Non-patent literature 1:S.Inoue et al., IEEE Workshop on CCDs and AdvancedImage Sensors 2001, page 16-19
Non-patent literature 2:Yoshinori Muramatsu et al., IEEE Journal of Solid-stateCircuits, vol.38, No.1, January 2003
Non-patent literature 3: image information medium association magazine, 57 (2003)
Summary of the invention
The present invention proposes in view of described situation, the objective of the invention is to, be provided at when keeping high sensitivity, high S/N ratio, can realize wide dynamic range solid camera head, line sensor, optical sensor, be used for when keeping high sensitivity, high S/N ratio realizing the method for work of the solid camera head of wide dynamic range.
In order to realize described purpose, solid camera head of the present invention becomes array-like to a plurality of set of pixels, and this pixel comprises: photodiode, receive light, and generate and the savings optical charge;
Pass on transistor, pass on described optical charge;
Floating region passes on described optical charge by the described transistor that passes on;
The savings capacity cell connects described floating region and is provided with according to the mode that can carry out the combination of electromotive force and cut apart; With
The savings transistor is cut apart described floating region or is combined with the electromotive force of described savings capacity cell;
The savings capacity cell passes on the optical charge that transistor and described savings transistor savings overflows from described photodiode by described during the savings of described photodiode;
Be under the state of cutting apart at the electromotive force that makes described floating region and described savings capacity cell, to be transferred to described floating region at the optical charge of described photodiode savings, and be under the state of combination the optical charge that will pass at described floating region and mix at the electromotive force that makes described floating region and described savings capacity cell from the optical charge that described photodiode overflows at described savings electric capacity savings.
The savings capacity cell of the optical charge that described solid camera head of the present invention overflows the photodiode, savings that receive light and generate optical charge from photodiode becomes array-like via passing on the set of pixels of the structure that transistor connects.
Preferred described each pixel of described solid camera head of the present invention is under the state of cutting apart at the electromotive force that makes described floating region and described savings capacity cell, to be transferred to described floating region at the optical charge of described photodiode savings, to amplify at the optical charge of described floating region savings and be transformed into voltage signal, then, be under the state of combination the optical charge that will pass at described floating region and amplify from the mixed optical charge of optical charge that described photodiode overflows and to be transformed into voltage signal at described savings electric capacity savings at the electromotive force that makes described floating region and described savings capacity cell.
Preferred each pixel of described solid camera head of the present invention also has: reset transistor, and is connected with the transistorized connecting portion of described savings with described savings capacity cell and forms, be used to discharge described savings capacity cell and the interior optical charge of described floating region.
Preferred each pixel of each pixel of described solid camera head of the present invention also has: reset transistor, and is connected with described floating region and forms, be used to discharge in the described floating region and the interior optical charge of described savings electric capacity.
Preferred each pixel of described solid camera head of the present invention has the logarithmic transformation circuit, the optical charge that overflows from described photodiode is carried out logarithmic transformation, and read.
Preferred each pixel of described solid camera head of the present invention has the logarithmic transformation circuit, and the optical charge that overflows from described photodiode is carried out logarithmic transformation, puts aside in the described savings capacity cell.
In described solid camera head of the present invention, the described transistor that passes on is to have to constitute described surface of passing on transistorized substrate or that form and the embedding channel-type described semiconductor layer that passes on transistorized raceway groove same conductivity from the near surface to the given depth.
The described transistor that passes on has: form constituting the described given depth that passes on transistorized substrate, and for passing on transistorized raceway groove same conductivity with described, reduce the described semiconductor layer that passes on transistorized punch through barrier.
In the described solid camera head of the present invention, described savings capacity cell has the semiconductor region that becomes lower electrode that forms on the top layer part of the semiconductor substrate that constitutes described solid camera head, be formed on capacitor insulating film on the described semiconductor region, be formed on the upper electrode on the described capacitor insulating film.
Perhaps described savings capacity cell has: constituting the lower electrode that forms on the substrate of described solid camera head, be formed on capacitor insulating film on the described lower electrode, be formed on the upper electrode on the described capacitor insulating film.
Perhaps described savings capacity cell has: on the ditch inwall that is formed on the semiconductor substrate that constitutes described solid camera head the formed semiconductor region that becomes lower electrode, cover described ditch inwall and the capacitor insulating film that forms, bury described ditch and the upper electrode that forms via described capacitor insulating film.
First conductive-type semiconductor area, second conductive-type semiconductor area that engages with described first conductive-type semiconductor area embed the semiconductor substrate that constitutes described solid camera head, constitute described savings capacity cell.
Perhaps, the substrate that constitutes described solid camera head is SOI (the Semiconductor on Insulator) substrate that forms semiconductor layer on semiconductor substrate via dielectric film, use constitutes described savings capacity cell via relative described semiconductor substrate of described dielectric film and the capacitance insulation film between the described semiconductor layer.
Described solid camera head of the present invention also has: obtain from transfer to described floating region or transfer to described floating region and voltage signal that the optical charge of described savings capacity cell obtains, and the voltage signal of the reset level of described floating region or described floating region and described savings capacity cell between the noise removing parts of difference.
Also have: the memory unit of voltage signal of storing the reset level of described floating region and described savings capacity cell.
Described solid camera head of the present invention also has: the noise removing parts of obtaining the difference between the voltage signal of the level before described the passing on of the voltage signal that obtains from the optical charge that transfers to described floating region and described floating region.
Also have: the noise removing parts of obtaining the difference between the voltage signal of reset level of the voltage signal that obtains from the optical charge that transfers to described floating region and described savings capacity cell and described floating region and described savings capacity cell.
Also have: the memory unit of voltage signal of storing the reset level of described floating region and described savings capacity cell.
In the described solid camera head of the present invention, first electric charge coupling of the optical charge in the described photodiode of passing on is passed on route and described photodiode and is connected to form, described savings capacity cell connects between adjacent pixels, constitutes to pass on different second electric charge of the optical charge in the described savings capacity cell of passing on of route with described first electric charge coupling and be coupled and pass on route.
Also have: be connected to form with described photodiode, route is passed in the electric charge coupling of the optical charge in the described photodiode of passing on; Be connected to form with described savings capacity cell, be used to discharge the reset transistor of the optical charge in the described savings capacity cell; Optical charge in the described savings capacity cell is amplified the amplifier transistor that is transformed to voltage signal; Be connected to form with described amplifier transistor, be used to select the selection transistor of described pixel.
In the described solid camera head of the present invention, the transistor that constitutes described pixel is the n channel MOS transistor.Perhaps, the transistor that constitutes described pixel is the p channel MOS transistor.
In addition, in order to realize described purpose, line sensor of the present invention becomes linearity to a plurality of set of pixels, and described pixel comprises:
Photodiode receives light, generates and the savings optical charge;
Pass on transistor, pass on described optical charge;
Floating region passes on described optical charge by the described transistor that passes on;
The savings capacity cell connects described floating region and is provided with according to the mode that can carry out the combination of electromotive force and cut apart; With
The savings transistor is cut apart described floating region or is combined with the electromotive force of described savings capacity cell
The savings capacity cell passes on the optical charge that transistor and described savings transistor savings overflows from described photodiode by described during the savings of described photodiode;
Be under the state of cutting apart at the electromotive force that makes described floating region and described savings capacity cell, to be transferred to described floating region at the optical charge of described photodiode savings, and be under the state of combination the optical charge that will pass at described floating region and mix at the electromotive force that makes described floating region and described savings capacity cell from the optical charge that described photodiode overflows at described savings electric capacity savings.
In addition, in order to realize described purpose, optical sensor of the present invention has: photodiode, receive light, and generate and the savings optical charge;
Pass on transistor, pass on described optical charge;
Floating region passes on described optical charge by the described transistor that passes on;
The savings capacity cell connects described floating region and is provided with according to the mode that can carry out the combination of electromotive force and cut apart; With
The savings transistor is cut apart described floating region or is combined with the electromotive force of described savings capacity cell;
The savings capacity cell passes on the optical charge that transistor and described savings transistor savings overflows from described photodiode by described during the savings of described photodiode;
Be under the state of cutting apart at the electromotive force that makes described floating region and described savings capacity cell, to be transferred to described floating region at the optical charge of described photodiode savings, and be under the state of combination the optical charge that will pass at described floating region and mix at the electromotive force that makes described floating region and described savings capacity cell from the optical charge that described photodiode overflows at described savings electric capacity savings.
The savings capacity cell of the optical charge that described optical sensor of the present invention overflows the photodiode, savings that receive light and generate optical charge from photodiode connects via passing on transistor.
In order to realize described purpose, in the method for work of solid camera head of the present invention, solid camera head becomes array-like to a plurality of set of pixels, and this pixel comprises: receive light, generate the photodiode of optical charge; Pass on described optical charge pass on transistor and the savings transistor; Connect and the floating region of setting via the described described photodiode of transistor AND gate that passes on; Pass on the optical charge that transistor and described savings transistor savings overflow from described photodiode in when action savings by described, the savings capacity cell that combines or cut apart with the electromotive force of described floating region by described savings transistor controls; The method of work of described fixedly camera head comprises: before the electric charge savings, the described transistor that passes on is ended, make described savings transistor turns, discharge the step of the optical charge in described floating region and the described savings capacity cell; Read the step of voltage signal of the reset level of described floating region and described savings capacity cell; Electric charge before saturated in the optical charge that is produced by described photodiode is put aside in the described photodiode step that the supersaturation electric charge that overflows from described photodiode is put aside described floating region and described savings capacity cell; Described savings transistor is ended, cut apart the electromotive force of described floating region and described savings capacity cell, discharge the step of the optical charge in the described floating region; Read the step of voltage signal of the reset level of described floating region; Make the described transistor turns of passing on, described saturated preceding electric charge is passed on to described floating region, read the step of the voltage signal of described saturated preceding electric charge; Make described savings transistor turns, the electromotive force combination of described floating region and described savings capacity cell, mix described saturated before electric charge and described supersaturation electric charge, read described saturated before electric charge and described supersaturation electric charge and the step of voltage signal.
The method of work of described solid camera head of the present invention is before the electric charge savings, make and pass on transistor and end, make the savings transistor turns, discharge the optical charge in floating region and the savings capacity cell, read the voltage signal of the reset level of floating region and savings capacity cell.
Then, the saturated preceding electric charge in the optical charge that is produced by photodiode is put aside in the photodiode, the supersaturation electric charge that overflows from electric diode is put aside floating region and savings capacity cell.
Then, the savings transistor is ended, cut apart the electromotive force of floating region and savings capacity cell, discharge the optical charge in the floating region, read the voltage signal of the reset level of floating region.
Then, make and pass on transistor turns, electric charge before saturated is passed on to floating region, read saturated before the voltage signal of electric charge.
Then, make the savings transistor turns, the electromotive force combination of floating region and savings capacity cell, mixes saturated before electric charge and supersaturation signal, read saturated preceding electric charge and supersaturation signal and voltage signal.
The method of work of described solid camera head of the present invention also has: obtain described saturated before difference between the voltage signal of reset level of the voltage signal of electric charge and described floating region, to described saturated before the voltage signal of electric charge eliminate the step of noise; Obtain described saturated before electric charge and described supersaturation electric charge and voltage signal, with the voltage signal of the reset level of described floating region and described savings capacity cell between difference, to described saturated before electric charge and described supersaturation electric charge and the step of voltage signal elimination noise; Adjust described saturated before electric charge and described supersaturation electric charge and the gain of voltage signal, make become with described saturated before the step of the identical in fact gain of the voltage signal of electric charge; With reference voltage relatively, select to have eliminated electric charge before noise described saturated voltage signal, eliminated electric charge and described supersaturation electric charge before noise described saturated and voltage signal in any one step.
Saturated preceding electric charge in the optical charge that the method for work of described solid camera head of the present invention produces in described photodiode is put aside in the described photodiode, the supersaturation electric charge that overflows from described photodiode is put aside in the step described floating region and the described savings capacity cell, is described potential regulating of passing on transistor part to make the described level that transistor ends fully or than its also low level of passing on.
In order to realize described purpose, in the method for work of solid camera head of the present invention, solid camera head becomes array-like to a plurality of set of pixels, and this pixel comprises: receive light, generate the photodiode of optical charge; Pass on described optical charge pass on transistor and the savings transistor; Connect and the floating region of setting via the described described photodiode of transistor AND gate that passes on; Pass on the optical charge that transistor and described savings transistor savings overflow from described photodiode in when action savings by described, the savings capacity cell that combines or cut apart with the electromotive force of described floating region by described savings transistor controls; The method of work of described fixedly camera head comprises: before the electric charge savings, the described transistor that passes on is ended, make described savings transistor turns, discharge the step of the optical charge in described floating region and the described savings capacity cell; Read the step of voltage signal of the reset level of described floating region and described savings capacity cell; Electric charge before saturated in the optical charge that is produced by described photodiode is put aside in the described photodiode step that the supersaturation electric charge that overflows from described photodiode is put aside described floating region and described savings capacity cell; Described savings transistor is ended, cut apart the electromotive force of described floating region and described savings capacity cell, read the step of the voltage signal of level before the passing on of electric charge before described floating region described saturated; Make the described transistor turns of passing on, described saturated preceding electric charge is passed on to described floating region, read the step of the voltage signal of level afterwards of passing on of described saturated preceding electric charge; Make described savings transistor turns, the electromotive force combination of described floating region and described savings capacity cell, mix described saturated before electric charge and described supersaturation electric charge, read described saturated before electric charge and described supersaturation electric charge and the step of voltage signal.
The method of work of described solid camera head of the present invention is before the electric charge savings, make and pass on transistor and end, make the savings transistor turns, discharge the optical charge in described floating region and the described savings capacity cell, read the voltage signal of the reset level of floating region and savings capacity cell.
Then, the saturated preceding electric charge in the optical charge that is produced by photodiode is put aside in the photodiode, the supersaturation electric charge that overflows from photodiode is put aside floating region and savings capacity cell.
Then, the savings transistor is ended, cuts apart the electromotive force of floating region and savings capacity cell, read saturated before the voltage signal of level before the passing on of electric charge.
Then, make and pass on transistor turns, electric charge before saturated is passed on to floating region, read saturated before the voltage signal that passes on the back level of electric charge
Then, make the savings transistor turns, the electromotive force combination of floating region and savings capacity cell, mixes saturated before electric charge and supersaturation signal, read saturated preceding electric charge and supersaturation signal and voltage signal.
The method of work of described solid camera head of the present invention also has: obtain described saturated before electric charge pass on the back level voltage signal and described saturated before the difference between the voltage signal of level before the passing on of electric charge, to described saturated before the voltage signal of electric charge eliminate the step of noise; Obtain described saturated before electric charge and described supersaturation electric charge and the voltage signal of voltage signal and the reset level of described floating region and described savings capacity cell between difference, to described saturated before electric charge and described supersaturation electric charge and the step of voltage signal elimination noise; Adjust described saturated before electric charge and described supersaturation electric charge and the gain of voltage signal, make become with described saturated before the step of the identical in fact gain of the voltage signal of electric charge; With reference voltage relatively, select to have eliminated electric charge before noise described saturated voltage signal, eliminated electric charge and described supersaturation electric charge before noise described saturated and voltage signal in any one step.
Saturated preceding electric charge in the optical charge that the method for work of described solid camera head of the present invention produces in described photodiode is put aside in the described photodiode, the supersaturation electric charge that overflows from described photodiode is put aside in the step described floating region and the described savings capacity cell, is described potential regulating of passing on transistor part to make the described level that transistor ends fully or than its also low level of passing on.
According to solid camera head of the present invention, in low-light (level) shooting based on the photodiode that receives light and generation optical charge, keep high sensitivity, high S/N ratio, further by the savings capacity cell, the optical charge that savings overflows from photodiode, thereby carry out the shooting in the high illumination shooting, can enlarge dynamic range.
According to line sensor of the present invention, when keeping high sensitivity, high S/N ratio, can enlarge dynamic range.
According to optical sensor of the present invention, when keeping high sensitivity, high S/N ratio, can enlarge dynamic range.
According to the method for work of solid camera head of the present invention, when keeping high sensitivity, high S/N ratio, can enlarge dynamic range.
Embodiment
Below, with reference to the execution mode of description of drawings solid camera head of the present invention.
Execution mode 1
The solid camera head of present embodiment is a cmos image sensor, and Fig. 1 is the equivalent circuit figure of an amount of pixels.
Each pixel by receive light and generate optical charge photodiode PD, pass on from the optical charge of photodiode PD pass on transistor Tr 1, pass on the savings capacity cell C of the floating region FD of optical charge, savings overflows from described photodiode when the savings action optical charge by passing on transistor Tr 1
S, floating region FD and savings capacity cell C
SElectromotive force in conjunction with or the savings transistor Tr 2 cut apart, be connected to form and be used to discharge the reset transistor Tr3 of the optical charge in the floating region FD with floating region FD, the optical charge in the floating region FD is amplified be transformed to the amplifier transistor Tr4 of voltage signal and be connected to form with amplifier transistor and be used to select the selection transistor Tr 5 of pixel to constitute, be the cmos image sensor of so-called 5 transistor-types.For example described 5 transistors all are made of the n channel MOS transistor.
The cmos image sensor of present embodiment becomes array-like to a plurality of set of pixels of described structure, in each pixel, is passing on the gate electrode connection φ of transistor Tr 1, savings transistor Tr 2, reset transistor Tr3
T, φ
S, φ
REach drive wire, in addition, connect the pixel selection line SL (φ that drives by line shift register at the gate electrode of selecting transistor Tr 5
X), be connected output line out at the output one side source electrode of selecting transistor Tr 5 with drain electrode, by column shift register control, output.
About selecting transistor Tr 5, drive wire φ
X, for the selection that can carry out pixel, non-selection action, as long as it is just passable that the voltage of floating region FD is fixed on suitable value, so also can omit them.
Fig. 2-the 1st, each the pixel part that is equivalent to the cmos image sensor of present embodiment (photodiode PD, is passed on transistor Tr 1, floating region FD, savings transistor Tr 2, savings capacity cell C
S) the pattern cutaway view.
For example on n type silicon semiconductor substrate (n-sub) 10, form p type well (p-well) 11, form and distinguish each pixel and savings capacity cell C
SThe element separating insulation film (20,21,22) based on LOCOS method etc. in district forms p in the p type well 11 below the separating insulation film 20 that is equivalent to discrete pixels
+ Type Disengagement zone 12.
In p type well 11, form n N-type semiconductor N district 13, form p on its top layer
+N-type semiconductor N district 14 becomes the photodiode PD of charge transport embedded type by this pn structure.If inciding at pn, ties in the depletion layer that adds suitable bias voltage and produce light LT, because photoelectric effect just produces optical charge.
End in n N-type semiconductor N district 13 has from p
+The district of formation is stretched out in N-type semiconductor N district 14, leaves given distance from this district, becomes the n of floating region FD on the top layer of p type well 11
+Given distance is left from this district again by N-type semiconductor N district 15, forms n on the top layer of p type well 11
+N-type semiconductor N district 16.
Here, with n N-type semiconductor N district 13 and n
+In the relevant zone, N-type semiconductor N district 15, on p type well 11, form the gate electrode 30 that constitutes by polysilicon, n N-type semiconductor N district 13 and n via the gate insulating film 23 that constitutes by silica
+N-type semiconductor N district 15 is source electrode and drain electrode, constitute on the top layer of p type well 11 have a channel formation region pass on transistor Tr 1.
In addition, with n
+N-type semiconductor N district 15 and n
+In the relevant zone, N-type semiconductor N district 16, on p type well 11, form the gate electrode 31 that constitutes by polysilicon, n via the gate insulating film 24 that constitutes by silica
+N-type semiconductor N district 15 and n
+N-type semiconductor N district 16 is source electrode and drain electrode, constitutes on the top layer of p type well 11 to have the savings transistor Tr 2 of channel formation region.
In addition, in the zone of distinguishing by element separating insulation film (21,22), become the p of lower electrode on the top layer of p type well 11
+N-type semiconductor N district 17, layer forms the upper electrode 32 that is made of polysilicon etc. via the capacitor insulating film 25 that is made of silica etc. thereon, is made of them and puts aside capacity cell C
S
Transistor Tr 1, savings transistor Tr 2 and savings capacity cell C are passed in covering
S, form the dielectric film that constitutes by silica, form and arrive n
+N-type semiconductor N district 15, n
+The peristome of N-type semiconductor N district 16 and upper electrode 32 forms respectively and n
+The wiring 33 that N-type semiconductor N district 15 connects, connection n
+The wiring 34 of N-type semiconductor N district 16 and upper electrode 32.
In addition, drive wire φ is set passing on to connect on the gate electrode 30 of transistor Tr 1
T, in addition, connection is provided with drive wire φ on the gate electrode 31 of savings transistor Tr 2
S
Reset transistor Tr3, amplifier transistor Tr4, selection transistor Tr 5, each drive wire (φ about described other key elements
T, φ
S, φ
R, φ
X) and output line out, constitute in the not shown zone on the semiconductor substrate shown in Fig. 2-1 10, thereby become the structure that wiring is connected the first-class equivalent circuit figure shown in Figure 1 of not shown amplifier transistor Tr4.
Fig. 2-the 2nd is equivalent to described photodiode PD, passes on transistor Tr 1, floating region FD, savings transistor Tr 2 and savings capacity cell C
SThe pattern potential energy diagram.
Photodiode PD constitutes the capacitor C of shallow relatively electromotive force
PD, floating region FD and savings capacity cell C
SConstitute the electric capacity (C of dark relatively electromotive force
FD, C
S).
Here, pass on transistor Tr 1 and savings transistor Tr 2, can get 2 energy levels according to transistorized on/off.
The driving method of the cmos image sensor of the present embodiment that illustrates in the cutaway view of equivalent circuit figure, Fig. 2-1 of key diagram 1 and the potential energy diagram of Fig. 2-2.
Fig. 3-the 1st is with drive wire (φ
T, φ
S, φ
R) on the voltage that adds be that 2 energy levels of on/off add about φ
TWith the (+α) sequential chart represented of 3 energy levels of energy level of expression.
Though drive wire φ
TOn the voltage that adds be that 2 energy levels of ON/OFF are just passable, but when as this example, being 3 energy levels, can be more effectively the charge-trapping that overflows from photodiode PD to floating region FD and savings capacity cell C
SIn, savings.
Fig. 3-2 and Fig. 3-3 is respectively photodiode PD, floating region FD and the savings capacity cell C of described sequential
SElectric capacity (the C that constitutes
PD, C
FD, C
S) current potential (V
PD, V
FD, V
CS) the curve chart of variation, Fig. 3-the 2nd, the photoelectron that is produced by photodiode PD is for making C
PDCurve chart during the following light quantity of saturated amount, Fig. 3-the 3rd makes C
PDCurve chart during the above light quantity of saturated amount.
In addition, Fig. 4-1~Fig. 4-4 and Fig. 5-1~Fig. 5-4 is equivalent to the potential energy diagram of each sequential of sequential chart.
At first, φ
TBe off, φ
SUnder the state on, φ
RBe on, the optical charge that produces in the preceding field is all discharged, resetted, at moment T
1, when next field begins, φ
RBe off.
At this moment, shown in Fig. 4-1, φ
SBe on, so become C
FD, C
SThe state of coupling after resetting, is accompanied by homing action, at C
FD+ C
SThe so-called kTC noise of middle generation.Here, C
FD+ C
SThe signal of reset level as noise N
2Read.
Read noise N
2, put aside in the frame memory of describing later (memory unit), when generating picture signal, utilize noise N
2Method be to make S/N than the best way, but during supersaturation, with saturated before electric charge+supersaturation electric charge compare noise N
2Enough little, so can replace noise N
2, use the noise N that describes later
1In addition, the noise N that replaces present frame
2, can use the noise N of next frame
2
Then, in the savings time T
LTThe time, the optical charge that generates among the savings photodiode PD.At this moment, about φ
T, as (+α) energy level is C
PDAnd C
FDBetween potential barrier reduce a little.
Shown in Fig. 3-2, optical charge is at first put aside C
PDIn, be accompanied by this, C
PDCurrent potential V
PDGradually descend.When photoelectron for making C
PDWhen saturated amount is following, has only C
PDCurrent potential V
PDChange C
FDAnd C
SCurrent potential (V
FD, V
CS) do not change.
And photoelectron is for making C
PDWhen saturated amount is above, surmount φ
TOnly having descended, (+α) the potential barrier of energy level, optical charge is from C
PDOverflow, put aside the C of this pixel selectively
FD+ C
SIn.At this moment, shown in Fig. 3-3, at C
PDBefore saturated, C
PDCurrent potential V
PDGradually descend C
FDAnd C
SCurrent potential (V
FD, V
CS) do not change, but from C
PDBegin C after saturated
PDCurrent potential V
PDBecome necessarily C
FDAnd C
SCurrent potential (V
FD, V
CS) descend gradually.
When photoelectron is when making the saturated amount of photodiode PD following, only at C
PDMiddle savings optical charge is when photoelectron is when making the saturated amount of photodiode PD above, except C
PD, at C
FDAnd C
SIn also put aside optical charge.
Fig. 4-2 represents C
PDSaturated, at C
PDCharge Q before middle savings is saturated
B, at C
FDAnd C
SMiddle savings supersaturation charge Q
AState.
In the savings time T
LTEnd the time, φ
TFrom (+α) energy level is got back to off, φ
SBe off, shown in Fig. 4-3, cut apart C
FDAnd C
SElectromotive force.
Make φ
RBe on, shown in Fig. 4-4, discharge C
FDIn optical charge, reset.
Then, at moment T
2, make φ
RBe off, after finishing to reset, shown in Fig. 5-1, the kTC noise is at C
FDIn newly produce.Here, C
FDThe signal of reset level as noise N
1Read.
Then, make φ
TBe on, shown in Fig. 5-2, C
PDIn saturated before charge Q
BTransfer to C
FDHere, C
PDElectromotive force compare C
FDMore shallow, the transistorized energy level that passes on compares C
PDDeeply, so can realize C
PDIn saturated before charge Q
BAll transfer to C
FDComplete electric charge pass on.
Here, at moment T
3, φ
TGet back to off, from transferring to C
FDSaturated before charge Q
BRead saturated preceding charge signal S
1,, have C here
FDNoise, thus actual read become S
1+ N
iFig. 5-2 expression makes φ
TGet back to off state before.
Then, make φ
SBe on, then make φ
TBe on, thereby C
FDAnd C
SThe electromotive force combination, shown in Fig. 5-3, mixed C
FDIn saturated before charge Q
BAnd C
SIn the supersaturation charge Q
A
Here, at moment T
4, make φ
TGet back to off, from expanding to C
FD+ C
SSaturated before charge Q
BWith the supersaturation charge Q
ARead saturated preceding charge signal S
1With supersaturation charge signal S
2And signal., have C here
FD+ C
SNoise is because from expanding to C
FD+ C
SElectric charge read, so actual read become S
1'+S
2'+N
2(S
1', S
2' be respectively according to C
FDAnd C
SCapacitance ratio, dwindle the S after the modulation
1And S
2Value).Fig. 5-3 represents φ
TGet back to off state before.
Then, as mentioned above, at φ
TBe off, φ
SUnder the state on, make φ
RBe on, the optical charge that produces in this field all discharged that reset (Fig. 5-4) transfers to next field.
The following describes all circuit structures of cmos image sensor that the set of pixels of described structure become array-like.
Fig. 6 is the equivalent circuit figure of all circuit structures of the cmos image sensor of expression present embodiment.
The pixel (Pixel) of a plurality of (scheming last 4) is configured to array-like, goes up in each pixel (Pixel) to connect by line shift register SR
VDrive wire (the φ of control
T, φ
S, φ
R, φ
X), power vd D and ground connection GND.
(Pixel) uses column shift register SR from each pixel
HAnd drive wire (φ
S1+N1, φ
N1, φ
S1 '+S2 '+N2, φ
N2) control, as mentioned above, charge signal (S before saturated
1)+C
FDNoise (N
1), C
FDNoise (N
1), the modulation after saturated before charge signal (S
1')+modulation after supersaturation charge signal (S
2')+C
FD+ C
SNoise (N
2) and C
SNoise (N
2) wait 4 values each the time ordered pair each output line output.
Here, saturated preceding charge signal (S
1)+C
FDNoise (N
1), C
FDNoise (N
1) each outlet end part CT
aAs described below, obtain their difference, so can on the cmos image sensor chip, form the circuit CT that comprises differential amplifier DC1
b
Fig. 7 is the saturated preceding charge signal (S that carries out by described output
1)+C
FDNoise (N
1), C
FDNoise (N
1), the modulation after saturated before charge signal (S
1')+modulation after supersaturation charge signal (S
2')+C
FD+ C
SNoise (N
2) and C
FD+ C
SNoise (N
2) wait the circuit of 4 Signal Processing.
From described output, to the saturated preceding charge signal (S of differential amplifier DC1 input
1)+C
FDNoise (N
1), C
FDNoise (N
1), obtain their difference, thereby eliminate C
FDNoise (N
1), obtain saturated preceding charge signal (S
1).Charge signal (S before saturated
1) can also ADC1 can be set by the A/D converter ADC1 digitlization that is provided with according to necessity, keep analog signal.
And the saturated preceding charge signal (S after the modulation
1')+modulation after supersaturation charge signal (S
2')+C
FD+ C
SNoise (N
2), C
FD+ C
SNoise (N
2) to differential amplifier DC2 input, obtain their difference, thus C eliminated
FD+ C
SNoise (N
2), by amplifier AP, according to C
FDAnd C
SCapacitance ratio restore, be adjusted into and saturated before charge signal (S
1) identical gain, obtain saturated before charge signal and supersaturation charge signal and (S
1+ S
2).S
1'+S
2'+N
2Signal and N
2Before the signal input differential amplifier DC2, A/D converter ADC2,3 digitlizations respectively by being provided with according to necessity perhaps are not provided with ADC2,3, keep analog signal, and differential amplifier DC2 is imported.
Here, shown in the sequential chart of Fig. 3-1~Fig. 3-3, C
FD+ C
SNoise (N
2) compare with other signal, obtain relatively soon, so before obtaining other signals, temporarily be stored in the memory unit, read from frame memory FM in the sequential that obtains other signals, carry out following processing.
The saturated preceding charge signal (S of described modulation is described
1')+modulation after supersaturation charge signal (S
2') recovery.
S
1', S
2', α is (from C
FDTo C
FD+ C
SCharge distributing than) and β (from C
STo C
FD+ C
SCharge distributing than) represent by following expression formula.
S
1’=S
1×α (1)
S
2’=S
2×α×β (2)
α=C
FD/(C
FD+C
S) (3)
β=C
S/(C
FD+C
S) (4)
Therefore, from C
FDAnd C
SValue, obtain α and β from described expression formula (3) and (4), the described expression formula of its substitution (1) and (2), restore and be S
1+ S
2, the S that can be adjusted into Yu obtain in addition
1Identical gain.
As shown in Figure 7, select by the described S that obtains
1And S
1+ S
2, as final output.
At first S
1To comparator CP input, with predefined reference potential V
0Relatively.And S
1And S
1+ S
2To selector SE input,, select S according to the output of described comparator C P
1And S
1+ S
2Any one party output.Select saturated preceding current potential, for example reference potential V according to the electric capacity of photodiode PD
0For about 0.3V.
If promptly S
1Deduct V
0, for negative, i.e. S
1Compare V
0Little, it is unsaturated just to be judged as photodiode PD, output S
1
On the contrary, if S
1Deduct V
0, for just, i.e. S
1Compare V
0Greatly, it is saturated just to be judged as photodiode PD, output S
1+ S
2
For example, on cmos image sensor chip CH, be formed into this output, to realize differential amplifier DC1 and the later circuit of frame memory FM in addition.In addition, as mentioned above,, also can on cmos image sensor chip CH, form about differential amplifier DC1.
In addition, about differential amplifier DC1 and the later circuit of frame memory FM, because the analogue data of handling increases, so before to differential amplifier DC1 and frame memory FM input, carry out the A/D conversion, differential amplifier DC1 and frame memory FM are carried out digitized processing later on.At this moment, can amplify by not shown amplifier in advance according to the input range of the A/D converter that uses.
As mentioned above, in the cmos image sensor of present embodiment, in a pixel, every field is obtained saturated preceding charge signal (S
1), saturated before charge signal and supersaturation charge signal and (S
1+ S
2) wait 2 signals, reality to judge photodiode PD (C
FD) whether be saturated or near its state, select S
1And S
1+ S
2Any one.
Fig. 8-the 1st for relative light quantity, describes to use C
FDThe time charge number that obtains figure, it is equivalent to signal S
1And Fig. 8-the 2nd for relative light quantity, describes to use C
FD+ C
SThe time charge number that obtains figure, it is equivalent to signal S
1+ S
2
As reference potential V
0(for example 0.3V) uses the signal S shown in Fig. 8-1 in low-light (level) one side
1, use the signal S shown in Fig. 8-2 in high illumination one side
1+ S
2
At this moment, in two curve charts, in the low-light (level) district noise Noise appears, but signal S
1Than signal S
1+ S
2Little, adopt signal S in low-light (level) one side
1So, do not improve the problem of noise level.
In addition, the sticking potential of CFD has skew in each pixel, on charge number, is 1 * 10
4~2 * 10
4, but before entering this zone, switch to and use C
FD+ C
SSignal S
1+ S
2So, be not subjected to C
FDThe advantage of influence of skew of sticking potential.
In addition, even reference potential V
0Skew, near band reference potential, C
FDCharge number and C
FD+ C
SThe charge number unanimity, so near reference potential, no matter use signal S
1, or signal S
1+ S
2All no problem.
Fig. 8-the 3rd, overlapping expression describes to use the capacitor C shown in Fig. 8-1 for relative light quantity
FDThe time the curve chart of voltage of floating region (be expressed as C
FD), describe to use the capacitor C shown in Fig. 8-2 for relative light quantity
FD+ C
SThe time the figure of curve chart of voltage of floating region.Correspond respectively to the curve chart shown in Fig. 8-1 and Fig. 8-2 is transformed to voltage from charge number.
, if use capacitor C
FD+ C
SEven, then shine identical light quantity, obtain identical charge number, C
SCapacitance also increase, so the voltage after the conversion descends by this part.
As mentioned above, low-light (level) one side before surpassing reference potential 0.3V is used by C
FDThe signal S of the curve chart of expression
1, high illumination one side surpassing 0.3V switches to by C
FD+ C
SThe signal S of the curve chart of expression
1+ S
2
According to the structure and the described method of operating of the cmos image sensor of present embodiment, obtain from eliminating noise respectively saturated before charge signal (S
1), saturated before charge signal and supersaturation charge signal and (S
1+ S
2) 2 signals, if photodiode PD (C
PD) unsaturation, just adopt saturated preceding charge signal (S
1), if saturated, just adopt saturated before charge signal and supersaturation charge signal and (S
1+ S
2).
In the unsaturated low-light (level) shooting of photodiode PD, by eliminating the saturated preceding charge signal (S that noise is obtained
1), can keep high sensitivity, high S/N ratio, in the saturated high illumination of photodiode PD is made a video recording, the optical charge that overflows from photodiode is put aside by the savings capacity cell, be taken into it, with described same, by eliminate the signal that noise obtains (before saturated charge signal and supersaturation charge signal and (S
1+ S
2)), can keep high S/N ratio, enlarge dynamic range in high illumination one side.
The cmos image sensor of present embodiment is except as mentioned above, do not reduce the sensitivity of low-light (level) one side, improve the sensitivity of high illumination one side, enlarge dynamic range, supply voltage does not rise from normally used scope yet, so can be corresponding to the miniaturization of imageing sensor in the future.
Appending of element suppresses minimumly, do not cause the expansion of Pixel Dimensions.
Need not as the imageing sensor of in the past realization wide dynamic range, cut apart the savings time, promptly not stride frame ground and put aside in the time, so can tackle the shooting of animation at same savings in high illumination one side and low-light (level) one side.
In addition, about the leakage current (FD leakage) of floating region FD, in the imageing sensor of present embodiment, C
FD+ C
SMinimum signal become supersaturation electric charge+, handle the also big quantity of electric charge of electric charge that leaks than FD from the saturated charge of photodiode PD, so have the advantage that is difficult to be subjected to the influence that FD leaks.
Execution mode 2
Present embodiment is the form of the circuit structure of the pixel of the cmos image sensor of execution mode 1 distortion.
Fig. 9-the 1st, the equivalent circuit figure of a pixel portion of an example of the cmos image sensor of present embodiment.Same with the equivalent circuit figure of Fig. 1 in fact, but amplifier transistor Tr4 and the connection difference of selecting transistor Tr 5, be higher level's one side that selection transistor Tr 5 is configured in amplifier transistor Tr4, the form that the output of amplifier transistor Tr4 is connected with output line out.
By such connection, can improve the Amplifier Gain of amplifier transistor Tr4.
In addition, Fig. 9-the 2nd, the equivalent circuit figure of a pixel portion of other examples of the cmos image sensor of present embodiment.Same with the equivalent circuit figure of Fig. 1 in fact, but, be structure with p channel MOS transistor displacement n channel MOS transistor about passing on 5 transistors such as transistor Tr 1, savings transistor Tr 2, reset transistor Tr3, amplifier transistor Tr4, selection transistor Tr 5.
In view of the above, the complete electric charge that can realize the hole passes on the imageing sensor of type, for example as silicon substrate, is suitable for situation about using by the p type etc.
Other structures can adopt the same structure of cmos image sensor with execution mode 1.
Cmos image sensor according to present embodiment, same with execution mode 1, in the undersaturated low-light (level) shooting of photodiode PD, by eliminating the saturated preceding charge signal that noise is obtained, can keep high sensitivity, high S/N ratio, in the saturated high illumination of photodiode PD is made a video recording, put aside the optical charge that overflows from photodiode by the savings capacity cell, be taken into it, with described same,, keep high S/N ratio by eliminating the signal that noise obtains (before saturated charge signal and supersaturation charge signal and), in high illumination one side, can realize wide dynamic range.
Execution mode 3
The solid camera head of present embodiment is a ccd image sensor.
Figure 10-the 1st, the equivalent circuit figure of an amount of pixels of an example of the ccd image sensor of present embodiment.
φ
V1And φ
V22 first electric charges couplings that drive mutually pass on route CCD1 and the coupling of second electric charge and pass on route CCD2 and extend configuration in vertical direction, the coupling of photodiode PD and first electric charge is passed on route CCD1 and directly is connected, and is coupled and passes on route CCD2 and be connected via passing on transistor Tr 1 and second electric charge.
Here, second electric charge coupling is passed on route CCD2 when photodiode PD is saturated, the savings capacity cell C of the optical charge that overflows from photodiode PD as savings
SWork.
In the ccd image sensor of described structure, pass on route CCD1 by first electric charge coupling and pass on the saturated front signal of low-light (level) one side, read by the driving of CCD, and with putting aside capacity cell C
SPut aside the supersaturation signal of high illumination one side, by savings capacity cell C
SThe driving of route CCD2 is passed in second electric charge coupling that constitutes, and remains untouched and reads.
Saturated front signal by reading low-light (level) one side respectively, the supersaturation signal of the optical charge that overflows from photodiode by high illumination one side of savings capacity cell savings, can realize wide dynamic range in high illumination one side.
Figure 10-the 2nd, the equivalent circuit figure of a pixel portion of other examples of the ccd image sensor of present embodiment.
Be equivalent in the cmos image sensor of execution mode 1, pass on route CCD1 by first electric charge coupling and pass on the saturated front signal of low-light (level) one side, the structure of reading by the driving of CCD.The reading to read equally with the signal of the cmos image sensor of execution mode 1 of the supersaturation signal of high illumination one side carried out.
At this moment, do not need to mix the step of saturated front signal and supersaturation signal, so floating region FD and savings capacity cell C can be set
SBetween savings transistor Tr 2.
Saturated front signal by reading low-light (level) one side respectively, the supersaturation signal of the optical charge that overflows from photodiode by high illumination one side of savings capacity cell savings, can realize wide dynamic range in high illumination one side.
Execution mode 4
Present embodiment is the form of the circuit structure of the pixel of the cmos image sensor of execution mode 1 distortion.
Figure 11-the 1st, the equivalent circuit figure of an amount of pixels of an example of the cmos image sensor of present embodiment.Same with the equivalent circuit figure of Fig. 1 in fact, still, be to append to constitute savings capacity cell C
SThe optical charge of middle savings is made logarithmic transformation, the form of the transistor Tr 6~8 of the logarithmic transformation circuit of reading.
By carrying out logarithmic transformation on one side, Yi Bian read, can tackle high illumination shooting, can realize wide dynamic range.Near photodiode PD saturated,, can improve S/N by mixing saturated front signal and supersaturation signal.
Figure 11-the 2nd, the equivalent circuit figure of an amount of pixels of other examples of the cmos image sensor of present embodiment.
Be to append the optical charge that constitutes overflowing to make logarithmic transformation from photodiode PD, savings capacity cell C
SIn the form of transistor Tr 6,7,9,10 of logarithmic transformation circuit.
By carrying out logarithmic transformation on one side, Yi Bian read, can tackle high illumination shooting, can realize wide dynamic range.Carry out logarithmic transformation, savings capacity cell C
SIn, so even savings capacity cell C
SLittle, also can help wide dynamic rangeization.
Execution mode 5
The solid camera head of present embodiment is the cmos image sensor same with execution mode 1, and Figure 12 is the equivalent circuit figure of an amount of pixels.
Each pixel by receive light and generate optical charge photodiode PD, pass on from the optical charge of photodiode PD pass on transistor Tr 1, pass on the savings capacity cell C of the floating region FD of optical charge, savings overflows from described photodiode when the savings action optical charge by passing on transistor Tr 1
S, floating region FD and savings capacity cell C
SElectromotive force in conjunction with or the savings transistor Tr 2 cut apart, with savings capacity cell C
SDirectly connect and be connected to form with floating region FD, and be used for discharging savings capacity cell C via savings transistor Tr 2
SAnd the reset transistor Tr3 of the optical charge in the floating region FD, the optical charge in the floating region FD amplified be transformed to the amplifier transistor Tr4 of voltage signal and be connected to form with amplifier transistor and be used to select the selection transistor Tr 5 of pixel to constitute, be the cmos image sensor of so-called 5 transistor-types.For example described 5 transistors all are made of the n channel MOS transistor.
The cmos image sensor of present embodiment becomes array-like to a plurality of set of pixels of described structure, in each pixel, is passing on the gate electrode connection φ of transistor Tr 1, savings transistor Tr 2, reset transistor Tr3
T, φ
S, φ
REach drive wire, in addition, connect the pixel selection line SL (φ that drives by line shift register at the gate electrode of selecting transistor Tr 5
X), be connected output line out at the output one side source electrode of selecting transistor Tr 5 with drain electrode, by column shift register control, output.
About selecting transistor Tr 5, drive wire φ
X, for the selection that can carry out pixel, non-selection action, as long as it is just passable that the voltage of floating region FD is fixed on suitable value, so also can omit them.
Figure 13 is equivalent to described photodiode PD, passes on transistor Tr 1, floating region FD, savings transistor Tr 2, savings capacity cell C
SThe pattern potential energy diagram.
Photodiode PD constitutes the capacitor C of shallow relatively electromotive force
PD, floating region FD and savings capacity cell C
SConstitute the electric capacity (C of dark relatively electromotive force
FD, C
S).
Here, pass on transistor Tr 1 and savings transistor Tr 2, can get 2 energy levels according to transistorized on/off.
The driving method of the cmos image sensor of the present embodiment that illustrates in the potential energy diagram of equivalent circuit figure, Figure 13 of Figure 12 is described.
Figure 14-the 1st is with drive wire (φ
T, φ
S, φ
R) on the voltage that adds be that 2 energy levels of on/off add about φ
TWith the (+α) sequential chart represented of 3 energy levels of energy level of expression.
Though drive wire φ
TOn the voltage that adds be that 2 energy levels of ON/OFF are just passable, but when as this example, being 3 energy levels, can be more effectively the charge-trapping that overflows from photodiode PD to floating region FD and savings capacity cell C
SIn, savings.
In addition, Figure 15-1~Figure 15-3 and Figure 16-1~Figure 16-3 is equivalent to the potential energy diagram of each sequential of sequential chart.
At first, at the beginning of a field (1F), φ
TBe off, φ
SUnder the state on, φ
RBe on, the optical charge that produces in the preceding field is all discharged, reset, at moment T
1, φ
RBe off.
At this moment, shown in Figure 15-1, φ
SBe on, so become C
FD, C
SThe state of coupling after resetting, is accompanied by homing action, at C
FD+ C
SThe so-called kTC noise of middle generation.Here, C
FD+ C
SThe signal of reset level as noise N
2Read.
Then, in the savings time T
LTThe time, the optical charge that generates among the savings photodiode PD.At this moment, about φ
T, as (+α) energy level is C
PDAnd C
FDBetween potential barrier reduce a little.
If the savings of electric charge begins, optical charge is at first put aside C
PDIn, when photoelectron for making C
PDWhen saturated amount is above, shown in Figure 15-2, surmount φ
TOnly having descended, (+α) the potential barrier of energy level, optical charge is from C
PDOverflow, put aside the C of this pixel selectively
FD+ C
SIn.
When photoelectron for making C
PDWhen saturated amount is following, only at C
PDIn the savings optical charge, when photoelectron for making C
PDWhen saturated amount is above, except C
PD, at C
FDAnd C
SIn also put aside optical charge.
Figure 15-2 represents C
PDSaturated, at C
PDCharge Q before middle savings is saturated
B, at C
FDAnd C
SMiddle savings supersaturation charge Q
AState.
In the savings time T
LTEnd the time, φ
TFrom (+α) energy level is got back to off, at moment T
2, φ
SBe off, shown in Figure 15-3, cut apart C
FDAnd C
SElectromotive force.At this moment, supersaturation charge Q
AAccording to C
FDAnd C
SCapacity ratio, be divided into Q
A1And Q
A2Here, keeping supersaturation part of charge Q
A1C
FDLevel signal as noise N
1Read.
Then make φ
TBe on, shown in Figure 16-1, C
PDIn saturated before charge Q
BTo C
FDPass on, with original C
FDThe middle supersaturation part of charge Q that keeps
A1Mix.
Here, C
PDElectromotive force compare C
FDShallow, the transistorized energy level that passes on compares C
PDDeeply, so can realize being positioned at C
PDIn saturated before charge Q
BAll transfer to C
FDComplete electric charge pass on.
At moment T
3, φ
TGet back to off, from transferring to C
FDSaturated before charge Q
BRead saturated preceding charge signal S
1, here, at C
FDIn exist saturated before charge Q
BWith supersaturation part of charge Q
A1And electric charge, actual read become S
1+ N
1Figure 16-1 expression makes φ
TGet back to off state before.
Then, make φ
SBe on, then make φ
TBe on, thereby C
FDAnd C
SThe electromotive force combination, shown in Figure 16-2, mixed C
FDIn saturated before charge Q
BWith supersaturation part of charge Q
A1And electric charge, C
SIn supersaturation part of charge Q
A2Supersaturation part of charge Q
A1With supersaturation part of charge Q
A2And be equivalent to cut apart before the supersaturation charge Q
ASo, become at C
FDAnd C
SIn conjunction with electromotive force in keep saturated before charge Q
BWith the supersaturation charge Q
AState.
Here, at moment T
4, make φ
TGet back to off, from expanding to C
FD+ C
SSaturated before charge Q
BWith the supersaturation charge Q
ARead saturated preceding charge signal S
1With supersaturation charge signal S
2And signal., have C here
FD+ C
SNoise is because from expanding to C
FD+ C
SElectric charge read, so actual read become S
1'+S
2'+N
2(S
1', S
2' be respectively according to C
FDAnd C
SCapacitance ratio, dwindle the S after the modulation
1And S
2Value).Figure 16-2 represents φ
TGet back to off state before.
More than, field (1F) finishes, and transfers to next field, at φ
TBe off, φ
SUnder the state on, make φ
RBe on, shown in Figure 16-3, the optical charge that produced in the former field all discharged, reset.
From by described 4 signal N that obtain
2, N
1, S
1+ N
1, S
1'+S
2'+N
2, by the step same with execution mode 1, obtain saturated before charge signal (S
1), saturated before charge signal and supersaturation charge signal and (S
1+ S
2).According to be saturated before or saturated after, select signal arbitrarily.
In described explanation, read noise N
2, put aside in the frame memory, when generating picture signal, utilize noise N
2, but when supersaturation, compare noise N with saturated preceding electric charge+supersaturation electric charge
2Enough little, so replace the noise N of present frame
2, can use the noise N of next frame
2
In addition, can drive according to the sequential chart shown in Figure 14-2.For the sequential chart of Figure 14-1, during the homing action of each field in, be provided with and make φ
TFor different during the on.At this moment, connect C
PDIn electric charge can both reset reliably.
Except described, all circuit structures and execution mode 1 are same structures.
Figure 17 is in the CMOS of present embodiment solid camera head, an example of the layout of the about amount of pixels when adopting plane savings capacity cell.
As dispose photodiode PD, savings capacity cell CS and 5 transistor Tr 1~Tr5 scheming, connect the floating region FD between transistor Tr 1 and the transistor Tr 2 and the grid of transistor Tr 4 with wiring W1, connect diffusion layer and savings capacity cell C between transistor Tr 2 and the transistor Tr 3 with wiring W2
SUpper electrode, can realize being equivalent to the circuit of the equivalent circuit figure of present embodiment shown in Figure 13.
In this layout, the channel width of transistor Tr 1 of passing on is wide in photodiode PD one side, and is narrow in floating region FD one side.Therefore, can efficiently make the electric charge that overflows from photodiode spill into floating region one side.And narrow down in floating region FD one side, can reduce the electric capacity of floating region FD, can increase the amplitude of fluctuation of current potential for the electric charge of putting aside among the floating region FD.
According to the cmos image sensor of present embodiment, same with execution mode 1, the saturated preceding charge signal (S that obtains from eliminating noise respectively
1), saturated before charge signal and supersaturation charge signal and (S
1+ S
2) 2 signals, if photodiode PD (C
PD) unsaturation, just adopt saturated preceding charge signal (S
1), if saturated, just adopt saturated before charge signal and supersaturation charge signal and (S
1+ S
2).
In the unsaturated low-light (level) shooting of photodiode PD, by eliminating the saturated preceding charge signal (S that noise is obtained
1), can keep high sensitivity, high S/N ratio, in the saturated high illumination of photodiode PD is made a video recording, the optical charge that overflows from photodiode is put aside by the savings capacity cell, be taken into it, with described same, by eliminate the signal that noise obtains (before saturated charge signal and supersaturation charge signal and (S
1+ S
2)), can keep high S/N ratio, enlarge dynamic range in high illumination one side.
The cmos image sensor of present embodiment is except as mentioned above, do not reduce the sensitivity of low-light (level) one side, improve the sensitivity of high illumination one side, enlarge dynamic range, supply voltage does not rise from normally used scope yet, so can be corresponding to the miniaturization of imageing sensor in the future.
Appending of element suppresses minimumly, do not cause the expansion of Pixel Dimensions.
Need not as the imageing sensor of in the past realization wide dynamic range, cut apart the savings time, promptly not stride frame ground and put aside in the time, so can tackle the shooting of animation at same savings in high illumination one side and low-light (level) one side.
In addition, about the leakage current (FD leakage) of floating region FD, in the imageing sensor of present embodiment, C
FD+ C
SMinimum signal become supersaturation electric charge+, handle the also big quantity of electric charge of electric charge that leaks than FD from the saturated charge of photodiode PD, so have the advantage that is difficult to be subjected to the influence that FD leaks.
The cmos image sensor of present embodiment and first execution mode are not subjected to the influence of the saturated skew of PD in the same manner.
Execution mode 6
The cmos sensor of present embodiment is in the cmos sensor of described execution mode 1~5, by adopting following structure, can suppress the cmos sensor of the leakage of floating region.
Figure 18-the 1st represents the cutaway view of floating region part of the cmos sensor of present embodiment in detail.
The active area of p type wells (p-well) 11 is separated by the element separating insulation film 20 based on the silica of LOCOS method, be equivalent to element separating insulation film 20 below p type wells 11 in form p
+Type Disengagement zone 12.In addition, below the end 20a of the LOCOS element separating insulation film 20 that is called beak, form p
+ Type Disengagement zone 12a.
Leave given distance from the end 20a of element separating insulation film 20, form the gate electrode 30 of polysilicon on the surface of p type wells 11 via the gate insulating film 23 that constitutes by silica.Form the sidewall spacing block 30a of silicon nitride at the sidepiece of gate electrode.
The top layer of the p type wells 11 between gate electrode 30 and element separating insulation film 20 becomes the n of floating region FD
+N-type semiconductor N district 15.n
+N-type semiconductor N district 15 is made of low concentration impurity district 15a and high concentration impurities district 15b.Here, become so-called LDD (the Lightly Doped Drain) structure that low concentration impurity district 15a stretches out from the end of high concentration impurities district 15b, near the 20a of the end of element separating insulation film 20 and near the gate electrode 30, at the end of element separating insulation film 20 20a and the more extensive formation low concentration impurity district 15a of gate electrode 30 1 sides.
By described gate electrode 30 and n
+What the top layer that source electrode that N-type semiconductor N district 15 constitutes and drain electrode are formed in p type wells 11 had a channel formation region passes on transistor Tr 1.
Cover gate electrode 30, n
+N-type semiconductor N district 15 and element separating insulation film 20 form the interlayer dielectric that is made of silica, form to arrive n
+The contact in N-type semiconductor N district 15, the n in the bottom, contact
+The stacked TiSi floor in the upper strata in N-type semiconductor N district 15 (perhaps Ti floor) 41 and TiN floor 42, layer embeds the contact thereon, forms tungsten plug 43.Be connected with tungsten plug 43, form upper strata wiring 44 on the upper strata of interlayer dielectric.To cover n
+The area in N-type semiconductor N district 15 forms upper strata wiring 44, is connected by the contact in addition, becomes and n
+The current potential that N-type semiconductor N district 15 is identical.
In cmos sensor, form p in the bottom of the beak of LOCOS element separating insulation film 20 with the structure shown in Figure 18-1
+ Type Disengagement zone 12a, n
+N-type semiconductor N district 15 becomes the LDD structure, relaxes n
+Near the beak of the end in the N-type semiconductor N district 15 LOCOS element separating insulation film 20 that particularly stress is big electric field is concentrated, so can suppress n
+Leakage in the N-type semiconductor N district 15 (floating region FD).
In addition, cover n
+N-type semiconductor N district 15 (floating region FD) forms idiostatic upper layer part line 44, by the screen effect based on upper layer part line 44, can suppress to become the n of the reason of leakage
+The exhausting on the surface in N-type semiconductor N district 15 (floating region FD).
As mentioned above, be to suppress n significantly
+The structure of the leakage in N-type semiconductor N district 15 (floating region FD).
Figure 18-2 and Figure 18 the-the 3rd, the cutaway view of the manufacturing step of the cmos sensor shown in the presentation graphs 18-1.
Shown in Figure 18-2, become the p that raceway groove blocks portion in the element Disengagement zone of p type well 11
+ Type Disengagement zone 12 by the LOCOS method, forms element separating insulation film 20, forms p in the beak bottom of element separating insulation film 20
+ Type Disengagement zone 12a.
Then form gate insulating film 23 on the surface of p type well 11 by thermal oxidation method, composition forms gate electrode 30, in order to stipulate the end by the beak of gate electrode and element separating insulation film 20, ion injects the conductive impurities DP1 of n type, forms low concentration impurity district 15a.
Then shown in Figure 18-3,, form silicon nitride film, by etching, at the sidepiece formation sidewall spacing block 30a of gate electrode 30 by CVD method (chemical vapour deposition (CVD)) comprehensively.In addition, stretch out to a certain degree, form etchant resist PR with the pattern of cladding element separating insulation film 20 from beak.
In order to stipulate the end by described sidewall spacing block 30a and etchant resist PR, ion injects the conductive impurities DP2 of n type, forms high concentration impurities district 15b.
By described step, not only the easy side of gate electrode also can become the LDD structure in LOCOS element separating insulation film 20 1 sides.
Then,, form interlayer dielectric,, form and arrive n for the interlayer dielectric of obtaining comprehensively the silica film forming by the CVD method
+The contact in N-type semiconductor N district for example by sputtering method, forms TiSi layer (perhaps Ti) layer 41 in the bottom, contact, forms TiN layer 42 again, embeds in the contact and forms tungsten plug 43.By metal material, to cover n
+The width in N-type semiconductor N district 15 forms upper strata wiring 44, becomes the structure shown in Figure 18-1.
According to the cmos sensor of present embodiment, same with described each execution mode, can realize wide dynamic range in high illumination one side, and can suppress the leakage current of floating region.
Execution mode 7
The cmos sensor of present embodiment is in the cmos sensor of described execution mode 1~6, drive wire φ
TOn the voltage that adds be not with shown in Fig. 3-1 (+α) the energy level of expression only with 2 energy levels of on/off, just can make when the savings of electric charge the electric charge that overflows from photodiode to the floating region cmos sensor of mobile structure smoothly.
In the cmos sensor shown in Figure 19-1 and Figure 19-2, the transistor that passes on be have constitute pass on transistorized substrate the surface or from the near surface to the given depth, form with pass on the embedding channel-type of semiconductor layer of transistorized raceway groove same conductivity.
Figure 19-the 1st, the cutaway view of an example of the cmos sensor of present embodiment is equivalent to photodiode PD, passes on the part of transistor Tr 1, floating region FD, savings transistor Tr 2.Become the source electrode of savings transistor Tr 2 and the n of drain electrode
+N-type semiconductor N district 16 is connected with not shown savings capacity cell CS.
Here, from passing on the surface of substrate of gate electrode 30 bottoms of transistor Tr 1 to given depth, with n N-type semiconductor N district 13 and n
+N-type semiconductor N district 15 is local overlapping, forms n N-type semiconductor N district 50.N N-type semiconductor N district 50 is than n N-type semiconductor N district 13 and n
+The n type district that the valid density of the impurity in N-type semiconductor N district 15 is low.
In described structure, the transistor Tr 1 of passing on embeds raceway grooveization, and this is equivalent to reduce the potential barrier between photodiode and the floating region.Therefore, even at drive wire φ
TOn do not add by Fig. 3-1 (+α) expression current potential, also can obtain equal electromotive force, when the savings of electric charge, can successfully move the electric charge that overflows from photodiode to floating region.
Figure 19-the 2nd, the cutaway view of an example of the cmos sensor of present embodiment, same with the cmos sensor of Figure 19-1, from passing on the surface of substrate of gate electrode 30 bottoms of transistor Tr 1 to given depth, with n N-type semiconductor N district 13 and n
+N-type semiconductor N district 15 is local overlapping, forms n N-type semiconductor N district 50.Up to passing on gate electrode 30 lower areas of transistor Tr 1, extend to form the p that forms on the top layer of photodiode PD
+N-type semiconductor N district 14.
By forming n N-type semiconductor N district 50 and p
+N-type semiconductor N district 14, the transistor Tr 1 of passing on embeds raceway grooveization, and this is equivalent to reduce the potential barrier between photodiode and the floating region.Therefore, even at drive wire φ
TOn do not add by Fig. 3-1 (+α) expression current potential, also can obtain equal electromotive force, when the savings of electric charge, can successfully move the electric charge that overflows from photodiode to floating region.
Cmos sensor shown in Figure 20-1 and Figure 20-2 is to pass on transistor to have and pass on the given depth of transistorized substrate in formation and form, and passes on transistorized raceway groove homotype mutually, reduces to pass on the structure of semiconductor layer of transistorized punch through barrier.
Figure 20-the 1st, the cutaway view of an example of the cmos sensor of present embodiment is equivalent to photodiode PD, passes on the part of transistor Tr 1, floating region FD, savings transistor Tr 2.Become the element of savings transistor Tr 2 and the n of drain electrode
+N-type semiconductor N district 16 is connected with not shown savings capacity cell CS.
Passing in the zone of given depth of gate electrode 30 bottoms of transistor Tr 1, be connected with n N-type semiconductor N district 13, form n N-type semiconductor N district 51.
Described structure is equivalent to reduce and passes on the punch through barrier of transistor Tr 1.51 to floating region FD oblique break-through route becomes and overflows route PA from photodiode to floating region FD from n N-type semiconductor N district, even at drive wire φ
TOn do not add by Fig. 3-1 (+α) expression current potential, when the savings of electric charge, also can the electric charge break-through of overflowing from photodiode successfully be moved to floating region.
Figure 20-the 2nd, the cutaway view of an example of the cmos sensor of present embodiment, same with the cmos sensor of Figure 20-1, passing in the zone of given depth of gate electrode 30 bottoms of transistor Tr 1, be connected with n N-type semiconductor N district 13, form n N-type semiconductor N district 52.In present embodiment, n N-type semiconductor N district 52 extends to form the below of floating region.
Described structure is equivalent to reduce and passes on the punch through barrier of transistor Tr 1.The break-through route of 52 to floating region FD almost vertical direction becomes and overflows route PA from photodiode to floating region FD from n N-type semiconductor N district, even at drive wire φ
TOn do not add by Fig. 3-1 (+α) expression current potential, when the savings of electric charge, also can the electric charge break-through of overflowing from photodiode successfully be moved to floating region.
Execution mode 8
Present embodiment is illustrated in described each execution mode, is used to put aside the variation of form of the savings capacity cell of the optical charge that overflows from photodiode.
As the savings capacity cell, when considering junction type savings capacity cell, consideration condition, 1 μ m
2Electrostatic capacitance be 0.3~3fF/ μ m
2About, area efficiency is not so good, is difficult to enlarge dynamic range.
And in plane savings capacity cell, in order to suppress the dielectric film leakage current of capacitor insulating film, making the dielectric film electric field is below 3~4MV/cm, maximum applied voltage is 2.5~3V, when the thickness setting of capacitor insulating film is the 7nm left and right sides, the dielectric constant of the material of capacitor insulating film is 3.9, is 4.8fF/ μ m
2, dielectric constant is 7.9, is 9.9fF/ μ m
2, dielectric constant is 20, is 25fF/ μ m
2, dielectric constant is 50, is 63fF/ μ m
2
Except silica (dielectric constant is 3.9), by using silicon nitride (7.9), Ta
2O
5(20~30), HfO
2(30), ZrO
2(30), Ra
2O
3So-called high k material about (40~50) can be realized bigger static capacity, can realize the imageing sensor of the wide dynamic range of 100~120dB of the plane of structure relatively merely.
By use suppressing occupied area, can enlarge structures such as the stack-up type of the area that helps electric capacity or ditch type, can realize the wide dynamic range of 120dB, by making up described high k material, can realize 140dB with stack-up type, can realize 160dB with the ditch type.
The example of below representing applicable savings capacity cell in the present embodiment.
Figure 21-the 1st, the profile of the plane MOS savings capacity cell identical with first execution mode.
Promptly put aside capacity cell CS and be for example have the top layer part that is formed on savings capacity cell 10 become lower electrode p
+N-type semiconductor N district 17, be formed on p
+The capacitor insulating film 25 of the silica in the N-type semiconductor N district 17, be formed on the structure of the upper electrode 32 of polysilicon on the capacitor insulating film 25 etc.
Figure 21-the 2nd, the profile of the savings capacity cell of plane MOS and junction type.
For example, be formed on the top layer part of the p type well 11 on the n N-type semiconductor N substrate 10, with the n that becomes transistorized source electrode of savings and drain electrode
+The integrally formed n that becomes lower electrode of N-type semiconductor N district 16a
+N-type semiconductor N district 16b, the capacitor insulating film 25 formation upper electrodes 32 via the silica on it constitute savings capacity cell C
SAt this moment, at upper electrode 32 additional power source voltage VDD or ground connection GND.
Savings capacity cell shown in the cutaway view of Figure 22-1 is the plane MOS savings capacity cell same with Figure 21-1.
, capacitor insulating film 25a is by silicon nitride or Ta
2O
5Contour k material constitutes, and is bigger than the electric capacity of the savings capacity cell of Figure 21-1.
Savings capacity cell shown in the cutaway view of Figure 22-2 is and the same plane MOS of Figure 21-2 and the savings capacity cell of junction type.
, capacitor insulating film 25a is by silicon nitride or Ta
2O
5Contour k material constitutes, and is bigger than the electric capacity of the savings capacity cell of Figure 21-2.
Figure 23-the 1st, the cutaway view of stack-up type savings capacity cell.
For example, be to have the lower electrode 37 that forms on the element separating insulation film that is formed on the n N-type semiconductor N substrate 10, be formed on capacitor insulating film 25 on the lower electrode 37, be formed on the structure of the upper electrode 38 on the capacitor insulating film 25.
Here, become the n of transistorized source electrode of savings and drain electrode
+N-type semiconductor N district 16 is connected by wiring 36 with lower electrode 37.At this moment, additional power source voltage VDD or ground connection GND on upper electrode 38.
Figure 23-the 2nd, the cutaway view of the stack-up type savings capacity cell of drum.
For example, be to have and the n that becomes transistorized source electrode of savings and drain electrode
+The structure of the lower electrode 37a of the drum that N-type semiconductor N district 16 is connected to form, the capacitor insulating film 25 that on the internal face of the lower electrode 37a of drum, forms, the upper electrode 38a that forms via capacitor insulating film 25 in the mode of the inside part of the cylinder of burying lower electrode 37a.
Here, additional power source voltage VDD or ground connection GND on upper electrode 38a.
The lower electrode 37a of drum compares with common stack-up type with the structure of the upper electrode 38a that mode with the inside part of the cylinder of burying lower electrode 37a forms, more can increase the relative area that helps electrostatic capacitance.
Figure 24 is the cutaway view of the compound savings capacity cell of combined planar MOS type and stack-up type.According to this example, can form the high big electric capacity of area efficiency.
Figure 25-the 1st, the cutaway view of ditch type savings capacity cell.
Connecting the p type well 11 of n N-type semiconductor N substrate 10, form the ditch TC that arrives n type substrate, is the n that becomes lower electrode that has in the inwall formation of ditch TC
+N-type semiconductor N district 18, cover the inwall of ditch TC and the capacitor insulating film 25 that forms, bury ditch TC and the structure of the upper electrode 40 that forms via capacitor insulating film 25.
Here, become the n of transistorized source electrode of savings and drain electrode
+N-type semiconductor N district 16 is connected by wiring 34 with upper electrode 40.
Figure 25-the 2nd, the ditch type with knot is put aside the cutaway view of capacity cell.
Be in the p type well 11 of n N-type semiconductor N substrate, to form ditch TC, at inwall and the n that becomes transistorized source electrode of savings and drain electrode of ditch TC
+The integrally formed n that becomes lower electrode of N-type semiconductor N district 16c
+N-type semiconductor N district 16d, the inwall that covers ditch TC forms capacitor insulating film 25, buries ditch TC and forms the structure of upper electrode 40 via capacitor insulating film 25.
Figure 26-the 1st, the cutaway view of ditch type savings capacity cell.
Be the p type well 11 that connects n N-type semiconductor N substrate 10, form the ditch TC that arrives n type substrate, in the darker zone of ditch TC, have the n that becomes lower electrode that is formed on its inwall than certain degree of depth
+N-type semiconductor N district 18, cover the inwall of ditch TC and the capacitor insulating film 25 that forms, bury ditch TC and the structure of the upper electrode 40 that forms via capacitor insulating film 25.
Here, become the n of transistorized source electrode of savings and drain electrode
+N-type semiconductor N district 16 is connected by wiring 34 with upper electrode 40.
Figure 26-the 2nd, the cutaway view of ditch type savings capacity cell.
Be the p type well 11 that connects n N-type semiconductor N substrate 10, form the ditch TC that arrives n type substrate, have the p that becomes lower electrode that is formed on ditch TC inwall
+N-type semiconductor N district 19, cover the inwall of ditch TC and the capacitor insulating film 25 that forms, bury ditch TC and the structure of the upper electrode 40 that forms via capacitor insulating film 25.
At this, be connected to become the n of the transistorized source electrode of savings, drain electrode by wiring 34
+N-type semiconductor N district 16 and upper electrode 40.
Figure 27 is the cutaway view with cmos sensor of the embedding savings capacity cell that uses junction capacitance.
For example, on p type silicon semiconductor substrate (p-sub) 60, form p type epitaxial loayer 61, stride p N-type semiconductor N substrate 60 and p type epitaxial loayer 61, form n
+N-type semiconductor N district 62.That is n,
+Type (first conductivity type) semiconductor region and p type (second conductivity type) semiconductor region that engages with it embed the inside of the semiconductor substrate that constitutes solid camera head, form the embedding savings capacity cell that uses junction capacitance.
In p N-type semiconductor N substrate 60 and p type epitaxial loayer 61 districts, further form p+ type Disengagement zone 63.
On p type epitaxial loayer 61, form p type semiconductor layer 64, same for p type semiconductor layer 64 with described each execution mode, form photodiode PD, pass on transistor Tr 1, floating region FD, savings transistor Tr 2.
For example, become the n of savings capacity cell
+N-type semiconductor N district 62 strides described photodiode PD, each of transistor Tr 1, floating region FD, savings transistor Tr 2 of passing on forms the district and extensively formed.
In addition, become the source electrode of savings transistor Tr 2 and the n of drain electrode
+N-type semiconductor N district 16 is by vertically extending n in p type semiconductor layer 64
+N-type semiconductor N district 65 is with the n that constitutes the savings capacity cell
+N-type semiconductor N district 62 connects.
Figure 28 is the cutaway view with cmos sensor of the embedding savings capacity cell that uses capacitance insulation film and junction capacitance.
Though be the structure same with Figure 27, but become on p N-type semiconductor N substrate (p-sub) 60, form a p type epitaxial loayer 61a and the 2nd p type epitaxial loayer 61b via dielectric film 60a, on semiconductor substrate, form SOI (the Semiconductor on Insulator) substrate of semiconductor layer via dielectric film.
Here, stride a p type epitaxial loayer 61a and the 2nd p type epitaxial loayer 61b, arrive the zone that contacts with dielectric film 60a, form n
+N-type semiconductor N district 62 uses via relative semiconductor substrate of dielectric film and the capacitance insulation film between the semiconductor layer, constitutes the savings capacity cell.
Same with the savings capacity cell of Figure 27, at n
+Form junction capacitance between N-type semiconductor N district 62, a p type epitaxial loayer 61a and the 2nd p type epitaxial loayer 61b.
About other structures, same with the cmos sensor of Figure 27.
Figure 29 is the cutaway view with cmos sensor of the embedding savings capacity cell that uses capacitance insulation film and junction capacitance.
Though be the structure same, at the n of n N-type semiconductor N district 13 that constitutes photodiode PD and formation savings capacity cell with Figure 28
+Form low concentration semiconductor layer (i floor) 66 between the N-type semiconductor N district 62.
Described structure is equivalent to reduce n N-type semiconductor N district 13 and n
+Potential barrier between the N-type semiconductor N district 62 becomes and overflows route PA from photodiode to floating region FD.In view of the above, even at drive wire φ
TOn do not add by Fig. 3-1 (+α) expression current potential, when the savings of electric charge, also can the electric charge break-through of overflowing from photodiode be moved to floating region.
Described various savings capacity cell can both be used in above-mentioned execution mode 1~7, as mentioned above, puts aside the optical charge that overflows from photodiode by the savings capacity cell of these shapes, can realize wide dynamic range in high illumination one side.
(embodiment 1)
In cmos image sensor of the present invention, make C
FDAnd C
SSaturation voltage, C
SElectrostatic capacitance value when being changed to various value, obtain the dynamic range that can realize by emulation.Here, noise level is 2e
-
C
FDAnd C
SSaturation voltage be 500mV, C
SDuring for the electrostatic capacitance of 64fF, perhaps C
FDAnd C
SSaturation voltage be 1V, C
SDuring for the electrostatic capacitance of 32fF, comprise C
SSaturated the time electron number be 2 * 10
5e
-, can realize the dynamic range of 100dB.
In addition, C
FDAnd C
SSaturation voltage be 500mV, C
SDuring for the electrostatic capacitance of 200fF, perhaps C
FDAnd C
SSaturation voltage be 1V, C
SDuring for the electrostatic capacitance of 100fF, comprise C
SSaturated the time electron number be 6.3 * 10
5e
-, can realize the dynamic range of 110dB.
C
FDAnd C
SSaturation voltage be 500mV, C
SDuring for the electrostatic capacitance of 640fF, perhaps C
FDAnd C
SSaturation voltage be 1V, C
SDuring for the electrostatic capacitance of 320fF, comprise C
SSaturated the time electron number be 2 * 10
6e
-, can realize the dynamic range of 120dB.
(embodiment 2)
Obtain the dynamic range that can realize when the described ditch type of application is put aside capacity cell in cmos image sensor of the present invention by emulation.
Figure 30 is the general view of the pixel when adopting ditch type savings capacity cell.
Each pixel is made of the savings capacity cell Cap of photodiode PD, image element circuit PC and ditch type.
Here, if one side what suppose each pixel is about 5 μ m, the length on the plane graph of ditch type savings capacity cell is about 4 μ m * 2.
Figure 31 is the ideograph that the ditch type of explanation supposition is put aside the size of capacity cell.
Be in the p type well 11 of n N-type semiconductor N substrate 10, to form ditch TC, become the p N-type semiconductor N district 19 of lower electrode at the inwall of ditch TC, cover the inwall of ditch TC, form the capacitor insulating film 25 of silica, bury ditch TC and form the structure of upper electrode 40 via capacitor insulating film 25.
Here, length L is 4 μ m * 2 as mentioned above.
If the depth D of ditch is 2 μ m, the thickness T of the capacitor insulating film 25 of silica (dielectric constant 3.9)
OxBe 7nm, when then only considering the side of ditch, electric capacity is 160fF, and the electron number when saturated is 5 * 10
5e
-, can realize the dynamic range of 100~108dB.
(embodiment 3)
Obtain the dynamic range that can realize when in cmos image sensor of the present invention, using described plane savings capacity cell.
Figure 32 is the layout of the pixel when adopting plane savings capacity cell.
Configuration photodiode PD, floating region FD, savings capacity cell C
SWith other image element circuits, obtain the layout of Figure 32.
If one side of pixel is 8.2 μ m, the capacitor insulating film of plane savings capacity cell is the silica of 7nm thickness, just obtains C
S=38fF.At this moment, C
FD=4.2Ff (except the edge power supply) as dynamic range, obtains 88~96dB.
(embodiment 4)
In cmos image sensor of the present invention, Yi Bian suppose to be that the area of photodiode PD of pixel of 3 μ m is 25% with aperture opening ratio, group is gone into miniature lens in photodiode PD again, and essence becomes the pixel of aperture opening ratio 80%.
Here,, set 2 kinds of 64fF and 640fF etc., in both, obtain before photodiode PD is saturated and the output (V) after saturated and the linearity of light quantity (lux) with emulation as the photoelectronic savings capacity cell that savings overflows from photodiode PD.
Figure 33-the 1st for light quantity (lux), describes the figure of the output (V) of photodiode PD before saturated because be saturated before, so that the savings capacity cell is 64fF is all consistent during with 640fF, that confirms to export (V) and light quantity (lux) relevantly has a high linearity.
In addition, Figure 33-the 2nd for light quantity (lux), describes the figure of the output (V) after saturated, and is lower than 64fF output when the savings capacity cell is 640fF during identical light quantity, confirms that the linear part that has before output is saturated obtains wide.
At this moment, for example 10
2Below the lux, adopt saturated preceding output, 10
2More than the lux, adopt the output after saturated, the saturated front and back of contact photodiode PD for light quantity, can be obtained in wide scope and have high linear output.
In addition, in table 1, sum up the performance of cmos image sensor of the present invention.
[table 1]
The present invention is not limited to described explanation.
For example, in execution mode, solid camera head is described, but be not limited thereto, about be the pixel arrangement of each solid camera head linearity line sensor, the pixel of each solid camera head is constituted separately the optical sensor of obtaining, also can realize the wide dynamic range that in the past can not obtain and high sensitivity, high S/N ratio.
In addition, the shape of savings capacity cell does not limit especially, in the memory savings capacity cell of DRAM, in order to improve electric capacity, can adopt the whole bag of tricks of exploitation before this.
As solid camera head, if connect the structure of the savings capacity cell of the optical charge that photodiode and savings overflow from photodiode via passing on transistor, just can, except cmos image sensor, also can be applied to CCD.
In the scope that does not break away from aim of the present invention, can carry out various changes.