초록 ▼

By providing dummy pixels separately from effective pixels, the total number of pixel rows is equalized with the number of horizontal sync signals included in one frame interval (which is called an “HD number”). A period during which a reset signal for an electronic shuttering operatio

By providing dummy pixels separately from effective pixels, the total number of pixel rows is equalized with the number of horizontal sync signals included in one frame interval (which is called an “HD number”). A period during which a reset signal for an electronic shuttering operation is being supplied to an arbitrary pixel row overlaps with a period during which another pixel row is selected to perform a readout operation thereon. Thus, it is possible to suppress a variation in reset potential among effective pixels.

대표청구항 ▼

What is claimed is: 1. An amplifying solid-state imaging device comprising: a signal storage section for creating a signal charge through photoelectric conversion and storing thereon signal information corresponding to the signal charge; a plurality of pixels arranged in columns and rows, each of s

What is claimed is: 1. An amplifying solid-state imaging device comprising: a signal storage section for creating a signal charge through photoelectric conversion and storing thereon signal information corresponding to the signal charge; a plurality of pixels arranged in columns and rows, each of said plurality of pixels including the signal storage section; a row selecting unit for sequentially selecting at least one row of pixels from the plurality of pixels to perform a signal readout operation; a first power supply for resetting the signal charge from the signal storage section; a vertical signal line for outputting the signal charge from the signal storage section; a second power supply for receiving current flowing from the first power supply through the vertical signal line; a reset signal supply unit for generating a reset signal for an electronic shuttering operation which drains the signal charge in the signal storage section with a reset device within an effective pixel area and supplying the reset signal to the pixels belonging to one of the rows that has been selected to perform the electronic shuttering operation thereon, thereby resetting the signal storage sections included in the pixels of the selected row to a supply potential of the first power supply, the reset signal supply unit setting a period for supplying the reset signal to overlap with a period during which the row selecting unit is selecting a pixel row other than a reset row to perform the readout operation thereon; and a signal detector for reading out the signal information, which is stored in the signal storage sections included in the pixels on the row that has been selected by the row selecting unit to perform the signal readout operation, the signal detector including an amplifier that is connected in series between the first power supply and the second power supply, the signal detector sensing the signal information by controlling a current flow between the first power supply and the second power supply, amplifying the signal information and then outputting the amplified signal information, wherein the plurality of pixels include: m effective pixel rows which are provided within the effective pixel area, and to which, while the reset signal for the electronic shuttering operation is being supplied to an ith row of the m effective pixel rows, a pulse is supplied so that a jth row of the m effective pixel rows is selected, where 1≦i <m, 1≦j <m, i<j, and 2 ≦m; and one or more dummy pixel rows which are provided in an area other than the effective pixel area, to which a second pulse is supplied so that at least one row of the dummy pixel rows is selected while the reset signal for the electronic shuttering operation is being supplied to an nth row of the m effective pixel rows, where 1≦n<m, and to which the second pulse is supplied so that the at least one row of the dummy pixel rows is selected in a period overlapping with a timing of supplying the reset signal for the electronic shuttering operation to the m effective pixel rows after the last mth row of the m effective pixel rows has been read and before the first row of the m effective pixel rows is read. 2. The amplifying solid-state imaging device of claim 1, wherein the reset signal supply unit is included in the row selecting unit. 3. The amplifying solid-state imaging device of claim 1, wherein the amplifier of the signal detector comprises: drivers provided for the respective pixels; and load devices provided for respective pixel columns. 4. The amplifying solid-state imaging device of claim 3, wherein each said drivers is a transistor comprising: a gate electrode connected to associated one of the signal storage sections; a drain connected to the first power supply; and a source connected to associated one of the load devices. 5. The amplifying solid-state imaging device of claim 3, wherein each said drivers and an associated one of the load devices together form a source follower circuit. 6. The amplifying solid-state imaging device of claim 1, wherein each said signal storage section comprises: a photodiode for performing photoelectric conversion; a capacitor for storing charge created by the photodiode; and a transistor for electrically connecting or disconnecting the photodiode to/from the capacitor. 7. A method for driving an amplifying solid-state imaging device including m effective pixel rows provided within an effective pixel area and one or more dummy pixel rows provided in an area other than the effective pixel area, the amplifying solid-state imaging device configured for performing an electronic shuttering operation draining signal charge in a signal storage section with a reset device within the effective pixel area, the method comprising the steps of: supplying a pulse to select a jth row of the m effective pixel rows when a reset signal for the electronic shuttering operation is being supplied to an ith row of the m effective pixel rows, where 1≦i<m, 1≦j <m, and i <j ; and supplying a pulse to select any one of the dummy pixel rows when a reset signal for the electronic shuttering operation is being supplied to an nth row of the m effective pixel rows, where 1≦n <m, wherein a pulse is supplied so that at least one of the dummy pixel rows is selected in a period overlapping with a timing of supplying the reset signal for the electronic shuttering operation to the m effective pixel rows after the last mth row of the m effective pixel rows has been read and before the first row of the m effective pixel rows is read. 8. The method of claim 7, wherein a number of the one or more dummy pixel rows is equal to a number obtained by subtracting a number of the effective pixel rows from a number of horizontal sync signals included in one frame interval. 9. The method of claim 7, wherein a number of the one or more dummy pixel rows is different from a number obtained by subtracting a number of the effective pixel rows from a number of horizontal sync signals included in one frame interval. 10. The method of claim 7, wherein the reset signal is sequentially given to each of the m effective pixel rows. 11. The method of claim 7, further comprising a step of supplying the reset signal for the electronic shuttering operation to each pixel row that has been selected within the m effective pixel rows after a predetermined time has passed since a readout operation was performed. 12. The method of claim 7, wherein an effective pixel includes a transfer gate, and the signal storage section is a signal storage node. 13. The method of claim 7, wherein the signal storage section is a photodiode. 14. The device of claim 1, wherein an effective pixel includes a transfer gate, and the signal storage section is a signal storage node. 15. The device of claim 1, wherein the signal storage section is a photodiode.