JP2002091583A - Constant-voltage output device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a constant-voltage generation device in which a consumption current when the generation device is driven by a backup power supply can be made small and reliability can be improved by making driving time by the backup power supply long and also preventing a malfunction. SOLUTION: A constant-voltage output device is provided with a switching circuit 110 for switching voltage from external normal power supply and the backup power supply and transmitting the voltage to the inside of an IC 100 for a timer, and a constant-voltage circuit 120 for feeding a constant-voltage to each circuit inside the IC 100 for a timer. The consumption current can be made small while the device is driven by the backup power supply by making the circuit 120 operate intermittently by the backup power supply in accordance with a clock signal while driven by the backup power supply.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to an integrated circuit (IC).
The present invention relates to a constant voltage output device that is built in a circuit or the like and supplies a constant voltage to an IC or the like. In particular, it relates to a constant voltage output device that supplies a constant voltage to a timer circuit, a transmission circuit, and the like.

[0002]

2. Description of the Related Art Conventionally, in a timer IC, an RTC (Real Time Clock) IC or the like having a built-in constant voltage circuit, when an external normal power supply is turned on, the constant voltage circuit is driven by the normal power supply. When the normal power supply is off, the constant voltage circuit is driven by an external backup power supply such as a backup battery.

FIG. 4 shows an example of the configuration of such a conventional timer IC. In FIG. 4, a timer IC
A switching circuit 300 switches the voltage VDD of an external normal power supply (not shown) or the voltage VBK of a backup power supply (not shown) to output a supply voltage VPS, and a predetermined circuit 300 based on an input of the supply voltage VPS. Voltage Vout for timer IC
A constant voltage circuit 320, which is a constant voltage output device for supplying each circuit inside 300; an oscillating circuit 330 which receives a constant voltage from the constant voltage circuit 320 and oscillates;
A timer circuit 340 that operates a timer by receiving a constant voltage from 0.

The switching circuit 310 and the constant voltage circuit 320
They are connected by a power supply line 370. Further, the constant voltage circuit 320, the oscillation circuit 330, and the timer circuit 340 are connected by a constant voltage output line 380.

[0005] The normal power supply and the switching circuit 310 are connected by a normal power supply line 350. Normal power supply (VD
D) is supplied to the switching circuit 310 via the normal power supply line 350. The backup power supply and the switching circuit 310 are connected by a backup power supply line 360. The backup power supply (VBK) is connected to the switching circuit 310 via the backup power supply line 360.
Supplied to

Here, the normal power supply is turned on / off as appropriate. When the normal power supply is turned on, the output voltage of the normal power supply (hereinafter, also referred to as “VDD”) is 3 [V] or 5 [V DD].
[V]. Also, when the power is normally off,
VDD is 0 [V].

[0007] The backup power supply is a battery for maintaining the operation of the timer IC 300 when the normal power supply is turned off. The output voltage of the backup power supply (hereinafter also referred to as “VBK”) is maintained at 3 [V] as long as the remaining battery power remains.

FIG. 5 is a diagram showing an example of the internal configuration of the constant voltage circuit 320. In FIG. 5, the constant voltage circuit 320
Includes a constant voltage source 321 for supplying a predetermined voltage, and an operational amplifier 322 for outputting a constant voltage Vout based on a power supply (VPS) supplied from the switching circuit 310 (FIG. 4).

The positive output terminal of the constant voltage source 321 is connected to the non-inverting input terminal (+) of the operational amplifier 322. The negative output terminal of the constant voltage source 321 is grounded (connected to GND). The operational amplifier 322 and the constant voltage source 32
1 constitutes a voltage follower.

An output terminal of the operational amplifier 322 is connected to a constant voltage output line 380. The operational amplifier 322
Are connected to the inverting input terminal (-) of the operational amplifier 322 by negative feedback.

The operation of the conventional timer IC 300 will be described below with reference to FIGS. First, regarding the operation of the switching circuit 310, VDD is 5 [V] and VBK is 3
[V].

When the normal power supply is on, that is, when VDD is 5 [V], the switching circuit 310 selects the normal power supply (VDD) and connects the normal power supply line 350 and the power supply line 370.

When the normal power supply is off, that is, when VDD is 0 [V], the switching circuit 310 selects the backup power supply (VBK), and the backup power supply line 360 and the power supply line 370.
And connect.

Next, the operation of the constant voltage circuit 320 will be described.
explain. The power supply (VPS) is always supplied to the power supply line 370 via the switching circuit 310 regardless of whether the normal power supply (VDD) is on or off. Therefore, the operational amplifier 322
Are always driven. Therefore, the operational amplifier 322
The constant voltage Vout is constantly output to the constant voltage output line 380.

[0015]

However, the conventional constant voltage device has a problem that the driving time by the backup power supply is short because the current consumption of the constant voltage circuit 320 is large.

In order to reduce current consumption, a watch IC is required.
It is conceivable that the constant voltage circuit 320 is operated intermittently as described above. However, in this case, while the constant voltage circuit 320 stops the intermittent operation, the normal power supply (V
DD) is turned on, that is, when the power supply is switched from the backup power supply to the normal power supply, the output voltage VPS from the switching circuit 310, that is, the voltage VPS of the power supply line 370 becomes VBK.
(For example, 3 [V]) to VDD (for example, 5 [V]). Therefore, the voltage change of the power supply line 370 affects the constant voltage circuit 320, and there is a problem that the timer IC 300 malfunctions.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and has as its object to reduce the current consumption when driven by a backup power supply, extend the drive time by the backup power supply, and prevent malfunction. An object of the present invention is to provide a constant voltage generator capable of preventing the voltage and improving the reliability.

[0018]

In order to solve the above problems, a constant voltage output device according to the present invention comprises a switching circuit for switching between a first power supply and a second power supply, and a first power supply supplied from the switching circuit. Or a constant voltage circuit that is operated by a second power supply and outputs a power supply of a predetermined voltage. In the constant voltage output device, the switching circuit determines whether the power supplied to the constant voltage circuit is the first power supply. A control signal indicating a second power supply is output to a constant voltage circuit, and the constant voltage circuit performs an intermittent operation based on a control signal from a switching circuit.

Here, the first power supply is a normal power supply,
The second power supply may be a backup power supply, and the constant voltage circuit may perform the intermittent operation when the control signal from the switching circuit is a control signal indicating the supply of the second power supply. When the control signal from the switching circuit is a control signal indicating the supply of the second power, the constant voltage circuit may perform an intermittent operation based on the control signal and the clock signal.

The first power supply and the second power supply are switchably connected to each other, and the power supply is intermittently supplied to the constant voltage output circuit at the time of driving by the second power supply. Current consumption can be reduced.

[0021]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a constant voltage output device according to the present invention will be described in detail with reference to the drawings.

FIG. 1 is a diagram showing a configuration example in which the constant voltage output device of the present invention is applied to a timer IC. In FIG. 1, a timer IC 100 switches a voltage VDD of an external normal power supply (not shown) or a voltage VBK of a backup power supply (not shown) to supply voltage VPS and control signal Sout.
And a switching circuit 110 for outputting a predetermined voltage Vout based on the input of the supply voltage VPS and the control signal Sout.
A constant voltage circuit 120 that is a constant voltage output device that supplies each circuit inside the C100; an oscillation circuit 130 that receives a constant voltage from the constant voltage circuit 120 and oscillates;
And a timer circuit 140 that receives a supply of a constant voltage from the timer 20 and operates a timer.

The switching circuit 110 and the constant voltage circuit 120
They are connected by a power supply line 170. A switching circuit 1 is provided between the switching circuit 110 and the constant voltage circuit 120.
A power supply selection signal line 180 for supplying a control signal from 10 to the constant voltage circuit 120 is provided. In addition, the constant voltage circuit 1
20, the oscillation circuit 130 and the timer circuit 140 are connected by a constant voltage output line 190.

The normal power supply and the switching circuit 110 are connected by a normal power supply line 150. Normal power supply (VD
D) is supplied to the switching circuit 110 via the normal power supply line 150. The backup power supply and the switching circuit 110 are connected by a backup power supply line 160. The backup power supply (VBK) is connected to the switching circuit 110 via the backup power supply line 160.
Supplied to

Here, the normal power supply is turned on / off as appropriate. When the normal power supply is turned on, the output voltage of the normal power supply (hereinafter, also referred to as “VDD”) is generally 3 [V] or 5 [V]. When the normal power supply is turned off, VDD is 0 [V]. This normal power supply corresponds to a first external power supply.

The backup power supply is a battery for maintaining the operation of the timer IC 300 when the normal power supply is turned off. The output voltage of the backup power supply (hereinafter, also referred to as “VBK”) is kept at 1.5 [V] to 3 [V] as long as there is a remaining battery. This backup power supply corresponds to a second external power supply.

FIG. 2 is a diagram showing the internal configuration of the switching circuit 110. 2, a switching circuit 110 includes a p-channel MOS (Metal Oxide Semiconductor) transistor 111, a constant current source 112 that inputs a constant current,
It includes a p-channel MOS transistor 113, a p-channel MOS transistor 114, a p-channel MOS transistor 115, an n-channel MOS transistor 116, and a buffer 117.

Here, the source of the MOS transistor 111 is connected to the normal power supply line 150. Also,
The gate and drain of the MOS transistor 111 are connected to a constant current source 112.

The source of the MOS transistor 114 is connected to the backup power supply line 160. Also,
The drain of the MOS transistor 114 is connected to the power supply line 1
70. Further, the MOS transistor 11
The gate of No. 4 is connected to the drain of the MOS transistor 111.

The source of the MOS transistor 115 is connected to the power supply line 170. The gate of the MOS transistor 115 is connected to the drain of the MOS transistor 111. Further, the drain of the MOS transistor 115 is connected to the drain of the MOS transistor 116.

The source of the MOS transistor 116 is grounded. The gate of the MOS transistor 116 is connected to the drain of the MOS transistor 111.

The source of the MOS transistor 113 is normally connected to the power supply line 150. The drain of the MOS transistor 113 is connected to the power supply line 170. Further, the gate of the MOS transistor 113 is connected to the drain of the MOS transistor 115.

The input terminal of the buffer 117 is connected to the drains of the MOS transistors 115 and 116.
The output terminal of the buffer 117 is connected to the power selection signal line 1
80.

FIG. 3 is a diagram showing an example of the configuration of the constant voltage circuit 120. 3, a constant voltage circuit 120 includes an OR gate circuit 121 that logically ORs a control signal Sout from a power supply selection signal line 180 and a clock signal CLK having a predetermined frequency, a buffer 122, an n-channel MOS transistor 123, p-channel MOS transistor 1
24, a constant voltage source 125 for supplying a predetermined power supply voltage,
An operational amplifier 126 that outputs a predetermined voltage Vout.

One of the two input terminals of the OR gate circuit 121 is connected to the power supply selection signal line 180. The other one of the two input terminals of the OR gate circuit 121 is connected via a clock signal input line 127 to
It is connected to a clock generator (not shown).

The drain of the MOS transistor 123 is
It is connected to the operational amplifier 126, and the source of the MOS transistor 123 is grounded. Further, the gate of the MOS transistor 123 is connected to the output terminal of the OR gate circuit 121.

The input terminal of the buffer 122 is connected to the output terminal of the OR gate circuit 121. The output terminal of the buffer 122 is connected to the gate of the MOS transistor 124.

The source of the MOS transistor 124 is normally connected to the power supply line 170. The drain of the MOS transistor 124 is connected to the operational amplifier 126.

The positive output terminal of the constant voltage source 125 is connected to the positive power input terminal of the operational amplifier 126. The negative output terminal of the constant voltage source 125 is grounded. The operational amplifier 126 and the constant voltage source 125 constitute a voltage follower.

The output terminal of the operational amplifier 126 is connected to a constant voltage output line 190. The operational amplifier 126
Is connected to the negative power supply input terminal of the operational amplifier 126 by negative feedback.

The timer IC 1 will now be described with reference to FIGS.
The operation of 00 will be described. Here, in the following description, the normal power supply voltage VDD is 5 [V] when it is on, 0 [V] when it is off, and the backup power supply voltage VBK is 3 [V].
The case will be described.

First, the normal power supply is turned on, that is, VDD is 5
The operation of the switching circuit 110 at the time of [V] will be described.

When VDD is 5 [V] (that is, VDD> V
KB), MOS transistor 111 and constant current source 11
2, a signal of logic "H" is input to the gates of the MOS transistors 114 to 116, respectively. Therefore, M
OS transistors 114 and 115 are turned off.
Further, the MOS transistor 116 is turned on.

When the MOS transistor 116 is turned on, the logic "L" is applied to the gate of the MOS transistor 113.
Is input. Therefore, the MOS transistor 11
3 is turned on.

When MOS transistor 113 is turned on, normal power supply line 150 and power supply line 170 are connected. Therefore, the voltage VPS of the power supply line 170 is VDD
(5 [V]).

When the MOS transistor 116 is turned on, a signal of logic “L” is input to the input terminal of the buffer 117. Therefore, the control signal Sout of logic “H” is output from the output terminal of the buffer 117. Therefore, the control signal Sout of logic “H” is output to the power supply selection signal line 180.

Next, the normal power supply is turned off, that is, VDD is set to 0.
The operation of the switching circuit 110 at the time of [V] will be described.

When VDD is 0 [V] (that is, when VDD <V
KB), MOS transistor 111 and constant current source 11
2, a signal of logic "L" is input to the gates of the MOS transistors 114 to 116, respectively. Therefore, M
OS transistors 114 and 115 are turned on.
Further, the MOS transistor 116 is turned off.

When MOS transistor 114 is turned on, backup power supply line 160 and power supply line 170
And are connected. Therefore, the voltage VPS of the power supply line 170
Becomes VBK (3 [V]).

When MOS transistor 115 is turned on, a logic "H" is applied to the gate of MOS transistor 113.
Is input. Therefore, the MOS transistor 11
3 is off.

When the MOS transistor 115 is turned on, a signal of logic “H” is input to the input terminal of the buffer 117. Therefore, the control signal Sout of logic “L” is output from the output terminal of the buffer 117. Therefore, the control signal Sout of logic “L” is output to the power supply selection signal line 180.

As described above, when VDD is 5 [V] (VDD> V
KB), the power supply line 170 is the normal power supply line 15
0, and a control signal Sout of logic “H” is output to the power supply selection signal line 180. VDD is 0 [V]
In the case of (VDD <VKB), the power supply line 170 is connected to the power supply line 160, and the control signal Sout of logic “L” is output to the power supply selection signal line 180.

Next, the operation of the constant voltage circuit 120 will be described.
explain.

First, the control signal S of the power supply selection signal line 180
The operation of the constant voltage circuit 120 when out is logic “H”, that is, when the normal power supply is turned on, will be described. When the normal power supply is turned on, the power supply line 170 is connected to the normal power supply by the switching circuit 110 as described above.

When the control signal Sout of logic “H” is input from the power supply selection signal line 180 to the OR gate circuit 121, the output signal of the OR gate circuit 121 is independent of the signal value of the clock signal input line 127. It becomes logic "H".

When the output signal of the OR gate circuit 121 is logic "H", a signal of logic "H" is input to the gate of the MOS transistor 123 connected to the output terminal of the OR gate circuit 121. Therefore, the MOS transistor 123 is turned on.

When the output signal of the OR gate circuit 121 is logic "H", a signal of logic "H" is input to the input terminal of the buffer 122 connected to the output terminal of the OR gate circuit 121. Therefore, the buffer 122
Output signal becomes logic "L". Therefore, the buffer 12
The signal of logic “L” is input to the gate of the MOS transistor 124 connected to the output terminal of No. 2. for that reason,
MOS transistor 124 is turned on.

As described above, when the MOS transistor 123 is turned on, the operational amplifier 126 is grounded. When the MOS transistor 124 is turned on, the power of the normal power supply is supplied to the operational amplifier 12 via the power supply line 170.
6. Therefore, the operational amplifier 126 is driven by the normal power supply (VPS = VDD). Then, the operational amplifier 126 outputs the constant voltage Vout to the constant voltage output line 190.

Next, the operation of the constant voltage circuit 120 when the signal on the power supply selection signal line 180 is logic "L", that is, when the normal power supply VDD is turned off will be described. still,
When the normal power supply is turned off, the power supply line 170 is connected to the backup power supply VBK by the switching circuit 110 as described above.

When the control signal Sout of logic “L” is input from the power supply selection signal line 180 to the OR gate circuit 121, the output signal of the OR gate circuit 121 depends on the signal value of the clock signal input line 127. Becomes

Since the control signal Sout of the power supply selection signal line 180 is logic "L", when the signal CLK of the clock signal input line 127 is logic "H", the output signal of the OR gate circuit 121 is logic "H". Become. Therefore, as described above, the MOS transistor 123 and the MOS transistor 124 are turned on. Therefore, backup power (VPS = VBK) is supplied to the operational amplifier 126 via the power supply line 170. Therefore, the operational amplifier 126
Driven by backup power supply. As a result, the operational amplifier 126 outputs the constant voltage Vout to the constant voltage output line 190.
Is output.

When the control signal Sout of the power supply selection signal line 180 is logic "L" and the signal CLK of the clock signal input line 127 is logic "L", the output signal of the OR gate circuit 121 is logic "L". Therefore, a logic "L" signal is input to the gate of the MOS transistor 123 connected to the output terminal of the OR gate circuit 121. Therefore, MO
S transistor 123 is turned off. When the output signal of the OR gate circuit 121 is logic “L”, O
Buffer 1 connected to the output terminal of R gate circuit 121
A logic "L" signal is input to the input terminal 22. Therefore, the output signal of the buffer 122 becomes logic "H".
Therefore, the MO connected to the output terminal of the buffer 122
A signal of logic “H” is input to the gate of S transistor 124. Therefore, the MOS transistor 124 is turned off. When the MOS transistor 123 and the MOS transistor 124 are turned off, the supply of power to the power terminal of the operational amplifier 126 is cut off. Therefore, the operational amplifier 126 stops operating.

As described above, when the control signal Sout of the power supply selection signal line 180 is at logic “H”, the operational amplifier 12
6 is normally driven by a power supply VDD. Then, the operational amplifier 126 outputs the constant voltage Vout to the constant voltage output line 190. Also, the control signal Sout of the power supply selection signal line 180
Is logic "L" and the signal CLK on the clock signal input line 127 is logic "H", the operational amplifier 126 is driven by the backup power supply VBK. Then, the operational amplifier 126 outputs the constant voltage Vout to the constant voltage output line 190. On the other hand, the control signal Sou of the power supply selection signal line 180
When t is logic “L” and the signal CLK on the clock signal input line 127 is logic “L”, the operational amplifier 126 stops operating.

As described above, in the switching circuit 110 and the constant voltage circuit 120 of the present invention, the op-amp 126 is operated intermittently according to the clock signal CLK while being driven by the backup power supply VBK, so that the operation is performed by the backup power supply. Current consumption can be reduced.

[0065]

As described above, according to the constant voltage output device of the present invention, the constant voltage output circuit can be operated intermittently while being driven by the second external power supply such as the backup power supply. The current consumption while being driven by the second external power supply can be reduced. For this reason, accurate and long-term operation with a backup power supply became possible.

[Brief description of the drawings]

FIG. 1 is a diagram showing a configuration example of an IC using a constant voltage output device according to the present invention.

FIG. 2 is a diagram showing a part of a configuration example of an embodiment of a constant voltage output device according to the present invention.

FIG. 3 is a diagram showing a part of a configuration example of an embodiment of a constant voltage output device according to the present invention.

FIG. 4 is a diagram showing a configuration example of an IC using a conventional constant voltage circuit.

FIG. 5 is a diagram showing a configuration example of a conventional constant voltage circuit.

[Explanation of symbols]

100, 300 Timer IC 110, 310 Switching circuit 111, 113, 114, 115, 124 P-channel MOS transistor 112 Constant current source 116, 123 N-channel MOS transistor 117, 122 Buffer 120, 320 Constant voltage circuit 121 OR gate circuit 125 , 321 Constant voltage source 126, 322 Operational amplifier 130, 330 Oscillation circuit 140, 340 Timer circuit

Claims (3)

[Claims] 1. A switching circuit for switching between a first power supply and a second power supply, and a constant voltage which is operated by the first power supply or the second power supply supplied from the switching circuit and outputs a power supply of a predetermined voltage. A constant voltage output device comprising: a switching circuit, wherein the switching circuit supplies a control signal indicating whether a power supply supplied to the constant voltage circuit is the first power supply or the second power supply to the constant voltage circuit. The constant voltage output device, wherein the constant voltage circuit performs an intermittent operation based on the control signal from the switching circuit. 2. The power supply according to claim 1, wherein the first power supply is a normal power supply, the second power supply is a backup power supply, and the constant voltage circuit is configured such that the control signal from the switching circuit is a power supply of the second power supply. The constant voltage output device according to claim 1, wherein an intermittent operation is performed in the case of a control signal indicating supply. 3. When the control signal from the switching circuit is a control signal indicating the supply of the second power, the constant voltage circuit performs an intermittent operation based on the control signal and a clock signal. The constant voltage output device according to claim 2, wherein: