US20150222835A1

US20150222835A1 - Image pickup circuit

Info

Publication number: US20150222835A1
Application number: US14/689,883
Authority: US
Inventors: Shigetaka Kudo
Original assignee: Sony Corp
Current assignee: Sony Corp
Priority date: 2007-08-31
Filing date: 2015-04-17
Publication date: 2015-08-06
Also published as: US20090059024A1; US9485443B2; US9992434B2; US9374539B2; US20160094795A1; US10855943B2; US8102449B2; US20120104234A1; JP2009060327A; JP4386118B2; US9041839B2; US20160269663A1; US20170019620A1; US20180241957A1

Abstract

An image pickup circuit including a plurality of circuit blocks. Each of the plurality of circuit blocks includes a plurality of comparing elements, a single counter, and a plurality of storage units. Each of the comparing elements compares a pixel signal supplied through a vertical signal line connected to vertically aligned pixels in a plurality of pixels arranged in a matrix, and a slope signal whose voltage is changed from an initial voltage at a constant slope. The counter counts an elapsed time since a voltage of the slope signal starts to change from the initial voltage. Each of the storage units stores a count value obtained by the counter in accordance with a comparison result of the comparator, the count value corresponding to an elapsed time until the voltage of the slope signal is changed from the initial voltage to a voltage coinciding with the pixel signal.

Description

RELATED APPLICATION DATA

This application is a continuation of U.S. patent application Ser. No. 12/197,372, filed Aug. 25, 2008, the entirety of which is incorporated herein by reference to the extent permitted by law. The present application claims the benefit of priority to Japanese Patent Application No. JP 2007-225208 filed in the Japanese Patent Office on Aug. 31, 2007, the entirety of which is incorporated by reference herein to the extent permitted by law.

BACKGROUND OF THE INVENTION

The present invention relates to an image pickup circuit.
In the recent years, solid-state image pickup devices such as CMOS (complementary metal oxide semiconductor) sensors have been widely implemented to portable telephones, compact digital cameras, high-class single-lens reflex cameras, camcoders, monitor cameras and guide apparatuses.
Recently, there has been developed a high performance sensor including an on-chip processing blocks such as an image processing circuit together with a CMOS sensor to thereby output high quality images.
For example, sensors employing column-parallel A/D (analog to digital) conversion method (hereinafter referred for convenience to as “column AD method”) have been proposed.
In the column AD method, an A/D converter is provided for every column of pixels (hereinafter referred to as a “column” where appropriate), and the pixel signals (analog signals) of individual pixels for the respective columns are read by one operation and then A/D converted directly.
Further, the column AD method employs parallel processing for every horizontal line in an image, thus eliminating the necessity for high-frequency horizontal scanning. This enables the A/D conversion to be performed vertically at a low frequency, making it easy to separate signal components and noise components generated in a high frequency band.
The configuration of a solid-state image pickup device employing the column AD method will be described here with reference to FIGS. 1 and 2.
FIG. 1 is a block diagram showing the configuration of an example of the solid-state image pickup device employing the column AD method.
In FIG. 1, a solid-state image pickup device 11 includes a vertical scanning circuit 21, a pixel array 22, vertical signal lines 23 ₁to 23 _N(N is a positive integer), current sources 24 ₁to 24 _N, a slope generating circuit 25, comparators 26 ₁to 26 _N, and counters 27 ₁to 27 _N.
Under control of the controller (not shown), the vertical scanning circuit 21 supplies sequentially output control signals for controlling the outputs of pixel signals to vertically aligned pixels 22 ₁to 22 _Nin the pixel array 22 at a predetermined timing.
The pixel array 22 is composed of a plurality of pixels arranged in a matrix. FIG. 1 shows the pixels 22 ₁to 22 _Ndisposed in a horizontal direction for one line, with the vertically aligned pixels omitted. In the pixel array 22, the individual pixels 22 _nwhich are vertically aligned output sequentially a pixel signal on the basis of the output control signal supplied from the vertical scanning circuit 21.
In the pixel array 22 of FIG. 1, the N pixels 22 ₁to 22 _Nare disposed horizontally (horizontal direction). The pixels 22 _n(n=1, 2, . . . , N) photoelectrically convert the incident light, and output the pixel signal of a voltage corresponding to the light. These pixels 22 ₁to 22 _Nare connected to the N vertical signal lines 23 ₁to 23 _N, respectively, and the pixel signals outputted from the pixels 22 ₁to 22 _Nare supplied through the vertical signal lines 23 ₁to 23 _Nto one of two input terminals in each of the N comparators 26 ₁to 26 _N, respectively. The pixels 22 ₁to 22 _Nare also grounded through the N current sources 24 ₁to 24 _N, respectively.
The slope generating circuit 25 supplies a slope signal, whose voltage drops (or rises) at a constant slope from a predetermined initial voltage, to the other of the two input terminals in each of the N comparators 26 ₁to 26 _N, respectively.
The comparators 26 ₁to 26 _Ncompare the pixel signals supplied from the pixels 22 ₁to 22 _N, and the slope signal supplied from the slope generating circuit 25, and supply comparative signals representing the comparison results to the N counters 27 ₁to 27 _N, respectively.
The counters 27 ₁to 27 _Ncount a predetermined clock signal on the basis of the comparative signals supplied from the comparators 26 ₁to 26 _N, respectively, and supply the count values to the circuit of the subsequent stage (not shown). In the circuit of the subsequent stage, pixel data (pixel values) are outputted on the basis of the count values supplied from the counters 27 ₁to 27 _N.
In FIG. 1, the slope generating circuit 25, the comparators 26 _n, and the counters 27 _nconstitute the A/D converter.
The solid-state image pickup device 11 thus configured necessitates the counters corresponding to the number N of the columns, thereby increasing the circuit area and power consumption.
FIG. 2 is a block diagram showing the configuration of other example of the solid-state image pickup device employing the column AD method.
In FIG. 2, the same references have been used as in FIG. 1 for similar components, and the description thereof is omitted.
In FIG. 2, a solid-state image pickup device 31 includes a vertical scanning circuit 21, a pixel array 22, vertical signal lines 23 ₁to 23 _N, current sources 241 to 24 _N, a slope generating circuit 25, comparators 26 ₁to 26 _N, a counter 41, and latch circuits 42 ₁to 42 _N.
Each of the comparators 26 ₁to 26 _Nsupply comparative signals representing the comparison results, to the N latch circuits 42 ₁to 42 _N, respectively. The comparative signals are obtained by comparing the pixel signals supplied from the pixels 22 ₁to 22 _Nand the slope signal supplied from the slope generating circuit 25.
The counter 41 counts a predetermined clock signal and supplies the count value to the latch circuits 42 ₁to 42 _N, respectively.
The latch circuits 42 ₁to 42 _Nstore the count values counted by the single counter 41 in response to the comparative signals from the comparators 26 ₁to 26 _N, and supply the stored count values to the circuit of the subsequent stage (not shown). In the circuit of the subsequent stage, pixel data are outputted on the basis of the count values supplied from the latch circuits 42 ₁to 42 _N.
In FIG. 2, the slope generating circuit 25, the comparators 26 n, the counter 41, and the latch circuits 42 _nconstitute the A/D converter.
The solid-state image pickup device 31 thus configured can reduce the number of counters to only one, namely the counter 41.
However, when the single counter 41 is provided as in the solid-state image pickup device 31, a greater distance between the counter 41 and the latch circuit 42 _ncauses a greater delay in counted pulse indicating the count value supplied from the counter 41 to the latch circuit 42 _n, due to wire resistance and wire capacity. Consequently, between the column of the latch circuit 42 _nhaving a short distance to the counter 41, and the column of the latch circuit 42 _n′ (n′=1, 2, . . . , N) having a long distance to the counter 41, a difference resulted from wire resistance and wire capacity occurs in pixel data outputted, thereby adversely affecting image quality.
There are also those having a plurality of arrangements that an A/D converter (a comparator and a counter) is shared among a plurality of columns (for example, see Japanese Unexamined Patent Application Publication No. 2006-80861 hereinafter referred to as Patent Document 1).
However, in the configuration of the Patent Document 1, the pixel signals of a plurality of columns are serially transmitted to be A/D converted, thus lowering the transmission rate. The counter is required to operate for a number of columns, and the power consumption thereof becomes the same as the power consumption when each of the columns has a counter.

SUMMARY OF THE INVENTION

As described above, it has been difficult for the earlier developed solid-state image pickup devices to reduce power consumption.
Accordingly, it is desirable to reduce power consumption.
In accordance with one aspect of the present invention, there is provided an image pickup circuit which includes a plurality of circuit blocks each including a plurality of comparing elements, a single counter, and a plurality of storage units. Each of the plurality of comparing elements compare a pixel signal supplied through a vertical signal line connected to vertically aligned pixels in a plurality of pixels arranged in a matrix, and a slope signal whose voltage is changed from an initial voltage at a constant slope. The single counter counts an elapsed time since a voltage of the slope signal is started to change from the initial voltage. Each of the plurality of storage units store a count valued obtained by the counter, in accordance with a comparison result of the comparing elements, the count value corresponding to an elapsed time until the voltage of the slope signal is changed from the initial voltage to a voltage coinciding with the pixel signal.
In one embodiment, a pixel column in one circuit block among the plurality of circuit blocks may be arranged between two adjacent pixel columns aligned vertically in another one circuit block among the plurality of circuit blocks.
In one embodiment, a pixel signal of a pixel in the pixel column in one circuit block among the plurality of circuit blocks and a pixel signal of a pixel in the pixel column aligned vertically in another one circuit block among the plurality of circuit blocks may be added.
In one embodiment, a pixel signal of a pixel in the pixel column in one circuit block among the plurality of circuit blocks arranged between two adjacent pixel columns aligned vertically in another one circuit block among the plurality of circuit blocks may be thinned out.
In one embodiment, the storage unit may include a latch circuit or a sample-hold circuit.
The circuit blocks may further may include selecting elements for selecting the pixel signals supplied from the plurality of the vertical signal lines to supply the selected pixel signals to the comparators.
According to one embodiment, in the plurality of circuit blocks, the plurality of comparators compare a pixel signal supplied through the vertical signal line connected to the vertically aligned pixels in the plurality of pixels arranged in the matrix, and the slope signal whose voltage is changed at the constant slope from the predetermined initial voltage. In accordance with the comparison result of the comparators, the plurality of storage units store the count value obtained by the single counter, corresponding to the elapsed time until the slope signal voltage is changed from the initial voltage to the voltage coinciding with the pixel signal.
According to an embodiment of the present invention, the image pickup circuit is capable of reducing power consumption.
The above summary of the present invention is not intended to describe each illustrated embodiment or every implementation of the present invention. The figures and the detailed description which follow more particularly exemplify these embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram showing the configuration of an embodiment of a solid-state image pickup device employing column AD method;

FIG. 2 is a block diagram showing the configuration of other embodiment of the solid-state image pickup device employing the column AD method;

FIG. 3 is a block diagram showing a configuration example of an embodiment of the solid-state image pickup device to which the present invention is applied;

FIG. 4 is a time chart for explaining the operation of the solid-state image pickup device;

FIG. 5 is a block diagram showing a configuration example of a solid-state image pickup device in which a counter is shared among all columns;

FIG. 6 is a circuit diagram modeling wire resistance and wire capacity generated in the solid-state image pickup device of FIG. 5;

FIG. 7 is a block diagram showing a configuration example of other embodiment of the solid-state image pickup device to which the present invention is applied; and

FIG. 8 is a block diagram showing a configuration example of still other embodiment of the solid-state image pickup device to which the present invention is applied.

DETAILED DESCRIPTION OF EMBODIMENTS

Before describing the following embodiments of the invention, the association between the configuration requirements of the invention and the embodiments described and shown in the specification or the drawings will be described below. That is, the following is to confirm that the embodiments supporting the invention are described and shown in the specification or the drawings. Even if there is a certain embodiment which is described in the specification or the drawings but not described here as an embodiment corresponding to a certain configuration requirement of the invention, it does not mean that this embodiment does not correspond to this configuration requirement. Reversely, even if a certain embodiment is described as one corresponding to a certain configuration requirement, it does not mean that the embodiment does not correspond to any configuration requirement other than that.
The image pickup circuit of one embodiment of the invention includes a plurality of circuit blocks (e.g. circuit blocks BL₁to BL_Min FIG. 3), each having a plurality of comparing elements (e.g. comparators 76 _m1to 76 _mPin FIG. 3), a counter (e.g. a counter 77 _min FIG. 3) and a plurality of storage units (e.g. latch circuits 78 _m1to 78 _mPin FIG. 3). Each of the plurality of comparing elements compares a pixel signal supplied through a vertical signal line connected to vertically aligned pixels in a plurality of pixels arranged in a matrix, and a slope signal whose voltage is changed from a predetermined initial voltage at a constant slope. The counter counts an elapsed time since a voltage of the slope signal is started to change from the initial voltage. Each of the plurality of storage units stores a count value obtained by the counter, in accordance with a comparison result of the comparing elements, the count value corresponding to an elapsed time until the voltage of the slope signal is changed from the initial voltage to a voltage coinciding with the pixel signal.
A pixel column aligned vertically in a circuit block (e.g. a circuit block BL₂in FIG. 7) among the plurality of circuit blocks may be arranged between two adjacent pixel columns aligned vertically in another one circuit block (e.g. a circuit block BL₁in FIG. 7).
In one embodiment, the image pickup device may be configured to add a pixel signal of a pixel (e.g. a pixel 72 ₁₁in FIG. 7) of the pixel column aligned vertically in the one circuit block among the plurality of circuit blocks, and a pixel signal of a pixel (e.g. a pixel 72 ₂₁in FIG. 7) of the pixel column aligned vertically in the another one circuit block among the plurality of circuit blocks.
In one embodiment, the image pickup device may be configured to thin out the pixel signals of pixels (e.g. pixels 72 ₂₁to 72 _2Pin FIG. 7) of the pixel columns vertically aligned in one circuit block among the plurality of circuit blocks, wherein the pixel columns are arranged between the two adjacent pixel columns aligned vertically in another one circuit block, the pixel columns each having pixels (e.g. pixels 72 ₁₁to 72 _1Pin FIG. 7).
The circuit blocks may further include selecting elements (e.g. switches 271 _m1to 27 _1m(P/2)) in FIG. 8) for selecting the pixel signals supplied from the plurality of vertical signal lines to supply the selected pixel signals to the comparing elements.
Embodiments of the present invention will be described below with reference to the accompanying drawings.
FIG. 3 is block diagram showing a configuration example of the solid-state image pickup device according to an embodiment of the present invention.
A solid-state image pickup device 51 of FIG. 3 may be, for example, a CMOS sensor or other solid-state image pickup device.
In FIG. 3, the solid-state image pickup device 51 includes one vertical scanning circuit 71, one pixel array 72, vertical signal lines the number of which is M×P, 73 ₁₁to 73 _1P, 73 ₂₁to 73 _2P, . . . , and 73 _M1to 73 _MP(each M and P is a positive integer, particularly an integer equal to or greater than 2), current sources 74 ₁₁to 77 _1Pthe number of which is M×P, 74 ₂₁to ⁷⁴ _2P, . . . , and 74 _M1to 74 _MP, one slope generating circuit 75, comparators the number of which is M×P, 76 ₁₁to 76 _1P, 76 ₂₁to 76 _2P, . . . , and 76 _M1to 76 _MP, counters the number of which is M, 77 ₁to 77 _M, and latch circuits the number of which is M×P, 78 ₁₁to 78 _1P, 78 ₂₁to 78 _2P, . . . , and 78 _M1to 78 _MP.
For the sake of convenience, the arrangement of the vertical signal lines 73 ₁₁to 73 _1P, 73 ₂₁to 73 _2P, . . . , and 73 _M1to 73 _MPare hereinafter referred to as “vertical signal lines 73 ₁₁to 73 _MP, or “vertical signal lines 73 _MP(m=1, 2, . . . , and M; p=1, 2, . . . , and P).” The same is applied to other arrangements.
Similarly, the arrangement made up of P vertical signal lines 73 _m1to 73 _mP, P current sources 74 _m1to 74 _mP, P comparators 76 _m1to 76 _mP, a counter 77 _m, and P latch circuits 78 _m1to 78 _mPis hereinafter referred to as a “circuit block BL_m.” In this case, the solid-state image pickup device 51 includes a vertical scanning circuit 71, a pixel array 72, a slope generating circuit 75, and circuit blocks BL₁to BL_Mthe number of which is M.
Under control of a controller (not shown), the vertical scanning circuit 71 supplies sequentially output control signals for controlling the outputs of pixel signals to the pixels 72 ₁₁to 72 _MParranged vertically in the pixel array 72 at a predetermined timing.
The pixel array 72 is composed of a plurality of pixels arranged in a matrix. FIG. 3 shows the pixels 72 ₁₁to 72 _MPhorizontally aligned in one column, with vertically aligned pixels omitted. In the pixel array 72, the vertically aligned individual pixels 72 _mpoutput sequentially pixel signals on the basis of the output control signal supplied from the vertical scanning circuit 71.
In the pixel array 72 of FIG. 3, the pixels 72 ₁₁to 72 _MPthe number of which is M×P are arranged horizontally. The pixel 72 _mpphotoelectrically converts the incident light, and outputs the pixel signal of a voltage corresponding to the light. These pixels 72 ₁₁to 72 _MPare connected to the M×P vertical signal lines 73 ₁₁to 73 _MP, respectively, and the pixel signals outputted from the pixels 72 ₁₁to 72 _MPare supplied through the vertical signal lines 73 ₁₁to 73 _MPto one of two input terminals in each of the comparators 76 ₁₁to 76 _MPthe number of which is M×P, respectively. The pixels 72 ₁₁to 72 _MPare also grounded through the M×P current sources 74 ₁₁to 74 _MP, respectively.
The slope generating circuit 75 supplies a slope signal, whose voltage is changed, namely drop (or rise), at a constant slope from an initial voltage, to the other of the two input terminals in each of the comparators 76 ₁₁to 76 _MP, respectively.
The comparators 76 ₁₁to 76 _MPcompare the pixel signals supplied from the pixels 72 ₁₁to 72 _MPand the slope signal supplied from the slope generating circuit 75, and supply comparative signals representing the comparison results to the latch circuits the number of which is M×P, 78 ₁₁to 78 _MP, respectively.
The counters 77 _mcount a predetermined clock signal in a circuit block BL_m, and supply the count value to the latch circuits 78 _m1to 78 _mP.
More specifically, the counter 77 ₁supplies the count value of a clock signal to the latch circuits 78 ₁₁to 78 _1Pin the circuit block BL₁, and the counter 77 ₂supplies the count value of a clock signal to the latch circuits 78 ₂₁to 78 _2Pin the circuit block BL₂.
Similarly, the counter 77 _Msupplies the count value of a clock signal to the latch circuits 78 _M1to 78 _MPin the circuit block BL_M.
In accordance with the comparative signal from the comparator 76 _mp, the latch circuit 78 _mpstores (latches) the count value counted by the counters 77 _min the circuit blocks BL_m, and supplies the stored count value to the circuit of the subsequent stage(not shown). In the circuit of the subsequent stage, pixel data are outputted on the basis of the count values supplied from the latch circuits 78 _m1to 78 _mP.
The slope generating circuit 75, and the comparator 76 mp, the counters 77 _m, and the latch circuit 78 _mpin the circuit blocks BL_mconstitute the A/D converter.
Next, the operation of the solid-state image pickup device 51 will be described with reference to FIG. 4.
FIG. 4 is a timing chart for explaining the operation of the solid-state image pickup device 51.
The following is the operation of the solid-state image pickup device 51, focusing on the p-th pixel 72 _mpof the circuit blocks BL_m.
In FIG. 4, a slope signal supplied from the slope generating circuit 75 to the comparator 76 _mp, a pixel signal supplied from the pixel 72 _mpof the pixel array 72 to the comparator 76 _mp, a comparative signal supplied from the comparator 76 _mpto the latch circuit 78 _mp, and a count value latched by the latch circuit 78 _mpare plotted in the top-down order, plotting time as the abscissa.
The slope generating circuit 75 supplies the slope signal whose voltage drops at a constant slope from an initial voltage, as shown at the first plot from the top in FIG. 4.
During the time the slope signal voltage drops from the initial voltage, there are a reset phase having a predetermined duration and a signal output phase having a longer duration than the reset phase. The slope signal is a signal causing a reset phase and a signal output phase subsequent to the reset phase to be repeated in one set form.
The pixel 72 _mpof the pixel array 72 supplies a pixel signal to the comparator 76 _mpaccording to the output control signal supplied from the vertical scanning circuit 71, as shown at the second plot from the top in FIG. 4.
In the solid-state image pickup device 51, light enters the pixel 72 _mpin the signal output phase, whereas the light entering into the pixel 72 _mpis intercepted in the reset phase.
As a result, in the reset phase, noise components are supplied as a pixel signal from the pixel 72 _mpto the comparator 76 _mp. During the signal output phase, a pixel signal containing a charge-based signal component corresponding to the light receiving amount of a photodiode (not shown) is supplied from the pixel 72 _mpto the comparator 76 _mp.
As shown at the third plot from the top in FIG. 4, the comparator 76 _mpcompares the slope signal and the pixel signal, and supplies an H (high) level comparative signal to the latch circuit 78 _mpwhen the pixel signal voltage is smaller than the slope signal voltage, and supplies an L (low) level comparative signal to the latch circuit 78 _mpwhen the pixel signal voltage is larger than the slope signal voltage.
Here, the initial voltage of the slope signal is larger than the maximum value of voltages attainable by the pixel signal. Accordingly, as the slope signal voltage drops from the initial voltage, the slope signal voltage is changed from a voltage larger than the pixel signal to a voltage coinciding with the pixel signal. The change of the slope signal voltage from the voltage larger than the pixel signal to the voltage coinciding with the pixel signal causes the comparative signal to be inverted from the H level to the L level.
As presented in the fourth plot from the top (the lowermost) of FIG. 4, the comparator 78 _mpstores according to the comparative signal from the comparator 76 _mp, the count values (the counted pulses) obtained by the counters 77 _m, corresponding to a period of time that the slope signal voltage is changed from the initial voltage to the voltage coinciding with the pixel signal, and supplies the count values to the circuit of the subsequent stage (not shown).
That is, the latch circuit 78 _mpstores the count values counted by the counters 77 _m(reset phase count values Cp) in the period between the time when the slope signal voltage starts to drop in the reset phase and the time when the comparative signal is inverted from the H level to the L level. Thereafter, the latch circuit 78 _mpstores the count values counted by the counters 77 _m(signal output phase count values Cd) in the period between the time when the slope signal voltage starts to drop in the signal output phase and the time when the comparative signal is inverted from the H level to the L level. The latch circuit 78 _mpsupplies successively the reset phase count values Cp and the signal output phase count values Cd to the circuit of the subsequent stage (not shown).
In the circuit of the subsequent stage, a digital CDS (corrected double sampling) is performed to obtain a difference Cp−Cd between the reset phase count value Cp and the signal output phase count value Cd, and the difference Cp−Cd is outputted as signal components of pixel data.
As described with reference to FIG. 3, owing to the arrangement that in each of the plurality of circuit blocks BL₁to BL_M, the single counter 77 _mis shared among P columns (P sets of the comparator 76 _mPand the latch circuit 78 _mP), the number of counters can be reduced to a 1/P than the arrangement that one counter is provided for every column. This enables the suppression of circuit area, reducing power consumption.
This is effective to prevent circuit area and power consumption from being increased with increasing the number of pixels and the processing speed in future solid-state image pickup devices.
The counters 77 m may be noise generating source because they operate almost all of the circuit operating time. However, the solid-state image pickup device 51 requires less number of the counters 77 _m, thereby achieving a noise reduction.
Although the individual counters 77 _mare shared among the columns the number of which is P in the foregoing description, the circuit blocks BL_mmay have different numbers of columns P sharing the individual counters 77 _m.
Preferably, the numbers of columns P sharing the single counter 77 _mis determined (optimized) by considering the delay due to wire resistance and wire capacity when the solid-state image pickup device 51 is operated at high speed.
FIG. 5 is a block diagram showing a configuration example of the solid-state image pickup device in which a single counter is shared among all columns.
A solid-state image pickup device 111 of FIG. 5 includes comparators 131 ₁to 131 ₂₇₀₀the number of which is 2700, a counter 132, and latch circuits 133 ₁to 133 ₂₇₀₀the number of which is 2700. In the solid state image pickup device 111, the single counter 132 is shared among 2700 columns (2700 sets of a comparator 131 _iand a latch circuit 133 _i(i is an integer in the range 1 to 2700)).
The comparators 131 ₁to 131 ₂₇₀₀, the counter 132, and the latch circuits 133 ₁to 133 ₂₇₀₀in FIG. 5 have the same basic operations as the comparator 76 _mp, the counter 77 _mand the latch circuit 78 _mp, respectively, and the description thereof is omitted here.
For example, assuming that the counter 132 counts count values in DDR (double data rate) method by setting the operating frequency at 300 MHz, the count value is incremented by one for 1.67 nsec. It is also assumed that the count value of the counter 132 is sequentially propagated to the latch circuits 133 ₁to 133 ₂₇₀₀in this order.
It is further assumed that the wire resistance between the adjacent latch circuits 133 _iand 133 _i+1is 0.7 Ω and the wire capacity therebetween is 1.48 fF.
In this case, the wire resistance R between the latch circuit 133 ₁having the shortest distance to the counter 132 and the latch circuit 133 ₂₇₀₀having the longest distance to the counter 132 is approximately 2 kΩ (≈2700×0.7 Ω), and the wire capacity C therebetween is approximately 4 pF (≈2700×1.48×10⁻¹⁵F).
FIG. 6 is a circuit diagram modeling wire resistance and wire capacity generated in the solid-state image pickup device 111 of FIG. 5.
In FIG. 6, the latch circuit 1331 having the shortest distance to the counter 132 is represented by point A, and the latch circuit 133 ₂₇₀₀having the longest distance to the counter 132 is represented by point B. The wire resistance R and the wire capacity C between the points A and B are modeled by an n-type circuit.
When a simulation is performed using the circuit shown in FIG. 6, a 1.78 nsec delay occurs between the count pulse (the count value) supplied from the counter 132 to the latch circuit 133 ₁and the count pulse supplied from the counter 132 to the latch circuit 133 ₂₇₀₀.
This delay is greater than 1.67 nsec for one count of the counter 132, and a difference of one count occurs between the count value in the column having the shortest distance to the counter 132 and the count value in the column having the longest distance to the counter 132.
Accordingly, in circuit of the subsequent stage (not shown) to which the count values from the latch circuits 133 ₁to 133 ₂₇₀₀are supplied, when pixel data are outputted by subjecting the count values to gain multiplication by a predetermined number, a 1 count difference of the count value in the pixel data outputted is increased to a 4 count difference in a 4×gain multiplication, a 8 count difference in a 8×gain multiplication, and a 16 count difference in a 16×gain multiplication.
On the other hand, assuming in the example of FIG. 5 that the number of columns is 675 (=2700/4) and a single counter 132 is shared among the 675 columns, the wire resistance and the wire capacity between the column having the shortest distance to the counter 132 and the column having the longest distance to the counter 132 are an approximately ¼ of the case where a single counter 132 is shared among 2700 columns. That is, the wire resistance R is approximately 0.47 kΩ (≈675×0.7 Ω), and the wire capacity C is approximately 1 pF (≈675×1.48×10⁻¹⁵F).
When the single counter 132 is shared among the 675 columns and the simulation is performed by using the circuit shown in FIG. 6, a 0.31 nsec delay occurs between the counted pulse supplied to the latch circuit 133 ₁having the shortest distance to the counter 132 and the counted pulse supplied to the latch circuit 133 ₆₇₅having the longest distance to the counter 132. The value 0.31 nsec is sufficiently smaller than 1.67 nsec that is the time corresponding to the 1 count of the counter 132. Consequently, there is no difference between the count value in the column having the shortest distance to the counter 132 and the count value in the column having the longest distance to the counter 132.
Thus, deterioration of image quality can be prevented while reducing the power consumption of the solid-state image pickup device 111, by setting the number of columns sharing a single counter 132 so that the delay due to the wire resistance R and the wire capacity C when the solid-state image pickup device 111 is operated at high speed becomes sufficiently smaller than the time required for a 1 count.
That is, when the number of columns of the solid-state image pickup device 111 is 2700 as in the case of FIG. 5, the reduction in power consumption and the prevention of deterioration in image quality can be achieved by setting four counters similar to the counter 132 so that a single counter 132 is shared among 675 columns.
FIG. 7 is a block diagram showing a configuration example of the solid-state image pickup device according to another embodiment of the present invention.
In FIG. 7, the same references have been used as in FIG. 3 for similar components, and the description thereof is omitted.
A solid-state image pickup device 151 of FIG. 7 is identical to the solid-state image pickup device 51 of FIG. 3 in that the device 151 includes a vertical scanning circuit 71, a pixel array 72, a slope generating circuit 75, and circuit blocks BL₁to BL_Mthe number of which is M, except for the following point.
That is, in the solid-state image pickup device 151 shown in FIG. 7, a column of vertically aligned pixels in a second circuit block BL_m+1among the circuit blocks BL₁to BL_Mthe number of which is M is arranged between two columns of vertically aligned pixels in a circuit block BL_m. In the solid-state image pickup device 51 shown in FIG. 3, the column in the circuit block BL_m+1is not arranged between the two columns in the first circuit block BL_m.
More specifically, pixels 72 ₂₁to 72 _2Pin the circuit block BL2 are arranged between pixels 72 ₁₁to 72 _1Pin the circuit block BL₁, respectively.
Similarly, pixels 72 _M1to 72 _MPin the circuit block BL_Mare arranged between pixels 72 _(M−1)1to 72 _(M−1)Pin the circuit block BL_M−1, respectively.
That is, in the pixel array 72 of FIG. 7, pixels 72 ₁₁to 72 _MPthe number of which is M×P are arranged horizontally, and the order thereof is different from that in the configuration of FIG. 3. These pixels are arranged in the following order: the pixels 72 ₁₁, 72 ₂₁, 72 ₂₂. . . , 72 _1P, 72 _2P. . . , 72 _(m−1)p, 72 _mp. . . , 721 _(M−1)1, 72 _M1, . . . , 72 _(M−1)pand 72 _MP.
Thus, in the solid-state image pickup device 151, instead of the configuration that a single counter 77 _mis shared among the adjacent pixels (columns), a single counter 77 _mis shared among pixels (columns) arranged every other pixel columns.
The solid-state image pickup device 151 shown in FIG. 7 has a function of pixel addition (pixel signal addition), so-called binning function.
That is, the solid-state image pickup device 151 in FIG. 7 has a binning function of performing pixel addition between two horizontally adjacent pixels, namely, pixels 72 ₁₁and 72 ₂₁, pixels 72 ₁₂and 72 ₂₂, . . . , pixels 72 _1Pand 72 _2P, . . . , respectively. When the binning function is turned on, the pixel signals of the horizontally adjacent pixels 72 _mpand 72 _(m+1)pare added, and the pixel signal as the result of addition is supplied through a vertical signal line 73 _mpto a comparator 76 _mp.
At this time, it is unnecessary to process the pixel signals on the vertical signal line 73 _(m+1)p. Accordingly, in the circuit block BL_m+1of the circuit block BL_mand the circuit block BL_m+1, the latch circuit 78 _(m+1)pis not required to operate, and the counter 77 _m+1connected to the latch circuit 78 _(m+1)pis also not required to operate, where m=1, 3, . . . , M−1.
Thus, the counter 77 _m+1in the circuit block BL_m+1, connected to the vertical signal line 73 _(m+1)pnot used to supply the pixel signal as the result of addition, is not required to operate during the addition of pixels (when the binning function is turned on), permitting a further reduction in power consumption.
In the above description, the addition of pixels is performed between the two horizontally adjacent pixels. Without limiting to this, the addition of pixels may be performed among two horizontally adjacent pixels and two vertically adjacent pixels (2×2 pixels) or a total of four pixels, or alternatively among 3×3 pixels or a total of nine pixels.
In addition to the binning function, pixel thinning out (pixel signal thinning out) function may be imparted to the solid-state image pickup device 151 of FIG. 7.
That is, the solid-state image pickup device 151 in FIG. 7 has the pixel thinning out function to perform pixel thinning out of the pixels 72 ₂₁, 72 ₂₂, . . . , 72 ₂P, . . . , and 72 _(m+1)p. When the pixel thinning out function is turned on, the pixel signal of the pixel 72 _(m+1)pis thinned out, eliminating the necessity of processing the pixel signals on the vertical signal line 73 _(m+1)p. Therefore, in the circuit block BL_m+1of the circuit block BL_mand the circuit block BL_m+1, the latch circuit 78 _(m+1)pis not required to operate, and the counter 77 _m+1connected to the latch circuit 78 _(m+1)pis also not required to operate, where m=1, 3, . . . , M−1.
Thus, the counter 77 _m+1of the circuit block BL_m+1, connected to the vertical signal line 73 _(m+1)pnot used to supply the pixel signal as a pixel thinning out result, is not required to operate during the pixel thinning out, permitting a further reduction in power consumption.
In the above description, the pixel thinning out is performed every other pixel (every other column). Without limiting to this, the pixel thinning out may be performed every two or more pixels (every two or more columns).
FIG. 8 is a block diagram showing a configuration example of still other embodiment of the solid-state image pickup device to which the present invention is applied.
In FIG. 8, the same references have been used as in FIG. 3 for similar components, and the description thereof is omitted.
A solid-state image pickup device 251 of FIG. 8 is identical to the solid-state image pickup device 51 of FIG. 3 in that circuit blocks BL_mhave counters 77 _m. The solid-state image pickup device 251 is different from the solid-state image pickup device 51 in that the circuit blocks BL_mhave P/2 pieces of current sources 74 _mp, comparators 76 _mpand latch circuits 78 _mp, and P/2 pieces of switches 271 _mp.
Under control of a controller (not shown), the switches 271 _mpselectively supply pixel signals supplied from vertical signal lines 73 _m(2p−1)and 73 _m(2p), to the comparators 76 _mp.
Thus, the solid-state image pickup device 251 has the configuration that a single comparator 76 _mpis shared between two pixels (two columns) 72 _m(2p−1)and 72 _m(2p).
Although in FIG. 8, a single comparator 76 _mpis shared between the two pixels (columns) 72 _m(2p−1)and 72 _m(2p), a single comparator 76 _mpmay be shared among more than two pixels (columns) or n pixels (n columns).
Unlike the Patent Document 1 having P/2 arrangements that a single A/D converter (the comparator and the counter) is shared among n columns, the solid-state image pickup device 251 has the arrangement that a counter is shared among P/2 arrangements that a comparator and a latch circuit are shared among n columns. Therefore, the number of counters needed for n×(P/2) columns can be reduced from P/2 to one, permitting a reduction in power consumption.
As described above, the solid-state image pickup device 51, the solid-state image pickup device 151 and the solid-state image pickup device 251 are capable of reducing the number of the counters 77 _m, thereby reducing power consumption than the case of providing a counter for every column. That is, in each of the plurality of circuit blocks BL_m, the plurality of comparators 76 _mpcompare a pixel signal supplied through a vertical signal line connected to vertically aligned pixels 72 _mpamong the plurality of pixels arranged in the matrix, and the slope signal whose voltage is changed at the constant slope from the predetermined initial voltage. In accordance with the comparison results of the comparators 76 _mp, the plurality of latch circuits 78 _mpstore the count values obtained by the counters 77 _m, corresponding to an elapsed time from when the slope signal voltage is changed from the initial voltage to the voltage coinciding with the pixel signal.
Although the latch circuits 78 _mpstore the count values in the embodiments described above, a sample-hold circuit or other storage media may store the count values.
Although there has been shown herein and described certain embodiments of the invention, it will be understood that many changes and modifications may be made therein without departing from the spirit or scope of the invention.

Claims

1-5. (canceled)

6. An image pickup circuit comprising:

a plurality of pixels arranged in a matrix of horizontally extending pixel rows and vertically extending pixel columns;

a plurality of vertical signal lines respectively connected to pixels in the pixel columns; and

a plurality of circuit blocks aligned along the horizontal direction,

wherein the vertical signal lines include a first vertical signal line connected to first pixels in a first pixel column, and a second vertical signal line connected to second pixels in a second pixel column adjacent to the first pixel column, and

wherein each of the plurality of circuit blocks includes:

(a) comparison circuitry configured to compare a pixel signal supplied through at least one of the first and second vertical signal lines and a reference signal having a voltage that is changed from an initial voltage; and

(b) a counter unit for counting an elapsed time since a voltage of the reference signal starts to change from the initial voltage, wherein the counter unit is shared among the first and second pixel columns.

7. The image pickup circuit of claim 6, further comprising storage units including at least one of latch circuits and sample-hold circuits.

8. The image pickup circuit of claim 6, wherein each circuit block further includes a selection circuit configured to select which pixel signals are supplied from the plurality of vertical signal lines.

9. The image pickup circuit of claim 6, wherein the comparison circuitry is shared by at least two pixel columns and the counter unit is shared by at least two comparison circuitries.

10. An image pickup circuit comprising:

a pixel array including first pixels and second pixels;

a plurality of vertical signal lines including a first vertical signal line and a second vertical signal line adjacent to the first vertical signal line;

a reference voltage generation circuit; and

a plurality of circuit blocks,

wherein

the first vertical signal line is connected to the first pixels,

the second vertical signal line is connected to the second pixels,

each of the circuit blocks includes:

(a) comparison circuitry configured to compare a pixel signal supplied through first or second vertical signal lines and a reference signal supplied from the reference voltage generation circuit; and

(b) a counter unit associated with the comparison circuitry, wherein the counter unit is shared among the first and second pixels.

11. The image pickup circuit of claim 10, further comprising storage units including at least one of latch circuits and sample-hold circuits.

12. The image pickup circuit of claim 10, wherein each circuit block further includes a selection circuit configured to select which pixel signals are supplied from the plurality of vertical signal lines to a selected one of the circuit blocks.

13. The image pick up circuit of claim 10, wherein the comparison circuitry is shared by at least two pixel columns and the counter unit is shared by at least two comparison circuitries.

14. An image pickup circuit comprising:

a pixel array including first pixels and second pixels;

a plurality of vertical signal lines including a first, second, third, and fourth vertical signal lines;

a reference voltage generation circuit; and

a plurality of circuit blocks,

wherein

the second vertical signal line is adjacent to the first vertical signal line,

the third vertical signal line is adjacent to the second vertical signal line,

the fourth vertical signal line is adjacent to the third vertical signal line,

each of the circuit blocks includes:

(a) a first comparison circuitry configured to compare a pixel signal supplied through first or second vertical signal lines and a reference signal supplied from the reference voltage generation circuit;

(b) a second comparison circuitry configured to compare a pixel signal supplied through third or fourth vertical signal lines and the reference signal supplied from the reference voltage generation circuit; and

(c) a counter unit associated with the first comparison circuitry and the second comparison circuitry.

15. The image pickup circuit of claim 14, further comprising storage units including at least one of latch circuits and sample-hold circuits.

16. The image pickup circuit of claim 14, wherein each circuit block further includes a selection circuit configured to select which pixel signals are supplied from the plurality of vertical signal lines to supply to a selected one of the circuit blocks.

17. The image pick up circuit of claim 14, wherein the comparison circuitry is shared by at least two pixel columns and the counter unit is shared by at least two of the comparison circuitries.

18. An imaging device comprising:

a pixel array including a plurality of pixel units arranged in columns and rows;

a reference voltage generation circuit; and

a circuit block including:

(a) a first circuit including:

a first plurality of comparators, and

a first counter unit configured to connect to the first plurality of comparators;

(b) a second circuit including:

a second plurality of comparators, and

a second counter unit configured to connect to the second plurality of comparators; and

a first readout circuit adjacent to a second read out circuit.

19. The imaging device according to claim 18, further comprising a plurality of vertical signal lines configured to respectively connect to the plurality of pixel units, wherein the plurality of pixel units is configured to connect to the circuit block through the plurality of vertical signal lines.

20. The imaging device according to claim 19, wherein a first vertical signal line of the plurality of vertical signal lines is configured to connect to a first comparator of the first plurality of comparators and a second vertical signal line of the plurality of the vertical signal lines is configured to connect to a second comparator of the first plurality of comparators.

21. The imaging device according to claim 20, wherein a third vertical signal line of the plurality of the vertical signal lines is configured to connect to a third comparator of the second plurality of comparators and a fourth vertical signal line of the plurality of the vertical signal lines is configured to connect to a fourth comparator of the second plurality of comparators.

22. The imaging device according to claim 21, wherein, a first vertical signal line of the plurality of vertical signal lines is shared with a first comparator and a second comparator of the first plurality of comparators.

23. The imaging device according to claim 22, wherein a second vertical signal line of the plurality of vertical signal lines is shared with a third comparator and a fourth comparator of the second plurality of comparators.

24. The imaging device according to claim 23, further comprising a first switching circuit, wherein a first pixel unit and a second pixel unit of the plurality of pixel units is configured to connect to the first comparator through the first switching circuit.

25. The imaging device according to claim 24, further comprising a second switching circuit, wherein a third pixel unit and a fourth pixel unit of the plurality of pixel units is configured to connect to the third comparator through the second switching circuit.

26. The imaging device according to claim 25, wherein the first pixel unit is adjacent to the second pixel unit.

27. The imaging device according to claim 26, wherein the third pixel unit is adjacent to the fourth pixel unit.

28. An electronic apparatus comprising;

an optical system;

an imaging device including:

a reference voltage generation circuit; and

a circuit block, wherein

the circuit block includes:

(a) a first circuit including:

a first plurality of comparators; and

(b) a second circuit including:

a second plurality of comparators; and

a second counter unit configured to connect to the second plurality of comparators, and

a first readout circuit adjacent to a second read out circuit.

29. The electronic apparatus according to claim 28, further comprising a plurality of vertical signal lines configured to respectively connect to the plurality of the pixel units, wherein the plurality of pixel units is configured to connect to the circuit block through the plurality of vertical signal lines.

30. The electronic apparatus according to claim 29, wherein a first vertical signal line of the plurality of vertical signal lines is configured to connect to a first comparator of the first plurality of comparators and a second vertical signal line of the plurality of vertical signal lines is configured to connect to a second comparator of the first plurality of comparators.

31. The electronic apparatus according to claim 30, wherein a third vertical signal line of the plurality of vertical signal lines is configured to connect to a third comparator of the second plurality of comparators and a fourth vertical signal line of the plurality of the vertical signal lines is configured to connect to a fourth comparator of the second plurality of comparators.

32. The electronic apparatus according to claim 31, wherein, a first vertical signal line of the plurality of vertical signal lines is shared with a first comparator and a second comparator of the first plurality of comparators.

33. The electronic apparatus according to claim 32, wherein a second vertical signal line of the plurality of vertical signal lines is shared with a third comparator and a fourth comparator of the second plurality of comparators.

34. The imaging device according to claim 33, further comprising a first switching circuit, wherein a first pixel unit and a second pixel unit of the plurality of pixel units is configured to connect to the first comparator through the first switching circuit.

35. The imaging device according to claim 34, further comprising a second switching circuit, wherein a third pixel unit and a fourth pixel unit of the plurality of pixel units is configured to connect to the third comparator through the second switching circuit.