KR20020058505A - Bit-line sense amp control circuit - Google Patents

Abstract

PURPOSE: An apparatus for controlling a bit line sense amplifier is provided, which stabilizes a restore operation by dispersing power noise, by activating a sensing driving control signal with a different timing as to a normal access operation mode and a refresh operation mode. CONSTITUTION: According to the apparatus for controlling a bit line sense amplifier, a decoding unit(15) generates a control signal informing a refresh operation mode by receiving and decoding a refresh control signal and a sensing start signal and a block selection signal generated under the control of an RAS bar signal. And an active timing control unit(50) delays an active timing of a sensing driving control signal during the refresh operation mode, by judging whether control to add a resistor to a current path to a power supply part, and its switching is controlled by the activation by receiving the control signal informing the refresh operation mode. The active timing control unit comprises a switching device(MN4,MP4) which is switched when the control signal in an inactive state is inputted, and a resistor component(Rs) connected to both sides of the switching device in parallel.

Description

Bit-line sense amp control circuit

The present invention relates to a bit line sense amplifier control device of a semiconductor memory device, and more particularly, to a bit line for controlling a bit line sense amplifier driving control signal to be activated at different timings for a normal access mode and a refresh mode. It relates to a sense amplifier drive control device.

In general, the / s and rto signals, which are the sense amplifier driving control signals, are generated using a signal derived from the rasbah (/ RAS) signal, and the potential states for each operation time point are as follows.

First, in the standby state, the potential of the word line is 0V, and the bit line precharge control signal BLP is applied as 'logic high', so that both bit lines BL and / BL have the same voltage (Vblp = Vcc / 2). Both driving control signals / s and rto are precharged to 'Vblp' so as to be precharged.

Thereafter, the bit line precharge control signal BLP becomes 'logic low', thereby turning off all the transistors in the bit line equalization circuit part, while both bit lines BL and / BL maintain the potential of Vcc / 2. It enters the floating state disconnected from the outside. In this state, the ROH decoder analyzes the ROH address input from the outside, selects one word line, and bootstraps to a potential of Vcc + Vt or more. Therefore, when the charge of the cell connected to the selected word line is loaded on the corresponding bit line and the data of '0' is stored in the cell, the potential of one bit line BL is lowered by ΔV. At this time, the potential of the opposite bit line / BL maintains the precharged voltage Vcc / 2.

In this state, as the voltage of the driving control signal / s gradually decreases from Vcc / 2, the bit line sense amplifier is activated to amplify the potential difference between the bit lines BL and / BL. In this case, the potential of one bit line BL is gradually lowered but the potential of the other bit line BL is not changed. Accordingly, when the potential difference between both bit lines BL and / BL increases, the two drive control signals / s and rto are rapidly changed to 0V and Vcc, respectively, and the BL is discharged to 0V. Charging / BL to Vcc completes the sensing operation.

When the read or write operation is completed through the above process, the voltage of the word line is lowered to maintain the data of the memory cell in the stored state, and the read or write operation is performed in preparation for the next read or write operation. In order to apply the bit line precharge control signal (BLP) to 'logic high' to maintain both bit lines in the precharge state, the sense amplifier drive control signals (/ s and rto) are all set to Vblp (= Vcc / 2) level. Will be generated.

FIG. 1 is a circuit diagram illustrating an example of a bit line sense amplifier driving control apparatus according to the related art. The output is generated by precharging, pull-up, and pull-down sensing sensing control signals rto and / s. A driver for generating a signal for driving control of the output driver unit 200 according to the decoding result of the block selection signal bs and the sensing start signal sg generated under the control of the driver unit 200 and the rasva signal. It comprises a drive control part 100.

The output driver 200 includes a pull-up transistor MP3 connected between a power supply voltage supply terminal and one output terminal (rto signal generating node), and a pull-up connected between a ground terminal and the other output terminal (/ s signal generating node). It is connected between the down transistor MN3 and the two transistors MP3 and MN3, and the potential of the two output terminals rto and / s signal generating nodes is set to Vcc / 2 by a bit line precharge control signal BLP. It consists of the precharge circuit part 20 which precharges to a level. Here, an internal cell core voltage Vcore is used as the power supply voltage.

Meanwhile, the driver driving controller 100 receives a block selection signal bs and a sensing start signal sg generated under the control of the rasva signal, respectively, and decodes the decoding circuit unit 10 and the decoding circuit unit. Each of the two output signals generated having the complementary potential level is received from (10), and the driving control signals of the pull-up transistor MP3 and the pull-down transistor MN3 in the output driver unit 200 connected to the rear stage are respectively received. And a pull-down drive controller 30 and a pull-down drive controller 40 for generating.

The pull-up driving controller 30 includes an PMOS transistor MP1 and an NMOS transistor MN1 connected to an inverter type via a load resistor R1 connected between a power supply voltage supply terminal and a ground terminal to a ground terminal side. . On the other hand, the pull-down driving controller 40 is a PMOS transistor (MP2) and the NMOS transistor (MN2) connected to the inverter type via the load resistor (R2) connected between the power supply voltage supply terminal and the ground terminal connected to the power supply terminal side. It consists of.

FIG. 2 is a circuit diagram illustrating a case where an external power supply voltage Vext is used as the high potential sensing voltage in the bit line sense amplifier driving control device shown in FIG. 1, and is only output to the basic configuration shown in FIG. 1. There is only a difference in that the additional PMOS transistor MP4 connected between the internal cell core voltage applying terminal in the driver unit 200 and the rto signal generating node is added. Accordingly, one sensing driving control signal rto is activated at a high speed by applying an external power supply voltage Vext, and then controlled to maintain an activation potential level ('logic high' level) by an internal cell core voltage.

However, the conventional bit line sense amplifier driving control apparatus having the above-described configuration has the timing of activation of both sensing driving control signals rto and / s not only in the normal access operation mode but also in the refresh operation mode. While being controlled only by two resistors R1 and R2, they are activated at nearly the same speed for both modes of operation to control the driving of the bit line sense amplifiers.

Accordingly, during the refresh operation, sensing drive control signals rto and / s are enabled in all banks, and power noise peak values due to the cell core voltage Vcore, the external power supply voltage Vext, and the ground voltage Vss are respectively increased. It is much higher than in normal access operation. As a result, there is a problem in that the malfunction rate of the cell data through the refresh is greatly increased and the reliability of the device is lowered.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to activate the sensing drive control signal with different timings for the normal access mode and the refresh mode, thereby distributing power noise to stabilize the restore operation. The present invention provides a bit line sense amplifier driving control device.

In order to achieve the above object, the bit line sense amplifier driving control apparatus according to the present invention receives a sensing start signal, a block selection signal, and a refresh control signal generated under the control of a rasva signal, and performs a refresh operation by decoding these signals. Decoding means for generating a control signal indicating a mode;

Switching is controlled according to the activation to receive the control signal informing that the refresh operation mode is activated, thereby controlling whether the resistance component is added to the current path to the power supply terminal, thereby delaying the activation timing of the sensing drive control signal in the refresh operation mode to a certain level. Activation timing adjusting means.

In addition, the activation timing adjusting means is configured by selectively connecting to each of the power supply terminals of the output driver and driver driving control.

1 is a circuit diagram showing an embodiment of a bit line sense amplifier driving control apparatus according to the prior art;

FIG. 2 is a circuit diagram illustrating a case where an external power supply voltage is used as a high potential sensing voltage in the bit line sense amplifier driving controller shown in FIG.

3 is a circuit diagram illustrating a first embodiment of a bit line sense amplifier drive control apparatus according to the present invention;

4 is a circuit diagram showing a second embodiment of the bit line sense amplifier drive control apparatus according to the present invention;

5 is a circuit diagram illustrating a third embodiment of a bit line sense amplifier drive control apparatus according to the present invention.

FIG. 6 is a circuit diagram illustrating a case where an external power supply voltage is used as a high potential sensing voltage in the bit line sense amplifier driving controller shown in FIG.

<Description of the symbols for the main parts of the drawings>

10, 15: decoding circuit section 20: precharge circuit section

30, 35: pull-up drive control unit 40, 45: pull-down drive control unit

50: activation timing adjusting means

100, 110, 120, 130, 140: driver drive control unit

200, 210, 220: output driver section

The above and other objects and features and advantages of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a circuit diagram illustrating a first embodiment of a bit line sense amplifier drive control apparatus according to the present invention, which is generated by precharging, pull-up, and pull-down sensing drive control signals rto and / s. And an output driver unit 200 to generate a signal for driving control of the output driver unit 200.

The output driver 200 includes a pull-up transistor MP3 connected between a power supply voltage supply terminal and one output terminal (rto signal generating node), and a pull-up connected between a ground terminal and the other output terminal (/ s signal generating node). It is connected between the down transistor MN3 and the two transistors MP3 and MN3, and the potential of the two output terminals rto and / s signal generating nodes is set to Vcc / 2 by a bit line precharge control signal BLP. It consists of the precharge circuit part 20 which precharges to a level. Here, an internal cell core voltage Vcore is used as the power supply voltage.

The driver driving control unit 120 receives a block selection signal bs, a sensing start signal sg, and a refresh control signal ref generated under the control of the rasva signal, and performs a refresh operation by decoding these signals. A decoding circuit section 15 for generating a control signal (refen) indicating that the mode, and both output signals generated with complementary potential levels from the decoding circuit section 15 are respectively received in the output driver section 200 connected to the rear stage. And a pull-up drive control unit 35 and a pull-down drive control unit 45 for generating drive control signals for the pull-up transistor MP3 and the pull-down transistor MN3, respectively.

The pull-up driving controller 35 includes an PMOS transistor MP1 and an NMOS transistor MN1 that are inverter type connected through a load resistor R1 connected between a power supply voltage supply terminal and a ground terminal to a ground terminal side. In a conventional configuration, the control signal (refen) indicating the refresh operation mode is received and switching is controlled according to whether the signal is activated to adjust the addition of the resistance component to the current path to the ground terminal (Vss), the refresh operation And an activation timing adjusting means 50 for delaying the activation timing of the sensing drive control signals rto and / s in the mode to a certain level.

On the other hand, the pull-down driving controller 45 is also connected to the PMOS transistor (MP2) and the NMOS transistor (MN2) connected to the inverter type via the load resistor (R2) connected between the power supply voltage supply terminal and the ground terminal. In the existing configuration, a control signal (refen) indicating a refresh operation mode is received and switching is controlled according to whether the signal is activated, thereby controlling whether or not the resistance component is added to the current path to the power supply terminal (Vcc), thereby providing a refresh operation. And an activation timing adjusting means 50 for delaying the activation timing of the sensing drive control signals rto and / s in the mode to a certain level.

The activating timing adjusting means 50 includes MOS transistors MN4 and MP4 as respective switching elements which are switched when the control signal refen, which indicates that the refresh operation mode output from the decoding circuit unit 15 is in an inactive state, is switched. And each resistor element Rs connected in parallel to the MOS transistor between the source terminal and the drain terminal of each of the MOS transistors MN4 and MP4.

Hereinafter, the operation of the present invention having the above configuration will be described in detail with reference to the drawings.

First, in the normal access operation mode, the control signal refen indicating whether to enter the refresh mode is output in an inactive state, thereby turning on the respective MOS transistors MN4 and MP4 in the activation timing adjusting means 50. do. Accordingly, the corresponding current path is formed without the addition of a resistor by the separate resistor Rs connected in parallel to each of the turned-on MOS transistors MN4 and MP4, and the pull-up controlled only by R1 and R2 is provided. And generating a pull-down driving control signal to drive the output driver 200 of the rear stage.

On the other hand, in the refresh mode, the control signal (refen) generated through the decoding circuit unit 15 is activated by 'logic high' and is generated by turning each of the MOS transistors MN4 and MP4 in the activation timing adjusting means 50. -Is turned off. As such, the turned-off MOS transistors MN4 and MP4 add resistance components to the respective paths by resistance elements Rs connected in parallel to them, resulting in pull-up and pull-down driving. The timing of activation of the control signal is delayed by a certain level. This delays the turn-on timing of the pull-up transistor MP3 and the pull-down transistor MN3 in the output driver unit 200 connected to the rear stage, and finally outputs the sensing drive control signals rto and / s. ) Is adjusted to be delayed by a certain level compared to the normal access operation mode.

As a result, the noise of power consumed when the sensing operation of the bit line sense amplifier is started during the refresh operation can be dispersed in a large amount, thereby performing a more stable restore operation.

FIG. 4 is a circuit diagram illustrating a second embodiment of the bit line sense amplifier driving control apparatus according to the present invention. In the embodiment shown in FIG. 3, the activation timing adjusting unit 50 included in the driver driving control unit 120 is shown. Is shown to be configured in the output driver 220, the basic operation is the same, so detailed operation description will be omitted.

FIG. 5 is a circuit diagram illustrating a third embodiment of a bit line sense amplifier driving control apparatus according to the present invention. In the embodiments shown in FIGS. 3 and 4, an activation timing including a MOS transistor and a resistor connected in parallel to each other is shown. Transfer gate elements MT1 and MT2 as switching elements which are switched when the control means refen, which informs the adjusting means 50 of the refresh operation mode output from the decoding circuit unit 15, is activated, and the transfer gate element The configuration is shown by replacing capacitors C1 and C2 as resistance elements connected in series between MT1 and MT2 and the ground terminal.

When the bit line sense amplifier driving control device having the above configuration enters the refresh operation mode, the control timing (refen) generated through the decoding circuit unit 15 is activated by 'logic high' and is activated. Each transfer gate element MT1 or MT2 in 50 is turned on. At this time, since the turned-on transfer gate elements MT1 and MT2 are connected to the capacitors C1 and C2 as resistive elements, resistance components to respective corresponding paths are added, resulting in pull-up and pull-up. It is possible to delay the activation timing of the down drive control signal to a certain level. This delays the turn-on timing of the pull-up transistor MP3 and the pull-down transistor MN3 in the output driver unit 200 connected to the rear stage, and finally outputs the sensing drive control signals rto and / s. ) Is adjusted to be delayed by a certain level compared to the normal access operation mode.

As a result, the noise of power consumed when the sensing operation of the bit line sense amplifier is started during the refresh operation can be dispersed in a large amount, thereby performing a more stable restore operation.

FIG. 6 is a circuit diagram illustrating a case where an external power supply voltage Vext is used as the high potential sensing voltage in the bit line sense amplifier driving control device shown in FIG. 3, and is only output to the basic configuration shown in FIG. 3. There is only a difference in that the additional PMOS transistor MP4 connected between the internal cell core voltage Vcore application terminal in the driver unit 200 and the rto signal generating node is added. Accordingly, the one-side sensing drive control signal rto is activated at high speed by applying the external power supply voltage Vext, and then maintains the activation potential level ('logic high' level) by the internal cell core voltage Vcore. Controlled.

The configuration of the output driver 200 may be similarly applied to each of the embodiments illustrated in FIGS. 4 and 5.

As described above, according to the bit line sense amplifier driving control apparatus according to the present invention, the sensing driving control signal can be activated with a different timing for the normal access operation mode and the refresh operation mode. By activating the activation timing of one sensing driving control signal by a certain level later than in the normal access operation mode, a considerable amount of noise of power consumed when the sensing operation of the bit line sense amplifier is started can be dispersed.

Accordingly, it is possible to greatly reduce the noise peak value of the power line, there is a very excellent effect that can perform a stable restore operation compared to the conventional.

In addition, the preferred embodiments of the present invention are disclosed for the purpose of illustration, and those skilled in the art will be able to make various modifications, changes, additions, etc. within the spirit and scope of the present invention, such modifications, changes, etc. are defined in the claims It should be seen as belonging.

Claims (7)

Decoding means for receiving a sensing start signal, a block selection signal, and a refresh control signal generated under the control of the rasva signal and generating a control signal informing of the refresh operation mode by decoding these signals; Switching is controlled according to the activation to receive the control signal informing that the refresh operation mode is activated, thereby controlling whether the resistance component is added to the current path to the power supply terminal, thereby delaying the activation timing of the sensing drive control signal in the refresh operation mode to a certain level. And an activation timing adjusting means. The method of claim 1, The activation timing adjusting means may include: a switching element that switches when a control signal indicating that the refresh operation mode output from the decoding means is input into an inactive state; And a resistance element connected in parallel to both ends of said switching element. The method of claim 2, And the switching device uses a MOS transistor. The method of claim 1, The activation timing adjusting means may include: a switching element that is switched when a control signal indicating that the refresh operation mode output from the decoding means is input into an active state; And a resistance element connected in series between the switching element and the ground terminal. The method of claim 4, wherein And the switching device uses a transfer gate device. The method of claim 4, wherein The resistive element is a bit line sense amplifier drive control device, characterized in that using a capacitor. The method of claim 1, And the activation timing adjusting means is selectively connected to a power supply terminal of each of the output driver and the driver driving control unit.