Image sensor

Details Image sensor Image sensor

1999-12-01

2004-02-10

Allen, Stephone (Department: 2878)

Radiant energy

Photocells; circuits and apparatus

Photocell controlled circuit

C250S2140RC

Reexamination Certificate

active

06690000

ABSTRACT:

BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to an MOS (Metal Oxide Semiconductor) type image sensor and, more particularly, to such an image sensor that uses depletion-type transistors as a group of transistors for initializing a pixel light-receiving unit.
2. Description of the Related Art
An image sensor is used in a TV camera etc. for converting into an electric signal the optical image information taken in from outside, by such a configuration that a large number of pixels are arranged in a matrix-shaped plane. An MOS-type image sensor has a photo-diode or photo-transistor as its photo-electric conversion unit and also does it comprise a pixel circuit as its peripheral circuit configured with MOS-type FETs (Field Effect Transistors), thus featuring reduced power dissipation, cost, etc. as compared to a traditional popular CCD (Charge Coupled Device).
In a conventional MOS-type image sensor, it has been quite common to use enhancement-type transistors easy to manufacture as a group of transistors for initializing a light-receiving unit in a pixel circuit.
FIG. 7
shows a configuration example 1 of a unitary pixel circuit in a conventional MOS-type image sensor, in which the pixel circuit is made of n-channel transistors. In the circuit shown in
FIG. 7
, when a Reset signal RST went high, a supply voltage VDD is supplied to a photo-diode
4
to reset it to a photo-electric conversion initiation state. An amplifying transistor
2
, together with a current source
5
, constitutes a source follower, to amplify a photo-electric conversion voltage for a photo-diode
4
. A transistor
3
for outputting data onto a bit line is turned on when a word-line readout control signal WL went high, thus connecting the transistor
2
via a bit line BL to the current source. Transistors
1
,
2
, and
3
are of an enhancement type. The photo-diode
4
generates a photo-electric conversion voltage which corresponds to an optical input level. The current source
5
, when the transistor
3
is turned on, supplies a current to the transistor
2
, thus permitting it to operate as a source follower.
The following will describe the operations of the conventional MOS-type image sensor shown in FIG.
7
.
In a first example of operation, the Reset signal RST activates the transistor
1
in an unexposed state to initialize the photo-diode
4
by charging it to VDD−Vt (Vt: threshold voltage of the transistor
1
), then the photo-diode starts to be exposed to a light. By the photo-electric effect of the photo-diode
4
caused by an optical input, a photo-electric conversion voltage given across the photo-diode
4
corresponding to the input optical level is amplified by the transistor
2
constituting the source follower, corresponding to its transconductance gm (=I/V). After an arbitrary lapse of time, the transistor
3
is activated corresponding to the state of the word-line readout control signal WL (whereupon exposure is finished), thus providing a signal amplified at the transistor
2
onto the bit line BL.
In a second example of operation, the Reset signal RST has its potential stepped up in potential to VDD+Vt (Vt: threshold voltage of the transistor) or higher to activate the transistor
1
in order to initialize the photo-diode
4
by charging it to a voltage VDD, thus subsequently starting the exposure of the photo-diode
4
. Thereafter, like in the case of the first operation example, a photo-electric voltage given across the photo-diode
4
is amplified at the transistor
2
which constitutes a source follower, so that after an arbitrary lapse of time, the transistor
3
is activated corresponding to the state of the word-line readout control signal WL (whereupon exposure is finished), thus outputting a resultant signal onto the bit line BL.
FIG. 8
shows a second configuration example 2 of a unitary pixel circuit in a conventional MOS-type image sensor, in which the circuit is made of n-channel transistors. In a circuit shown in
FIG. 8
, transistors
1
,
2
, and
3
as well as a photo-diode
4
and a current source
5
are similar to those in the configuration example 1 except that a transistor
6
is provided which constitutes a transfer gate. The transistor
6
consists of an enhancement-type transistor, which always disconnects the photo-diode
4
from a interconnection between a source of the transistor
1
and a gate of the transistor
2
, except when a gate signal TG went high, whereupon the transistor
6
is turned on to connect the photo-diode to this interconnection.
The following will describe the operations of a conventional MOS-type image sensor shown in FIG.
8
.
In a first example of operation, the reset signal RST activates the transistor
1
in an unexposed state and, at the same time, the gate signal TG activates the transistor
6
to initialize the photo-diode
4
by charging it to VDD−Vt (Vt: threshold voltage of the transistor
1
) and then, the gate signal TG is turned off to disconnect the photo-diode
4
from the source of the transistor
1
, thus starting the exposure of the photo-diode
4
. After an arbitrary lapse of time, the gate signal TG activates the transistor
6
again (whereupon exposure is finished) and, by the photo-electric effect of the photo-diode
4
caused by an optical input, a photo-electric conversion voltage produced on the photo-diode
4
according to a level of the optical input is read out and written into a temporary memory
7
formed by a capacitance of the gate of the transistor
2
, then the gate signal TG is turned off to disconnect the photo-diode
4
from the temporary memory
7
. With this, the voltage thus held in the temporary memory
7
is amplified by the transistor constituting a source follower, corresponding to its transconductance gm (=I/V), so that by activating the transistor
3
in correspondence with the state of the word-line readout control signal WL, a signal thus amplified by the word-line readout control signal WL may be activated, to output that signal amplified by the transistor
2
onto the bit line BL.
In a second example of operation also, the Reset signal RST and the gate signal TG are stepped up in potential, in an unexposed state, to VDD+Vt (Vt: threshold voltage of the transistor
1
) or higher to activate the transistors
1
and
6
in order to initialize the photo-diode
4
by charging it to a voltage VDD, then the gate signal TG is turned off to disconnect the photo-diode
4
from the gate of the transistor
1
, thus starting exposure of the photo-diode
4
. Subsequently, like in the case of the first example of operation, after an arbitrary lapse of time, the gate signal TG activates the transistor again (whereupon exposure is finished) and, a photo-electric conversion voltage of the photo-diode
4
is read out and written into the temporary memory
7
, thus disconnecting the photo-diode
4
from the temporary memory
7
. The voltage thus held in the temporary memory
7
is amplified at the transistor
2
constituting the source follower, so that the transistor
3
may be activated corresponding to the word-line readout control signal WL, thus outputting that signal amplified by the transistor
2
onto the bit line.
In a first example of configuration
1
shown in FIG.
7
and also in the case of the first example of operation, an initialization level of the photo-diode
4
drops due to the effect of the supply voltage VDD by as much as the threshold voltage of the resetting transistor
1
. Therefore, such a problem occurs that a dynamic range for an output signal shrinks. In the case of the second example of operation, the Reset signal RST is raised in potential to a step-up level of VDD+Vt when the resetting transistor
1
is activated, so that a step-up power supply is required. Moreover, since the transistor
1
is provided with the step-up level of VDD+Vt, a gate oxide film, for example, must be increased in thickness, to assure a high breakdown voltage, which leads to another problem.
Furthermore, in both cases o

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