JP3098480B2 - Power supply circuit - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to a power supply circuit,
In particular, the present invention relates to a power supply circuit that converts an externally supplied power to a constant voltage and internally supplies the same.

[0002]

2. Description of the Related Art An example of the configuration of a conventional power supply circuit will be described below with reference to FIG.

In a conventional power supply circuit, a voltage (VDD) supplied from an external power supply (battery or the like) is reduced to half the voltage by a voltage harbor circuit 301 in order to reduce current consumption for the purpose of extending the battery life of the set. As input to the power supply of the regulator 2. Further, the voltage regulated by the regulator 302 is supplied to an oscillator 303 which is an internal circuit.
And so on. The voltage harbor circuit has two
Switching capacitors in series and parallel
The voltage VDD is reduced to 1/2. Here, the output voltage that has been made constant by the regulator 302 is a voltage higher than the oscillation stop voltage of the supplied oscillator.

Next, a conventional power supply circuit will be described with reference to FIG. 4 when a power supply voltage is supplied from a battery which is an external power supply. FIG. 4 is a graph showing a relationship between power supply voltage and life time in the power supply circuit shown in FIG.

With the power supply voltage immediately after the use of the battery, the output voltage of the regulator 302 is supplied to the oscillator 303.
When the output of the voltage harbor circuit 301 becomes lower than the set voltage of the regulator 302, the output voltage of the voltage harbor circuit 301 is supplied to the oscillator 303. Therefore, even if the power supply voltage is higher than the oscillation stop voltage of the oscillator 303, the voltage harbor circuit 3
Oscillation of the oscillator 303 stops at the point A at which the output voltage of 01 becomes lower than the oscillation stop voltage.

[0006]

As described above, in the conventional power supply circuit, the power supply voltage is halved by a voltage harbor circuit in order to reduce the current consumption in order to extend the battery life of the set. The voltage regulated by the regulator is supplied to the oscillator.

However, in this configuration, even if the power supply voltage is higher than the oscillation stop voltage, the oscillator stops if half of the power supply voltage becomes lower than the oscillation stop voltage.
There is a problem that. For this reason, 10
This is a serious problem for microcomputers for sets (gas meters), which require low current consumption of annual operation.

Accordingly, the present invention has been made in view of the above problems, and has as its object to achieve low power consumption and extend the period until oscillation stops longer than in the conventional example. To provide a power supply circuit.

[0009]

In order to achieve the above object, the present invention provides an externally supplied power supply voltage having a constant voltage,
In a power supply circuit for supplying a constant voltage to an internal circuit, a first switch circuit having an input connected to a power supply voltage level, a first regulator circuit using an output of the first switch circuit as a power supply, A voltage harbor circuit that uses a power supply voltage level as a power supply, a second switch circuit that receives an output of the voltage harbor circuit as an input,
A second regulator circuit that uses the output of the switch circuit as a power supply, and an output voltage of the first and second regulator circuits that uses the outputs of the first and second regulator circuits as first and second inputs. And a switch circuit control circuit that receives the output of the comparator as an input, and outputs a first and a second output of the switch circuit control circuit to the first and second switches. A switch on / off control signal of the second switch circuit is input, and a power supply of a regulator having a lower voltage output among the outputs of the first and second regulators,
Off by the first or second switching circuit, said first, and second of the output of the regulator is intended to supply towards the high output to an external circuit, the switching circuit
By the control circuit, at any timing, the first and the second
Is turned on, and the first and second regulators are turned on.
After outputting both outputs of the comparator circuit, the comparator
The output of the first and second regulators
The switch circuit that compares the voltages and inputs the comparison result
The first and second regulators by a path control circuit.
Of the output of the circuit,
By turning off the power, the first and second registers are turned off.
The higher output voltage of the comparator circuit is supplied to the internal circuit.
To be characterized.

[0010]

Embodiments of the present invention will be described below. In a preferred embodiment of the power supply circuit of the present invention, a first switch circuit (106 in FIG. 1) whose input is connected to a power supply voltage level (VDD), and an output of the first switch circuit as a power supply. A first regulator circuit (101 in FIG. 1), a voltage harbor circuit (103 in FIG. 1) using a power supply voltage level as a power supply, and a second switch circuit (107 in FIG. 1) using an output of the voltage harbor circuit as an input. ), A second regulator circuit (102 in FIG. 1) that uses the output of the second switch circuit as a power source, and outputs of the first and second regulator circuits as first and second inputs, respectively. A comparator (104 in FIG. 1) that compares the output voltages of the first and second regulator circuits and outputs the comparison result, and a switch circuit control circuit that receives the output of the comparator as an input 105 of FIG. 1)
And the first and second outputs of the switch circuit control circuit (105 in FIG. 1) are used as switch on / off control signals for the first and second switch circuits (106 and 107 in FIG. 1). Of the first and second regulator circuits, the power supply of the regulator circuit with the lower voltage output is turned off by the first or second switch circuit, and the first and second switch circuits are turned off. The higher output voltage of the output of the regulator circuit is supplied to a circuit such as an oscillator (108 in FIG. 1).

In an embodiment of the present invention, when a voltage higher than a regulator output voltage is input to the power supplies of the first and second regulators, a voltage lower than the output voltage of the second regulator is output. The regulator to be used is referred to as the first regulator.

When the power supply voltage is equal to or higher than a specified value such as when the battery is exhausted, the output voltage of the second regulator circuit is supplied to the internal circuit, the power supply voltage drops, and the output voltage of the voltage harbor circuit is reduced. Is the second
From the time point when the voltage becomes lower than the set voltage of the regulator circuit, the output voltage of the voltage harbor circuit is supplied to the internal circuit, the power supply voltage further drops, and the output voltage of the voltage harbor circuit becomes the first voltage. When the voltage reaches the set voltage of the regulator circuit, the output voltage of the first regulator circuit is supplied to the internal circuit, and the power supply voltage becomes lower than the set voltage of the first regulator circuit. The voltage itself is supplied to the internal circuit. For example, the oscillation stop time of an internal circuit such as an oscillator can be extended.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS In order to describe the above-mentioned embodiment of the present invention in more detail, an embodiment of the present invention will be described below. FIG. 1 is a diagram showing the configuration of one embodiment of the present invention.

Referring to FIG. 1, in one embodiment of the present invention, a power supply circuit comprises first and second regulators 101,
102, a voltage harbor circuit 103, a comparator circuit 104, a switch control circuit 105, first and second switch circuits 106 and 107, and an oscillator 108 is connected to an external circuit of the power supply circuit.

A half voltage of the power supply voltage VDD is supplied by the voltage harbor circuit 103, and the output voltage of the second regulator 102 which outputs power higher than the oscillation stop voltage is lower than the output voltage of the second regulator 102. The output voltage of the first regulator 101 that outputs a voltage higher than the oscillation stop voltage is
The control circuit 105 turns off (off) the switch circuits 106 and 107 of the output voltage of the first regulator 101 and the output voltage of the second regulator 102 which have a lower output voltage according to the output result of the comparator 103. )
By doing so, a higher output voltage is supplied to the oscillator 108.

A power supply voltage (VD
D) is supplied to a power supply unit, and an electric circuit is opened and closed (off /
on), the input of the first switch circuit 106 is connected,
The output is input to the power supply of the first regulator 101. On the other hand, a power supply voltage (VDD) supplied from an external power supply
Is converted into a constant voltage by the voltage harbor circuit 103, and the voltage is connected to the input of the second switch circuit 107. The output of the second switch circuit 107 is input to the power supply of the second regulator 102.

The first regulator 101 and the second regulator 1 are controlled by a comparator 103 which receives as input the output voltage that has been made constant by the first regulator 101 and the output voltage that has been made constant by the second regulator 102.
02 is compared.

The output of the switch circuit control circuit 105 to which the comparison result of the comparator 3 is input is used as the on / off signal of the first switch circuit 106 and the second switch circuit 107 and the output of the first regulator 101 and the second switch circuit 107. The switch connected to the regulator with the lower voltage among the outputs of the second regulator 102 is turned off.

For this reason, of the outputs of the first regulator 101 and the second regulator 102, a higher output is supplied to an oscillator 108 or the like which is an internal circuit. However, the first regulator 101 and the second regulator 101
In the output voltage value setting of 02, when the same voltage is supplied to the power supply, the second regulator 102 outputs a higher voltage than the first regulator 101, and supplies the output voltage of the second regulator 102. The voltage is higher than the oscillation stop voltage of the oscillator 108.

Next, a case where a power supply voltage is supplied from a battery which is an external power supply in one embodiment of the present invention will be described with reference to FIG.

In general, as shown in FIG. 2, the voltage supplied to a battery decreases depending on its use time. First, in the operation at the point T in FIG. 2 immediately after the start of use of the battery, the first switch circuit 106 and the second switch circuit 108 are turned on by the switch circuit control circuit 105 at an arbitrary timing.
As a result, the output of the first regulator 101 and the output of the second regulator 102 supplied with half the power supply voltage by the voltage harbor circuit 103 are input to the comparator 103, and the output voltages are compared.

The output voltage values of the first regulator 101 and the second regulator 102 are set such that, when the same voltage is supplied to the power supply, the second regulator 102 outputs a higher voltage than the first regulator 101; Since the switch circuit control circuit 105 turns off the switch connected to the regulator having the lower voltage output, the output voltage of the second regulator 102 is supplied to the oscillator at the power supply voltage immediately after the use of the battery. .

Next, a case when the battery is exhausted will be described.

When the switch circuit control circuit 105 is operated in the same manner as described above, the power supply voltage immediately after the use of the battery causes the second
The output voltage of the regulator 102 is supplied to the oscillator 108. When the power supply voltage drops and the output voltage of the voltage harbor circuit 103 becomes lower than the set voltage of the second regulator 102, the voltage harbor circuit 103 Is supplied to the oscillator 108.

The power supply voltage further drops, and the output voltage of the voltage harbor circuit 103 becomes the first regulator 101
The first regulator 101
Is supplied to the oscillator 108, and after the power supply voltage becomes lower than the set voltage of the first regulator 101, the power supply voltage itself is supplied to the oscillator 108, and finally, at the point B of the oscillation stop voltage. Oscillation stops.

In the embodiment of the present invention, the output of the comparator 104 is input as the switch circuit control circuit 105, and the first and second switch circuits 106 and 107 are input.
A control circuit is constituted by a microcomputer which can be controlled by software and which outputs an input of the switch on / off signal of the first and second regulator circuits according to an output result of the comparator. The configuration may be such that the higher output voltage of the first and second regulators is supplied to the oscillator 108 by turning off the power of the lower regulator circuit.

[0027]

As described above, according to the present invention,
As compared with the case where the power supply of the conventional oscillator is used, there is an effect that the period until the oscillator stops can be not extended. That is, the battery life can be extended.

The reason is as follows. In the above-described conventional technology, the power supply voltage is halved by the voltage harbor circuit, and the voltage regulated by the regulator is supplied to the oscillator. Therefore, when half of the power supply voltage becomes lower than the oscillation stop voltage, the oscillation stops immediately. However, in the present invention, before the half of the power supply voltage becomes lower than the oscillation stop voltage, the power supply voltage is switched to a constant voltage by the first regulator before the oscillator in the present invention. To extend the time until oscillation stops (point B in FIG. 2).

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration of an embodiment and an example of the present invention.

FIG. 2 is a diagram showing a relationship between a power supply voltage and a life time in one embodiment of the present invention.

FIG. 3 is a diagram illustrating an example of a configuration of a power supply circuit according to the related art.

FIG. 4 is a diagram showing a relationship between a power supply voltage and a life time in the related art.

[Explanation of symbols]

 Reference Signs List 101 first regulator (regulator 1) 102 second regulator (regulator 2) 103 voltage harbor circuit 104 comparator 105 switch control circuit 106 first switch (switch 1) 107 second switch (switch 2) 108 oscillator 301 voltage Harbor circuit 302 Regulator 303 Oscillator

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) G05F 1 / 445,1 / 56 G05F 1 / 613,1 / 618

Claims (5)

(57) [Claims] 1. A external supplied power voltage constant voltage, met power circuit for supplying a constant voltage to the voltage to the internal circuit
A first switch circuit having an input connected to a power supply voltage level, a first regulator circuit using an output of the first switch circuit as a power supply, a voltage harbor circuit using a power supply voltage level as a power supply, A second switch circuit that receives an output of the voltage harbor circuit as an input, a second regulator circuit that uses an output of the second switch circuit as a power source, and an output of the first and second regulator circuits. A comparator that compares output voltages of the first and second regulator circuits as first and second inputs and outputs a comparison result as an output; and a switch circuit control circuit that receives an output of the comparator as an input. First and second outputs of the switch circuit control circuit are used as switch on / off control signals of the first and second switch circuits, respectively. Input, and among the outputs of the first and second regulator circuits, the power supply of the regulator circuit with the lower voltage output is turned off by the first or second switch circuit; Of the outputs of the regulator circuit 2
The power supply circuit that supplies the higher output voltage to the internal circuit
In addition, the switch circuit control circuit allows an arbitrary timing
Then, the first and second switch circuits are turned on , and both outputs of the first and second regulator circuits are output.
After the force is applied, the first and
Compare the output voltage of the second regulator and compare the results
Is input by the switch control circuit.
And the output of the second regulator circuit with the lower voltage
By turning off the power supply of the regulator circuit of
Higher output voltage of the first and second regulator circuits
Is supplied to the internal circuit. 2. The power supply circuit according to claim 1, wherein, instead of said switch circuit control circuit, an output of said comparator and an input of a switch on / off signal of said first and second switch circuits are provided. Outputting the output from the power supply circuit to the outside, connecting the output of the comparator and the switch on / off signals of the first and second switch circuits to a microcomputer which can be controlled by software; Of the first and second regulators, the power supply of the lower one of the regulator circuits is turned off, whereby the higher output voltage of the first and second regulator circuits is obtained. A power supply circuit for supplying the power to the internal circuit. 3. A regulator that outputs a voltage lower than the output voltage of the second regulator circuit when a voltage higher than the regulator output voltage is input to the power supply of the first and second regulator circuits. The power supply circuit according to claim 1, wherein the power supply circuit is a first regulator circuit. 4. When the power supply voltage is equal to or higher than a prescribed value, the output voltage of the second regulator circuit is supplied to the internal circuit, the power supply voltage drops, and the output voltage of the voltage harbor circuit is reduced to the second regulator. From the time when the voltage becomes lower than the set voltage of the circuit, the output voltage of the voltage harbor circuit is supplied to the internal circuit, the power supply voltage further drops, and the output voltage of the voltage harbor circuit becomes the first regulator circuit. The output voltage of the first regulator circuit is supplied to the internal circuit, and after the power supply voltage becomes lower than the set voltage of the first regulator circuit, the power supply voltage itself becomes power circuit according to claim 3, wherein There, characterized in that, supplied to the internal circuit. 5. A power supply circuit according to any one of claims 1及至4, characterized in that the internal circuit consisting of an oscillator.