JPH05244733A - Power supply switching circuit for portable telephone - Google Patents

Abstract

PURPOSE:To permit the use of communicating function and logic function even when the voltage of a main battery lowers, in a portable telephone operated by the battery. CONSTITUTION:A switching means 14 supplies the power supply voltage of a main battery 11 to a logic circuit 15 and a communication circuit 16 normally. When the output voltage of the main battery 11 lowers, a voltage lowness signal is outputted from a voltage monitoring means 13 and the switching means 14 switches the supply of a power from the main battery 11 to a sub-battery 12. Further, the supply of power to the communication circuit 16 is stopped by a power supply cutting means 17 when the power supply is switched from the main battery 11 to the sub-battery 12.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply switching circuit for a mobile phone operated by a battery, and more particularly to a power supply switching circuit for a mobile phone having a function of storing data such as a telephone number.

[0002] In recent years, as the demand for mobile communication has increased, not only is it possible to make a telephone call, but there is a demand for higher functionality and higher performance.

[0003]

2. Description of the Related Art As one of the advanced functions, a mobile phone has a memory so that data such as a telephone number and a name can be registered and called. In such a mobile phone, when the power supply voltage of the built-in battery falls below a threshold value required for communication, the power supply is cut off to stop all functions in order to prevent abnormal operation.

[0004]

By the way, in the case of a mobile phone capable of registering data such as a telephone number and a name, the mobile phone can be used as a system notebook even when communication is impossible. However, conventionally, when the voltage of the battery drops, not only the communication circuit but also the power supply to the logic circuit having the memory is stopped. Therefore, not only the communication function but also the logic function (function such as a system notebook) cannot be used.

When the battery voltage is low,
I was unable to make a call even in an emergency. The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a power supply switching circuit for a mobile phone capable of maintaining a communication function and a logic function by a sub battery even when the voltage of the main battery drops. To aim.

Another object of the present invention is to provide a power supply switching circuit for a mobile phone which can use a communication function and a logic function in an emergency even if the battery voltage drops. Another object of the present invention is to provide a power supply switching circuit for a mobile phone, which can use only the minimum logic function even when the battery voltage drops.

Another object of the present invention is to provide a power supply switching circuit for a mobile phone, which uses only one battery and can use only the logic function when the voltage drops.

[0008]

FIG. 1 is a first principle diagram of the present invention for achieving the above object. As a power source, a main battery 11 that is normally used and a sub battery 12 that is used as a backup of the main battery 11 are provided. The voltage monitoring means 13 constantly monitors the output voltage value of the main battery 11 and outputs a switching signal when the output voltage value is below a predetermined value. The switching means 14 is normally the logic circuit 1
5 and the communication circuit 16 are supplied with power from the main battery 11, and when a switching signal is received, power supply from the sub-battery 12 is switched.

FIG. 2 is a second principle diagram of the present invention. As a power source, a main battery 21 that is normally used and a sub battery 2 that is used as a backup of the main battery 21
2 are provided. On the case side of the mobile phone, a manual changeover switch 25 is provided to manually switch the supply of power to the logic circuit 23 and the communication circuit 24 from the main battery 21 to the sub battery 32.

FIG. 3 is a diagram showing a third principle of the present invention. As a power source, a main battery 31 that is normally used and a sub battery 3 that is used as a spare of the main battery 31
2 are provided. An emergency switch 33 that outputs an emergency signal by manual input is provided on the case side of the mobile phone. The switching signal output means 34a outputs the switching signal when receiving the emergency signal. The switching means 36 normally supplies the power of the main battery 31 to the logic circuit 34 and the communication circuit 35, and switches to the power supply from the sub-battery 32 when receiving the switching signal.

FIG. 4 shows the fourth principle of the present invention. As the power supply, a first battery 41 that normally supplies a power supply voltage to the logic circuit 43 and a second battery 42 that normally supplies a power supply voltage to the communication circuit 44 are provided. First
The voltage monitoring means 45 constantly monitors the power supply voltage of the first battery 41, and outputs the first voltage drop signal when the power supply voltage becomes equal to or lower than the first predetermined value. The power supply command means 43a outputs a power supply command signal when receiving the first voltage drop signal. Further, the power supply means 46 supplies a power supply voltage from the second battery to the logic circuit 43 when receiving the power supply command signal.

FIG. 5 is a fifth principle diagram of the present invention. As a power supply, a battery 51 that supplies a power supply voltage to the logic circuit 52 and the communication circuit 53 is provided. The first voltage monitoring unit 54 monitors the power supply voltage of the battery 51, and outputs a first voltage drop signal when the power supply voltage of the battery 51 becomes equal to or lower than a first predetermined value. The communication disconnecting means 55 stops the power supply to the communication circuit 53 when receiving the first voltage drop signal.

[0013]

In the first principle diagram, when the output voltage value of the normally used main battery 11 becomes less than the predetermined value,
The voltage monitoring means 14 outputs a switching signal, and the switching means 14
Normally supplies the power of the main battery 11 to the logic circuit 15 and the communication circuit 16, and switches to the power supply from the sub-battery 12 when receiving the switching signal.

In the second principle diagram, the manual changeover switch 25 provided on the case side of the portable telephone supplies power to the logic circuit 23 and the communication circuit 24 by manual input.
The main battery 21 is switched to the sub battery 32.

In the third principle diagram, the emergency switch 33 provided on the case side of the mobile phone outputs an emergency signal, and when the emergency signal is received, the switching signal output means 34a outputs the switching signal. The switching means 36 normally supplies the power of the main battery 31 to the logic circuit 34 and the communication circuit 35, and switches to the power supply from the sub-battery 32 when receiving the switching signal.

In the fourth principle diagram, the voltage monitoring means 45 is
The power supply voltage of the first battery 41 is constantly monitored, and the first voltage drop signal is output when the power supply voltage becomes equal to or lower than the first predetermined value. The power supply command means 43a outputs a power supply command signal when receiving the first voltage drop signal, whereby the power supply means 46 supplies the power supply voltage from the second battery to the logic circuit 43.

In the fifth principle diagram, the voltage monitoring means 54 is
The power supply voltage of the battery 51 is monitored, and the first voltage drop signal is output when it becomes equal to or lower than the first predetermined value. The communication disconnecting means 55 stops the power supply to the communication circuit 53 when receiving the first voltage drop signal.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 6 is an external view of a mobile phone embodying the present invention. A speaker 61, a display unit 62, and an opening / closing lid 63 are provided on the upper surface of the mobile phone 60. The display unit 62 displays a telephone number, a name, an alarm, or the like. A push button 64 and a microphone (not shown) are provided inside the opening / closing lid 63,
Communication can be performed through the antenna 65 by opening the opening / closing lid 63. Also, using the push button 64,
It is also possible to store and display the telephone number and name.

The push button 64 is an emergency button 64.
a is provided, and when the emergency button 64a is pressed when the battery voltage drops and communication is impossible,
Communication is possible temporarily. In addition to the emergency button 64a, the mobile phone 60 is provided with a slide-type emergency switch 66 so that communication can be forcibly made.

On the other hand, a battery storage 67 is provided on the lower surface of the mobile phone 60. This battery compartment 6
7 is removable, and can be charged without taking out the internal battery.

FIG. 7 is a circuit diagram showing the structure of the power source switching circuit of the portable telephone according to the first embodiment. In this example,
The sub-battery 120 is used in addition to the main battery 110. Both the batteries 110 and 120 are housed in the battery housing portion 67. However, these outputs are retrieved separately. Here, a nicad (nickel-cadmium) battery having a relatively large charging capacity is used for the main battery 110, and a small lithium battery is used for the sub battery 120.

The power supply voltages of the main battery 110 and the sub battery 120 are sent to the switching circuit 140. The output voltage value (5 V) of the main battery 110 is constantly monitored by the voltage monitoring circuit 130.

The voltage monitoring circuit 130 mainly comprises resistors R1 and R2, a constant voltage circuit 131, and an operational amplifier 132. The resistors R11 and R12 set the output voltage value of the main battery 110 to R12 / (R11 + R12).
Depressurize twice. The constant voltage circuit 131 includes the logic circuit 15
Using the power supply voltage (5V) finally sent to 0,
Generate a constant reference voltage. The operational amplifier 132 outputs a voltage Vc corresponding to the difference between the reduced battery voltage and the reference voltage.
To the switching circuit 140 side. This voltage Vc becomes high level when the power supply voltage of the main battery 110 is sufficient, and becomes low level otherwise.

The switching circuit 140 includes four transistors T
11 to T14. The voltage Vc output from the operational amplifier 132 is input to the base of the transistor T11 via the resistor R13. Also, the transistor T1
The power supply voltage of the main battery 110 is applied to the emitter of 2.
Further, the power supply voltage of the sub-battery 120 is input to the emitter of the transistor T14.

The voltage Vc output from the operational amplifier 132
Is high level, that is, when the power supply voltage of the main battery 110 is sufficient, the transistor T11 operates and the potential at the point P1 becomes low level. Then, the transistor T12 operates and the power supply voltage of the main battery 110 is supplied from the collector of the transistor T12 to the logic circuit 150 and the switch 170.

On the other hand, when the power supply voltage of the main battery 110 drops and the output voltage Vc of the operational amplifier 132 becomes low level, the transistor T11 stops operating. Therefore, the potential at the point P1 becomes high level, and the operation of the transistor T12 is stopped. The voltage from the main battery 110 is applied to the resistors R15, R14, and R
Is input to the base of the transistor T13 via 16,
The transistor T13 operates.

Further, as the transistor T13 operates, the potential at the point P2 becomes low level and the transistor T14 operates. As a result, the transistor T14
From the collector of the logic circuit 150 and switch 1
The power supply voltage of the sub-battery 120 is supplied to 70.

The power supply voltage of the main battery 110 or the sub-battery 120 is supplied to the logic circuit 150 for controlling the entire mobile phone 60 via the switching circuit 140. The logic circuit 150 has a processor configuration and stores data such as a telephone number and a name in a non-volatile memory. These data are input by operating the push button 64. Further, these data can be displayed on the display unit 62.

The logic circuit 150 constantly monitors the potential at the point P1 of the switching circuit 140. Then, it is determined whether the power supply voltage supplied from the switching circuit 140 is the main battery 110 or the sub-battery 120 depending on whether the potential at the point P1 is high level or low level.

The logic circuit 150 is the communication circuit 1
It also constantly monitors whether or not 60 is in a communication state. When the potential at the point P1 becomes high level when the communication circuit 160 is in the communication state, that is, when the operation is switched to the sub-battery 120, the logic circuit 150 displays an indication notifying that the sub-battery is currently operated. This is performed on the display unit 62. Then, after several minutes, a communication disconnection signal is output to the switch 170 to stop the power supply to the communication circuit 160. It should be noted that the time from the switching to the sub-battery operation to the output of the communication disconnection signal is
The time until the power supply voltage of 0 falls below the level at which the communication circuit 160 can operate normally is set.

The switch 170 is normally a switching circuit 140.
, But the voltage supply to the communication circuit 160 is stopped by the input of the communication disconnection signal. As the switch 170, a mechanical switch such as a relay or a switch circuit in which a transistor or the like is combined is used.

The logic circuit 150 immediately outputs a communication disconnection signal when the potential at the point P1 becomes high level when the communication circuit 160 is not in the communication state, and displays on the display unit 62 that the communication is impossible. To do.

FIG. 8 shows the logic circuit 150 of the first embodiment.
6 is a flowchart showing a procedure of power supply switching control by the. [S11] It is determined whether the communication circuit 160 is in a communication state,
If it is in the communication state, the process proceeds to step S2, and if not, the process proceeds to step S6.

[S12] It is determined whether or not the voltage of the main battery 110 has dropped, and if it has dropped, step S3.
Otherwise, return to step S1. [S13] It is confirmed that the power supply is switched from the main battery 110 to the sub battery 120 by detecting the potential at the point P1. [S14] The display unit 62 indicates that the logic circuit 150 and the communication circuit 160 are operated by the sub battery 120.
Display with.

[S15] A few minutes after switching to the sub-battery 120, a communication disconnection signal is sent to the switch 170 to stop the power supply to the communication circuit 160. [S16] It is determined whether the voltage of the main battery 110 has dropped. If it has dropped, the process proceeds to step S7, and if not, the process returns to step S1. [S17] A communication disconnection signal is sent to the switch 170 to stop the power supply to the communication circuit 160. [S18] The display unit 62 displays that communication is not possible.

As described above, in this embodiment, when the power supply voltage of the main battery 110 drops, the power supply is switched to the sub-battery 120, so that the main battery can be operated without stopping the function of the mobile phone 60. 11
A zero charge can be performed.

Further, even if the power supply to the communication circuit 160 is stopped, only the logic circuit 150 is operated, so that the data such as the telephone number can be displayed and stored. Therefore, even if communication is disabled, the function as a system notebook can be fulfilled.

Next, a second embodiment of the present invention will be described. FIG. 9 is a block diagram showing the configuration of the power supply switching circuit of the mobile phone according to the second embodiment. The power supply switching circuit of this embodiment is
It is assumed that the mobile phone 60 of FIG. 6 is built in like the first embodiment. In this embodiment, the emergency battery 220 is used in addition to the main battery 210. Here, a nicad (nickel-cadmium) battery having a relatively large charging capacity is used for the main battery 210, and a small lithium battery is used for the sub battery 120.

The power supply voltages of the main battery 210 and the sub battery 220 are sent to the switching circuit 240. Also,
The output voltage value (5V) of the main battery 210 is constantly monitored by the voltage monitoring circuit 230.

The voltage monitoring circuit 230 has almost the same circuit configuration as the voltage monitoring circuit 130 of FIG. 7 used in the first embodiment, and the logic circuit is used when the output voltage value of the main battery 210 becomes a predetermined value or less. Send a brownout signal to 250.

The switching circuit 240 normally supplies the power supply voltage of the main battery 210 to the logic circuit 250 and the communication circuit 260, and switches to the supply from the emergency battery 220 when the switching signal is supplied from the logic circuit 250. ..

A slide type emergency switch 66 is connected to the output side of the switching circuit 240. The emergency switch 66 is a switch for manually switching the power supply from the output side of the switching circuit 240 to the emergency battery 220 side. The emergency switch 66 is connected to the output side of the switching circuit 240 unless the user intentionally switches. Therefore, when the output voltage of the main battery 210 is a value sufficient for communication, the logic circuit 25
0 and the communication circuit 260 are supplied with power from the main battery 210.

The logic circuit 250 includes the voltage monitoring circuit 23.
When a voltage drop signal is sent from 0, an alarm is displayed on the display unit 62. The user presses the emergency button 64a when he / she wants to communicate when the alarm display is displayed. As a result, the emergency signal is input to the logic circuit 250. The logic circuit 250 outputs the switching signal to the switching circuit 240 when the voltage drop signal and the emergency signal are input. As a result, power is supplied from the main battery 210.
Is switched to the emergency battery 220.

On the other hand, when the output voltage of the main battery 210 is extremely lowered and the logic circuit 250 cannot operate, the user switches to the sub battery 220 by the emergency switch 66. Thus, the logic circuit 250 and the communication circuit 260 can be temporarily operated.

FIG. 10 shows the logic circuit 25 of the second embodiment.
6 is a flowchart showing a procedure of power supply switching control by 0. [S21] The output voltage of the main battery 210 decreases,
It is determined whether or not the voltage drop signal is output, and if it is output, the process proceeds to step S12, and if not, step S11 is repeated.

[S22] An alarm is displayed on the display unit 62. [S23] It is determined whether or not the emergency button 64a is pressed to output the emergency signal, and if it is output, step S
14. If not, step S13 is repeated. [S24] A switching signal is output to the switching circuit 240.

As described above, in this embodiment, since the emergency battery 64a is switched to the emergency battery 220 by pressing the emergency button 64a, even if the main battery 210 cannot be used in an emergency, Can communicate.

Further, in this embodiment, the emergency button 64a is used.
When is pressed, the battery can be switched only when the voltage of the main battery 210 is reduced, so that the emergency battery 220 is not consumed unnecessarily.

Further, in this embodiment, the emergency switch 6 is used.
Since the battery can be forcibly switched by means of 6, the emergency battery 220 can be used even when the operation of the logic circuit 250 is stopped due to the extreme decrease of the main battery 210.

In the present embodiment, the logic circuit 250
Although the emergency button 64a, which is one of the push buttons 64, is used as a means for transmitting an emergency signal to another, other means, for example, a slide type switch used for the emergency switch 66 may be used.

Next, a third embodiment of the present invention will be described. FIG. 11 is a block diagram showing the configuration of the power supply switching circuit of the mobile phone according to the third embodiment. The power supply switching circuit of this embodiment is similar to the first and second embodiments in that the mobile phone 6 of FIG.
It shall be built into 0. In this embodiment, a logic battery 310 that supplies power only to the logic circuit 350 and a communication battery 320 that normally supplies power to only the communication circuit 360 are used as power supplies. Here, a nicad (nickel-cadmium) battery having a relatively large charging capacity is used for the communication battery 320, and a small lithium battery is used for the logic battery 310.

The power supply voltage of the logic battery 310 is
It is directly supplied to the logic circuit. On the other hand, the power supply voltage of the communication battery 320 is supplied to the communication circuit 360 via the power supply disconnecting circuit 370. The output voltage value (5 V) of these batteries 310 and 320 is constantly monitored by the voltage monitoring circuit 330.

The voltage monitoring circuit 330 has a structure in which two voltage monitoring circuits 130 of FIG. 7 used in the first embodiment are incorporated, one for the logic battery 310 and one for the communication battery 320. Are distinguished. With such a configuration, the voltage monitoring circuit 330 outputs the logic voltage drop signal to the logic circuit 35 when the output voltage value of the logic battery 310 becomes equal to or lower than the logic predetermined value.
Output to 0. The predetermined value for logic is set on the basis of the lowest voltage value with which the logic circuit 350 can be operated accurately.

Further, the voltage monitoring circuit 330 outputs a communication voltage drop signal to the logic circuit 350 when the output voltage value of the communication battery 320 becomes equal to or lower than a predetermined value for communication. The predetermined value for communication is set based on the lowest voltage value with which the communication circuit 360 can be operated accurately.

A power supply circuit 340 is provided between the logic battery 310 and the communication battery 320. The power supply circuit 340 is a switch circuit including a transistor T31, and supplies the power supply voltage of the communication battery 320 to the logic circuit 350 side by the input of the power supply command signal from the logic circuit 350.

The power supply disconnecting circuit 370 is connected to the power supply circuit 34.
Like 0, it is a switch circuit composed of a transistor or a mechanical switch such as a relay. Power disconnect circuit 37
0 stops the power supply to the communication circuit 360 in response to the input of the power-off command signal from the logic circuit 350.

The logic circuit 350 sends a power supply command signal to the power supply circuit 340 when the output voltage value of the logic battery 310 drops and the logic voltage drop signal is sent from the voltage monitoring circuit 330. This allows
The power supply voltage is supplied from the communication battery 320 to the logic circuit 350 side, and the operation of the logic circuit 350 is continued. Further, at this time, the logic circuit 350 displays a display prompting the user to charge the logic battery 310.
Done in.

Further, in the logic circuit 350, the output voltage value of the communication battery 320 decreases, and the voltage monitoring circuit 33
When the communication voltage drop signal is sent from 0, the power cut command signal is sent to the power cut circuit 370. This allows
The power supply disconnecting circuit 370 stops the supply of power from the communication battery 320 to the communication circuit 360. At this time, the logic circuit 350 performs a display on the display unit 62 to inform that communication is impossible.

FIG. 12 shows the logic circuit 35 of the third embodiment.
6 is a flowchart showing a procedure of power supply switching control by 0. [S31] It is determined whether the output voltage value of the logic battery 310 has dropped, and if it has dropped, step S32.
Otherwise, to step S34. [S32] A power supply command signal is sent to the power supply circuit 340 to supply power from the communication battery 320 to the logic circuit 350 side.

[S33] The user has the logic battery 3
The display unit 62 displays a message prompting the charging of 10. [S34] It is determined whether or not the output voltage value of the communication battery 320 has decreased. If the output voltage value has decreased, the process proceeds to step S35, and if not, the present flowchart ends.

[S35] A power-off command signal is sent to the power-off circuit 370 to stop the power supply to the communication circuit 360. [S36] The display unit 62 displays a message indicating that communication is impossible.

As described above, in this embodiment, when the output voltage value of the logic battery 310 is lowered, the power supply voltage is supplied from the communication battery 320 to the logic circuit 350 side, so that the logic circuit is always available. 350 can be operated.

Further, when the output voltage value of the communication battery 320 drops, the power supply from the communication battery 320 to the communication circuit 360 is stopped, so that the abnormal operation of the communication circuit 360 is prevented. be able to.

Next, a fourth embodiment of the present invention will be described. FIG. 13 is a circuit diagram showing the configuration of the power supply switching circuit of the mobile phone of the fourth embodiment. In this embodiment, only the battery 410 is used as the power source. In this battery 410,
Ni-Cd batteries with relatively large charging capacity are used. The power supply voltage of the battery 410 is supplied to the logic circuit 460 via the logic disconnection circuit 420 and the communication disconnection circuit 430.
Is supplied to the communication circuit 470 via the. The output voltage value (5 V) of the battery 410 is constantly monitored by the voltage monitoring circuits 440 and 450.

The voltage monitoring circuit 440 mainly includes resistors R41 and R42, a constant voltage circuit 441, and an operational amplifier 44.
It consists of 2. The resistors R41 and R42 reduce the output voltage value of the battery 410 by R42 / (R41 + R42) times. The constant voltage circuit 441 is a logic circuit 460.
And the power supply voltage (5
V) is used to generate a constant reference voltage.

The operational amplifier 442 outputs a voltage Vx corresponding to the difference between the reduced battery voltage and the reference voltage to the logic circuit 460. The voltage Vx becomes high level when the power supply voltage of the battery 410 is equal to or higher than the minimum voltage value Va required to operate the logic circuit 460, and becomes low level otherwise.

The voltage monitoring circuit 450 mainly includes resistors R43 and R44, a constant voltage circuit 451, and an operational amplifier 45.
It consists of 2. The resistors R43 and R44 reduce the output voltage value of the battery 410 by R44 / (R43 + R44) times. Like the constant voltage circuit 451, the constant voltage circuit 451 uses the power supply voltage (5V) finally sent to the logic circuit 460 and the communication circuit 470 to generate a constant reference voltage.

The operational amplifier 452 outputs a voltage Vy corresponding to the difference between the reduced battery voltage and the reference voltage to the logic circuit 460 and the communication disconnection circuit 430. This voltage Vy is at a high level when the power supply voltage of the battery 410 is at least a voltage value Vb required to operate the communication circuit 470, and is at a low level otherwise.

FIG. 14 is a diagram showing the time characteristics of the voltage of the battery 410. As you can see from the figure, the battery 4
The output voltage of 10 becomes the inoperable voltage value Vb of the communication circuit 470 at time t1, and then becomes the inoperable voltage value Va of the logic circuit 460 at time t2. That is,
When the power supply voltage of the battery 410 decreases, the voltage Vy first becomes low level, and then the voltage Vx becomes low level.

Returning to FIG. 13, in the communication disconnection circuit 430,
The output voltage Vy of the voltage monitoring circuit 450 is input to the base of the transistor T41 via the resistor R45. When the power supply voltage of the battery 410 is sufficient and the voltage Vy is at high level, the transistor T41 operates. As a result, the other transistor T42 also operates, and the power supply voltage of the battery 410 is supplied to the communication circuit 470.

On the other hand, when the power supply voltage of the battery 410 drops and the voltage Vy becomes low level, the transistors T41 and T42 do not operate. Therefore, the power supply from the battery 410 to the communication circuit 470 is stopped.

The logic circuit 460 is a voltage monitoring circuit 45.
When the output voltage Vy from 0 becomes low level,
Confirm that the power supply to the communication circuit 470 has stopped,
The display unit 62 displays the communication failure. In addition, the logic circuit 460, when the output voltage Vx from the voltage monitoring circuit 440 becomes low level, the battery 410.
The display unit 62 displays a message for prompting the charging. Then, after several minutes have passed, a logic disconnection command signal is output to the logic disconnection circuit 420.

The logic disconnection circuit 420 is, for example, a switch circuit formed of transistors, and stops the power supply to the logic circuit 460 when the logic disconnection command signal is input. It is desirable that the logic disconnection command signal be in a low level output state. That is,
Normally, a high level logic disconnection command signal is input to the logic disconnection circuit 420, whereby the switch circuit is configured to be in a connected state, and when it becomes low level, the switch circuit is disconnected. Just configure it.

FIG. 15 shows the logic circuit 46 of the fourth embodiment.
It is a flow chart which shows the change control procedure by 0. [S41] It is determined whether or not the output voltage value of the battery 410 has become equal to or lower than Vb. If not, the process proceeds to step S42, and if not, step S41 is repeated. [S42] The display unit 62 displays that communication is impossible.

[S43] It is determined whether or not the output voltage value of the battery 410 has become equal to or lower than Va. If yes, the process proceeds to step S44, and if not, step S43 is repeated. [S44] The display unit 6 displays a message prompting charging of the battery 410.
Do in 2. [S45] A logic disconnection command signal is output after a few minutes have elapsed since the output voltage value of the battery 410 has become equal to or lower than Va, and power supply is stopped.

As described above, in this embodiment, the battery 41
When the output voltage value of 0 becomes equal to or lower than the incommunicable value Vb, the power supply to the communication circuit 470 is stopped, so that only the low power logic circuit 460 can be operated. Therefore, the function as the system notebook can be continued even when the mobile phone 60 is in a state where communication is impossible.

In the present embodiment, when the output voltage value of the battery 410 becomes Va or less, the logic circuit 4
Since the power supply to 60 is also stopped, malfunction of the logic circuit 460 can be prevented.

[0078]

As described above, according to the present invention, when the main battery and the sub-battery are provided with two batteries and the output voltage value of the main battery which is normally supplied with power is less than the predetermined value, Since the power supply is switched from the sub battery, the main battery can be charged without stopping the function of the mobile phone.

Further, since the power supply to the logic circuit and the communication circuit is switched from the main battery to the sub battery by the manual changeover switch provided on the case side of the mobile phone, the main battery is lowered in an emergency. Even when all the functions of the mobile phone are stopped, communication can be performed.

Furthermore, when the power of the main battery is normally supplied to the logic circuit and the communication circuit and the emergency switch provided on the case side of the mobile phone is input, the power supply is switched to the sub-battery by the switching signal from the emergency switch. Therefore, communication can be performed even when only the logic circuit is operating.

Normally, the first battery supplies power only to the logic circuit and the second battery supplies power only to the communication circuit, and the power supply voltage of the first battery is the first predetermined value. When the value becomes equal to or lower than the value, the power supply voltage is supplied from the second battery to the logic circuit, so that the logic circuit can be operated at all times.

Further, since only one battery is provided and power supply to the communication circuit is stopped when the power supply voltage of the battery becomes equal to or lower than the first predetermined value, the remaining power is supplied to the logic circuit. be able to. Therefore, the function of the battery can be effectively used.

[Brief description of drawings]

FIG. 1 is a first principle diagram of the present invention.

FIG. 2 is a second principle diagram of the present invention.

FIG. 3 is a third principle diagram of the present invention.

FIG. 4 is a fourth principle diagram of the present invention.

FIG. 5 is a fifth principle diagram of the present invention.

FIG. 6 is an external view of a mobile phone embodying the present invention.

FIG. 7 is a circuit diagram showing a configuration of a power supply switching circuit of the mobile phone according to the first embodiment.

FIG. 8 is a flowchart showing a procedure of power supply switching control by the logic circuit of the first embodiment.

FIG. 9 is a block diagram showing a configuration of a power supply switching circuit of a mobile phone according to a second embodiment.

FIG. 10 is a flowchart showing a procedure of power supply switching control by the logic circuit of the second embodiment.

FIG. 11 is a block diagram showing a configuration of a power supply switching circuit of a mobile phone according to a third embodiment.

FIG. 12 is a flowchart showing a procedure of power supply switching control by the logic circuit of the third embodiment.

FIG. 13 is a circuit diagram showing a configuration of a power supply switching circuit of a mobile phone according to a fourth embodiment.

FIG. 14 is a diagram showing time characteristics of battery voltage.

FIG. 15 is a flowchart showing a switching control procedure by the logic circuit of the fourth embodiment.

[Explanation of symbols]

 11 Main Battery 12 Sub Battery 13 Voltage Monitoring Means 14 Switching Means 15 Logic Circuit 15a Power Supply Disconnection Command Means 15b Display Means 16 Communication Circuit 17 Power Supply Disconnection Means 18 Display Unit

Claims (16)

[Claims] 1. A main battery (11) normally used in a power source switching circuit of a mobile phone operated by a battery, a sub-battery (12) used as a spare of the main battery (11), and the main battery. A voltage monitoring means (13) that constantly monitors the output voltage value of (11) and outputs a switching signal when the output voltage value becomes a predetermined value or less, usually a logic circuit (15) and a communication circuit ( 16) is provided with a switching means (14) for supplying power to the main battery (11) and switching to power supply from the sub-battery (12) when the switching signal is received. Power supply switching circuit. 2. The switching state of the switching means (14) upon receiving the switching signal causes the switching state of the sub-battery (1).
If the communication circuit (16) is not in the communication state at that time, the power supply disconnection command means (15a) for outputting a power supply disconnection signal, and the power supply disconnection signal The power supply switching circuit for a mobile phone according to claim 1, further comprising: a power supply disconnecting means (17) for stopping power supply to the communication circuit (16) when received. 3. The mobile phone according to claim 2, further comprising display means (15b) for displaying on the display unit (18) a message indicating that communication is impossible when the power-off signal is output. Power supply switching circuit. 4. The power-off command means (15a) is such that the switching state of the switching means (14) is the sub-battery (1).
2) and the communication circuit (1
6) is in a communication state, the sub battery (1
3. The power supply switching circuit for a mobile phone according to claim 2, wherein the power supply disconnection signal is output after a predetermined time has passed after switching to 2). 5. The display means (15b) is provided when the switching state of the switching means (14) is the supply state by the sub-battery (12) and the communication circuit (16) is in the communication state. 4. The power supply switching circuit for a mobile phone according to claim 3, wherein the display unit (18) displays a message indicating that the power is being supplied by the sub-battery. 6. A main battery (21) normally used in a power supply switching circuit of a mobile phone operated by a battery, a sub-battery (22) used as a spare of the main battery (21), and a main battery (21) of the mobile phone. The logic circuit (2
3) and a power supply to the communication circuit (24), a manual changeover switch (25) for manually changing over the supply of power from the main battery (21) to the sub-battery (32); Switching circuit. 7. A main battery (31) normally used in a power supply switching circuit of a mobile phone operated by a battery, a sub-battery (32) used as a spare of the main battery (31), and a mobile phone An emergency switch (33) provided on the case side for outputting an emergency signal by manual input, a switching signal output means (34a) for outputting a switching signal when the emergency signal is received, and usually the logic circuit (34) and Communication circuit (3
5) is provided with a switching means (36) for supplying power to the main battery (31) and switching to power supply from the sub-battery (32) when receiving the switching signal. Power supply switching circuit. 8. A switching signal, comprising: a voltage monitoring means (37) for constantly monitoring a power supply voltage of the main battery (31) and outputting a voltage drop signal when the power supply voltage becomes a predetermined value or less. 8. The power supply switching circuit for a mobile phone according to claim 7, wherein the output means (34a) is configured to output the switching signal when receiving the voltage drop signal and the emergency signal. 9. The mobile phone according to claim 8, further comprising display means (34b) for displaying an alarm on the display portion (38) when a voltage drop signal is received from the voltage monitoring means (37). Power supply switching circuit. 10. A power supply switching circuit for a mobile phone operated by a battery, which normally supplies a power supply voltage to a logic circuit (43).
Of the battery (41), a second battery (42) that normally supplies a power supply voltage to the communication circuit (44), and a power supply voltage of the first battery (41),
First voltage monitoring means (45) for outputting a first voltage drop signal when the power supply voltage becomes equal to or lower than a first predetermined value
A power supply command means (43a) for outputting a power supply command signal when receiving the first voltage drop signal; and a power supply for the logic circuit (43) from the second battery when receiving the power supply command signal. A power supply switching circuit for a mobile phone, comprising: a power supply means (46) for supplying a voltage. 11. The display unit 47 has a display means (43b) for displaying a request for charging the first battery (41) when the first voltage drop signal is received. Power supply switching circuit for mobile phones. 12. A power supply voltage of the second battery (42) is constantly monitored, and when the power supply voltage of the second battery (42) becomes a second predetermined value or less, a second voltage drop signal. A second voltage monitoring means (48) for outputting a power-off signal, a power-off commanding means (43c) for outputting a power-off signal when the second voltage-down signal is received, and a second power-off signal when the power-off signal is received. Battery (4
11. The power supply switching circuit for a mobile phone according to claim 10, further comprising a power supply disconnecting means (49) for stopping the power supply from 2) to the communication circuit (44). 13. A battery (51) for supplying a power supply voltage to a logic circuit (52) and a communication circuit (53), and a power supply voltage of the battery (51) in a power supply switching circuit of a mobile phone operated by a battery. Then, a first voltage monitoring means (54) that outputs a first voltage drop signal when the voltage becomes a first predetermined value or less, and the communication circuit (5) when the first voltage drop signal is received.
And a communication disconnecting means (55) for stopping power supply to (3). 14. The mobile phone according to claim 13, further comprising display means (52b) for performing a display for notifying the communication failure on the display unit (56) by receiving the first voltage drop signal. Power supply switching circuit. 15. A second voltage monitor that monitors the power supply voltage of the battery (51) and outputs a second voltage drop signal when the voltage drops below a second predetermined value that is lower than the first predetermined value. Means (57), a logic disconnection command means (52a) for outputting a logic disconnection signal when receiving the second voltage drop signal, and stopping the power supply to the logic circuit (52) when receiving the logic disconnection signal Logic cutting means (5
The power supply switching circuit for a mobile phone according to claim 13, further comprising: 16. The power supply disconnecting means (52a) is configured to output the logic disconnection signal after a predetermined time has elapsed after receiving the second voltage drop signal,
The display means (52b) is configured to display on the display unit (56) a message prompting charging of the battery (51) during the predetermined time.
A power supply switching circuit for the mobile phone described.