WO2010015787A1

WO2010015787A1 - Matrix of electronic cells

Info

Publication number: WO2010015787A1
Application number: PCT/FR2009/051570
Authority: WO
Inventors: Bernard Dinkespiler
Original assignee: Universite De La Mediterranee Aix-Marseille Ii; Centre National De La Recherche Scientifique (C.N.R.S)
Priority date: 2008-08-08
Filing date: 2009-08-07
Publication date: 2010-02-11
Also published as: EP2313977A1; FR2934935A1; FR2934935B1

Abstract

This matrix of electronic cells distributed in columns of cells linked to an input of at least one monitoring signal, is characterized in that it exhibits a single input point (17) for said at least one monitoring signal (S) and in that retarder-forming means (18, 19) for delaying the monitoring signal (S) are interposed between the successive columns (11, 12, 13) and/or the successive cells (14, 15, 16) of each column of this matrix, so as to cause a spatio-temporal propagation of the monitoring signal (S) through the matrix (10).

Description

Matrix of electronic cells

The present invention relates to an array of electronic cells.

Such a matrix of cells may for example be formed by a pixel detector which is in fact an integrated circuit organized according to an architecture, for example a three-dimensional array of rows and columns of pixels.

Each pixel then contains an analog part responsible for amplifying and processing the weak signal resulting from the photon-electron conversion of the pixel.

Beside this very sensitive analog part, there is, in each pixel, a digital part consisting of counters, configuration registers and clock distribution, etc.

For practical reasons, it is not possible to shift the digital part out of the pixel array. However, the cohabitation of these digital circuits with adjacent analog circuits, extremely sensitive, poses mutual interference problems that often prohibit their simultaneous operation.

A first problem, source of analog / digital interference, lies in the presence of rows and columns selection rails used to address the pixels to be read.

A second problem lies in the fact that the digital circuits in operation, trigger switches and current calls that can induce relatively large voltage and current variations on neighboring preamplifiers or on their supply and bias circuits.

Some digital operations are particularly penalizing for analog circuits.

This is for example operations triggered simultaneously on all pixels.

For example, a reset order of all the pixel counters is addressed to several hundreds of thousands of latches which are then likely to change state in a very short period of time.

This can then induce malfunctions on the analog circuits causing a drop in image quality even if, thanks to a careful routing of the circuit, these effects can be partially limited. In practice, the pixel imagers operate according to an operational scheme of time sharing between the image capture phase on the one hand and the sensor configuration and image transfer phases on the other hand. Clearly, it is prohibited to transfer data during the capture phase of the images.

This constraint results in the existence of a dead time that is detrimental under certain experimental conditions.

In crystallography for example, some experiments require continuous recording of the images, without dead time. In medical imaging too, a dead time is equivalent to a higher radiation dose for the patient, all other things being equal.

In general, it is known that it is possible to use a cascade of retarders to supply data processing devices with time-shifted clock signals (see for example US Pat. No. 6,954,093). . The object of the invention is to solve the problems mentioned above with regard to cell matrices to reduce the switching noise.

For this purpose, the subject of the invention is an array of electronic cells distributed by columns of cells connected to an input of at least one control signal, characterized in that it has a single point of entry for said at least one control signal and in that means forming a retarder of the control signal are interposed between the successive columns and / or the successive cells of each column of this matrix, to cause a spatio-temporal propagation of the control signal through the matrix. According to other aspects of the invention, the cell matrix comprises one of the following features:

the means forming a retarder are connected in series,

the means forming a cell retarder are directly integrated therein; the means forming a column retarder are integrated in an electrical circuit of the bottom of the columns of the matrix;

the cells are formed of pixels, and

the cells are formed of memory cells. The invention will be better understood from the following description given solely by way of example and with reference to the appended drawings in which: FIG. 1 illustrates a pixel matrix structure to which can be applied the invention, Figure 2 illustrates an elementary pixel of this matrix, and Figure 3 shows a block diagram illustrating the structure and operation of a matrix according to the invention.

As mentioned above, the invention relates to a bi or three-dimensional cell matrix, in which a large number of cells can be sent a given control signal.

In the following description, we will describe an exemplary embodiment based on a matrix of pixels, but it goes without saying of course that other cells such as for example memory cells can be envisaged. Such a structure is illustrated in FIG. 1, in which a matrix circuit designated by the general reference 1 in this figure is recognized, comprising a matrix of pixels designated by the general reference 2, divided into columns of pixels, which are associated with electronic means of bottom of columns designated by the general reference 3. These electronic means of bottom of columns contain circuits common to the pixels in a conventional manner.

More precisely, the constitution of an elementary pixel of this circuit 1 is illustrated in FIG. 2, where it can indeed be observed that such a pixel comprises a digital part designated by the general reference 4 in this associated figure. to an analog part designated by the general reference 5.

As can be seen from this figure, the digital portion is generally carefully separated from the analog portion to limit mutual influences.

However, this matrix structure leads to a certain inevitable proximity between the analog and digital parts of the pixels, with the disadvantages mentioned above. To solve these problems and as illustrated in Figure 3, it is proposed to minimize the simultaneous switching of the cells of the matrix, that is to say in the example shown, pixels.

3, a matrix of pixels which is designated by the general reference 10 and which thus comprises several columns such as, for example, the columns 1 1, 12 and 13, of pixels such as the pixels designated by the references 14, 15 and 16 for column 1 1.

It should be noted that in the rest of the text, the use of the term matrix can cover the whole of the matrix of the structure globally or different parts thereof, in which the different pixels are associated in the form of a subset. -matrix.

Thus, this matrix or this part of matrix comprises a single input for a control signal such as for example the signal designated S in this figure and bearing the reference 17 thereon, which is intended to be distributed to the various pixels of this matrix.

For this purpose, retarder means such as for example the retarder 18 are interposed in series between the various columns 1 1, 12 and 13.

These means forming a retarder are for example integrated in the electrical circuit of the bottom of columns of the matrix. Similarly, retarders such as for example the self-timer designated by the general reference 19, can be integrated in the pixels of each column, they are also connected in series.

Thus, any control signal intended for a large number of pixels and possibly all, such as for example any driving pulse, is transmitted by each pixel to the neighboring pixel of the top in its column, after passing through a delay circuit whose function is therefore to delay the propagation of this pulse, from a single point of entry.

Similarly, the propagation of this control signal from one column to the next of the matrix is delayed by a similar retarder located at the bottom of the column.

This then results in a propagation of the control signal through the matrix, according to a spatio-temporal pattern, in the manner of a wavefront similar to a wave, schematized by the line W moving in the direction D along a diagonal of the matrix.

Thus, by taking an example of a circuit in which a control pulse is sent on 12 flip-flops of 9600 pixels of each circuit, the change of state of approximately 1 10000 flip-flops is potentially triggered.

Without the delay device according to the invention, these switches would take place in a very short time of the order of 200 ps.

Thanks to the integration of the retarders according to the invention, these switches can be spread over time over about 100 ns and in the plane defined by the matrix, the wavefront of the wave thus generated moving approximately along the diagonal of the pixel matrix.

Thus, the inrush currents due to these switches are distributed regularly over time and according to the power pads, classically distributed along the circuit. This propagation in wave is then adapted to the discretion of the designer of the circuit for all the signals which it considers potentially troublesome in the context indicated previously.

By way of example, mention may be made of the use of such a matrix structure for a CMOS sensor for a camcorder imager or a digital camera. In this field also, it seeks a reduced switching noise.

In such a sensor, the propagation mode of the transverse wave control signal in the pixel array can be used to minimize the resetting noise of the capacitance of these pixels.

A good uniformity of resetting the voltage on the pixel capacity is indeed essential to obtain a large dynamic sensor.

Since the number of pixels in currently known sensors is in the millions and we want a 12-14 bit video signal, it is essential to zero the capabilities in a silent and uniform way. But, it goes without saying that other applications for example to a memory matrix electronic circuit, in 2 or 3 dimensions, can also be envisaged. By way of example also, it will be noted that the retarders can be integrated directly in the pixels of the columns for the pixel retarders, whereas for the column retarders, they can be integrated into the electronic circuit of the bottom of the columns. As indicated previously, the term matrix can be understood here as being a global matrix or a matrix part in which cells are associated in sub-matrix.

It has also been indicated previously that the structure according to the invention could be applied to a 3-dimensional block of plane matrices of the type described above.

Indeed, several flat matrices as described above can be associated by being backed to each other to form a 3-dimensional structure, in which delayers can also be used to control the propagation of matrix matrix control signal.

Claims

1. Matrix of electronic cells distributed by columns of cells connected to an input of at least one control signal, characterized in that it has a single point of entry (17) for said at least one control signal (S ) and that delay means (18, 19) of the control signal (S) are interposed between the successive columns (1 1, 12, 13) and the successive cells (14, 15, 16) of each column of this matrix, to cause a spatio-temporal propagation of the control signal (S) along a diagonal of the matrix (10).

2. Matrix of electronic cells distributed by columns of cells connected to an input of at least one control signal according to claim 1, characterized in that the delay means (18, 19) are connected in series.

3 Matrix of electronic cells distributed by columns of cells connected to an input of at least one control signal according to claim 1 or 2, characterized in that the cell retarder means (19) are directly integrated therein.

4. matrix of cells distributed by columns of cells connected to an input of at least one control signal according to any one of the preceding claims, characterized in that the means forming a column retarder (18) are integrated in a circuit bottom of columns (3) of the matrix.

5. Matrix of electronic cells distributed by columns of cells connected to an input of at least one control signal according to any one of the preceding claims, characterized in that the cells are formed of pixels.

6. Matrix of electronic cells distributed by columns of cells connected to an input of at least one control signal according to any one of the preceding claims 1 to 4, characterized in that the cells are formed of memory cells.