JP2000356655A - Voltage detection circuit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a voltage detection circuit which realize a low power consumption without a decline of detection precision of a circuit. SOLUTION: The voltage detection circuit 100 is used for an examination of the condition of a first voltage. The voltage detection circuit 100 consists of a detection voltage generation circuit 110 which generates a detection voltage 110a becoming a first voltage monitor, a reference voltage generation circuit 120 which generates a reference voltage 120a, and a comparator circuit 160 which compares the detection voltage with the reference voltage and outputs a result of the comparison as a detection signal 160a. Moreover, a voltage detection circuit 100 is provided with control circuits 140, 150 so that one circuit at least out of a detection voltage generation circuit 110, a reference voltage generation circuit 120 and a comparator circuit 130 can operate intermittently.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a voltage detection circuit for detecting a voltage state, such as a power supply voltage detection circuit.

[0002]

2. Description of the Related Art A power supply voltage detection circuit is a circuit mainly mounted in a microcomputer for portable equipment, and is widely used for detecting a battery life or detecting a capacitor power supply voltage when used in a backup mode state. Used. Furthermore, the power supply voltage detection circuit generates a reset signal for initialization at power-on or a reset signal for preventing system runaway at power fluctuation.
It can also serve as a power-on reset.

[0003] The configuration and operation of a conventional power supply voltage detection circuit 10 will be described with reference to FIG. The power supply voltage detection circuit 10 includes a detection voltage generation circuit 11, a reference voltage generation circuit 1,
2 and a comparison circuit 13. Detection voltage generation circuit 11
Generates a detection voltage 11a serving as a power supply voltage monitor,
The reference voltage generation circuit 12 generates a reference voltage 12a that is constant regardless of the power supply voltage. The comparison circuit 13 compares the detection voltage 11a with the reference voltage 12a, and outputs a result of the comparison as a comparison circuit output signal 13a. For example, a power supply voltage dividing circuit can be used as the detection voltage generating circuit 11, and a band gap reference circuit can be used as the reference voltage generating circuit 12, for example.

FIG. 2 shows the signal levels of the power supply voltage V, the detection voltage 11a, the reference voltage 12a, and the comparison circuit output signal 13a with respect to time. In the case of FIG.
When 1a becomes higher than the reference voltage 12a, the comparison circuit 13 outputs a comparison circuit output signal 13a. The detection voltage 11a is set to have a certain proportional relationship with the power supply voltage V.

As can be seen from FIG. 2, the magnitude relationship between the detection voltage 11a and the reference voltage 12a changes according to the change in the power supply voltage V. When the detection voltage 11a is higher than the reference voltage 12a, the output of the comparison circuit 13 goes high, and a signal having the same level as the power supply voltage V is output from the comparison circuit output signal 13a.
Is output as On the other hand, when the detection voltage 11a is equal to the reference voltage 1
When the voltage is lower than 2a, the comparison circuit output signal 13a is output from the comparison circuit 13 as a low-level signal. By such an operation, it is possible to detect whether the power supply voltage V is high or low with respect to a certain level, that is, whether the power supply voltage V is higher or lower than a certain level.

[0006]

According to the power supply voltage detection circuit 10 shown in FIG. 1, the comparison between the detection voltage 11a and the reference voltage 12a is always performed without interruption, and the comparison circuit output signal 13a is also used as the comparison circuit output signal 13a. 13 is always output. That is, in the power supply voltage detection circuit 10, in order to detect the power supply voltage, the detection voltage generation circuit 1
1. All of the reference voltage generation circuit 12 and the comparison circuit 13
It must always be operational. For this reason, there arises a problem that a power supply current always flows, which is necessary for the operation of the circuit.

As a means for solving this problem, when the comparison circuit 13 outputs a comparison circuit output signal 13a,
A method of stopping the operation of the circuit so as to cut the power supply current for the circuit operation can be considered. However, if so, the output from the comparison circuit 13 also stops.
This method is not feasible. Therefore, in order to solve the above problem, it is necessary to suppress the power supply current itself required for the operation of the circuit. However, in that case, the circuit is easily affected by temperature and element variation, and the detection accuracy is deteriorated. Another challenge arises.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a voltage detection circuit and a voltage detection method which realize low power consumption without deteriorating the voltage detection accuracy. To provide.

[0009]

A voltage detection circuit according to the present invention is a voltage detection circuit for examining a state of a first voltage, and a detection voltage for generating a detection voltage for monitoring the first voltage. A generation circuit, a reference voltage generation circuit that generates a reference voltage, and a comparison circuit that compares the detection voltage with the reference voltage and outputs a result of the comparison as a detection signal. A control circuit for controlling at least one of the generation circuit, the reference voltage generation circuit, and the comparison circuit to operate intermittently is provided, thereby achieving the above object.

[0010] In one embodiment, the control circuit includes an oscillation circuit that outputs a clock signal.

More preferably, there is further provided a frequency dividing circuit for converting the frequency of the clock signal by the oscillation circuit into a frequency of 1 / N (N is a natural number).

In one embodiment, the at least one circuit is the comparison circuit.

A voltage detection method according to the present invention is a voltage detection method for checking a state of a first voltage, wherein a detection voltage for monitoring the first voltage is intermittently compared with a reference voltage. , And outputs the result of the comparison as a detection signal, thereby achieving the above object.

In one embodiment, a cycle of the intermittent comparison operation is controlled by a clock signal having a predetermined frequency.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A voltage detection circuit according to the present invention has a detection voltage generation circuit, a reference voltage generation circuit, and a comparison circuit, and further controls at least one of these circuits to operate intermittently. A control circuit is provided. The intermittent operation of the circuit reduces the power consumption of the entire circuit.

The voltage detection circuit according to the present invention basically detects a voltage (hereinafter, referred to as a first voltage). The first voltage is a power supply of a voltage detection circuit or an integrated circuit including the voltage detection circuit, that is, a power supply voltage;
And an arbitrary power voltage other than the power supply voltage (for example, a power supply of another integrated circuit or a well bias required in a DRAM).

The voltage detection circuit of the present invention can be further applied to detection of a current such as a rush current of a heater or the like, a latch-up current, or a frequency. In such a case, the current and the frequency are first converted into a voltage, and the obtained voltage is detected using a voltage detection circuit.

Hereinafter, a specific embodiment of the present invention will be described using a voltage detection circuit for detecting a power supply voltage as an example.

(First Embodiment) FIG. 3 shows a configuration of a voltage detection circuit 100 for detecting a power supply voltage according to the present embodiment, and FIG. 4 shows a timing chart of the output of each part of the voltage detection circuit 100. .

The voltage detection circuit 100 includes a detection voltage generation circuit 110, a reference voltage generation circuit 120, and a comparison circuit 130.
Having. The detection voltage generation circuit 110 generates a detection voltage 110a which is a value proportional to the power supply voltage value (for example, 1 / n of the power supply voltage, n> 0) and serves as a monitor of the power supply voltage. The reference voltage generation circuit 120 generates a reference voltage 120a that is constant regardless of the power supply voltage. Comparison circuit 1
Reference numeral 30 denotes a differential type comparator, and a detection voltage 110
a and the reference voltage 120a, and outputs the result of the comparison as a comparison circuit output signal 130a. For example, a power supply voltage dividing circuit can be used as the detection voltage generating circuit 110, and a band gap reference circuit can be used as the reference voltage generating circuit 120, for example.

In this embodiment, the voltage detection circuit 100
Further includes an oscillation circuit 140 configured by a ring oscillator circuit, a delay circuit 150, and a latch circuit 160, for example.

The oscillation circuit 140 has a clock signal (oscillation circuit output signal) having a constant frequency as shown in FIG.
140a is output. The oscillation circuit output signal 140a is delayed by about 5 ns ± 2 ns by the delay circuit 150 to become a power-down signal 150a as shown in FIG. The detection voltage generation circuit 110, the reference voltage generation circuit 120, and the comparison circuit 130 to which the power down signal 150a is input operate intermittently in accordance with the power down signal 150a, and as shown in FIG. 120a and a comparison circuit output signal 130a.

As can be seen from FIG. 4, during the period when the power down signal 150a is high, the comparison circuit 130, the detection voltage generation circuit 110 and the reference voltage generation circuit 1
20 are performed and the power down signal 1
While 50a is low, these circuits are in a power down state and no comparison operation is performed. As described above, the detection voltage generation circuit 110, the reference voltage generation circuit 120, and the comparison circuit 130 are provided with a power-down function, and the intermittent comparison operation causes the comparison circuit 130 to output the comparison circuit output as shown in FIG. The signal 130a is obtained. Note that the comparison operation itself during the period when the power-down signal 150a is high is the same as the conventional example.

The comparison circuit output signal 1 from the comparison circuit 130
30a is latched by the latch circuit 160 simultaneously with the intermittent operation described above. The oscillation circuit output signal 140a from the oscillation circuit 140 is used as the latch clock. By latching in this manner, a continuous detection signal 160a as shown in FIG. In this embodiment, the latch circuit 1
A delay circuit 150 for adjusting data latch timing is provided so that the latch circuit 60 can reliably latch the comparison circuit output signal 130a.

Based on the detection signal 160a obtained in this way, information on the power supply voltage to be detected, for example, the life of the battery or the voltage drop, which is the main power supply of the portable information device, or the backup mode is used. The state of the voltage drop of the capacitor power supply voltage (for example, in the case of a cordless iron) can be checked. Based on the result, for example, in the case of a battery of an information portable device, when the battery voltage is lower than the reference voltage, power management such as stopping some circuits inside the information portable device can be performed. The detection signal 160a can also be used as a reset signal for initialization at power-on or for generating a reset signal for preventing system runaway at power fluctuation.

In the present embodiment, when the duty ratio of the pulse of the oscillation circuit output signal 140a output from the oscillation circuit 140 is 1, the power consumption of the entire circuit is halved without suppressing the operating power supply current of the circuit itself. be able to. By adjusting the duty ratio of the oscillation circuit output signal 140a, the rate of power consumption reduction can be changed as necessary.

In this embodiment, the power down signal 1
50a is a detection voltage generation circuit 110, a reference voltage generation circuit 1
20 and the comparison circuit 130, all of which operate intermittently, but the invention is not limited to this. Detection voltage generation circuit 110, reference voltage generation circuit 120, and comparison circuit 1
If at least one of the 30 units, for example, the comparison circuit 130 operates intermittently, the effect of the present invention of reducing the operating power supply current can be obtained. As shown in FIG. 5, the voltage detection circuit in this case has a configuration in which the delay circuit 150 is connected only to the comparison circuit 130 without being connected to the detection voltage generation circuit 110 and the reference voltage generation circuit 120. Similarly, the delay circuit 150, the detection voltage generation circuit 110, the reference voltage generation circuit 120, and the comparison circuit 130
By appropriately setting the connection between the two, the configuration may be such that only the detection voltage generation circuit 110 and / or the reference voltage generation circuit 120 operate intermittently. Such a modification is also possible in the second embodiment described below.

In the present embodiment, the oscillation circuit 140 and the delay circuit 150 constitute a control circuit that controls the above-described intermittent operation. In order to perform an intermittent operation, the present embodiment uses the oscillation circuit 140 (and the delay circuit 150) that generates a pulse signal. The essential point of the present invention is that the detection voltage generation circuit 110, the reference voltage generation circuit 120, and the comparison circuit 130
Is not operated continuously but after a certain period of time. With such a function, in other words, if the power down signal and the latch clock signal can be supplied, other means may be used as the control circuit instead of the combination of the oscillation circuit 140 and the delay circuit 150. .

(Second Embodiment) A voltage detection circuit for detecting a power supply voltage according to a second embodiment of the present invention will be described with reference to FIGS. This embodiment and the first
The difference from this embodiment is that the voltage detection circuit of this embodiment is provided with a frequency dividing circuit for dividing the frequency of the pulse signal output from the oscillation circuit. Other configurations are basically the same as those of the first embodiment.

FIG. 6 shows the voltage detection circuit 2 according to the present embodiment.
FIG. 7 shows a timing chart of the output of each part of the voltage detection circuit 200. The details will be described below.

The voltage detection circuit 200 includes a detection voltage generation circuit 110, a reference voltage generation circuit 120, and a comparison circuit 130.
Having. The detection voltage generation circuit 110 generates a detection voltage 110a which is a value proportional to the power supply voltage value (for example, 1 / n of the power supply voltage, n> 0) and serves as a monitor of the power supply voltage. The reference voltage generation circuit 120 generates a reference voltage 120a that is constant regardless of the power supply voltage. Comparison circuit 1
Reference numeral 30 denotes a differential type comparator, and a detection voltage 110
a and the reference voltage 120a, and outputs the result of the comparison as a comparison circuit output signal 130a. For example, a power supply voltage dividing circuit can be used as the detection voltage generating circuit 110, and a band gap reference circuit can be used as the reference voltage generating circuit 120, for example.

The voltage detection circuit 200 further includes an oscillation circuit 140 constituted by a ring oscillator circuit, for example.
Frequency divider 142, delay circuit 150, and latch circuit 16
0 is provided. The oscillation circuit 140 outputs a clock signal (oscillation circuit output signal) 140a having a constant frequency, as in the first embodiment (FIG. 7).

The frequency dividing circuit 142 is for dividing the frequency of the oscillation circuit output signal 140a from the oscillation circuit 140, and generates a frequency dividing circuit output 142a which is a clock signal having a specific frequency. As the frequency dividing circuit 142, a T-FF circuit (toggle flip-flop circuit) can be used. Oscillator output signal 140a and frequency divider output 14
2a is logically synthesized by an AND gate, so that the frequency of the clock signal of the oscillation circuit output signal 140a becomes 1 / N.
(N is a natural number), a frequency-divided signal 140b as shown in FIG. 7 is obtained, and applied to the delay circuit 150 and the latch circuit 160.

The divided signal 140b is output by the delay circuit 150.
Are delayed by about 5 ns ± 2 ns, and are output as a power-down signal 150a as shown in FIG.
Output from 0. Detection voltage generation circuit 110 to which power down signal 150a is input, reference voltage generation circuit 120
The comparison circuit 130 operates intermittently according to the power-down signal 150a, and outputs a detection voltage 110a, a reference voltage 120a, and a comparison circuit output signal 130a as shown in FIG.

As can be seen from FIG. 7, during the period when the power down signal 150a is high, the comparison circuit 130, the detection voltage generation circuit 110 and the reference voltage generation circuit 1
20 are performed and the power down signal 1
While 50a is low, these circuits are in a power down state and no comparison operation is performed. As described above, the detection voltage generation circuit 110, the reference voltage generation circuit 120, and the comparison circuit 130 are provided with a power down function, and the intermittent comparison operation causes the comparison circuit 130 to output a comparison circuit output signal as shown in FIG. 130a is obtained. Note that the comparison operation itself during the period when the power-down signal 150a is high is the same as the conventional example.

Comparison circuit output signal 1 from comparison circuit 130
30a is latched by the latch circuit 160 simultaneously with the intermittent operation described above. The frequency-divided signal 140b is used as the latch clock. By latching in this manner, a continuous detection signal 160a as shown in FIG.
Is output from the latch circuit 160. Note that, in the present embodiment, the latch circuit 160 outputs the comparison circuit output signal 130
A delay circuit 150 for adjusting the data latch timing is provided in order to reliably latch “a”.

According to the present embodiment, the power consumption of the entire circuit can be further reduced by half as compared with the first embodiment by dividing the frequency dividing circuit by two. In the present embodiment, the division ratio is set to divide-by-2, but the division ratio is set to another value (3
Needless to say, it can be set to (divide or more). By appropriately setting the frequency dividing N (N is a natural number) of the frequency dividing circuit,
The power consumption of the entire circuit can be reduced to a desired level.

FIG. 8 shows a voltage detection circuit 200 according to this embodiment.
2 is a table showing data of operating power supply current consumed by the conventional voltage detection circuit of FIG. 1. 8, the voltage detection circuit 200 of the present embodiment has a power supply voltage of 5 V
In the case where the frequency dividing circuit 142 is divided by, for example, 150 (the frequency of the clock signal of the oscillation circuit output signal 140a by the oscillation circuit 140 is converted to 1/150), that is, detection is performed for 1 μs at intervals of 150 μs. This is the data for the case. Note that an appropriate value may be determined for the frequency division ratio in consideration of the detection target. As can be seen from FIG. 8, in the power supply voltage detection circuit 200, the effect of reducing the operation power supply current by the reference voltage generation circuit, the detection voltage generation circuit, and the comparison circuit that perform the intermittent operation is reduced by the oscillation circuit and the frequency division circuit. Exceed the increase. Dividing circuit 14
By setting the value of 2 to 150, the operating power supply current consumed by the entire circuit can be reduced to 2.6% of that of the conventional example of FIG.

[0039]

The voltage detection circuit according to the present invention includes a control circuit for controlling at least one of the detection voltage generation circuit, the reference voltage generation circuit, and the comparison circuit to operate intermittently. The intermittent operation of the circuit reduces the power consumption of the entire circuit. According to the present invention,
Low power consumption can be realized without deteriorating the detection accuracy of the circuit. Therefore, by providing the voltage detection circuit according to the present invention, it is possible to extend the life of a power supply battery which is a main power supply of, for example, an information portable device.

[Brief description of the drawings]

FIG. 1 is a configuration diagram of a conventional power supply voltage detection circuit.

FIG. 2 is a diagram illustrating signal levels of detection voltage 11a, reference voltage 12a, comparison circuit output signal 13a, and power supply voltage V with respect to time.

FIG. 3 is a voltage detection circuit 1 according to the first embodiment of the present invention.
FIG.

FIG. 4 is a diagram showing a timing chart of output of each component.

FIG. 5 is a configuration diagram of an example in which the voltage detection circuit 100 is partially modified.

FIG. 6 shows a voltage detection circuit 2 according to a second embodiment of the present invention.
FIG.

FIG. 7 is a diagram showing a timing chart of the output of each component.

FIG. 8 is a table for comparing the operation power supply current of the voltage detection circuit 200 of the second embodiment with that of the conventional example.

[Explanation of symbols]

 100, 200 voltage detection circuit 110 detection voltage generation circuit 110a detection voltage 120 reference voltage generation circuit 120a reference voltage 130 comparison circuit 130a comparison circuit output signal 140 oscillation circuit 140a oscillation circuit output signal 140b frequency division signal 142 frequency division circuit 142a frequency division circuit Output 150 Delay circuit 150a Power down signal 160 Latch circuit 160a Detection signal

Claims (6)

[Claims] 1. A voltage detection circuit for checking a state of a first voltage, comprising: a detection voltage generation circuit for generating a detection voltage for monitoring the first voltage; and a reference voltage generation circuit for generating a reference voltage. A comparison circuit that compares the detection voltage with the reference voltage and outputs a result of the comparison as a detection signal. The detection voltage generation circuit, the reference voltage generation circuit, and the comparison circuit A voltage detection circuit, comprising: a control circuit that controls at least one of the circuits to operate intermittently. 2. The voltage detection circuit according to claim 1, wherein the control circuit includes an oscillation circuit that outputs a clock signal. 3. The voltage detecting circuit according to claim 2, further comprising a frequency dividing circuit for converting a frequency of a clock signal by said oscillation circuit into a frequency of 1 / N (N is a natural number). 4. The voltage detection circuit according to claim 1, wherein said at least one circuit is said comparison circuit. 5. A voltage detection method for checking a state of a first voltage, wherein a detection voltage serving as a monitor of the first voltage is intermittently compared with a reference voltage, and a result of the comparison is obtained. A voltage detection method that outputs as a detection signal. 6. A cycle of the intermittent comparison operation is controlled by a clock signal having a predetermined frequency.
4. The voltage detection method according to 1.