KR100904740B1 - Internal Voltage Compensation Circuit - Google Patents

Abstract

The present invention provides a power-up signal generator for generating a power-up signal in response to a level of a first external voltage or a second external voltage;

A selection signal generator configured to generate a selection signal by comparing the levels of the first external voltage and the second external voltage; And

An internal voltage compensation circuit including a voltage compensator electrically connecting an internal voltage to the first external voltage or the second external voltage in response to the selection signal.

Power-Up Signal, High Voltage Compensation Circuit

Description

Internal Voltage Compensation Circuit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a semiconductor memory device, and more particularly, to an internal voltage compensation circuit for properly compensating a level of an internal voltage in response to two different external voltages in a power-up section.

In general, the power-up signal generation circuit in the semiconductor device refers to a circuit that is responsible for initializing the semiconductor device. In order to operate the semiconductor device, an external voltage VDD is externally supplied. The voltage level of the external voltage VDD starts from 0 [V] and rises to a target voltage level with a constant slope. At this time, when all the circuits of the semiconductor device are directly applied with the external voltage VDD, a malfunction occurs due to the influence of the rising external voltage. Therefore, in order to prevent such chip malfunction, the semiconductor device includes a power-up signal generation circuit to enable a power-up signal, whereby each circuit after the external voltage VDD has reached a stable voltage level. To be supplied. The semiconductor device is initialized by powering up such an operation.

On the other hand, in order to turn on the NMOS transistor mainly used in DRAM memory cells, a voltage higher than the threshold voltage (Vt) than the source voltage should be applied to the gate. In general, the maximum voltage applied to the DRAM is the external voltage (VDD). Because of the level, in order to read the voltage of the complete external voltage VDD from the cell or the bit line or to write to the cell or the bit line, a boost voltage of more than the external voltage VDD + Vt must be applied to the gate of the NMOS transistor. Therefore, the high voltage VPP is generated by voltage pumping the external voltage VDD.

However, in the pumping of the high voltage VPP, when the level of the high voltage VPP is lower than the level of the external voltage VDD, the pumping may not be performed properly. Therefore, before the level of the external voltage VDD is raised to the target voltage level, that is, in the power-up section, the high voltage VPP is electrically connected to the external voltage VDD so that the level of the high voltage VPP is the external voltage VDD. To rise along the level.

1 is a block diagram showing a high voltage compensation circuit according to the prior art.

As shown in the drawing, the high voltage compensation circuit according to the related art converts the high voltage VPP into the external voltage VDD in response to the power up signal generator 10 and the power up signal pwrup that generate the power up signal pwrup. It consists of a high voltage compensation unit 12 electrically connected to.

The power-up signal generator 10 generates a power-up signal pwrup that rises according to the level of the external voltage VDD before the level of the external voltage VDD reaches the target voltage level, that is, during the power-up period. After the level of the external voltage VDD reaches the target voltage level, a power-up signal pwrup that transitions from the high level to the low level is generated. The power up signal pwrup is input to the high voltage compensator 12 to electrically connect the high voltage VPP to the external voltage VDD during the power up period. As a result, the level of the high voltage VPP increases along with the level of the external voltage VDD. After the level of the external voltage VDD reaches the target voltage level, the electrical connection between the high voltage VPP and the external voltage VDD is cut off, and the high voltage VPP is pumped through a high voltage pumping circuit (not shown). .

The high voltage compensation circuit according to the related art can properly compensate the level of the high voltage VPP in the power-up section when one kind of external voltage VDD is input. However, when different types of first external voltages VDD1 and second external voltages VDD2 are input, there is a problem in that they cannot be properly handled. That is, when the high voltage VPP is electrically connected to the first external voltage VDD1 in the power-up period as shown in FIG. 2, the high voltage VPP is smaller than the level of the second external voltage VDD2 in the section A. FIG. When the high voltage VPP is electrically connected to the second external voltage VDD2, a phenomenon in which the high voltage VPP becomes smaller than the level of the first external voltage VDD1 in section B occurs. When the high voltage VPP is lower than the level of the first external voltage VDD1 or the second external voltage VDD2, problems such as latch up may occur.

Therefore, the present invention electrically connects the high voltage VPP to the largest level of the plurality of external voltages in the power-up section when a plurality of different external voltages are input, so that the level of the internal voltage is higher than the level of the external voltage. An internal voltage compensation circuit is disclosed to prevent the voltage from falling.

To this end, the present invention is a power-up signal generator for generating a power-up signal; A selection signal generation unit configured to generate first and second selection signals by comparing levels of a first external voltage and a second external voltage, wherein the second selection signal is generated in response to the power-up signal; And a voltage compensator electrically connecting an internal voltage to the first external voltage or the second external voltage in response to the first and second selection signals.

In the present invention, the power-up signal generation unit preferably generates a power-up signal in response to the level of the first external voltage or the second external voltage.

In an embodiment of the present invention, the selection signal generation unit may include a comparison unit configured to generate a comparison signal by comparing a first external voltage and a second external voltage; A level shifter for level shifting the comparison signal to generate the first selection signal; And a logic unit configured to receive the power-up signal and the first selection signal and perform a logic operation to generate the second selection signal.

In the present invention, the comparator includes: a first voltage divider configured to voltage divide the first external voltage; A second voltage divider configured to voltage divide the second external voltage; And a differential amplifier configured to differentially amplify the output signal of the first voltage divider and the output signal of the second voltage divider to generate the comparison signal.

In the present invention, the first voltage divider comprises: a first resistor connected between a first external voltage terminal and a first node; And a second resistor connected between the first node and a ground terminal.

In the present invention, the second voltage divider includes: a first resistor connected between a second external voltage terminal and a first node; And a second resistor connected between the first node and a ground terminal.

In an embodiment, the level shifter may include: a first pull-down device configured to pull down a first node in response to the comparison signal; A second pull-down device configured to pull-down the first selection signal in response to the comparison signal; A first pull-up element configured to pull-up the first node in response to the first selection signal; And a second pull-up element configured to pull-up the first selection signal in response to the signal of the first node.

In the present invention, the logic unit preferably performs a negative logical operation.

The voltage compensating part may include a first switch electrically connecting the internal voltage to the first external voltage in response to the first selection signal; And a second switch electrically connecting the internal voltage to the second external voltage in response to the second selection signal.

The select signal generator generates a first select signal of a first level and a second select signal of a second level when the level of the first external voltage is greater than the level of the second external voltage. When the level of the first external voltage is smaller than the level of the second external voltage, it is preferable to generate the first selection signal of the second level and the second selection signal of the first level.

In the present invention, when the first level is low level and the second level is high level, the first and second switches are preferably PMOS transistors.

In the present invention, it is preferable that the first and second switches are NMOS transistors when the first level is high level and the second level is low level.

Hereinafter, the present invention will be described in more detail with reference to Examples. These examples are only for illustrating the present invention, and the scope of protection of the present invention is not limited by these examples.

4 is a block diagram showing a high voltage compensation circuit according to a first embodiment of the present invention.

As shown, the high voltage compensation circuit according to an embodiment of the present invention operates in response to a power-up signal generator 20 that generates a power-up signal pwrup, and operates in response to a power-up signal pwrup. A selection signal generator 22 for generating a selection signal sel by comparing the levels of the voltage VDD1 and the second external voltage VDD2; And a high voltage compensator 24 electrically connecting the high voltage VPP to the first external voltage VDD1 or the second external voltage VDD2 in response to the selection signal sel.

The power-up signal generator 20 increases the power-up signal pwrup before the level of the first external voltage VDD1 reaches the target voltage level, that is, according to the level of the first external voltage VDD1 during the power-up period. ), And after the level of the first external voltage VDD1 reaches the target voltage level, a power-up signal pwrup that transitions from the high level to the low level is generated. In some embodiments, the power-up signal generator 20 may generate the power-up signal pwrup according to the level of the second external voltage VDD2.

As shown in FIG. 5, the selection signal generator 22 receives the PMOS transistors P1 and P2 forming the current mirror, and the NMOS transistors receiving the first external voltage VDD1 and the second external voltage VDD2, respectively. An NMOS transistor N3 is configured to receive the N1 and N2 and the power-up signal pwrup and to enable an operation of comparing the levels of the first external voltage VDD1 and the second external voltage VDD2. When the level of the first external voltage VDD1 is greater than the level of the second external voltage VDD2, the selection signal generation unit 22 configured as described above outputs a selection signal sel having a low level. When the level of VDD1) is smaller than the level of the second external voltage VDD2, the high selection signal sel is output.

The high voltage compensator 24 is configured to electrically connect the high voltage VPP to the first external voltage VDD1 in response to the selection signal sel and a high voltage in response to the selection signal sel. And a second high voltage compensator 28 electrically connecting the VPP to the second external voltage VDD2. As illustrated in FIG. 6, the first high voltage compensator 26 receives a low-level selection signal sel to electrically connect the high voltage VPP to the first external voltage VDD1. P5). In addition, as illustrated in FIG. 7, the second high voltage compensator 28 receives an NMOS transistor having a high level selection signal sel and electrically connects the high voltage VPP to the second external voltage VDD2. N5). According to an exemplary embodiment, the first high voltage compensator 26 is an NMOS transistor operated by receiving a high level select signal sel, and the second high voltage compensator 28 is input a low level select signal sel. It can also be implemented as a PMOS transistor that operates.

The operation of the high voltage compensation circuit of the present invention configured as described above will be described with reference to FIG. 8.

First, before the level of the first external voltage VDD1 reaches the target voltage level, that is, the power-up signal pwrup generated by the power-up signal generator 20 in the power-up period is excluded from the initial period of the power-up period. And high level. Therefore, the selection signal generator 22 receiving the high level power-up signal pwrup is enabled to compare the levels of the first external voltage VDD1 and the second external voltage VDD2 to select the signal sel. Create That is, when the level of the first external voltage VDD1 is greater than the level of the second external voltage VDD2, the select signal sel having the low level is output, and the level of the first external voltage VDD1 is the second external voltage. If the level is smaller than the level of VDD2, the selection signal sel having a high level is output.

When the low level select signal sel is generated, the first high voltage compensator 26 operates to electrically connect the high voltage VPP to the first external voltage VDD1. Meanwhile, when the high level selection signal sel is generated, the second high voltage compensator 28 operates to electrically connect the high voltage VPP to the second external voltage VDD2. Therefore, the high voltage VPP increases with an external voltage having a higher level among the first external voltage VDD1 or the second external voltage VDD2 in the power-up period.

Next, after the level of the first external voltage VDD1 reaches the target voltage level, the power-up signal pwrup generated by the power-up signal generator 20 transitions from the high level to the low level. Therefore, the selection signal generator 22 receiving the low level power-up signal pwrup stops driving.

The waveform of the high voltage VPP generated by the high voltage compensation circuit according to the present embodiment described above can be confirmed through FIG. 8. As shown, when different types of first external voltages VDD1 and second external voltages VDD2 are input, the high voltage VPP is connected to an external voltage having a higher level, thereby providing a high voltage in the power-up period. It is possible to prevent a phenomenon such as latch up that occurs when VPP is lower than the level of the first external voltage VDD1 or the second external voltage VDD2.

9 is a block diagram showing a high voltage compensation circuit according to a second embodiment of the present invention.

As shown, the high voltage compensation circuit according to the present embodiment includes a power-up signal generator 30 that generates a power-up signal pwrup, and levels of the first external voltage VDD1 and the second external voltage VDD2. In response to the selection signal generator 32 generating the first selection signal SEL1 and the second selection signal SEL2 and the first selection signal SEL1, the high voltage VPP is applied to the first external voltage ( The first high voltage compensator 34 electrically connected to the VDD1 and the second high voltage compensator electrically connecting the high voltage VPP to the second external voltage VDD2 in response to the second selection signal SEL2. 36). The second external voltage VDD2 is generated in response to the power up signal pwrup.

The power-up signal generator 30 increases the power-up signal pwrup before the level of the first external voltage VDD1 reaches the target voltage level, that is, according to the level of the first external voltage VDD1 during the power-up period. ), And after the level of the first external voltage VDD1 reaches the target voltage level, a power-up signal pwrup that transitions from the high level to the low level is generated. In some embodiments, the power-up signal generator 30 may generate the power-up signal pwrup based on the level of the second external voltage VDD2.

As shown in FIG. 10, the selection signal generator 32 compares the first external voltage VDD1 and the second external voltage VDD2 to the comparison unit 320 to generate a comparison signal PPE. A level shifter 326 for level shifting the signal PPE to generate the first selection signal SEL1, a power-up signal pwrup, and a first selection signal SEL1 are input to perform a negative AND operation. And a logic unit 328 for generating two selection signals SEL2.

The comparator 320 is composed of resistors R1 and R2, and includes a first voltage divider 322 for voltage-dividing the first external voltage VDD1, and resistors R3 and R4, respectively. Comparing signal PPE by differentially amplifying the second voltage divider 324 for dividing the voltage VDD2, the output signal of the first voltage divider 322, and the output signal of the second voltage divider 324. It consists of a differential amplifier 326 to generate. Herein, the resistance values of the resistors R1, R2, R3, and R4 may be output when the first external voltage VDD1 is greater than the second external voltage VDD2. It is preferable that the distribution unit 324 is set to be larger than the output signal.

 The level shifter 326 is connected between the node nd1 and the ground terminal and NMOS transistor N14 that pulls down and drives the node nd1 in response to an inverted signal of the comparison signal PPE, and the node nd2 and the ground terminal. Connected between the NMOS transistor N16 that pulls down the node nd2 in response to the comparison signal PPE, and is connected between the high voltage terminal VPP and the node nd1 in response to the signal of the node nd2. PMOS transistor P14 driving pull-up of node nd1 and PMOS transistor P16 connected between high voltage terminal VPP and node nd2 to pull-up driving node nd2 in response to a signal from node nd1. It is composed of

Referring to FIG. 11, the first high voltage compensator 34 includes a PMOS transistor P30 connected between the first external voltage terminal VDD1 and the ground terminal and turned on in response to the first selection signal SEL1. Referring to FIG. 12, the second high voltage compensator 36 includes a PMOS transistor P32 connected between the second external voltage terminal VDD2 and the ground terminal to be turned on in response to the second selection signal SEL2.

The operation of the high voltage compensation circuit according to the present embodiment configured as described above will be described with reference to FIG. 13 as follows.

Referring to FIG. 13, the first external voltage VDD1 is higher than the second external voltage VDD2 until about 15 (μsec) in the power-up section, and the second external voltage after about 15 (μsec) in the power-up section. The voltage VDD2 is greater than the first external voltage VDD1. After the power-up period ends, that is, after about 18 (μsec), the level of the first external voltage VDD1 rises to a desired level so that the power-up signal pwrup transitions from a high level to a low level.

First, the comparator 320 generates a high level comparison signal PPE in a period before 15 (μsec) when the level of the first external voltage VDD1 is greater than the second external voltage VDD2. That is, since the output signal of the first voltage divider 322 is greater than the output signal of the second voltage divider 324, the turn-on degree of the NMOS transistor N10 is greater than the turn-on degree of the NMOS transistor N12. PPE) goes high level.

The level shifter 326 receives the high level comparison signal PPE and generates a low level first selection signal SEL1. This is because the high level comparison signal PPE turns on the NMOS transistor N16 to pull down the node nd2. The level shifter 326 generates the first selection signal SEL1 by inverting the input comparison signal PPE.

The low level first selection signal SEL1 is input to one end of the logic unit 328. Accordingly, the logic unit 328 generates the high selection second select signal SEL2.

As described above, the first selection signal SEL1 is generated at a low level in the period before 15 (μsec) when the level of the first external voltage VDD1 is greater than the second external voltage VDD2, and the second selection signal SEL2 is generated. ) Is generated at a high level. The low level first select signal SEL1 turns on the PMOS transistor P30 of the first high voltage compensator 34, and the high level second select signal SEL2 turns on the PMOS of the second high voltage compensator 36. Since the transistor P32 is turned off, the high voltage VPP is electrically connected to the first external voltage terminal VDD1. Therefore, the level of the high voltage VPP increases according to the first external voltage VDD1.

Next, the comparator 320 receives the low level comparison signal PPE in a period between 15 μm and 18 μm in which the level of the first external voltage VDD1 is smaller than the second external voltage VDD2. Create

The level shifter 326 receives the low level comparison signal PPE and generates a high level first selection signal SEL1. This is because the low-level comparison signal PPE turns on the NMOS transistor N14 to pull down the node nd1, and turns on the PMOS transistor P16 to pull up the node nd2.

The high level first selection signal SEL1 is input to one end of the logic unit 328. At this time, the power-up signal pwrup rises along the level of the first external voltage VDD1 in the power-up section except for the initial section of the power-up section, as shown in FIG. Is entered at the other end. Accordingly, the logic unit 328 generates the low level second selection signal SEL2.

As such, the first selection signal SEL1 is generated at a high level in a period between 15 μm and 18 μm in which the level of the first external voltage VDD1 is smaller than the second external voltage VDD2. The two select signals SEL2 are generated at a low level. The high level first select signal SEL1 turns off the PMOS transistor P30 of the first high voltage compensator 34, and the high level second select signal SEL2 is applied to the second high voltage compensator 36. Since the PMOS transistor P32 is turned on, the high voltage VPP is electrically connected to the second external voltage terminal VDD2. Therefore, the level of the high voltage VPP increases according to the second external voltage VDD2.

Next, since the power-up signal pwrup transitions from the high level to the low level in the period after 18 (μsec), the logic unit 328 generates the second selection signal SEL2 of the high level. Accordingly, the PMOS transistor P32 of the second high voltage compensator 36 is also turned off to cut off the electrical connection between the high voltage VPP and the second external voltage terminal VDD2. In the period after 18 (μsec), since the first external voltage VDD1 has risen to a desired level, the high voltage VPP is not electrically connected to the first external voltage VDD1 or the second external voltage VDD2. VPP) to pump through a pumping circuit (not shown). Since the high voltage (VPP) pumping circuit is a well-known configuration, detailed description thereof will be omitted.

As described above, the high voltage compensation circuit according to the present embodiment has a higher level of the high voltage VPP in the power-up period when different types of the first external voltage VDD1 and the second external voltage VDD2 are input. By connecting to an external voltage having a voltage, a phenomenon such as latch up that occurs when the high voltage VPP becomes lower than the level of the first external voltage VDD1 or the second external voltage VDD2 is prevented.

1 is a block diagram showing a high voltage compensation circuit according to the prior art.

2 and 3 are waveform diagrams schematically showing internal signal waveforms included in FIG. 1.

4 is a block diagram showing a high voltage compensation circuit according to a first embodiment of the present invention.

5 is a diagram illustrating a configuration of a selection signal generator included in FIG. 4.

6 is a circuit diagram of a first high voltage compensator included in FIG. 4.

FIG. 7 is a circuit diagram of a second high voltage compensator included in FIG. 4.

FIG. 8 is a waveform diagram illustrating the internal signal waveform included in FIG. 4 in more detail.

9 is a block diagram showing a high voltage compensation circuit according to a second embodiment of the present invention.

FIG. 10 is a diagram illustrating a configuration of a selection signal generator included in FIG. 9.

FIG. 11 is a circuit diagram of a first high voltage compensator included in FIG. 9.

FIG. 12 is a circuit diagram of a second high voltage compensator included in FIG. 9.

FIG. 13 is a waveform diagram illustrating in more detail an internal signal waveform included in FIG. 9.

Claims (22)

A power up signal generator configured to generate a power up signal in response to a level of the first external voltage or the second external voltage; A selection signal generator configured to generate a selection signal by comparing the levels of the first external voltage and the second external voltage; And And a voltage compensator for electrically connecting an internal voltage to the first external voltage or the second external voltage in response to the selection signal. delete The method of claim 1, wherein the voltage compensation unit A first switch electrically connecting the internal voltage to the first external voltage in response to the selection signal; And And a second switch electrically connecting the internal voltage to the second external voltage in response to the selection signal. The method of claim 3, wherein the selection signal generator generates a selection signal having a first level when the level of the first external voltage is greater than the level of the second external voltage, and wherein the level of the first external voltage is the second. An internal voltage compensation circuit for generating a selection signal of a second level when the voltage is less than the level of the external voltage. The internal voltage compensation circuit of claim 4, wherein the first level is a low level and the second level is a high level. 6. The internal voltage compensation circuit as claimed in claim 5, wherein the first switch is a PMOS transistor and the second switch is an NMOS transistor. The internal voltage compensation circuit of claim 4, wherein the first level is a high level and the second level is a low level. 8. The internal voltage compensation circuit as claimed in claim 7, wherein the first switch is an NMOS transistor and the second switch is a PMOS transistor. A power up signal generator configured to generate a power up signal in response to a level of the first external voltage or the second external voltage; A selection signal generation unit configured to generate first and second selection signals by comparing levels of the first external voltage and the second external voltage, wherein the first and second selection signals are generated in response to the power-up signal; And And a voltage compensator configured to electrically connect an internal voltage to the first external voltage or the second external voltage in response to the first and second selection signals. delete The method of claim 9, wherein the selection signal generator A comparator configured to generate a comparison signal by comparing a first external voltage and a second external voltage in response to the power-up signal; A level shifter for level shifting the comparison signal to generate the first selection signal; And And a logic unit configured to receive the power-up signal and the first selection signal and perform a logic operation to generate the second selection signal. The method of claim 11, wherein the comparison unit A first voltage divider configured to voltage divide the first external voltage; A second voltage divider configured to voltage divide the second external voltage; And And a differential amplifier configured to differentially amplify the output signal of the first voltage divider and the output signal of the second voltage divider to generate the comparison signal. The method of claim 12, wherein the first voltage divider is A first resistor connected between the first external voltage terminal and the first node; And And a second resistor connected between the first node and a ground terminal. The method of claim 12, wherein the second voltage divider is A first resistor connected between the second external voltage terminal and the first node; And And a second resistor connected between the first node and a ground terminal. The method of claim 11, wherein the level shifter A first pull-down device configured to pull down the first node in response to the comparison signal; A second pull-down device configured to pull-down the first selection signal in response to the comparison signal; A first pull-up element configured to pull-up the first node in response to the first selection signal; And And a second pull-up element configured to pull-up the first selection signal in response to the signal of the first node. 12. The internal voltage compensation circuit of claim 11, wherein the logic unit performs a negative logical product operation. The method of claim 9, wherein the voltage compensation unit A first switch electrically connecting the internal voltage to the first external voltage in response to the first selection signal; And And a second switch electrically connecting the internal voltage to the second external voltage in response to the second selection signal. 18. The method of claim 17, wherein the selection signal generator generates a first selection signal of a first level and a second selection signal of a second level when the level of the first external voltage is greater than the level of the second external voltage. And generating a first selection signal of a second level and a second selection signal of a first level when the level of the first external voltage is less than the level of the second external voltage. 19. The internal voltage compensation circuit according to claim 18, wherein the first level is low level and the second level is high level. 20. The internal voltage compensation circuit according to claim 19, wherein said first and second switches are PMOS transistors. 19. The internal voltage compensation circuit as claimed in claim 18, wherein the first level is high level and the second level is low level. 22. The internal voltage compensation circuit as claimed in claim 21, wherein the first and second switches are NMOS transistors.

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