KR100732390B1 - current mirror type circuit for compensating leakage current - Google Patents

Abstract

The present invention relates to a current mirror type leakage current compensation circuit configured to reduce leakage of cell data and consumption of static power by configuring a leakage current compensation circuit in a bit line, including: a cell array; each cell array; A leakage current detector configured between the bit lines Bit / Bitb connected to the cells and detecting leakage currents of the bit lines Bit / Bitb; each bit line Bit, The first leakage current compensation block and a second leakage current compensation block connected to the bit line Bitb to compensate for leakage current in the read / write period and the first precharge period P1; A first operation mode conversion unit for selectively converting the normal precharge mode and the dynamic current mirror mode, and a second operation mode conversion unit, and the same amount of current when the leakage current is detected by the leakage current detection unit. Claim characterized in that the supply of the leakage current compensation block, the second bit line leakage current compensation block (Bit), / bit line (Bitb) through.

Leakage Current, Current Mirror Type, SRAM

Description

Current mirror type circuit for compensating leakage current             

1 is a configuration diagram of a typical SRAM unit cell

2 is a block diagram of a current mirror type leakage current compensation circuit according to the present invention

3 is an operation timing diagram of a current mirror type leakage current compensation circuit according to the present invention;

4A and 4B are graphs comparing operation timings of the leakage current compensation circuit according to the present invention.

* Description of the symbols for the main parts of the drawings *

21. Cell array 22. Leakage current detector

23a. First Leakage Current Compensation Block 23b. 2nd leakage current compensation block

24a. First operation mode converter 24b. Second operation mode converter

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a semiconductor memory, and more particularly, to a current mirror type leakage current compensation circuit configured to reduce leakage of cell data and consumption of static power by configuring a leakage current compensation circuit in a bit line.

SRAM memory cells fall into two categories. One is a high load resistor cell which adopts high resistance as a load element, and the other is a CMOS cell which adopts PMOS transistor as a load element.

CMOS cells fall into two categories. One is a thin film transistor cell employing a thin film transistor as a load element, and the other is a complete CMOS cell employing a bulk transistor as a load element.

Hereinafter, the SRAM of the prior art will be described.

1 is a block diagram of a conventional SRAM cell.

The CMOS SRAM cell comprises a pair of driver transistors (TD1, TD2), a pair of transfer transistors (TA1, TA2) and a pair of load transistors. transistor; TL1 and TL2).

Here, the pair of driving transistors TD1 and TD2 and the pair of transfer transistors TA1 and TA2 are all formed of NMOS transistors, while the pair of load transistors TL1 and TL2 are all formed of PMOS transistors. do.

The first driving transistor TD1 and the first transfer transistor TA1 are connected in series with each other.                         

The source region of the first driving transistor TD1 is connected to the ground line Vss, and the drain region of the first transfer transistor TA1 is connected to the first bit line BL.

Similarly, the second driving transistor TD2 and the second transfer transistor TA2 are also connected in series with each other.

The source region of the second driving transistor TD2 is connected to the ground line Vss.

On the other hand, the source region and the drain region of the first load transistor TL1 are connected to the power region Vcc and the drain region of the first driving transistor TD1, that is, the first node N1, respectively.

Similarly, the source region and the drain region of the second load transistor TL2 are connected to the drain region of the power line Vcc and the second driving transistor TD2, that is, the second node N2, respectively.

The gate electrode of the first driving transistor and the gate electrode of the first load transistor are both connected to the second node N2, and the gate electrode of the second driving transistor and the gate electrode of the second load transistor are both the first node N1. ) Is connected.

In addition, the gate electrodes of the first and second transfer transistors TA1 and TA2 are connected to the word line WL.

In the conventional SRAM having such a structure, as the integration and the speed of the prior art are increased, the threshold voltage of the transistors constituting the cell becomes low.

However, such a conventional semiconductor memory has the following problems.                         

In order to achieve high speed in processes below 0.15 μm, the MOS threshold voltage (Vt) must be lowered, which leads to an increase in bit line leakage current.

This may cause a decrease in the ΔV value of the bit / bitb during read, resulting in loss of cell data and an increase in static power consumption.

SUMMARY OF THE INVENTION The present invention solves the problems of the prior art semiconductor memory, and detects and compensates the bit line leakage current caused by lowering the transistor Vt for high speed in SRAM by using a current mirror type structure. The present invention provides a current mirror type leakage current compensation circuit which can prevent distortion of cell data.

In accordance with an aspect of the present invention, there is provided a current mirror type leakage current compensation circuit including a cell array; a bit line configured between a bit line Bit and / or a bit line connected to each cell of the cell array. A leakage current detection unit configured to detect leakage currents of the bit and bit lines Bitb, respectively, connected to the bit lines Bit and bit lines Bitb, respectively, in the read / write period and the first precharge period P1. A first leakage current compensation block for compensating for leakage current, a second leakage current compensation block; a first operation mode converter for selectively converting a normal precharge mode and a dynamic current mirror mode by a mode switching signal SWb, and a second It is configured to include an operation mode conversion unit when the leakage current is detected by the leakage current detection unit the same amount of current through the first leakage current compensation block, the second leakage current compensation block bit line (Bit) / bit line (Bitb) It is characterized in that supplied to).

Hereinafter, the current mirror type leakage current compensation circuit according to the present invention will be described in detail.

2 is a block diagram of a current mirror type leakage current compensation circuit according to the present invention.

3 is an operation timing diagram of the current mirror type leakage current compensation circuit according to the present invention, and FIGS. 4A and 4B are graphs comparing operation timings of the leakage current compensation circuit according to the present invention.

The present invention is constructed between a bit line (Bit), a bit line (Bitb) connected to each of the cells of the SRAM cell array 21 and the cell array 21, the bit line (Bit) / / bit line (Bitb) A leakage current detection unit 22 for detecting a leakage current of the first and second bit lines connected to the bit line Bit and / or bit line Bitb to compensate for the leakage current in the read / write section and the first precharge section P1, respectively. First operation mode converter 24a for selectively converting the normal precharge mode and the dynamic current mirror mode by the first leakage current compensation block 23a, the second leakage current compensation block 23b, and the mode switching signal SWb. And a second operation mode converter 24b.

The leakage current detector 22 includes an equalization transistor PM9 configured between a bit line Bit and a bit line Bitb and an equalization signal EQb applied to a gate, and two PMOS transistors. A precharge unit connected to a power supply voltage terminal VDD and to which a precharge control signal PRECHb is commonly applied to a gate, and a first operation mode converter 24a connected to the transistors of the precharge unit in series; ), And the first and second leakage current detection transistors PM1 and PM5 to which the output signal of the second operation mode converter 24b is applied.

In addition, the first operation mode converter 24a is switched by the switching transistor PM4 to which the inverted mode switch signal SWb is applied to the gate, and the mode transistor signal SWb and the inverted mode switch signal SWb. The first transmission gate TM1 selectively applies the power supply voltage supplied by the PM4 to the gate of the first leakage current detection transistor PM1.

In addition, the second operation mode converter 24b is switched by the switching transistor PM8 to which the inverted mode switch signal SWb is applied to the gate, and the switching transistor PMb by the mode switch signal SWb and the inverted mode switch signal SWb. The second transmission gate TM2 selectively applies the power supply voltage supplied by the PM8 to the gate of the second leakage current detection transistor PM5.

The first leakage current compensation block 23a is connected in series to a first compensation transistor PM3 and a first compensation transistor PM3 to which one electrode is connected to a power supply voltage terminal and a leakage current compensation signal COMb is applied to a gate. The gate is connected to one electrode of the switching transistor PM4 of the first operation mode converter 24a and the one electrode is common to the drain and the gate of the first leakage current detection transistor PM1 of the leakage current detector 22. It is composed of a second compensation transistor (PM2) connected.

The second leakage current compensation block 23b is connected in series to a third compensation transistor PM7 and a third compensation transistor PM7 having one electrode connected to a power supply voltage terminal and a leakage current compensation signal COMb applied to a gate thereof. The gate is connected to one electrode of the switching transistor PM8 of the second operation mode converter 24b and the one electrode is common to the drain and the gate of the second leakage current detection transistor PM5 of the leakage current detector 22. The fourth compensation transistor PM6 is connected.

As described above, the current mirror type leakage current compensation circuit of the present invention “PM2 / PM7” is turned on by the COMb (compensation) signal during the read / write period and the first precharge period P1 as shown in FIG. 3. The same amount of current is injected into PM6 to compensate for the bit / bitb line.

During the precharge period, the bit line and the bitb line are precharged to “H” (VDD value) under the control of the PRECHb signal, the EQb signal, and PM1 / PM5.

In the P1 section of the precharge section, when the initial bit / bitb is “H” precharged, the P2 section disables the EQb (equalize) signal to “H” to separate the bit / bitb, and PM1 / PM5 turns off. Thus reducing the reduction of static power.

In the standby P2 section, the TM1 / TM2 (transmission gate) is controlled by the SWb signal and is enabled as “L” so that the PM1 / PM5 and PM2 / PM6 enter the current mirror operation mode of the same size transistor. .

If a leakage current occurs in the bit / bitb line in the P2 section, the leakage current is detected in PM1 / PM5, and the current is injected as much as the leakage current detected in PM2 / PM6 to compensate for the leakage current in the bit / bitb line.

In the P3 section, the EQb signal is again enabled by "L" to equalize bit / bitb, the SWb signal is disabled by "H", and becomes the normal precharge mode, and the COMb signal is enabled by "L" again by PM2 / Inject compensating current into PM6.

Thereafter, there is no decrease in the ΔV value of the bit / bitb in the read / write section, thereby preventing the loss of cell data during the read operation.

Such a current mirror leakage current compensation circuit according to the present invention has the following effects.

The present invention detects and compensates a bit line leakage current by using a current mirror type structure to reduce cell data loss due to an increase in the bit line leakage current due to a decrease in the threshold voltage and a decrease in the ΔV value of the bit / bitb Suppress the partial static power reduction.

Claims (6)

Cell arrays; A leakage current detector configured between bit lines Bit / Bitb in each cell of the cell array to detect leakage currents of the bit lines Bit / Bitb; A first leakage current compensation block connected to the bit line Bit to compensate for leakage current in the read / write section and the first precharge section P1; A second leakage current compensation block connected to the bit line Bitb to compensate for leakage current in the read / write section and the first precharge section P1; A first operation mode conversion unit selectively converting the normal precharge mode and the dynamic current mirror mode by the mode switching signal SWb; A second operation mode conversion unit for selectively converting the normal precharge mode and the dynamic current mirror mode by the mode switching signal SWb, When the leakage current is detected by the leakage current detection unit, the first leakage current compensation block and the second leakage current compensation block supply the same amount of current to the bit lines Bit and / bit lines Bitb. Circuit. 2. The semiconductor device of claim 1, wherein the leakage current detector comprises: an equalizing transistor PM9 configured between a bit line Bit and a bit line Bitb and to which an equalization signal EQb is applied to a gate; A precharge unit comprising two PMOS transistors, one electrode of which is connected to a power supply voltage terminal VDD and to which a precharge control signal PRECHb is commonly applied to a gate; And a first and second leakage current detection transistors PM1 and PM5 connected in series to the transistors of the precharge unit and to which respective output signals of the first and second operating mode converters are applied. A current mirror type leakage current compensation circuit. The method of claim 1, wherein the first operation mode conversion unit A buffer INV1 for inverting the mode switch signal SWb; A switching transistor (PM4) connected between a predetermined node connected to the first leakage current compensation block and a power supply voltage terminal, and configured to pull-up the node in response to an output signal of the buffer INV1; And a transfer gate (TM1) for transmitting the signal of the node to the leakage current detector in response to the mode switch signal (SWb). The method of claim 1, wherein the second operation mode conversion unit A buffer INV2 for inverting the mode switching signal SWb; A switching transistor (PM8) connected between a predetermined node connected to the second leakage current compensation block and a power supply voltage terminal, and configured to pull-up the node in response to an output signal of the buffer (INV2); And a transfer gate (TM2) for transmitting the signal of the node to the leakage current detector in response to the mode switch signal (SWb). The method of claim 1, wherein the first leakage current compensation block A first compensation transistor (PM3) connected between a power supply voltage terminal and a predetermined node and pulling up the node in response to a leakage current compensation signal; And a second compensation transistor (PM2) connected between the node and the bit line and transferring the signal of the node to the bit line in response to an output signal of the first operation mode converter. The method of claim 1, wherein the second leakage current compensation block A first compensation transistor PM7 connected between a power supply voltage terminal and a predetermined node and pulling up the node in response to a leakage current compensation signal; A current mirror type leakage current compensation connected between the node and the bit line and including a second compensation transistor PM6 that transfers a signal of the node to the / bit line in response to an output signal of the second operation mode converter. Circuit.

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