JP3235570B2 - Communication device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a communication apparatus capable of selecting one communication system from a plurality of different communication systems.

[0002]

2. Description of the Related Art Conventionally, in a mobile communication terminal such as a portable telephone, the following technique has been proposed in order to avoid an unusable state when the battery capacity is reduced.

The radio selective calling receiver disclosed in Japanese Patent Laid-Open Publication No. 3-201830 discloses a first low-voltage detection circuit for detecting a stable operation voltage of a radio unit and a second low-voltage detection circuit for detecting an operation limit voltage of the radio unit. And a low voltage detection circuit. And
The notification is performed in different forms depending on the combination of the outputs of the first low-voltage detection circuit and the second low-voltage detection circuit. Therefore, the user can accurately determine the power supply battery voltage state by recognizing the notification output in different forms.

Further, in the low-voltage alarm notification circuit of the radio selective calling receiver disclosed in Japanese Patent Application Laid-Open No. 3-145342, the reception function is stopped when the battery voltage drops to a predetermined value. , An alert is issued. This alarm is stopped after a predetermined time has elapsed, and battery consumption due to the alarm notification is suppressed. In addition, the elapsed time from the stop of the reception function is displayed by the user's request. Therefore, the user can easily recognize the elapsed time from the stop of the reception function.

[0005] The mobile phone disclosed in Japanese Patent Application Laid-Open No. Hei 8-251098 has two batteries, a main battery and an auxiliary battery. Normally, power is supplied from the main battery to each circuit in the mobile phone. When the remaining battery level of the main battery becomes equal to or less than a predetermined value, power is supplied from the auxiliary battery to only the transmission unit that consumes large current. On the other hand, circuits other than the transmission unit are continuously supplied with power from the main battery. In this way, when the remaining battery level of the main battery becomes equal to or less than the predetermined value, power is supplied from the auxiliary battery to the transmitting unit that consumes a large amount of current, so that the operation of the transmitting unit is not stopped, and Can be prevented from being cut off halfway.

Further, the cordless telephone disclosed in Japanese Utility Model Laid-Open Publication No. Hei 5-11603 incorporates two batteries, a regular battery and a spare battery, and usually supplies power to each circuit in the cordless telephone from the regular battery. Is supplied. When the remaining battery capacity of the working battery falls below a predetermined value, a light emitting diode provided in the cordless telephone flashes. When the user confirms the blinking and operates the changeover switch, the regular battery is switched to the spare battery, and power is supplied from the spare battery to each circuit in the cordless telephone. In this way,
When the remaining battery level of the regular battery falls below the predetermined value, the user operates the switch to switch the regular battery to the spare battery. Cutting can be prevented.

[0007]

In these techniques, an auxiliary battery is provided or an alarm is output to a user.

[0008] On the other hand, there has conventionally been proposed a portable telephone which can be connected to one of two different communication systems. For example, a slave unit used in a cordless telephone including a master unit and a slave unit is used as a mobile station wirelessly connected to a base station.

It is an object of the present invention to provide an improved communication device applicable to a plurality of different communication systems.

Another object of the present invention is to provide a communication device capable of extending a standby time, as will be described in detail later.

Another object of the present invention is to provide a communication apparatus capable of automatically switching between a plurality of different communication systems during standby.

It is another object of the present invention to provide a communication apparatus which can select an optimum communication system from among a plurality of different communication systems when a user performs a calling operation.

Another object of the present invention is to provide a communication device capable of reducing the adverse effect of a call being cut off halfway.

It is still another object of the present invention to provide a communication device that improves operability.

[0015]

In order to achieve the above object, a communication apparatus according to the present invention comprises:
Selecting means for selecting a connectable communication system; battery voltage detecting means for detecting a battery voltage for driving the communication device; and controlling the selecting means based on a battery voltage value detected by the battery voltage detecting means. Control means for performing the operation.

Further, the communication device of the present invention comprises a first communication system, a second communication system, a battery voltage detecting means for detecting a battery voltage for driving the communication device, and a detecting means for the battery voltage detecting means. Comparing means for comparing the obtained battery voltage with a predetermined value, and switching means for switching between the first communication system and the second communication system when the battery voltage is equal to or less than the predetermined value. And The second communication system can wait for reception at a voltage value lower than the predetermined value. The predetermined value can be changed by a user. Further, the predetermined value is larger than a minimum voltage value necessary for the reception standby in the first communication system. It is preferable that the first and second communication systems have different current consumptions and have the same minimum voltage value at which reception standby is possible. In the first and second communication systems, current consumption may be the same, and minimum voltage values at which reception standby is possible may be different from each other. In the first and second communication systems, both the current consumption and the lowest voltage value at which reception standby is possible may be different from each other. Preferably, the switching means is performed automatically. The communication device of the present invention further includes an output unit that outputs a sound when the communication system is switched from the first communication system to the second communication system. Further, a display unit for displaying information on a communication system capable of waiting for reception may be provided. Preferably, the first and second communication shims are PDC and PHS, respectively. The first and second communication shims are each GS
M and PHS. In addition, the first and second
May be a PDC and a wireless paging, respectively. Further, the first and second communication shims may be a PHS and a radio paging, respectively.

Further, the communication device of the present invention comprises first and second communication devices.
Communication system, a battery voltage detecting means for detecting a battery voltage that drives the communication device, a comparing means for comparing the battery voltage detected by the battery voltage detecting means with a predetermined value, and A switching unit configured to switch between the first and second communication systems and the second communication system when the value is equal to or less than the predetermined value. The second
Can wait for reception at a voltage value lower than the predetermined value. The predetermined value can be changed by a user. The predetermined value is larger than a minimum voltage value required for the reception standby in the first communication system. It is preferable that the first and second communication systems have different current consumptions and have the same minimum voltage value at which reception standby is possible. Preferably, the switching means is performed automatically. The communication device of the present invention further includes an output unit that outputs a sound when the communication system is switched from the first and second communication systems to the second communication system. Preferably, the audio is different depending on the switched communication system. Further, a display unit for displaying information on a communication system capable of waiting for reception may be provided.

Further, the communication device of the present invention includes a first communication system, a second communication system, a battery voltage detecting unit for detecting a battery voltage for driving the communication device, and a detecting unit for detecting the battery voltage. A comparing unit that compares the obtained battery voltage with a predetermined value, and a switching unit that switches between the first communication system and the second communication system when the battery voltage is equal to or less than the predetermined value. And

Further, the communication device of the present invention comprises first and second communication devices.
Communication system, a battery voltage detection unit that detects a battery voltage that drives the communication device, a comparison unit that compares the battery voltage detected by the battery voltage detection unit with a predetermined value, and the battery voltage A switching unit configured to switch between the first and second communication systems and the second communication system when the value is equal to or less than the predetermined value.

Further, the communication device of the present invention comprises first and second communication devices.
At least one communication system among the communication systems, a battery voltage detecting means for detecting a battery voltage for driving the communication device, and, at the time of calling, the battery voltage detecting means based on the battery voltage detected by the battery voltage detecting means. Selecting means for selecting a connectable communication system from the first and second communication systems.

Further, the communication device of the present invention comprises first and second communication devices.
At least one of the communication systems, battery voltage detection means for detecting a battery voltage for driving the communication device, and determination means for determining whether a calling operation has been performed in the first communication system And when the determination means determines that a calling operation has been performed in the first communication system, determines whether the battery voltage is equal to or lower than a minimum connectable voltage value in the first communication system. And a selection unit that selects the second communication system when the determination unit determines that the battery voltage is equal to or lower than the minimum voltage value. The first
Preferably, the second communication system differs from the second communication system in both the current consumption and the minimum voltage value required for connection. Further, it is preferable that the apparatus further includes a connection unit that connects in the first communication system when the determination unit determines that the battery voltage is higher than the minimum voltage value. When the selection means has selected the second communication system, an output means for outputting an alarm when the battery voltage value becomes equal to or less than a first predetermined value may be provided. When the selection unit selects the second communication system, the communication unit may include a disconnection unit that disconnects the call when the battery voltage value becomes equal to or less than a second predetermined value. In addition, when the connection unit is connected to the first communication system, an output unit that outputs an alarm when the battery voltage value becomes equal to or lower than a third predetermined value may be included. When the connection means is connected in the first communication system, the battery voltage value becomes the fourth.
May be provided for disconnecting the call when the predetermined value becomes equal to or less than the predetermined value. The communication device of the present invention further includes a receiving unit that receives a radio signal in a connectable communication system based on the battery voltage value when receiving a call. Further, it has a display means for displaying information on a connectable communication system. It is preferable that the display unit displays the information on the connectable communication system at the same place as the display of the information on the battery voltage. The first and second communication shims are:
Preferably, they are PDC and PHS, respectively. The first and second communication shims are GSM and PHS, respectively.
It may be. Further, the first and second communication shims may be a PDC and a radio paging, respectively. Further, the first and second communication shims each include a PHS
And a wireless paging device.

Further, the communication device of the present invention includes a selection means for selecting a connectable communication system among a plurality of communication systems, a detection means for detecting information regarding a remaining capacity of a battery for driving the communication device, Control means for controlling the selection means based on the remaining capacity of the battery detected by the detection means.

Also, the communication device of the present invention includes a first radio unit for receiving a communication signal in the first communication system, a second radio unit for receiving a communication signal in the second communication system, A selector for selecting at least one of the first wireless unit and the second wireless unit; a battery for driving the communication device; a detecting unit for detecting a remaining capacity of the battery; It has a CPU that controls the selector based on the remaining capacity of the battery, and a notification unit that performs notification when a communication signal is received by the first wireless unit and the second wireless unit.

Further, the communication device of the present invention comprises first and second communication devices.
At least one communication system among the communication systems, a battery voltage detection unit that detects a battery voltage that drives the communication device, and at the time of calling, based on the battery voltage detected by the battery voltage detection unit, And a connection unit connected by a connectable communication system among the first and second communication systems.

Further, the communication device according to the present invention includes at least one of the first and second communication systems, a battery voltage detecting unit for detecting a battery voltage for driving the communication device, and the first and second communication systems. A determining unit that determines whether a calling operation has been performed in the communication system; and if the determining unit determines that the calling operation has been performed in the first communication system, the battery voltage is equal to the first voltage. A determining unit that determines whether or not the battery voltage is equal to or lower than a connectable minimum voltage value in the communication system; And a selecting unit for selecting

The system switching method for a communication device according to the present invention
Performing a reception standby in the first communication system;
Detecting a battery voltage for driving the communication device; comparing the battery voltage detected in the detecting step with a predetermined value; and performing the first communication based on a comparison result of the comparing step. Switching from the system to the second communication system to perform reception standby.

[0027] Also, in the system switching method for a communication device according to the present invention, a step of detecting a battery voltage for driving the communication device, and comparing the battery voltage detected in the detecting step with a first predetermined value. And when the battery voltage is greater than the first predetermined value,
Performing a reception standby in the communication system; determining whether the battery voltage is equal to or less than the first predetermined value; and determining in the determination step that the battery voltage is equal to the first predetermined value. A step of switching the first communication system to a second communication system to perform reception standby when it is determined to be the following, comparing the battery voltage with a second predetermined value, Disabling reception standby in the first and second communication systems when the battery voltage is equal to or lower than the second predetermined value.

Further, according to the system switching method of the communication apparatus of the present invention, a step of performing reception standby in at least one of the first and second communication systems, and detecting a battery voltage for driving the communication apparatus. Steps and
At the time of calling, based on the battery voltage detected in the detecting step, of the first and second communication systems,
Connecting with a connectable communication system.

Further, the system switching method of the communication device according to the present invention includes a step of performing reception standby in at least one of the first and second communication systems;
Detecting a battery voltage for driving the communication device; determining whether a call operation has been performed in the first communication system; and performing the call operation in the first communication system in the determination step. Determining that the battery voltage is equal to or lower than a minimum voltage value connectable by the first communication system; and determining that the battery voltage is equal to or lower than the minimum voltage value in the determination step. And connecting to the second communication system when it is determined that: A step of determining whether a calling operation has been performed in the second communication system; and a step of determining that the calling operation has been performed in the second communication system in the determining step.
Judging whether or not the battery voltage is equal to or lower than a minimum voltage value connectable by the second communication system, and when it is determined that the battery voltage is equal to or lower than the minimum voltage value in the judgment step. And disabling the connection in the second communication system.

Therefore, according to the present invention, when the battery voltage decreases and reaches a predetermined value during standby, the communication system is switched to a communication system that consumes less current, so that the standby time can be extended.

In the standby mode, a plurality of communication systems are automatically switched based on the battery voltage.
Operability can be improved.

Further, according to the present invention, when a user performs a calling operation in a communication system that consumes a large amount of current, the detected battery voltage is small, so that the user cannot connect to the communication system. Can be prevented from having to perform the calling operation again.

Also, when the user performs a calling operation,
When the detected battery voltage is low, a communication system with low current consumption is selected, so that it is possible to prevent a call from being cut off halfway.

Further, at the time of calling, a communication system with low current consumption is automatically selected based on the battery voltage, so that operability can be further improved.

[0035]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring to FIG. 1, a communication device according to the present invention, preferably a portable telephone, and a plurality of communication systems connectable to the portable telephone, for example, a Personal Digital Cellula.
r (PDC) and Personal Handy phone System (PH
S) will be described.

In FIG. 1, the PDC service area 5 centered on the PDC base station 3 has a radius of several km,
PHS service area 4 centering on HS base station 2
The radius is several hundred meters. In addition, PDC and PHS have different current consumptions during standby, calling, and talking. The average value of the consumption current of the PDC is 1.5 mA during standby and 300 mA during a call. On the other hand, the average value of the current consumption of the PHS is 55 μA during standby and 450 μA during talking. Generally, the current consumption of the PDC is larger than the current consumption of the PHS. For this reason, when the remaining battery level decreases to a predetermined value during standby in the PDC, the standby time is extended by switching from the PDC with large current consumption to the PHS with small current consumption.

A configuration of a preferred example of the portable telephone according to the present invention will be described with reference to FIG.

In FIG. 2, the PDC radio section 12
The communication signal transmitted from the DC base station 3 is received via the antenna 11. The PHS radio unit 14 receives a communication signal transmitted from the PHS base station 2 via the antenna 13. The selector 15 is controlled by the selector control unit 16 and selects the PDC radio unit 12 and / or the PHS radio unit 14. The battery 17 supplies power to each circuit, but the power supply to each circuit of the battery 17 is not shown for simplicity. The battery 17 is, for example, L
An i-ion battery is used. The voltage value V0 in one full charge of the Li-ion battery is, for example, 3.75V. Battery voltage detector 18 detects battery voltage V based on the current output from battery 17. Memory unit 23
Stores a program for operating the PDC and the PHS, a program for operating the entire mobile phone 1, and first to eighth specified values to be described later. The CPU 19 controls the selector controller 16 based on the battery voltage V output from the battery voltage detector 18. Further, the CPU 19 controls each communication system of PDC and PHS, and controls the entire mobile phone 1. The CPU 19 is, for example, a μPD manufactured by NEC.
78001B is used. The LCD 20 has a CPU 19
And displays the communication system, the remaining battery level, and the like during standby. The notification unit 21 is controlled by the CPU 19 and notifies the user when the communication system is switched during standby. The notification unit 11 includes a speaker and an LED
And at least one of a vibrator. The switch unit 22 is used for initial setting of a communication system, a calling operation, and the like.

PDC radio unit 12 and / or PHS
The communication signal received by the wireless communication unit 14 is transmitted to the CP via the selector 15 controlled by the selector control unit 16.
Output to U19. When a communication signal is input from the selector 15, the CPU 19 controls the LCD 20 and / or the notification unit 21 to notify an incoming call. The incoming call notification is stopped when the user presses the switch unit 22 or when a predetermined time is measured by a timer (not shown).

Next, the operation of the portable telephone shown in FIG. 2 when waiting for reception will be described in detail with reference to FIG. In FIG. 3, it is assumed that the minimum voltage values required when waiting in the PDC or the PHS are equal to each other, and the current consumptions in the standby state are different from each other.

In FIG. 3, it is determined whether or not the power of the mobile phone 1 is turned on by the user pressing the switch section 22 (S401). When the power of the mobile phone 1 is turned on (YES in S401), the battery voltage V is detected by the battery voltage detector 18 (S40).
2). The battery voltage V is detected every predetermined time, for example, every 1 msec after the power is turned on. Then, it is determined whether the detected battery voltage V is equal to or less than the eighth specified value V8 stored in the memory unit 23 (S403).
The eighth specified value V8 indicates the battery voltage V at which reception standby is not possible, and is, for example, 2.5-2.7V. If the battery voltage V is equal to or less than the eighth specified value V8 (S40)
3 and YES), the power of the mobile phone 1 is turned off (S
404).

If the remaining battery voltage V is greater than the eighth specified value V8 (NO in S403), the detected battery voltage V
Is smaller than or equal to the first specified value V1 stored in the memory unit 23 (S406). The first specified value V1 is a value slightly larger than the minimum voltage value V2 required when waiting in the PDC and the PHS, for example, 3.2V, for example, 3.3V. When it is determined that the battery voltage V is higher than the first specified value V1, (S
If NO in 406, the PDC system is selected (S40)
5). At this time, when a call is received, the PDC radio unit 12 can receive a radio signal, but the PHS radio unit 14
Cannot receive wireless signals. In addition, at the time of calling, a call can be made by the PDC, but a call cannot be made by the PHS. However, when the user operates the switch unit 22 to arbitrarily select a desired communication system, incoming and outgoing calls can be made in a plurality of communication systems. After that, again for every predetermined time, for example, 1
The battery voltage V is detected every msec (S410). Thereafter, when it is determined that the battery voltage V is higher than the first specified value V1, the selection of the PDC system is maintained.

On the other hand, when it is determined that the battery voltage V is equal to or less than the first specified value V1 (YES in S406),
The HS system is selected (S407). That is, the communication system at the time of standby is automatically switched from the PDC to the PHS, and the reception standby at the PDC cannot be performed. At this time, since the current consumption of the PHS is smaller than that of the PDC, the voltage drop due to the internal resistance of the battery is reduced. Then, the voltage value at the battery terminal is increased, which means that the battery voltage value is increased.

Thereafter, it is determined whether the battery voltage V is equal to or less than the second specified value V2 stored in the memory unit 23, for example, 3.2 V (S408). When it is determined that the battery voltage V is higher than the second specified value V2 (S
(NO at 408), and the battery voltage V is detected again at predetermined time intervals (S411). When the battery voltage V is equal to the second specified value V2
In the following cases (YES in S408), both the PDC and PHS systems are disconnected (S409). That is, reception standby cannot be performed in any of the PDC and PHS systems.

In FIG. 3, when the user performs a predetermined operation of the switch section 22, the communication system may be switched at that time. When the user turns off the power, the power is turned off at that time.

Next, the operation of the portable telephone of the present invention shown in FIG. 3 when waiting for reception will be described more specifically with reference to FIG. In FIG. 4, it is assumed that when the power is turned on at time 0, the battery voltage V is fully charged. FIG. 4 shows that the current consumption of the PDC is 500 mA, the current consumption of the PHS is 250 mA, and the capacity of the battery 17 is 500 mA.
The relationship between the battery voltage V and the reception standby time in the case of mAh is shown.

In FIG. 4, when the power is turned on at time 0, the PDC waits for reception. And time t
In 1, when the battery voltage V reaches the first specified value V 1,
The communication system at the time of standby is automatically switched from PDC to PHS. Therefore, after that, the reception standby is performed in the PHS, and the reception standby in the PDC cannot be performed. At this time, since the current consumption of the PHS is smaller than that of the PDC, the battery voltage increases from V1 to V3. Thereafter, at time t2, when the battery voltage V reaches the second specified value V2, reception standby becomes impossible in both the PDC and PHS communication systems.

At time t1, when the communication system is automatically switched, the notification unit 21 notifies the user of the switching of the communication system. At this time, it is preferable that the notification of the switching of the communication system is output in a form different from the notification of the incoming call so that the user can accurately recognize the notification. In addition, it is preferable that the notification mode differs depending on the switched communication system so that the user can recognize which communication system has been switched.

The LCD 20 may always indicate whether the PDC or the PHS is waiting for reception.

FIGS. 5A to 5C are diagrams showing the transition of the battery voltage value and the change in the operation of the PDC radio unit 12 and the PHS radio unit 14 corresponding thereto.

As shown in FIG. 5 (a), at the point A where the battery voltage value V has decreased and the battery voltage value V has reached the first specified value V1, the communication system at the time of waiting for reception is a PDC.
Is automatically switched to PHS. Therefore, as shown in FIG. 5B, the PDC radio unit 12
Is turned on every predetermined time, for example, every 720 ms,
Beyond the point, it turns off. On the other hand, the PHS radio unit 1
Reference numeral 4 is off until point A, and after point A, it is turned on every predetermined time, for example, every 1,25 s.

As described above, when the reception standby is performed by the PDC without switching the communication system at all, the time t
3. For example, after 30 minutes, it becomes impossible to wait for reception. On the other hand, according to the mobile phone of the present invention, at time t2, for example, 9
The reception standby can be performed up to 0 minutes. for that reason,
The reception waiting time is greatly extended.

In FIGS. 3, 4 and 5 (a) to 5 (c),
After the power is turned on, the reception standby is performed by the PDC until time t1, but the reception standby may be performed by the PHS when the power is turned on, or the reception standby may be performed by both the PDC and the PHS. It is preferable that a user can operate the switch unit 22 to set in advance which communication system should use the standby mode when the power is turned on.

FIG. 6 is a diagram showing the relationship between the battery voltage V and the standby time when the reception standby is first performed by the PHS after the power is turned on.

In FIG. 6, when the power is turned on at time 0, the PHS waits for reception until time t4. Then, at time t4, the PHS is automatically switched to the PDC, and at time t5, the PHS is switched again from the PDC.
Is automatically switched to At time t6,
It is automatically switched from PHS to PDC again. Thereafter, reception standby is performed in the PDC, and at time t1, when the battery voltage V reaches the first specified value V1, the communication system performing the reception standby is automatically switched from the PDC to the PHS. Then, reception standby is performed in the PHS, and at time t2, the battery voltage V becomes the second specified value V2.
, Reception standby becomes impossible in both the PDC and PHS communication systems.

Switching of the communication system at times t4, t5, and t6 is preferably performed when a predetermined time has elapsed, when the received electric field strength has decreased, and the like. Also, if the PHS exists in the PHS service area 4, the PHS
On the other hand, by connecting to the PDC when the mobile terminal is in the PDC service area 5, it is possible to prioritize waiting for reception by the PHS.

FIGS. 7A to 7C are diagrams showing changes in the battery voltage value and changes in the operation of the PDC radio unit 12 and the PHS radio unit 14 in response to the change.

As shown in FIG. 7A, after the point c,
At the point B where the battery voltage value V decreases and the battery voltage value V reaches the first specified value V1 in a state where the reception waiting is performed by the PDC, the communication system at the time of the reception waiting is set to the PDC.
Is automatically switched to PHS. Therefore, as shown in FIG. 7B, the PDC radio unit 12
It is turned on every predetermined time from point to point B, and turned off after point B. On the other hand, the PHS radio section 14 is off from the point c to the point B, and is turned on every predetermined time after the point B.

As described above, when the reception standby is performed by the PHS without switching the communication system at all, the time t
3. For example, in 80 minutes, the reception standby cannot be performed. On the other hand, according to the mobile phone of the present invention, at time t2, for example, 9
The reception standby can be performed up to 0 minutes. for that reason,
The reception waiting time is extended.

FIG. 8 is a diagram showing the relationship between the battery voltage V and the standby time when reception standby is performed in both the PDC and PHS communication systems after the power is turned on.

In FIG. 8, when the power is turned on at time 0, reception standby is performed in both the PDC and PHS communication systems until time t1. Thereafter, at time t1, when the battery voltage V reaches the first specified value V1, the communication system that performs standby for reception is automatically switched from both the PDC and the PHS to only the PHS. After the switching, the PDC cannot wait for reception. And PH
At S, the reception standby is performed. At time t2, when the battery voltage V reaches the second specified value V2, the reception standby at the PHS becomes impossible.

Even if the current consumption and the minimum voltage value in both the PDC and PHS communication systems are the same, the communication system in which the
Can be switched to PHS only, the load is reduced, and the reception standby time is extended.

FIGS. 9A to 9C are diagrams showing changes in the battery voltage value and changes in the operation of the PDC radio unit 12 and the PHS radio unit 14 in response to the change.

As shown in FIG. 9 (a), at the point A where the battery voltage value V has decreased and the battery voltage value V has reached the first specified value V1, the communication system at the time of waiting for reception is a PDC.
And PHS are automatically switched to PHS only. Therefore, as shown in FIG.
The radio unit 12 for C is turned on every predetermined time until point C,
It is turned off after the point. On the other hand, as shown in FIG. 9C, after the power is turned on, the PHS radio unit 14 is turned on at predetermined intervals until reception standby becomes impossible.

PDC radio section 12 and PHS radio section 1
4 have different ON / OFF periods, both the PDC radio unit 12 and the PHS radio unit 14 may be turned ON at the same time. At this time, the PDC radio unit 12 and the PHS
The communication signal may be received simultaneously by both of the wireless units 14 for use. In this case, the communication signal is received by the priority communication system set in advance by the user. That is, when the priority communication system is set to PDC by the user, the CPU 19
2 for receiving the communication signal received from the PHS radio unit 14, and not for receiving the communication signal received from the PHS radio unit 14. On the other hand, when the priority communication system is set to PHS by the user, the CPU 19 performs a reception process on the communication signal received from the PHS radio unit 14 and a reception process on the communication signal received from the PDC radio unit 12. do not do. If the priority communication system is not set in any of the communication systems by the user, the communication signal is received and processed in the communication system that has been initially set.

When a communication signal is received simultaneously by both the PDC radio section 12 and the PHS radio section 14, the Received Signal Strength Indicator at that time is received.
A communication signal may be received in a communication system having a large (RSSI). The RSSI corresponds to the received electric field strength, and is measured at a predetermined time, for example, every 5 milliseconds, in each of the PDC and the PHS during reception standby. That is, when a communication signal is received simultaneously in both the PDC radio unit 12 and the PHS radio unit 14,
When the RSSI of the PDC is larger than the RSSI of the PHS, the CPU 19 performs the receiving process on the communication signal received from the wireless unit for PDC 12 and does not perform the receiving process on the communication signal received from the wireless unit for PHS 14. On the other hand, RSSI of PDC
If the RSSI of the PHS is greater than the PHS, the communication processing section 213 performs a reception process on the communication signal received from the PHS radio section 14 and does not perform a reception processing on the communication signal received from the PDC radio section 12. P
If the RSSI of DC and RSSI of PHS are equal,
The communication signal is received by a system set in advance by the user or a system set by default.

Further, when a communication signal is received simultaneously by both the PDC radio unit 12 and the PHS radio unit 14, the CPU 19 converts the received communication signal based on the caller number received together with the communication signal. The receiving process may be performed. That is, when the received caller number matches the number specified in advance by the user, the communication signal received together with the caller number is subjected to reception processing. Therefore, if the received caller number does not match the number specified in advance by the user, the reception processing of the communication signal received together with the caller number is not performed. on the other hand,
When the calling party number received simultaneously by both the PDC radio unit 12 and the PHS radio unit 14 does not match the number specified by the user, and both the numbers specified by the user in advance If they match, the user confirms those caller numbers displayed on the LCD 20, and the user selects a caller number for which a call is desired by operating the switch unit 22 or the like. The communication signal received with the selected calling number is transmitted to the CPU 19.
Is received.

As described above, when the reception standby is performed by the PDC and the PHS without switching the communication system at all, the reception standby cannot be performed at the time t3, for example, 50 minutes. On the other hand, according to the mobile phone of the present invention, at time t2,
For example, reception standby can be performed for up to 60 minutes. Therefore, the reception waiting time is extended.

In FIGS. 4 to 9A to 9C, the PDC
And PHS communication systems have different current consumptions, and the minimum voltage value of each communication system is equal to the battery voltage V2. However, the mobile phone 1 of the present invention can also be applied to a case where a plurality of communication systems to be switched have the same current consumption and different minimum voltage values. Further, the mobile phone 1 of the present invention can be applied to a case where both the current consumption and the minimum voltage value of a plurality of communication systems to be switched are different.

FIG. 10 is a diagram showing the relationship between the battery voltage V and the standby time when the current consumptions of the system 1 and the system 2 are equal and the minimum voltage values of the system 1 and the system 2 are different.

In FIG. 10, the lowest voltage value of the system 1 is the battery voltage V3, and the lowest voltage value of the system 2 is
Battery voltage V2. When the power is turned on at time 0, the system 1 waits for reception. And at time t1
, When the battery voltage V reaches the first specified value V1,
The communication system during standby is changed from system 1 to system 2
Is automatically switched to Therefore, after that, the reception standby is performed in the system 2 and the reception standby in the system 1 cannot be performed. At this time, since the current consumption of the system 2 is equal to the current consumption of the system 1, the battery voltage value does not increase. Thereafter, at time t2, the battery voltage V
Reaches the second specified value V2, it is impossible to wait for reception in the communication systems of both the system 1 and the system 2.

As described above, when the reception standby is performed in the system 1 without switching the communication system at all, the reception standby cannot be performed at the time t3, for example, 30 minutes.
On the other hand, according to the mobile phone of the present invention, reception standby can be performed until time t2, for example, 45 minutes. Therefore, even when the minimum voltage values of the system 1 and the system 2 are different, the reception standby time is extended.

FIG. 11 is a diagram showing the relationship between the battery voltage V and the standby time when both the current consumption and the minimum voltage value of the system 1 and the system 2 are different.

In FIG. 11, the lowest voltage value of the system 1 is the battery voltage V3, and the lowest voltage value of the system 2 is
Battery voltage V2. When the power is turned on at time 0, the system 1 waits for reception. And at time t1
, When the battery voltage V reaches the first specified value V1,
The communication system during standby is changed from system 1 to system 2
Is automatically switched to Therefore, after that, the reception standby is performed in the system 2 and the reception standby in the system 1 cannot be performed. At this time, since the current consumption of the system 2 is smaller than that of the system 1, the battery voltage value becomes V
Increase from 1 to V4. Thereafter, at time t2, when the battery voltage V reaches the second specified value V2, reception standby is disabled in both of the communication systems of the system 1 and the system 2.

As described above, when the reception standby is performed in the system 1 without switching the communication system at all, the reception standby cannot be performed at the time t3, for example, 30 minutes.
On the other hand, according to the mobile phone of the present invention, reception standby can be performed until time t2, for example, 120 minutes. Therefore, even when the current consumption and the minimum voltage value of the system 1 and the system 2 are different from each other, the reception standby time is extended.

Therefore, according to the present embodiment, the communication system is automatically switched according to the detected battery voltage value during standby, regardless of the current consumption and the minimum voltage value of the plurality of communication systems to be switched. Thus, the reception waiting time can be greatly extended.

In the present embodiment, FIGS.
As shown in (c), by displaying on the LCD 20 the communication system in which the reception standby is performed,
The user may be able to recognize which communication system is performing reception standby. FIG. 12 (a)
Is an LCD 20 when reception standby is performed in both the PDC and PHS communication systems shown in FIG.
The example of a display of is shown. FIG. 12B shows a display example of the LCD 20 when the reception waiting is performed in the PDC shown in FIGS. FIG. 12C shows a display example of the LCD 20 when the reception standby is performed in the PHS shown in FIGS. FIG.
2 (d) is the PDC and PH shown in FIGS.
L when reception standby is not performed in any of S
The example of a display of CD20 is shown.

Next, the operation of a communication apparatus, preferably a portable telephone, according to another embodiment of the present invention at the time of calling and talking will be described with reference to FIGS. Regarding the relationship between the mobile phone in the present embodiment and a plurality of communication systems connectable to the mobile phone, for example, PDC and PHS, and the configuration of a preferred example of the mobile phone in the present embodiment,
It is the same as that shown in FIGS. 1 and 2 and its description is omitted to avoid redundancy. 13 to 15, P
The minimum voltage values required when connecting by DC or PHS are different from each other. The minimum voltage value V7 required when connecting by PDC is, for example, 3.63 V
The minimum voltage value V8 required for connection by PHS is, for example, 3.57V.

In FIG. 13, the user operates the switch section 22.
By pressing, it is determined whether the power of the mobile phone 1 is turned on (S101). When the power of the mobile phone 1 is turned on (YES in S101), the battery voltage V is detected by the battery level detection unit 18 (S10).
2). The battery voltage V is detected every predetermined time, for example, every 1 msec after the power is turned on. Then, it is determined whether or not the detected battery voltage V is equal to or lower than a seventh specified value V7 (S103). The seventh specified value V7 indicates the battery voltage V for which reception standby is not possible.
5-2.7V. If battery voltage V is equal to or lower than seventh prescribed value V7 (YES in S103), mobile phone 1
Is turned off (S104).

If the remaining battery voltage V is greater than the seventh specified value V7 (NO in S103), the detected battery voltage V
Is determined to be less than or equal to the sixth specified value V6 (S105). The sixth specified value V6 is a value slightly larger than the minimum voltage V8 required when connected to the PHS, and is, for example, 3.58V. When it is determined that the battery voltage V is equal to or lower than the sixth specified value V6 (S105
YES), PDC radio section 12 and PHS radio section 1
4 is turned off (S106).

On the other hand, when it is determined that the battery voltage V is higher than the sixth specified value V6 (NO in S105),
It is determined whether the battery voltage V is equal to or less than the fifth specified value V5 (S107). The fifth specified value V5 is a value slightly larger than the battery voltage required when connected to the PDC, and is, for example, 3.64V. If it is determined that the battery voltage V is equal to or less than the fifth specified value V5 (S1
07, YES), the PDC radio unit 12 is turned off, and P
The HS radio unit 14 is turned on (S108).

If it is determined that battery voltage V is higher than fifth specified value V5 (NO in S107), PDC
Wireless unit 12 and PHS wireless unit 14 are turned on.

Thereafter, it is determined whether or not the calling operation has been performed by the user pressing the destination number or the like using the switch unit 22 (S110). If the calling operation is not performed (NO in S110), the process returns to S102, and the battery voltage V is detected.

On the other hand, when a call operation is performed (S1
Then, as shown in FIG. 14, it is determined whether a PDC has been designated (S111). For example, it is determined whether or not the PDC is automatically specified at the time of a calling operation by the user. Also,
When a user can select a communication system to be connected to by operating the switch unit 22 at the time of calling, the user can switch the switch unit 2 connected to the PDC.
It is determined whether operation 2 has been performed.

At the time of calling, if the user has performed the process of connecting with the PDC (YES in S111), it is determined whether or not the PDC radio unit 12 is turned on (S11).
2). When the PDC wireless unit 12 is ON (YES in S112), the mobile phone 1 is connected to the PDC (S114), and a call is started (S115). Thereafter, it is determined whether or not the call has ended (S116).
If it is determined that the call has not ended (S116).
Then, it is determined whether the battery voltage V is equal to or lower than the fifth specified value V5 (S117). When it is determined that the battery voltage V is higher than the fifth specified value V5 (S11
(NO in 7), the processes of S115 and S116 are continued until the battery voltage V becomes equal to or lower than the fifth specified value V5.

If it is determined that battery voltage V is equal to or lower than fifth specified value V5 (YES in S117), notification section 2
1 outputs an alarm (S118). Thereafter, it is determined whether or not the call has ended (S119). If it is determined that the call has not ended (NO in S119),
It is determined whether the battery voltage V is equal to or less than the seventh specified value V7 (S120). When the battery voltage V is equal to the seventh specified value V7
If it is determined that it is larger than (N in S120)
O), until the battery voltage V becomes equal to or less than the seventh specified value V7.
The process of S119, that is, whether or not the call has ended is determined.

When it is determined that the remaining battery charge V is equal to or less than the seventh prescribed value V7 (YES in S120), the call is forcibly disconnected (S121).

On the other hand, in the process of S111, when the user does not perform the process of connecting with the PDC,
If the PDC radio unit 12 is not turned on in the process of step 12, it is determined whether the PHS radio unit is turned on as shown in FIG. 15 (S12).
2). If the PHS radio unit 14 is turned off (NO in S122), the connection cannot be established by PHS, so the process returns to S102 again, and the battery voltage V is detected.

If the PHS radio section 12 is ON (YES in S122), the mobile phone 1 is connected to the PHS (S124), and a call is started (S125).
Thereafter, it is determined whether the call has ended (S12).
6). If it is determined that the call has not ended (S
It is determined whether the battery voltage V is equal to or lower than the sixth specified value V6 (S127). When it is determined that the battery voltage V is higher than the sixth specified value V6 (NO in S127), the processing of S125 and S126 is continued until the battery voltage V becomes equal to or less than the sixth specified value V6.

When it is determined that battery voltage V is equal to or lower than sixth prescribed value V6 (YES in S127), notification section 2
1 outputs an alarm (S128). Thereafter, it is determined whether or not the call has ended (S129). If it is determined that the call has not ended (NO in S129),
It is determined whether the battery voltage V is equal to or less than the eighth specified value V8 (S130). When the battery voltage V is equal to the eighth specified value V8
If it is determined that it is larger than (N in S130,
O), until the battery voltage V becomes equal to or less than the eighth specified value V8.
The process of S129, that is, whether or not the call has ended is determined.

When it is determined that the battery voltage V is equal to or lower than the eighth specified value V8 (YES in S130), the call is forcibly disconnected (S131).

Next, the operation of the portable telephone 1 of the present embodiment shown in FIG. 13 when waiting for reception will be described more specifically with reference to FIG. FIG. 16 shows the relationship between the battery voltage V and the reception standby time. It is assumed that when the power is turned on at time 0, the battery voltage V is fully charged. It is preferable that the battery voltage values V5, V7 and V8 in FIG. 16 are equal to the battery voltage values V1, V3 and V2 in FIG. 11, respectively.

In FIG. 16, when the power is turned on at time 0, the battery voltage V is higher than the fifth specified value V5 because the battery voltage V is fully charged. Therefore, PD
Both the C radio unit 12 and the PHS radio unit 14 are ON. When the battery voltage V reaches the fifth specified value V5 at time t5, the PDC radio unit 12
F. Therefore, after that, the reception standby is performed in the PHS, and the reception standby in the PDC cannot be performed.
At this time, since the current consumption of the PHS is smaller than that of the PDC, the battery voltage value increases from V5. Thereafter, at time t6, when the battery voltage V reaches the sixth specified value V6, PD
Receiving standby cannot be performed in both the C and PHS communication systems. Therefore, the mobile phone 1 can connect to both the PDC and the PHS until the standby time t5. Then, the mobile phone 1 can connect to the PHS from the standby time t5 to t6,
It cannot be connected to PDC. Also, the mobile phone 1
Cannot connect to either the PDC or the PHS after the standby time t6.

Next, the operation of the portable telephone 1 of the present embodiment shown in FIGS. 13 to 15 at the time of calling and talking will be described more specifically with reference to FIG. FIG. 17 shows the relationship between the battery voltage V and the reception standby time. It is assumed that the battery voltage V is fully charged when the calling operation is performed at time 0.

In FIG. 17, when the user performs a calling operation using the switch unit 22 at time 0, the mobile phone 1
When talking by connecting to DC, the battery voltage V gradually decreases until the talk time T7, for example, 110 minutes, and then decreases rapidly. The battery voltage V corresponding to the talk time T7 is the seventh specified value V7. The battery voltage V becomes 0 during a talk time T0, for example, 120 minutes. The battery voltage V corresponding to the talk time T5, for example, 105 minutes is the fifth specified value V5. Therefore, the mobile phone 1
When a call is made until the call time T5, an alarm is output from the notification unit 21. Thereafter, the call is forcibly disconnected at the talk time T7, and the power is turned off at the talk time T0.

On the other hand, when the mobile phone 1 is connected to the PHS and talks, the battery voltage V is equal to the talk time T8, for example, 17 hours.
It decreases slowly until 0 minutes, and then decreases rapidly.
The battery voltage V corresponding to the talk time T8 is the eighth specified value V8. The battery voltage V is equal to the talk time T0 ', for example, 1
It goes to 0 at 80 minutes. The battery voltage V corresponding to the talk time T6, for example, 165 minutes is the sixth specified value V6. Therefore, when the mobile phone 1 makes a call until the talk time T6, an alarm is output from the notification unit 21. Thereafter, the call is forcibly disconnected at the talk time T8, and the power is turned off at the talk time T0 '.

The alarm at time T5 and the alarm at time T6 may be output in different notification forms.
The alarm may be output from a receiver (not shown) instead of the notifier 21. In addition, the alarm may be output from the notification unit 21 and the receiving unit (not shown).

Next, with reference to FIG. 18, the operation of the portable telephone 1 in the present embodiment when receiving a call will be described in detail.

In FIG. 18, when there is an incoming call (S301)
The CPU 19 determines which of the PDC wireless unit 12 and the PHS wireless unit 14 has received the wireless signal (S302). At this time, since the communication system that can be connected is selected by the selector 15 according to the battery voltage V, the wireless unit 12 or 14 corresponding to the communication system that cannot be connected cannot receive the wireless signal. Can not.

When the battery voltage V is higher than the fifth specified value V5, that is, when both the PDC radio unit 12 and the PHS radio unit 14 are ON, the PDC radio unit 12 and the PHS radio There is a case where a communication signal is received by both of the units 14 at the same time. In this case, the communication signal is received by the priority communication system set in advance by the user. That is, when the priority communication system is set to PDC by the user, the CPU 19
The communication signal received from the PDC radio unit 12 is received, and the communication signal received from the PHS radio unit 14 is not received. On the other hand, if the priority communication system is P
When set to HS, the CPU 19
Receiving processing of the communication signal received from the
The communication signal received from the C radio unit 12 is not subjected to reception processing. If the priority communication system is not set in any of the communication systems by the user, the communication signal is received and processed in the communication system that has been initially set.

When the communication signal is received by both the PDC radio unit 12 and the PHS radio unit 14 at the same time, the Received Signal Strength Indicator at that time is received.
A communication signal may be received in a communication system having a large (RSSI). The RSSI corresponds to the received electric field strength, and is measured at a predetermined time, for example, every 5 milliseconds, in each of the PDC and the PHS during reception standby. That is, when a communication signal is received simultaneously in both the PDC radio unit 12 and the PHS radio unit 14,
When the RSSI of the PDC is larger than the RSSI of the PHS, the CPU 19 performs the receiving process on the communication signal received from the wireless unit for PDC 12 and does not perform the receiving process on the communication signal received from the wireless unit for PHS 14. On the other hand, RSSI of PDC
If the RSSI of the PHS is greater than the PHS, the communication processing section 213 performs a reception process on the communication signal received from the PHS radio section 14 and does not perform a reception processing on the communication signal received from the PDC radio section 12. P
If the RSSI of DC and RSSI of PHS are equal,
The communication signal is received by a system set in advance by the user or a system set by default.

Further, when the communication signal is received simultaneously by both the PDC radio unit 12 and the PHS radio unit 14, the CPU 19 converts the received communication signal based on the caller number received together with the communication signal. The receiving process may be performed. That is, when the received caller number matches the number specified in advance by the user, the communication signal received together with the caller number is subjected to reception processing. Therefore, if the received caller number does not match the number specified in advance by the user, the reception processing of the communication signal received together with the caller number is not performed. on the other hand,
When the calling party number received simultaneously by both the PDC radio unit 12 and the PHS radio unit 14 does not match the number specified by the user, and both the numbers specified by the user in advance If they match, the user confirms those caller numbers displayed on the LCD 20, and the user selects a caller number for which a call is desired by operating the switch unit 22 or the like. The communication signal received with the selected calling number is transmitted to the CPU 19.
Is received.

If the CPU 19 has received the communication signal received via the PDC radio section 12 (S30)
When the user presses the switch unit 22, the telephone call is started (S303). The subsequent operation during the call, that is, the processing of S303 to S309 is the same as the processing of S115 to S121 shown in FIG.
The description is omitted here to avoid redundancy.

On the other hand, the CPU 19
(S302: NO, S310: YES), the user starts the communication by pressing the switch unit 22 (S311). The subsequent operation during a call, that is, the processing of S311 to 317, is performed in S125 shown in FIG.
The processing is the same as that of steps 131 to 131, and a description thereof is omitted here to avoid redundancy.

As described above, according to the mobile phone of the present embodiment, when the connection is made by the PDC at the time of calling, when the battery voltage V is lower than the battery voltage connectable to the PDC, Since the call is automatically switched to the PHS and a call is made, operability can be improved. Further, since the alarm is notified a predetermined time before the call is disconnected, it is possible to prevent the call from being suddenly disconnected.

In the present embodiment, FIGS.
As shown in (c), the connectable communication system is L
By displaying on the CD 20, the user may be able to recognize which communication system is connectable. FIG. 19A shows a display example of the LCD 20 when connection is possible with both the PDC and the PHS.
FIG. 19B shows a display example of the LCD 20 when the connection is possible with the PHS but not with the PDC.
FIG. 19C shows a display example of the LCD 20 when it is not possible to connect to both the PDC and the PHS. Also, in order to more clearly recognize the connectable communication system,
It is preferable to display a comment such as "can be connected" or "cannot connect to PDC". At this time, if connection is not possible with both the PDC and the PHS, it is preferable that a comment prompting charging, for example, "Please charge" is displayed.

As shown in FIGS. 20A to 20C, a connectable communication system may be displayed together with the battery voltage V. FIG. 20A is a diagram showing the remaining battery level at the time of full charge.
Since it can be connected to both DC and PHS, the character "P
Both "DC" and "PHS" flash. FIG.
(B) cannot be connected to the PDC,
S is a diagram showing a battery voltage V that can be connected, and characters "PHS" are blinking. FIG. 20 (c)
FIG. 7 is a diagram showing a battery voltage V that cannot be connected to both DC and PHS, and neither characters “PDC” nor “PHS” are blinked.

Also, when a call is made in the selected communication system, the other party's mobile phone is set in the communication system selected in the calling party because the remaining battery level of the other party's mobile phone is low. Communication may not be possible. In this case, it is preferable that the exchange manages a communication system to which each mobile phone can be connected, and the exchange transmits information on the communication system to which the other party can connect to the calling side. The information of the communication system to which the own device can be connected is, for example,
It is preferable that the mobile phone adds the location registration request signal transmitted at the time of location registration and transmits the signal to the exchange.

In the above-described embodiment and other embodiments, PDC and PHS are switched and used according to the battery voltage V. However, connectable communication systems are:
There is no limitation to PDC and PHS. For example, Global S
ystem for Mobile communic-ation (GSM) and PH
S, the handset of the cordless telephone and the portable telephone, the radio selective calling receiver and the portable telephone may be switched and used. In addition, the connectable communication system pairs are not limited to the communication system pairs described above. Furthermore, the number of connectable communication systems is not limited to two. When there are three connectable communication systems, two prescribed values indicating the battery voltage value at the time of switching are provided, and switching is performed twice based on the current consumption and the minimum voltage value of each communication system.

The PDC radio unit 12 shown in FIG.
And the PHS radio unit 14 are provided separately, but they may be configured as an integrated radio unit. At this time,
It is preferable that by switching a part of the integrally configured wireless unit, it is possible to perform a call using power or a protocol corresponding to each communication system.

It is preferable that each specified value can be changed by the user pressing the switch section 22. In particular, it is preferable that the fifth specified value V5 and the sixth specified value V6 in other embodiments can be changed. Fifth
Can be changed, the user can change the time from when the alarm is issued until the call is forcibly disconnected. Further, by providing more specified values, more alarms may be notified.

Further, in the above-described embodiment and other embodiments, switching of a plurality of communication systems, generation of an alarm, and disconnection of a call are performed based on the battery voltage value detected by the battery voltage detecting unit 18. I have. However, the battery voltage detection unit 18 may calculate the remaining amount of the battery 17 itself, and switch between a plurality of communication systems, generate an alarm, and disconnect the call based on the calculated remaining amount. Therefore, the battery voltage detector 18 can detect not only the battery voltage value but also any information on the battery 17. Then, based on the information on the battery 17 detected by the battery voltage detection unit 18, the CPU 19
Switches a plurality of communication systems, generates an alarm, and disconnects a call.

As described above, according to the communication apparatus of the present invention, when the battery voltage decreases to a predetermined value during standby, the communication apparatus can be switched to a communication system with smaller current consumption. The standby time can be extended.

Further, during standby, a plurality of communication systems are automatically switched based on the battery voltage, so that operability can be improved.

Further, according to the present invention, when the user performs a call operation, if the detected battery voltage is low, the communication is switched to a communication system with low current consumption, so that the call is interrupted during the call. It can be prevented from being cut.

Furthermore, at the time of calling, a communication system with low current consumption is automatically selected based on the battery voltage, so that operability can be further improved.

[Brief description of the drawings]

FIG. 1 is a diagram showing a relationship between a mobile phone of the present invention and PDC and PHS connectable to the mobile phone.

FIG. 2 is a diagram showing a configuration of a preferred example of a mobile phone according to the present invention.

FIG. 3 is a flowchart for explaining a preferred example of operation of the mobile phone shown in FIG. 2 when waiting for reception;

FIG. 4 is a diagram showing a relationship between a battery voltage and a reception standby time when the PDC and the PHS have the same current consumption, the PDC and the PHS have the same minimum voltage value, and when the power is on, the PDC performs the reception standby; .

FIG. 5 is a diagram showing a transition of a battery voltage value and an operation change of a PDC wireless unit and a PHS wireless unit based on the relationship diagram shown in FIG. 4;

FIG. 6 is a diagram showing a relationship between a battery voltage and a reception standby time when the PDC and the PHS have the same current consumption and the PDC and the PHS have the same minimum voltage value, and when the power supply is ON, the reception standby is performed at the PHS. .

FIG. 7 is a diagram showing a transition of a battery voltage value and a change in operation of a PDC radio unit and a PHS radio unit based on the relationship diagram shown in FIG. 6;

FIG. 8 is a diagram showing the relationship between the battery voltage and the reception standby time when the PDC and the PHS perform reception standby when the power consumption is equal and the PDC and the PHS have the same current consumption and the PDC and the PHS have the same minimum voltage value. It is.

FIG. 9 is a diagram showing a transition of a battery voltage value and an operation change of a PDC wireless unit and a PHS wireless unit based on the relationship diagram shown in FIG. 8;

FIG. 10: PDC and PHS have the same current consumption and PDC
FIG. 7 is a diagram showing a relationship between battery voltage and reception standby time when the minimum voltage values of the PHS and the PHS are different.

FIG. 11 shows the difference in the current consumption between PDC and PHS.
FIG. 7 is a diagram showing a relationship between battery voltage and reception standby time when the minimum voltage values of the PHS and the PHS are different.

12 is a diagram showing a preferred display example of the LCD 10 shown in FIG.

FIG. 13 illustrates a mobile phone according to another embodiment in a reception standby state.
It is a flowchart for demonstrating the operation | movement of a suitable example at the time of a call and at the time of a telephone call.

FIG. 14 illustrates a state in which the mobile phone according to another embodiment waits for reception.
It is a flowchart for demonstrating the operation | movement of a suitable example at the time of a call and at the time of a telephone call.

FIG. 15 illustrates a state in which the mobile phone according to another embodiment waits for reception.
It is a flowchart for demonstrating the operation | movement of a suitable example at the time of a call and at the time of a telephone call.

FIG. 16 is a diagram illustrating a relationship between a battery voltage and a reception standby time for specifically describing an operation of the mobile phone according to the other embodiment illustrated in FIG. 13 during reception standby.

FIG. 17 is a diagram illustrating a relationship between a battery voltage and a reception standby time for specifically explaining the operation of the mobile phone according to another embodiment shown in FIGS. 14 and 15 at the time of calling and talking. is there.

FIG. 18 is a flowchart illustrating a preferred example of operation of the mobile phone according to another embodiment when a call is received.

FIG. 19 is a diagram showing a preferred display example of the LCD 10 shown in FIG.

20 is a diagram showing a preferred display example of the LCD 10 shown in FIG.

[Explanation of symbols]

 Reference Signs List 1 mobile phone 2 PHS base station 3 PDC base station 4 PHS service area 5 PDC service area 11 antenna 12 PDC radio unit 13 antenna 14 PHS radio unit 15 selector 16 selector control unit 17 battery 18 battery voltage detection unit 19 CPU Reference Signs List 20 LCD 21 Notification unit 22 Switch unit 23 Memory unit

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁷ , DB name) H04Q ^7/ 00-7/38 H04B ⁷ /24-7/26

Claims (43)

(57) [Claims] [Claim 1] of the call can be a plurality of communication systems,
Selecting means for selecting a connectable communication system; battery voltage detecting means for detecting a battery voltage for driving the communication device; controlling the selecting means based on a battery voltage value detected by the battery voltage detecting means. and control means for, have a, said control means, the detected battery voltage
Until the communication system drops to a predetermined value.
When the voltage reaches the predetermined voltage value,
Standby on a communication system that can be connected to
A communication device characterized by performing . 2. A call can first communication system and a second communication system capable calls, a battery voltage detecting means for detecting a battery voltage driving the communication apparatus, is detected in the battery voltage detecting means Comparing means for comparing the battery voltage with a predetermined value; and when the battery voltage is equal to or less than the predetermined value, the first
It has a, a switching unit for switching between the communication system and second communication system, said switching means, said power supply voltage is the predetermined value
The first or second communication system
Switch to stand by at least one of them,
When the battery voltage reaches the predetermined value, the battery is connected below the voltage.
A communication device characterized by switching to a communication system that can be connected. 3. The communication device according to claim 2, wherein the second communication system is capable of waiting for reception at a voltage value lower than the predetermined value. (4)A first communication system capable of making a call; A callable second communication system; Battery voltage detecting means for detecting the battery voltage for driving the communication device
Steps and The battery voltage detected by the battery voltage detecting means
And comparison means for comparing the predetermined value with When the battery voltage is equal to or less than the predetermined value, the first
Between the first communication system and the second communication system
Switching means; Has, The predetermined value can be changed by the user.
Characterized byCommunication device. 5. The communication device according to claim 2, wherein the predetermined value is larger than a minimum voltage value required for performing reception standby in the first communication system. 6. The communication device according to claim 2, wherein the first and second communication systems have different current consumptions and the same minimum voltage value at which reception standby is possible. 7. The communication device according to claim 2, wherein the first and second communication systems have the same current consumption and different minimum voltage values at which reception standby is possible. 8. The communication apparatus according to claim 2, wherein the first and second communication systems are different from each other in both current consumption and a minimum voltage value at which reception standby is possible. 9. The communication device according to claim 2, wherein the switching unit is automatically performed. 10. The communication device according to claim 2, further comprising an output unit that outputs a sound when the communication system is switched from the first communication system to the second communication system. 11. The communication apparatus according to claim 2, further comprising display means for displaying information on a communication system capable of waiting for reception. 12.First communication unit by PDCWhen,Second communication unit by PHS When,Battery voltage detecting means for detecting the battery voltage for driving the communication device
Steps and The battery voltage detected by the battery voltage detecting means
And comparison means for comparing the predetermined value with When the battery voltage is equal to or less than the predetermined value, the first
Switching means for switching between the communication unit and the second communication unit, Having A communication device characterized by the above-mentioned. Claim 13First communication unit by GSMWhen,Second communication unit by PHS When,Battery voltage detecting means for detecting the battery voltage for driving the communication device
Steps and The battery voltage detected by the battery voltage detecting means
And comparison means for comparing the predetermined value with When the battery voltage is equal to or less than the predetermined value, the first
Switching means for switching between the communication unit and the second communication unit, Having A communication device characterized by the above-mentioned. 14. The switching means, wherein the power supply voltage is
Until the first and second communication systems are reduced to a predetermined value.
The system switches to standby and the battery voltage
Becomes the predetermined value, the one that can be connected at the voltage or less
The communication device according to claim 2, wherein the communication device is switched to a communication system. 15. The communication system according to claim 15, wherein said first and second communication systems wait.
During communication, communication signals are received from both communication systems.
Connection to the communication system with the higher received electric field strength
The communication device according to claim 14 , wherein the communication is performed. 16. A first and a second communication system capable of talking, a battery voltage detecting means for detecting a battery voltage for driving a communication device, a battery voltage detected by the battery voltage detecting means, and a predetermined value. comparing means for comparing the bets, when the battery voltage is below the predetermined value, have a, a switching unit for switching between said first and second communication system and second communication system, The switching means determines that the detected battery voltage value is a predetermined value.
Until the value decreases to a value, the first and second communication systems
The reception standby is alternately repeated until the predetermined voltage
Value, the communication system that can be connected below
A communication device which performs reception standby in a system. 17. The communication device according to claim 16, wherein said second communication system is capable of waiting for reception at a voltage value lower than said predetermined value. 18. The communication device according to claim 16, wherein the predetermined value can be changed by a user. 19. The communication apparatus according to claim 16, wherein the predetermined value is larger than a minimum voltage value required for performing reception standby in the first communication system. 20. The first and second communication systems,
17. The communication device according to claim 16, wherein current consumptions are different from each other, and a minimum voltage value at which reception standby is possible is the same. 21. The communication device according to claim 16, wherein said switching means is automatically performed. 22. The communication apparatus according to claim 16, further comprising output means for outputting a voice when the first and second communication systems are switched to the second communication system. 23.First and second communication systems capable of talking
And Battery voltage detecting means for detecting the battery voltage for driving the communication device
Steps and The battery voltage detected by the battery voltage detecting means
And comparison means for comparing the predetermined value with The battery voltage is
The first and second communications when the value is equal to or less than the predetermined value;
Switching means for switching between the system and the second communication system
Steps and A second communication system from the first and second communication systems;
Output means for outputting audio when switched to Has, The audio is transmitted by the switched communication system.
Are characterized byCommunication device. 24. A display device for displaying a communication system capable of waiting for reception.
The communication device as described. 25. At least one of the first and second communication systems, a battery voltage detecting means for detecting a battery voltage for driving the communication device, and a call detection by the battery voltage detecting means upon calling. Selecting means for selecting a connectable communication system from the first and second communication systems based on the battery voltage obtained. 26. A communication system comprising: at least one of a first communication system and a second communication system; a battery voltage detection means for detecting a battery voltage for driving the communication device; Determining means for determining whether or not the call operation has been performed; and when the determining means determines that a calling operation has been performed in the first communication system, the battery voltage is the lowest connectable in the first communication system. Determining means for determining whether the battery voltage is equal to or less than a voltage value, and selecting means for selecting the second communication system when the battery voltage is determined to be equal to or less than the minimum voltage value, A communication device comprising: 27. The first and second communication systems,
Both the current consumption and the minimum voltage required to connect
27. The communication device according to claim 26, wherein the communication devices are different from each other . 28. The method according to claim 28 , wherein the battery voltage is
When it is determined that the voltage is greater than the minimum voltage value,
Having connection means for connecting in the first communication system;
27. The communication device according to claim 26, wherein: 29. The communication system according to claim 29, wherein said selection means is provided with said second communication system.
The battery voltage value is a first predetermined value.
Having output means to output an alarm when:
The communication device according to claim 26, wherein: 30. The communication system according to claim 30, wherein said selecting means is provided for said second communication system.
The battery voltage value is equal to a second predetermined value.
Have disconnection means to disconnect the call when:
The communication device according to claim 26, wherein: 31. The communication system as claimed in claim 31, wherein the connection means includes a first communication system.
The battery voltage value is equal to a third predetermined value.
Having output means to output an alarm when:
29. The communication device according to claim 28, wherein: 32. The communication system according to claim 31, wherein said connection means is provided with said first communication system.
The battery voltage value is equal to a fourth predetermined value.
Have disconnection means to disconnect the call when:
29. The communication device according to claim 28, wherein: 33. Upon receiving a call, connection based on the battery voltage value
Has a receiving means for receiving radio signals in a possible communication system.
27. The communication device according to claim 26, wherein: 34. Information on a connectable communication system
3. A display means for displaying a message.
7. The communication device according to 6 . 35. The connectable communication device, wherein
Information about the system,
35. A display is provided at the same place as the display.
The communication device as described. 36. The first and second communication systems,
Claims are PDC and PHS respectively
Item 29. The communication device according to item 26 . 37. The first and second communication systems,
GSM and PHS respectively
Item 29. The communication device according to item 26 . 38. At least one of the first and second communication systems, a battery voltage detection unit for detecting a battery voltage for driving the communication device, and a call operation in the first communication system. A determination unit that determines whether or not a call operation has been performed in the first communication system when the determination unit determines that a calling operation has been performed in the first communication system;
A determination unit that determines whether the battery voltage is equal to or lower than a connectable minimum voltage value in the communication system, and when the battery voltage is determined to be equal to or lower than the minimum voltage value, the second communication A communication device, comprising: a selection unit that selects a system. 39.Received by the first communication system capable of talking
Performing a standby; Detecting a battery voltage for driving the communication device;
When, The battery voltage detected in the detecting step,
Comparing with a predetermined value; Based on the comparison result of the comparing step, the first communication
Switch from the communication system to the second communication system capable of talking
Step of waiting for reception. Communication system switching method characterized by having
Law . 40.The battery voltage for driving the communication device is detected.
Steps to issue, The battery voltage detected in the detecting step,
Comparing with a first predetermined value; When the battery voltage is higher than the first predetermined value
At the first communication system where communication is possible
Steps Whether or not the battery voltage is equal to or less than the first predetermined value;
The step of determining; In the determining step, the battery voltage is equal to the first voltage.
Is determined to be equal to or less than the predetermined value of the first communication.
Switch the communication system to the second communication system capable of talking
Performing reception standby by Comparing the battery voltage with a second predetermined value
When, When the battery voltage is equal to or less than the second predetermined value,
The reception waiting in the first and second communication systems is disabled.
Enabling steps; Communication system switching method characterized by having
Law . 41. A step of performing reception standby in at least one of the first and second communication systems; detecting a battery voltage for driving the communication device; Based on the detected battery voltage, of the first and second communication systems,
Connecting with a connectable communication system; and a system switching method for a communication device. 42. A step of performing reception standby in at least one of the first and second communication systems, a step of detecting a battery voltage for driving the communication device, and a step of transmitting in the first communication system. A step of determining whether a call operation has been performed; and, if it is determined in the determination step that a call operation has been performed in the first communication system, the battery voltage can be connected in the first communication system. Determining whether the battery voltage is equal to or less than a minimum voltage value, and, when the battery voltage is determined to be equal to or less than the minimum voltage value in the determining step, connecting in the second communication system; A system switching method for a communication device, comprising: 43. A step of determining whether a call operation has been performed in the second communication system; and a case in which it is determined in the determination step that a call operation has been performed in the second communication system. Determining whether or not the battery voltage is equal to or lower than a minimum voltage value connectable by the second communication system; and determining that the battery voltage is equal to or lower than the minimum voltage value in the determining step. 43. The system switching method for a communication device according to claim 42 , further comprising: disabling connection in the second communication system.