JPH1051954A - Method and device for detecting outage of electronic equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method and device for detecting outage of electronic equipment by which the dropping, stoppage, and restoration of the power supply voltage to electronic equipment can be detected accurately. SOLUTION: An outage detecting circuit 25 is constituted of two voltage dividing resistors 2 and 3 and the A/D(analog/digital) conversion input terminal 10a of a microcomputer 8 is used as the outage input terminal of the circuit 25. The voltage V1 supplied to a voltage regulator 6 from a power source circuit 4 is supplied to the circuit 25 and divided by the resistance values r1 and r2 of the resistors 2 and 3 connected in series with each other. The connecting point between the resistors 2 and 3 is connected to the input terminal 10a of the microcomputer 8 and the occurrence of an outage is detected.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a voltage regulator and a microcomputer to which a stabilized voltage is supplied from the voltage regulator.
The present invention relates to a power failure detection method and a power failure detection device for an electronic device including:

[0002]

2. Description of the Related Art FIG. 6 is a circuit diagram showing an example of an electronic apparatus provided with a conventional power failure detection device, and FIG. 7 is a timing chart showing the operation of the conventional power failure detection device.

In FIG. 6, reference numeral 1 denotes a power failure detection circuit, 4 denotes a power supply circuit to which commercial power is input, 5 denotes an electrolytic capacitor for smoothing the output voltage of the power supply circuit 4, 6 denotes a voltage adjusting means, for example, a voltage regulator, and 7 denotes a voltage regulator. An electrolytic capacitor for smoothing the output voltage of the voltage regulator 6, and 8 is a microcomputer. The microcomputer 8 includes a power supply voltage input terminal 9, a power failure detection terminal 10,
A clock output terminal 11 and a data output terminal 12 are provided. Reference numeral 13 denotes a peripheral IC such as an EEPROM, which includes a clock input terminal 14 and a data input terminal 15, and these terminals 14 and 15 are connected to the clock output terminal 11 and the data output terminal 12 of the microcomputer 8, respectively.

The power failure detection circuit 1 includes a diode 20,
It comprises a pnp-type transistor 21, an electrolytic capacitor 22, resistors 23 and 24 for dividing a voltage, and the like.

Next, the operation of the power failure detection device will be described with reference to the timing chart of FIG.

[0006] When the commercial power supply is normally performed, the electronic device operates as follows. Assuming that the output voltage of the power supply circuit 4 is V1, the voltage V1 is smoothed by the smoothing electrolytic capacitor 5. Thereafter, the voltage V1 is converted into a voltage V2 in the voltage regulator 6. This voltage V2 is lower than the output voltage V1 of the power supply circuit 4,
In addition, a stable voltage suitable as the power supply voltage of the microcomputer 8 is input to the power supply voltage input terminal 9 of the microcomputer 8. The peripheral IC 13 connected to the microcomputer 8 receives signals output from the clock output terminal 11 and the data output terminal 12 of the microcomputer 8 at the clock input terminal 14 and the data input terminal 15 of the peripheral IC, and performs predetermined control. Be executed.

When the commercial power drops (instantaneous power failure) or stops (power failure), the output voltage V1 of the power supply circuit 4 of the electronic device starts to decrease (timing T0) as shown in FIGS. 7 (a) and 7 (b). The output voltage V2 of the voltage regulator 6 is maintained for a certain period thereafter.

[0008] When the output voltage V1 of the power supply circuit 4 is further lowered to V _a, even if the output voltage V2 of the voltage regulator 6 starts decreasing (timing T _3). It decreases output voltage V2 of the voltage regulator 6, and reaches the voltage V _b which can not be guaranteed the operation of the microcomputer 8 (timing T _4), at which time it can no longer be guaranteed control near IC13 by the microcomputer 8, the electronic There is a risk that the entire device malfunctions.

[0009] Thus, the input voltage V2 of the power supply voltage input terminal 9 of the microcomputer 8 is lowered, even if below the voltage V _b of the operation of the microcomputer 8 is guaranteed, the microcomputer 8 will continue controlling peripheral IC13 Therefore, a malfunction occurs in the control of the electronic device. For example, if the peripheral IC 13 is EE
In the case of a PROM, if the voltage V2 supplied to the microcomputer 8 is reduced and writing to the EEPROM is performed when the operation of the microcomputer 8 is not guaranteed, erroneous writing may occur.

A power failure detection device is added to prevent such a problem from occurring. The power failure detection circuit 1 detects a drop in the power supply voltage before a malfunction occurs as described below. Of the peripheral IC 13 can be stopped.

FIG. 7C is a diagram showing an input voltage to a power failure detection terminal 10 to which the power failure detection circuit 1 is connected. Now, the reduction of the commercial power supply (instantaneous blackout) or stopped (power failure), begins to decrease the output voltage V1 is the timing T ₀ from the power supply circuit 4 of the electronic device, reduces the base voltage of Toranjita 21, voltage by the diode 20 When the voltage drops by a voltage equal to the sum of the drop and V _{BE of the} transistor 21 (timing T ₁ ), the transistor 21 turns on. Therefore, the electric charge previously stored in the electrolytic capacitor 22 is supplied to the resistors 23 and 24 as the collector current of the transistor 21 until all of the electric charge is discharged. The resistance values of the voltage dividing resistors 23 and 24 are
As shown in FIG. 7C, the input voltage to the microcomputer 8 does not exceed the maximum rating of the microcomputer 8, and the power failure detection terminal 10
Input voltage to the timing T immediately after the timing T _1
The value is set to a value that reaches the threshold value (peak value in the figure) of the power failure detection by the microcomputer 8 in ₂ . That is,
Since the power failure detection signal is input to the microcomputer 8 at a timing (timing T ₂ ) earlier than the timing T ₄ at which the operation of the microcomputer 8 is no longer guaranteed, the microcomputer 8 requires the power supply voltage input terminal 9 to reduce the power supply voltage in advance. In the vicinity I
Control of C13 can be stopped.

[0012]

As described above, while the operation of the microcomputer 8 is guaranteed, the microcomputer 8 is connected to the peripheral IC.
It is necessary to detect a drop in the power supply voltage earlier than the timing of performing various controls on the power supply.

However, in the conventional power failure detection device configured as described above, the decrease in the power supply voltage to be detected is determined by the sum of the voltage drop by the diode 20 and the V _{BE of the} transistor 21. In addition, the detection voltage fluctuates due to variations in elements constituting a circuit such as a transistor, and the timing at which the power supply voltage decreases cannot be accurately determined. Therefore, there is a variation in the time ΔT (= T ₄ −T ₂ ) from the detection of the drop of the power supply voltage (timing T ₂ ) to the drop of the voltage to the voltage at which the operation of the microcomputer 8 is guaranteed (timing T ₄ ). If the time ΔT is short, the operation of the microcomputer 8 is guaranteed, and the process for stopping the control from the microcomputer 8 to the peripheral IC 13 during the normal operation may not be completed.

Further, the conventional power failure detection device only detects the timing at which the power supply voltage drops, and when the power supply voltage returns to a predetermined voltage thereafter, it is not possible to detect the return timing. could not. Further, once the decrease in the power supply voltage is detected, the power failure detection signal cannot be output until the electrolytic capacitor 22 is charged again because the electrolytic capacitor 22 has been discharged. For this reason, the decrease and stop of the power supply voltage cannot be repeatedly detected, and the processing to be performed by the microcomputer 8 after the power supply voltage has returned to the predetermined voltage cannot be immediately executed.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a power failure detection method and a power failure capable of accurately detecting a decrease, a stop, and a return of a power supply voltage of an electronic device. It is to provide a detection device.

[0016]

According to the present invention, there is provided a method for detecting a power failure of an electronic device, comprising: a voltage adjusting means; and a microcomputer to which a stabilized voltage is supplied from the voltage adjusting means. Determining whether the power supply voltage on the input side of the voltage adjustment means is reduced; and determining whether the voltage supplied to the microcomputer is low when the power supply voltage on the input side of the voltage adjustment means is reduced. Determining whether or not the voltage has decreased, and, when the voltage supplied to the microcomputer has decreased, determining whether the voltage has decreased to or below the operation assurance voltage of the microcomputer. Including.

Further, after the voltage supplied to the microcomputer falls below the operation guarantee voltage of the microcomputer, the control from the microcomputer to the peripheral circuit is stopped, and the power supply voltage on the input side of the voltage adjusting means is reduced. And determining whether the voltage has returned to a predetermined voltage.

A power failure detection device for electronic equipment according to the present invention includes a microcomputer having an A / D conversion input terminal, and a power failure detection device for electronic equipment in which a power supply voltage is supplied as a stabilized voltage via voltage adjusting means. In the above, the power supply voltage to the voltage adjusting means is divided and supplied to an A / D conversion input terminal of the microcomputer, so that the microcomputer detects the fluctuation of the power supply voltage stepwise.

The power failure detection device for electronic equipment according to the present invention includes a microcomputer having a plurality of power failure detection terminals,
In a power failure detection device of an electronic device in which a power supply voltage is supplied as a stabilized voltage via a voltage adjustment unit, a resistor for dividing a power supply voltage to the voltage adjustment unit, and a voltage value divided by the resistor And a plurality of comparators for comparing the comparison signals with different comparison voltages of a plurality of comparison voltage generating means, respectively supplying the respective output signals of the comparators to the power failure detection terminal of the microcomputer, and gradually changing the power supply voltage. Is to be detected.

Further, in the power failure detection device for electronic equipment according to the present invention, the power supply voltage is supplied as a stabilized voltage to the electronic equipment having a microcomputer having at least one power failure detection terminal via a voltage adjusting means. In the power failure detection device of the electronic device, the power supply voltage to the voltage adjustment unit is divided and supplied to a power failure detection terminal of the microcomputer to determine whether the power supply voltage on the input side of the voltage adjustment unit is reduced. To judge.

[0021]

BRIEF DESCRIPTION OF THE DRAWINGS FIG.
An embodiment of the present invention will be described.

Embodiment 1 FIG. 1 is a circuit configuration diagram illustrating a power supply portion of an electronic device including the power failure detection device according to the first embodiment.

In FIG. 1, a power failure detection circuit 25 is composed of two voltage dividing resistors 2 and 3, and an A / D (analog / digital) of the microcomputer 8 is provided at a power failure input terminal.
The conversion input terminal 10a is used.

In the power failure detection circuit 25, the voltage V1 is supplied from the power supply circuit 4 to the voltage regulator 6, and is divided by the resistance values r ₁ and r ₂ of the resistors 2 and 3 connected in series. The connection point of the resistors 2 and 3 is the A / D of the microcomputer 8
Connected to the conversion input terminal 10a, power failure detection is performed as described below. The circuit portions other than the power failure detection circuit 25, which correspond to the conventional device in FIG. 6, are denoted by the same reference numerals. Further, the voltage adjusting means is not limited to the three-terminal regulator as described above.

Next, the operation of the power failure detection device according to the first embodiment will be described.

FIG. 2 is a timing chart showing the operation of the power failure detection device, and FIG. 3 is a flowchart for explaining the detection operation.

The power supply voltage V1 is supplied to a power failure detection terminal A of the microcomputer 8 through voltage dividing resistors 2 and 3.
It is converted into a voltage value that satisfies the maximum rating of the / D conversion input terminal 10a. That is, for the voltage value V1 of the power supply circuit 4, the analog voltage value V input to the A / D conversion input terminal 10a is as follows: V = V1 × r ₂ / (r ₁ + r ₂ ).

The A / D conversion input terminal 10 shown in FIG.
The terminal voltage “a” is A / D converted inside the microcomputer 8 and recognized as a digital value. Therefore, the microcomputer 8 can determine a change in the power supply voltage V1 in the power supply circuit 4 stepwise according to the converted digital value.

Now, for example, the microcomputer 8 has a 6-bit A /
If it has a D input terminal, its resolution is 6 bits (64 bits).
), The power supply voltage V1 can be detected in 64 stages. Further, since the power supply voltage is always input to the power failure detection terminal (A / D conversion input terminal 10a) of the microcomputer 8, even if the power supply voltage drops or returns to the original voltage after the stop, Microcomputer 8
If the operation is within the guaranteed range, the microcomputer 8 can judge the return stepwise.

Further, the operation of detecting the power supply voltage will be described in detail with reference to the flowchart shown in FIG.

In the first embodiment, the power failure detection terminal is
A terminal voltage as shown in (c) is input. Assuming that the microcomputer 8 currently used has an N-bit A / D conversion input terminal, A
The input voltage of the / D conversion input terminal 10a can be determined inside the microcomputer 8 in ^2N steps.

[0032] For example, in FIG. 2, and in order to guarantee the voltage value of the input voltage V2 to the microcomputer 8, the minimum voltage (voltage at T ₃₎ V _a as the output voltage V1 of the power supply circuit 4 is required I do. To recognize an analog voltage value to the A / D conversion input terminal 10a at the timing T ₃ as a digital value x ₁ in the microcomputer 8, the voltage value _{V a, V a = {x} 1/2 N} × ｛V1 × r ₂ / (r ₁ + r
As a _2)} may be set a digital value x _1.

[0033] In order to recognize the analog voltage value to the A / D conversion input terminal 10a at the timing T ₄ the operation of the microcomputer 8 can not be guaranteed as a digital value x ₂ in the microcomputer 8, similarly the voltage V _{b , V b = {x 2/} 2 N} × {V1 × r 2 / (r 1 + r
As a _2)} may be set a digital value x _2.

Similarly, a digital value x ₀ (= 2 ^N ) is set for the normal power supply voltage. Here, the relationship between the digital values is x ₀ > x ₁ > x ₂ , and a digital value x ₃ satisfying x ₀ > x ₃ > x ₁ is set by software inside the microcomputer 8, and A / D conversion input is performed. The digital value x at the terminal 10a is always detected.

As shown in FIG. 3, when the detection result x in step S1 is judged to be equal to x _0, the power supply voltage is not lowered. When the detection result x is determined to not equal to x _0, the process proceeds to step S2, x _0> x> supply voltage if x ₁ it is seen that begins to fall. Therefore, the timing at which the drop of the power supply voltage V1 starts is actually
There may be a timing T ₃ prior to reduction, known at the time of the timing T _5.

The digital value ΔX (= x ₀ −x 3) is determined according to the range of the normal value of the power supply voltage V1.

Further, when the detection result x in step S2 it is determined that the digital value x ₁ is smaller than, the flow proceeds to step S3, that the input voltage V2 from the time (timing T ₃₎ to the microcomputer 8 began falling I understand. In this step S3, the digital value x is determined to be the digital value x ₂ is smaller than, seen also can not be guaranteed operation of the microcomputer 8 at the time (timing T _4). Therefore, it is possible to accurately know the timing T _{3 at} which the input voltage V2 to the microcomputer 8 starts to decrease and the timing T _{4 at} which the operation cannot be guaranteed.

[0038] Here, in order to ensure as much as possible the operation guarantee time ΔT1 from the timing T ₄ the operation of the microcomputer 8 can not be guaranteed long, if only large set of digital values x ₃ can than x ₁ and x ₂ Good. That is, according to the time required to stop the control of the peripheral IC 13 after determining the decrease in the input voltage to the microcomputer 8,
The length of the operation guarantee time ΔT1 can be freely determined.

Also, once the detection result x is a digital value x
After the power supply voltage drops to a smaller digital value than _2, if again the digital value x ₂ or more digital values detected by the microcomputer 8, it is also possible to recognize that the power supply voltage V1 begins to return at that time.

As described above, according to the power failure detection device of the first embodiment, it is determined whether or not the power supply voltage V1 on the input side of the voltage regulator 6 has dropped. When the power supply voltage V1 of the microcomputer 8 is decreasing, it is determined whether the voltage V2 supplied to the microcomputer 8 is decreasing. Further, when the voltage V2 supplied to the microcomputer 8 is decreasing, since the voltage is determined whether the falls below the guaranteed operating voltage V _b of the microcomputer 8, it is possible to know the each timing T _0, T _3, T ₄ of the power supply voltage V1 is reduced to correct.

The voltage V supplied to the microcomputer 8 is
2 falls below the operation guarantee voltage _Vb of the microcomputer 8, the control from the microcomputer 8 to the peripheral IC 13 is stopped, and whether the power supply voltage V1 on the input side of the voltage regulator 6 has returned to the predetermined voltage or not. Because it judges
Processing to be performed by the microcomputer 8 after the power supply voltage has returned to the predetermined voltage can be immediately executed.

Embodiment 2 FIG. 4 is a circuit configuration diagram showing a power supply portion of an electronic device including the power failure detection device according to the second embodiment.

In FIG. 4, a power failure detection circuit 26 includes two voltage dividing resistors 2 and 3, and three comparators 1 having the voltage value divided by these resistors 2 and 3 as one input.
6, 17, 18 and comparison voltage generating means, for example, a Zener diode 19, connected to the other input sides of the comparators 16, 17, 18 and having different comparison voltages.
b, 19c, and 19d.
Output signals 7 and 18 are supplied to power failure detection terminals 10b, 10c and 10d of the microcomputer 8, respectively. In addition,
Here, circuit portions other than the power failure detection circuit 26 and corresponding to the conventional device of FIG. 6 are denoted by the same reference numerals.

In the second embodiment, when the microcomputer 8 does not have an A / D conversion input terminal, the power supply voltage V1 is divided by the resistors 2 and 3, and the divided voltage is then divided by a plurality of comparators. 16, 17, and 18, each of which compares three Zener diodes 19 b, 19 c, and 19 d with a Zener voltage (comparison voltage), and compares the comparison result with the microcomputer 8.
It is supplied to the two power failure detection terminals 10b, 10c, 10d. Therefore, the input signal levels to the power failure detection terminals 10b, 10c, 10d of the microcomputer 8 are switched to L / H according to the different Zener voltages, so that the power supply voltage V1 decreases as in the case of the first embodiment. You can know the timing accurately.

For example, three Zener diodes 19
b, 19c, the Zener voltage value by 19d, respectively _{V1 × r 2 / (r 1} + r 2), V a × r 2 / (r 1 + r
_2), it is set to _{V b × r 2 / (r} 1 + r 2). When the comparator 16 is turned on and the comparison result is input to the detection terminal 10b, the microcomputer 8 can determine that "the power supply voltage has dropped". In addition to the comparator 16, the comparator 17 is also turned on, it is possible to perform determination that "the power source voltage is lowered below V _a" by the microcomputer 8. Further, when all of the comparators 16 to 18 are turned on, the microcomputer 8 can determine that the power supply voltage has dropped to _Vb or less.

As described above, by setting the comparison voltage in a plurality of stages, the rate of decrease in the power supply voltage can be easily determined.
In addition, by setting the comparison voltage to an appropriate value other than the set value of the zener voltage described above, it is possible to easily determine how much the power supply voltage has dropped, so that the electronic device can stably operate. It becomes possible to operate.

Embodiment 3 FIG. 5 is a timing chart illustrating the operation of the power failure detection device according to the third embodiment.

The power failure detection device according to the third embodiment uses one power failure detection terminal, similarly to the microcomputer 8 shown in FIG. 6, and, like the power failure detection circuit 25 in FIG. It is composed of only the pressure resistors 2 and 3. That is, the power failure detection device is provided with the power failure detection terminal 10 shown in FIG.
As a, a general input terminal of the microcomputer 8 is used instead of the A / D conversion input terminal.

When a general input terminal such as a microcomputer is used as a power failure detection terminal, the input terminal voltage is about 4 V to 5 V at a high level (“H”) and about 5 V at a low level (“L”). 0V to about 2V. Therefore, when the input voltage V1 of the voltage regulator is sufficiently higher than the output voltage V2, the resistance of the resistors 2 and 3 is adjusted so that the voltage value satisfies the maximum input rating of the power failure detection terminal 10a of the microcomputer 8. the value to a large value, yet set the resistance value r ₂ of the resistor 3 as possible to a large value, when the power supply voltage V1 is not reduced, and configured to determine the "H" in the power failure detection terminal 10a Keep it. By doing so, as shown in FIG. 5 (c), because when the power supply voltage V1 is lowered, an input power failure detection terminal 10a of the first timing T ₀ the microcomputer 8 is level "H", the power supply voltage It can be determined that V1 has not decreased, and when the power supply voltage V1 subsequently decreases, the power failure detection terminal 10a of the microcomputer 8 determines that the level is "L", so that a decrease in the power supply voltage V1 can be detected. FIG 5 shows the timing as T _6.

[0050] That is, conventional diode such as a power failure detection circuit 1, transistor, or the like without the electrolytic capacitor, even if the circuit consists only resistors few dividing, at the timing T ₆ of the power supply voltage V1 The drop can be detected accurately.
If the power supply voltage V1 is sufficiently large with respect to V2, i.e. reduced or point timing T ₆ starts to decrease the power supply voltage V2 to the microcomputer 8 (timing T _3), the power supply voltage V2 to the microcomputer 8 to V _b If the operation can be detected earlier than the point (timing T ₄ ) at which the operation of the microcomputer 8 cannot be guaranteed, necessary processing can be performed before the operation of the microcomputer 8 is stopped. FIG.
And smoothing capacitor 7 subsequent voltage regulator 6 shown in such is sufficiently large, even below the minimum voltage V _a power supply voltage V1 to ensure the input voltage V2 to the microcomputer 8, noted the output voltage of the voltage regulator 6 V2 When the input voltage V1 to the voltage regulator 6 is sufficiently large, the A / D conversion input terminal need not always be used as the power failure detection terminal 10a.

As described above, in the power failure detection device according to the third embodiment, the power supply voltage is supplied as a stabilized voltage via the voltage regulator to the electronic device including the microcomputer having at least one power failure detection terminal. When
When the input / output voltage ratio of the voltage regulator is large, or when the capacitance value of the smoothing capacitor on the output side of the voltage regulator is large, divide the power supply voltage to the voltage regulator and supply it to the power failure detection terminal of the microcomputer. Thus, it is determined whether the power supply voltage on the input side of the voltage regulator has dropped. Therefore, it is not necessary to configure a circuit using transistors and diodes, and the circuit can be configured at low cost.

[0052]

Since the present invention is configured as described above, it has the following effects.

According to the first aspect of the present invention, it is possible to accurately detect a decrease, a stop, and a return of the power supply voltage of an electronic device having a microcomputer, as compared with a power failure detection method configured as in the related art.

According to the invention of claim 2, the microcomputer A / A
Since the power supply voltage is always input to the D conversion input terminal, even when the power supply voltage returns to a predetermined voltage, the microcomputer can determine the stage of the recovery,
The microcomputer can immediately execute the processing to be performed after the return of the power supply voltage.

According to the power failure detection device of the third aspect of the present invention,
Since the power supply voltage is always input to the A / D conversion input terminal of the microcomputer, even when the power supply voltage returns to the predetermined voltage, the microcomputer can determine the stage of the return, and the microcomputer can The processing to be performed after the return of the power supply voltage can be immediately executed.

According to the invention of claim 4, the microcomputer A / A
Even if the D conversion input terminal is not used, it is not necessary to configure a circuit using a transistor or a diode as compared with a conventional power failure detection device, and it is possible to more accurately determine a drop in the power supply voltage. Can be.

According to the invention of claim 5, the microcomputer A / A
Even when the D conversion input terminal is not used, it is not necessary to configure a circuit using transistors and diodes as in the related art, and the circuit can be configured at low cost.

[Brief description of the drawings]

FIG. 1 is a circuit configuration diagram illustrating a power supply portion of an electronic device including a power failure detection device according to a first embodiment.

FIG. 2 is a timing chart illustrating an operation of the power failure detection device according to the first embodiment.

FIG. 3 is a flowchart illustrating a detection operation of the power failure detection device according to the first embodiment.

FIG. 4 is a circuit configuration diagram showing a power supply portion of an electronic device including a power failure detection device according to a second embodiment.

FIG. 5 is a timing chart showing the operation of the power failure detection device according to the third embodiment.

FIG. 6 is a circuit diagram illustrating an example of an electronic apparatus including a conventional power failure detection device.

FIG. 7 is a timing chart showing the operation of a conventional power failure detection device.

[Explanation of symbols]

1, 25, 26 power failure detection circuit, 2 resistor for voltage division, 3 resistor for voltage division, 4 power supply circuit,
5 electrolytic capacitor, 6 voltage regulator, 7
Electrolytic capacitor, 8 microcomputer, 9 power supply voltage input terminal, 10 power failure detection terminal, 11 clock output terminal, 12 data output terminal, 13 peripheral IC, 14 clock input terminal,
15 data input terminal, 16, 17, 18 comparator,
19b, 19c, 19d Zener diode,
Reference Signs 20 Diode, 21 Transistor, 22 Electrolytic Capacitor, 23, 24 Resistor for voltage division.

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁶ Identification code Agency reference number FI Technical indication location H02H 3/24 G06F 1/00 333D H02J 9/00 341P

Claims (5)

[Claims] 1. A method for detecting a power failure of an electronic device, comprising: a voltage adjusting means; and a microcomputer to which a stabilized voltage is supplied from the voltage adjusting means, wherein a power supply voltage on an input side of the voltage adjusting means decreases. Determining whether or not the voltage supplied to the microcomputer is reduced when the power supply voltage on the input side of the voltage adjusting means is reduced; and supplying the voltage to the microcomputer. Determining whether the voltage has fallen to or below the operation guarantee voltage of the microcomputer when the voltage has been reduced. Further, after the voltage supplied to the microcomputer drops below the operation guarantee voltage of the microcomputer, the control from the microcomputer to the peripheral circuit is stopped, and the voltage of the input side of the voltage adjusting means is reduced. The method according to claim 1, further comprising determining whether a power supply voltage has returned to a predetermined voltage. 3. A power failure detection device for an electronic device, comprising: a microcomputer having an A / D conversion input terminal, wherein a power supply voltage is supplied as a stabilized voltage via a voltage adjustment means. A power failure detection device for an electronic device, wherein a voltage is divided and supplied to an A / D conversion input terminal of the microcomputer, whereby the microcomputer detects the power supply voltage fluctuation stepwise. 4. A power failure detection device for an electronic device, comprising: a microcomputer having a plurality of power failure detection terminals, wherein a power supply voltage is supplied as a stabilized voltage via a voltage adjustment means. A resistor for dividing the voltage, and a plurality of comparators for comparing a voltage value divided by the resistor with respective different comparison voltages of a plurality of comparison voltage generating means, wherein each microcomputer outputs each output signal of the comparator to the microcomputer. A power failure detection terminal for detecting a power supply voltage fluctuation in a stepwise manner. 5. A power failure detection device for an electronic device in which a power supply voltage is supplied as a stabilized voltage via a voltage adjustment device to an electronic device including a microcomputer having at least one power failure detection terminal, the voltage adjustment device comprising: A power outage detection device, wherein the power supply voltage to the microcomputer is divided and supplied to a power outage detection terminal of the microcomputer to determine whether or not the power supply voltage on the input side of the voltage adjusting means is reduced.