KR20080043500A - A high voltage detector and a high voltage generator using the same - Google Patents

Abstract

An internal voltage detector and an internal voltage generator using the same are provided to adjust the level of an internal voltage inputted to a differential amplifier variously using a test mode signal. A voltage divider part(200) divides an internal voltage, and adjusts the level of a divided voltage according to a test mode signal. A comparison part(210) outputs an operation control signal of an oscillator by comparing an output level of the voltage divider part with a reference voltage. The voltage divider part includes a plurality of resistors serially connected between an internal voltage input port and a ground voltage port, an output stage connected among the resistors, and a first and a second transistor connected to a specific resistor among the plurality of resistors. The first and the second transistor make a corresponding resistor short circuit in response to a first and a second test mode signal having contrary logic levels.

Description

Internal voltage detector and internal voltage generator using the same {A high voltage detector and a high voltage generator using the same}

1 is a block diagram showing the configuration of a generator according to the present invention.

2 is a circuit diagram illustrating a configuration of an internal voltage detector according to an exemplary embodiment of the present invention.

<Description of main parts of drawing>

100: internal voltage generator 110: internal voltage detector

120: oscillator 130: pump control circuit

140: pump circuit

200: voltage divider 210: differential amplifier

220: buffer unit 230: comparison unit

The present invention relates to an internal voltage generator of a DRAM (Dynamic Random Access Memory), and more particularly, an internal voltage detector for detecting whether an internal voltage is generated while changing the level of the internal voltage using a test mode, and using the same. An internal voltage generator.

Generally, a DRAM is a random access memory capable of writing or reading data to a memory cell composed of one transistor and one capacitor. However, since DRAM uses NMOS as a transistor constituting a memory cell, a word line generating a potential of an external power supply voltage VDD + a threshold voltage Vt + V in consideration of voltage loss caused by the threshold voltage Vt. A driving voltage pumping device is included.

That is, in order to turn on the NMOS, which is mainly used for memory cells, a voltage higher than the threshold voltage (Vt) than the source voltage must be applied to the gate. Therefore, in order to read or write the complete level voltage VDD from the cell or bit line, a boosted voltage of VDD + Vt or more must be applied to the gate of the NMOS. Therefore, in order to drive the word line of the DRAM device, an internal voltage generator for generating the boosted voltage VPP is required.

The internal voltage generator is a device that supplies a constant internal voltage to a circuit in a chip that requires a voltage higher than an external voltage VDD in a semiconductor device. The internal voltage generator includes an internal voltage detector for detecting whether an internal voltage (VPP) is generated, an oscillator for generating pulses for periodically performing charge pumping, a pump circuit for pumping charge of an internal voltage, and the oscillator in the It consists of a pump control circuit which controls said pumping circuit by the output pulse which comes out.

In this case, a typical internal voltage detector receives an internal voltage (VPP), which is the output of the pumping circuit, as an input, determines whether an internal voltage is generated through a differential amplifier, and transmits a signal for determining whether the oscillator is operating. As the speed of DRAM speed increases, it is important to accurately control the oscillation period output from the oscillator. For this purpose, an internal voltage detector capable of variously adjusting the level of the input internal voltage VPP is required.

In order to solve the above problems, the present invention provides an internal voltage detector and an internal voltage generator using the same, including a voltage divider for variously adjusting the level of the internal voltage input to the differential amplifier using the test mode signal. For the purpose of

The internal voltage detector of the present invention for achieving the above object is to divide the internal voltage, the voltage divider for adjusting the level of the divided voltage according to the test mode signal, and compares the output level and the reference voltage of the voltage divider And a comparator for outputting an operation control signal of the oscillator.

In addition, the internal voltage generator of the present invention includes a pump circuit for generating an internal voltage by pumping a power supply voltage in response to an input clock, a voltage divider for distributing the internal voltage in response to a test mode signal, and the voltage division. And a comparison unit comparing the voltage divided by the allocation with the reference voltage and changing the period of the clock according to the output thereof.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram showing a configuration of an internal voltage generator 100 to which the present invention is applied.

The internal voltage generator 100 includes an internal voltage detector 110, an oscillator 120, a pump control circuit 130, and a pump circuit 140.

The internal voltage detector 110 detects a potential level of the internal voltage VPP, which is the output of the pump circuit 140, and detects when the internal voltage falls below a predetermined level to activate the oscillator 120. Raises (Enable).

The oscillator 120 starts oscillation by an enable signal (Enable). The oscillation frequency of the oscillator is appropriately selected so as to efficiently form an internal voltage.

The pump control circuit 130 receives a oscillation signal from the oscillator 120 and applies a predetermined control signal to the pump circuit 140 outputting the internal voltage VPP by the charge pumping operation.

The pump circuit 140 generates an internal voltage VPP by a pumping operation in response to a clock input from the pump control circuit 130, and a part of the pump circuit 140 feeds back the internal voltage detector 110.

2 is a circuit diagram showing the configuration of an internal voltage detector 110 according to an embodiment of the present invention.

The internal voltage detector 110 converts the input voltage, that is, the internal voltage VPP, which is the output voltage of the pump circuit 140, to a predetermined level by a resistance ratio and outputs the voltage divider 200 and the voltage divider 200. And a comparison unit 210 for receiving and outputting the output signal of the comparison.

Preferably, the comparator may be configured in the form of a differential amplifier 210.

The differential amplifier 210 is a component that outputs an operation control signal of the oscillator by comparing a reference voltage signal and an output signal of the voltage divider, and outputs the output signal VPPref and the reference voltage Vref of the voltage divider 200. ), And a voltage comparator 230 for comparing the voltages and the buffers 220 for converting the compared voltage to an external voltage VDD level.

The voltage comparator 230 includes an NMOS transistor 232 that receives the output signal VPPref of the voltage divider 200 as a gate and an NMOS transistor 234 that receives the reference voltage Vref as a gate. The NMOS transistor 236 receives an enable signal Vact as a gate between the node N1 to which the sources of the NMOS transistors 232 and 234 are connected, and the ground power source VSS.

The buffer unit 220 includes current mirror type PMOS transistors 222 and 224 connected between an external voltage VDD and a node N2 and whose gate is commonly connected to the node N3, and the node N2. Inverter 226 for inverting and outputting the voltage level of the.

Looking at the operation of the differential amplifier 210, the voltage signal of the nodes (N2, N3) is the magnitude of the mutually opposite magnitude depending on the magnitude of the voltage signal (VPPref, Vref) supplied to the gate of the NMOS transistors (232, 234) Will have When the output signal VPPref of the voltage divider 200 is greater than the reference voltage Vref, the NMOS transistor 232 is turned on to apply the ground voltage VSS to the node N2, and through the inverter 226. A high level signal is output, which is transmitted to the oscillator 120 to stop the oscillation operation. As a result, the operation of the pump control circuit 130 and the pump circuit 140 is stopped, and the level of the output voltage VPP of the pump circuit 140 is lowered.

On the contrary, when the output signal VPPref is smaller than the reference voltage Vref, the NMOS transistor 234 is turned on so that the ground voltage VSS is applied to the node N3, which causes the PMOS transistors 222 and 224 to be turned on. When turned on, a power supply voltage VDD is applied to the node N2, and a low level signal is output through the inverter 226, which is transmitted to the oscillator 120 to activate the oscillation operation. As a result, the operations of the pump control circuit 130 and the pump circuit 140 are activated to increase the level of the output voltage VPP of the pump circuit 140.

In summary, the differential amplifier 210 outputs a signal for stopping the operation of the oscillator 120 when the output signal of the voltage divider 200 is greater than a reference voltage signal, and outputs the voltage divider 200. If the signal is smaller than the reference voltage signal, a signal for activating the operation of the oscillator 120 is output.

The voltage divider 200 includes a plurality of resistors R1, R2, R3, and R4 connected in series between an internal voltage input terminal VPP and a ground voltage terminal VSS, and an output terminal connected between the resistors. And first and second transistors 202 and 204 connected in parallel with a specific resistor of the plurality of resistors and shorting the corresponding resistor in response to a specific signal. As the specific signal, first and second test mode signals having opposite logic levels are input.

The first transistor 202 is connected in parallel with a specific resistor connected between the internal voltage input terminal and the output terminal, and the second transistor 204 is connected in parallel with a specific resistor connected between the ground voltage terminal and the output terminal. Connected.

Each of the resistors R1, R2, R3, and R4 has a voltage level of the internal voltage input terminal VPP when the first and second transistors 202 and 204 are turned off. Each resistance value is set such that the output signal VPPref and the reference voltage Vref of the voltage divider 200 input to the differential amplifier 210 have the same voltage.

Meanwhile, the reference voltage Vref has a substantially constant voltage level regardless of the change in the power supply voltage VDD and is set to have the same value as the output signal VPPref.

At this time, the voltage value of the output signal (VPPref) is as shown in Equation 1 according to the voltage division law.

First, when the high level voltage signal VPP_down is applied and the first transistor 202 is turned on, the resistor R2, which is connected in parallel with the first transistor 202, is short-circuited to output the output signal VPPref. It becomes larger than in the case of Equation 1.

This means that the output signal VPPref and the reference voltage Vref of the voltage distribution unit 200 have the same voltage before the input voltage VPP reaches a specific level, and the input voltage VPP reaches a specific level. After that, it means that the output signal VPPref of the voltage divider 200 becomes larger than the reference voltage Vref.

Therefore, when the input voltage VPP reaches a specific level, according to the operation of the differential amplifier 210 described above, the NMOS transistor 232 is turned on, and the ground voltage VSS is applied to the node N2, and the inverter The high level signal is passed through 226.

On the contrary, if the high level voltage signal VPP_up is applied and the second transistor 204 is turned on, the resistor R4, which has been connected in parallel with the second transistor 204, is short-circuited to output the output signal VPPref. It becomes smaller than the case of 1.

This means that even when the input voltage VPP reaches a certain level, the output signal VPPref of the voltage divider 200 has a voltage smaller than the reference voltage Vref, and the input voltage VPP must be further increased. This means that the output signal VPPref has the same value as the reference voltage Vref.

Therefore, when the input voltage VPP reaches a certain level, according to the operation of the differential amplifier 210 described above, the NMOS transistor 234 is turned on to apply the ground voltage VSS to the node N3. As a result, the PMOS transistors 222 and 224 are turned on to apply the power supply voltage VDD to the node N2, and a low level signal is transmitted through the inverter 226.

In summary, the voltage divider 200 outputs an output voltage greater than that of the corresponding transistor when the first transistor 202 is turned on in response to the first test mode signal, and outputs the second test mode signal. In response thereto, when the second transistor 204 is turned on, an output voltage smaller than that of the transistor is output. As a result, the differential amplifier 210 outputs a signal for stopping the operation of the oscillator 120 when the first transistor 202 is turned on, and the oscillator when the second transistor 204 is turned on. A signal for activating the operation 120 is output.

As such, the signals applied to the first and second transistors 202 and 204 may be adjusted to increase or decrease the level of the output voltage VPP of the pump circuit 140.

According to the configuration of the present invention as described above, it is possible to easily control the level of the output voltage of the internal voltage generator by changing the level of the voltage input to the differential amplifier included in the internal voltage detector.

Claims (14)

A voltage divider for distributing an internal voltage and adjusting a level of the divided voltage according to a test mode signal; And a comparator for comparing an output level of the voltage divider and a reference voltage to output an operation control signal of the oscillator. The logic of claim 1, wherein the voltage divider is connected in parallel with a plurality of resistors connected in series between an internal voltage input terminal and a ground voltage terminal, an output terminal connected between the resistors, and a specific resistor among the plurality of resistors, and the logics opposite to each other. And first and second transistors for shorting corresponding resistors in response to the first and second test mode signals having a level. 3. The transistor of claim 2, wherein the first transistor is connected in parallel with a specific resistor connected between the internal voltage input terminal and the output terminal, and the second transistor is in parallel with a specific resistor connected between the ground voltage terminal and the output terminal. Connected to the internal voltage detector. The internal voltage detector of claim 2, wherein the voltage divider outputs the same output voltage as the reference voltage signal when the first and second transistors are turned off. 3. The internal voltage detector of claim 2, wherein the voltage divider outputs a larger output voltage than before the corresponding transistor is turned on in response to the first test mode signal. 4. . 3. The internal voltage detector of claim 2, wherein the voltage divider outputs an output voltage smaller than before turn-on of the transistor in response to the second test mode signal. 4. 3. The internal voltage detector of claim 2, wherein the comparator comprises a differential amplifier configured to receive a reference voltage signal and an output signal of an output terminal of the voltage divider, and to output an operation control signal of the oscillator. 4. The internal voltage detector of claim 2, wherein the comparator outputs a signal to stop the operation of the oscillator when the first transistor is turned on in response to the first test mode signal. The internal voltage detector of claim 2, wherein the comparator outputs a signal for activating the operation of the oscillator when the second transistor is turned on in response to the second test mode signal. The internal voltage detector of claim 1, wherein the comparator outputs a signal to stop the operation of the oscillator when the output signal of the voltage divider is greater than a reference voltage signal. The internal voltage detector of claim 1, wherein the comparator outputs a signal for activating an operation of the oscillator when an output signal of the voltage divider is smaller than a reference voltage signal. A pump circuit for generating an internal voltage by pumping a power supply voltage in response to an input clock; A voltage divider for distributing the internal voltage in response to a test mode signal; And a comparing unit comparing the voltage divided by the voltage dividing unit with a reference voltage and changing a period of the clock according to an output thereof. The method of claim 12, The voltage divider may include first distribution resistors connected in series between an internal voltage input terminal and a first node; Second distribution resistors connected in series between the first node and ground; A first switching element connected in parallel to one of the first distribution resistors and turned on in response to a first test mode signal; A second switching element connected in parallel to one of the second distribution resistors and turned on in response to a second test mode signal having a level opposite to the first test mode signal; Internal voltage generator comprising a. 13. The internal voltage generator of claim 12, wherein each of the first and second switching elements comprises a transistor.

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