a reset gate;
In the case of the alternate output mode, a signal for discharging each charge after being alternately transferred by the multiplex unit and converted into a voltage by the charge voltage conversion means to the reset drain is given to the reset gate, and the single column output mode In this case, among the charges transferred alternately in the multiplex unit, the charges transferred in the second charge transfer train are reset in synchronism with the timing at which the charges are transferred to the charge voltage conversion means. A solid-state imaging device comprising: potential generating means for supplying a signal to be discharged to the drain to the reset gate. A first charge transfer column for sequentially transferring charges taken in by the first light receiving pixel row; a second charge transfer row for sequentially transferring charges taken by the second light receiving pixel row; and the first charge transfer. In a method for driving a solid-state imaging device, comprising: a final stage of a column; and a multiplex unit provided between the final stage of the second charge transfer column and the charge-voltage conversion unit ;
In the alternate output mode, since the respective charges transferred in the first charge transfer sequence and the second charge transfer sequence are alternately transferred in the multiplex unit, the last stage of the first charge transfer sequence And applying a transfer potential having an opposite phase to the final stage of the second charge transfer train,
In the single-column output mode, in order to transfer each charge transferred in the first charge transfer sequence by the multiplex unit, a transfer potential is applied to the final stage of the first charge transfer sequence and the second A method for driving a solid-state imaging device, wherein a constant potential is applied to the last stage of the charge transfer train. 5. The method of driving a solid-state imaging device according to claim 4, wherein in the single column output mode, the charges transferred up to the last stage of the second charge transfer column are discharged at a predetermined timing. A first charge transfer column for sequentially transferring charges taken in by the first light receiving pixel row; a second charge transfer row for sequentially transferring charges taken by the second light receiving pixel row; and the first charge transfer. A multi-channel that is connected adjacent to the final stage of the column and the final stage of the second charge transfer column and alternately transfers the charges transferred in the first charge transfer column and the second charge transfer column. Solid-state imaging device driving method comprising: a plexer; a charge-voltage converter connected to a subsequent stage of the multiplex part via an output gate; and a reset drain connected to the charge-voltage converter via a reset gate In
In the case of the alternate output mode, a signal for discharging each charge after being alternately transferred by the multiplex unit and converted into a voltage by the charge voltage conversion means to the reset drain is given to the reset gate,
In the single column output mode, out of the charges transferred alternately in the multiplex unit, the charges transferred in the second charge transfer column are synchronized with the timing of transfer to the charge voltage conversion means. A driving method of a solid-state imaging device, wherein a signal for discharging electric charge to the reset drain is given to the reset gate. A first charge transfer column for sequentially transferring charges taken in by the first light receiving pixel row; a second charge transfer row for sequentially transferring charges taken by the second light receiving pixel row; and the first charge transfer. Provided between the final stage of the column and the final stage of the second charge transfer column and the charge-voltage conversion means, and in the alternate output mode, transfer is performed in the first charge transfer column and the second charge transfer column. was transferred to each of the charge alternately, for a single row output mode, a multiplexing unit for transferring the charges transferred by said first charge transfer column, the case of the alternate output mode, the first charge giving each transfer potential opposite phases at the final stage and the final stage of the second charge transfer row transfer column, the case of the single column output mode, giving a transfer potential to the final stage of the first charge transfer row In addition, a constant potential is applied to the final stage of the second charge transfer train. An image input apparatus characterized by using a solid-state imaging device and a potential generating means for obtaining. The image input device according to claim 7, wherein a charge discharging unit is provided adjacent to a final stage of the second charge transfer train in the solid-state imaging device. A first charge transfer column for sequentially transferring charges taken in by the first light receiving pixel row; a second charge transfer row for sequentially transferring charges taken by the second light receiving pixel row; and the first charge transfer. A multi-channel that is connected adjacent to the final stage of the column and the final stage of the second charge transfer column and alternately transfers the charges transferred in the first charge transfer column and the second charge transfer column. In the case of an alternating output mode, a plex part, a charge voltage conversion means connected to the subsequent stage of the multiplex part via an output gate, a reset drain connected to the charge voltage conversion means via a reset gate, A signal that discharges each charge after being alternately transferred in the multiplex part and converted into a voltage by the charge voltage conversion means to the reset drain is supplied to the reset gate. A signal that discharges the charges transferred to the second charge transfer train to the reset drain in synchronism with the timing at which the charges transferred in the second charge transfer sequence are transferred to the charge voltage conversion means among the charges transferred alternately in the multiplex unit An image input device comprising: a solid-state imaging device including a potential generating means for applying a voltage to the reset gate.

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