JP2002222030A - Portable electronic equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make portable electronic equipment, which has a real-time clock circuit in addition to a main system and makes the both operate with an internal main battery, small in size, light in weight and low in cost by eliminating the need for a subordinate battery for the real-time clock circuit and increasing the use rate of the main battery. SOLUTION: The main battery 1 which supplies the operating electric power of the main system 4 supplies the operating electric power of the real-time clock circuit 5 and the operable voltage of the real-time clock circuit 5 is set lower than the operable voltage of the main system; when the electromotive force of the main battery 1 drops below the operable voltage of the main system 4, the power supply to the main system is cut off and the electric power continues to be supplied to the real-time clock circuit 5.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a portable electronic device having at least a main system and a real-time clock circuit.

[0002]

2. Description of the Related Art A portable telephone or a portable data terminal (a so-called mail terminal connected to a portable telephone via a cable or the like to create a text such as an e-mail), a PDA (Personal)
Many portable electronic devices such as Digital Assistants) include a main system that performs main functions such as communication, and a real-time clock circuit that is attached to the main system and performs functions such as a clock and a calendar.

The real-time clock circuit generates clock data for holding time data, calendar data, and the like, which should always be maintained. Therefore, regardless of whether the main system is operating or not, the real-time clock circuit further operates. Even if the power supply is cut off due to battery exhaustion,
Need to work continuously. Therefore, it is common practice to provide an operating power supply for the real-time clock circuit with a sub-battery separately from the main battery that supplies the operating power of the main system, and to supply the operating power from the sub-battery.

[0004] In the above-described portable electronic device, most of the power is consumed by the main system, and thus a relatively large-capacity secondary battery (for example, a nickel metal hydride battery) is used as the main battery. On the other hand, since the real-time clock circuit generates only clock data such as time and date and consumes a small amount of power, a small-sized lithium-ion battery having a long storage life is often used.

[0005]

By the way, in portable electronic equipment, miniaturization, weight reduction and cost reduction of equipment are very important issues. To solve this problem, the number of parts constituting the equipment is important. It is indispensable to reduce the size and size of each part. However, in a device equipped with a real-time clock circuit, as described above, in order to continue the operation of the real-time clock circuit, a sub-battery must be incorporated separately from the main battery, which makes the device smaller and lighter. This has been a major impediment to achieving cost reductions.

Therefore, it has been proposed to supply the operating power of the real-time clock circuit from the same main battery as that of the main system. According to this, the auxiliary battery can be omitted.

However, in this case, it is necessary to recharge or replace the main battery while the capacity (electromotive force) of the main battery is still sufficient in order to secure the operating power supply of the real-time clock circuit. This causes a problem that the utilization rate of the main battery decreases. To compensate for this decrease in the utilization rate, it is necessary to increase the capacity of the main battery, but this increases the size, weight, and cost of the main battery, and reduces the size, weight, and cost of portable electronic devices. And contradictory results.

Further, when a secondary battery such as a nickel-metal hydride battery is used as the main battery, recharging is performed repeatedly in an insufficiently discharged state. There is also a problem that deterioration of the semiconductor is likely to occur.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and has as its object to operate a real-time clock circuit with a main battery that operates a main system in a portable electronic device having a real-time clock circuit. ,
An object of the present invention is to eliminate the need for a sub-battery for a real-time clock circuit and to increase the utilization rate of a main battery, thereby making it possible to reduce the size, weight, and cost of equipment.

[0010]

In order to solve the above problems, the present invention provides the following means.

That is, the means of the present invention is a portable electronic device that includes at least a main system and a real-time clock circuit and operates both of them with a built-in main battery. While supplying the operating power of the clock circuit, the operable voltage of the real-time clock circuit was set lower than the operable voltage of the main system, and the electromotive force of the main battery became equal to or less than the operable voltage of the main system. In some cases, control means is provided for interrupting power supply to the main system and continuing power supply to the real-time clock circuit.

According to the above-mentioned means, even if the electromotive force of the main battery is used until it becomes lower than the operable voltage of the main system, the electromotive force necessary for the operation of the real-time clock circuit can be obtained from the main battery. As a result, in a portable electronic device having a real-time clock circuit, a sub-battery for the real-time clock circuit can be dispensed with, the utilization rate of the main battery can be increased, and the size, weight, and cost of the device can be reduced. .

In the above means, when the volatile data in the main system is saved in the non-volatile storage means prior to the stop of the operation of the main system, the power supply to the main system is performed. When the detected electromotive force of the main battery becomes equal to or less than a preset detection threshold value, the save operation is performed, and then the operation of the main system is stopped by shutting off the power supply, whereby the nonvolatile The utilization rate of the main battery can be increased without impairing the sex data.

When the main system is started, when volatile data in the main system is loaded from the non-volatile storage means, it is detected that the power supply to the main system is shut off. When the electromotive force of the main battery becomes equal to or higher than a preset detection threshold, by executing a start-up process of the main system including the load, the load of the main battery is reduced while the load is correctly performed. Can be enhanced.

Further, in the above means, voltage monitoring means for detecting whether or not the electromotive force of the main battery is equal to or lower than the operable voltage of the real-time clock circuit; By providing a control unit for initializing the real-time clock circuit when a state is detected, an error in clock data due to running out of remaining power of the main battery can be avoided in advance.

When a DC-DC converter for converting the electromotive force of the main battery to a predetermined voltage and supplying the voltage to the main system is used, the case where the electromotive force of the main battery falls below a predetermined detection threshold value is used. At the same time, the operation of the main system is stopped by shutting off the power supply, and the DC-
By stopping the operation of the DC converter and continuing the operation of the real-time clock circuit by the recovered electromotive force of the main battery, the operation of the real-time clock circuit by the main battery is continued while increasing the utilization rate of the main battery. Thus, clock data such as time can be protected.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a block circuit diagram showing one embodiment of a portable electronic device according to the present invention.

The portable electronic device shown in FIG. 1 has a built-in secondary battery 1 serving as a main battery and a sub-battery, and a secondary battery (main battery) 1.
Charging circuit 2 for charging using an external power supply (DCIN),
DC for boosting and converting the electromotive force of the secondary battery 1 to a predetermined voltage
A DC converter 3, a main system 4 for executing a main function of the portable electronic device, a real-time clock circuit 5 for generating clock data such as time and calendar, a battery voltage monitoring circuit 6 for monitoring an electromotive force of the secondary battery 1, and It has a power supply control circuit 7 and the like. The main system 1 handles volatile data and includes a nonvolatile storage means (not shown) for saving the volatile data.

FIG. 2 is a waveform chart of a main part of the portable electronic device shown in FIG. 1, and FIG. 3 is a flowchart of a control procedure thereof.

1 to 3, a battery voltage monitoring circuit 6 performs first to fourth voltage detections.

The first voltage detection is performed to warn of a decrease in the capacity of the main battery (for example, a normal electromotive force of 2.4 to 2.8 V) (step S1).

The second voltage detection is performed for a shutdown process for forcibly stopping the operation of the main system 4 by shutting off the power (steps S2 to S6). The third voltage detection is performed in order to determine whether or not the main system is activated by power supply.

The first voltage detection in step S1 is performed by detecting a decrease in the main battery electromotive force when the main system 4 is in an operating state, that is, in a high load state, by a first detection threshold value set in advance (for example, 2.2 V). In the first voltage detection, when the electromotive force of the main battery 1 falls below the first detection threshold, the user is notified that the remaining capacity of the main battery is low by displaying a warning message, lighting an LED, or the like. Execute the process.

In this case, the first detection threshold is a voltage at which the operation of the main system 4 can be performed for the time being, but a warning voltage (for example, an initial voltage of 2.8 V) indicating that the remaining capacity of the main battery 1 is small. 2.2 V). The electromotive force of a nickel-metal hydride battery or the like has a characteristic that it sharply decreases at the end of the capacity when the remaining capacity of the main battery is exhausted. The first detection threshold is set to a value that can detect a decrease in electromotive force that appears as a precursor to the end of the capacity. As a result, while the main system 4 is operable, a decrease in the capacity of the main battery 1 can be detected and a warning can be issued in advance.

In the second voltage detection, when the main system 4 is in the operating state, that is, when the main battery 4 is in a high load state, the decrease in the main battery electromotive force is determined by a second detection threshold value set in advance (for example, 2.0 V). Perform using. This second detection threshold value (2.0 V) is lower than the first detection threshold value (2.2 V) and slightly higher than the lowest operating voltage (lowest operable voltage) of the main system 4. Is set. When the second voltage detection is performed, the evacuation process for saving the non-volatile data in the main system 4 to the non-volatile storage unit is performed, and then
A shutdown process for stopping the operation of the main system 4 by shutting off the power is executed (steps S2 to S6).

The third voltage detection is based on the fact that the main battery electromotive force in the state where the power supply to the main system 4 is cut off, that is, in the low load state where only the real-time clock circuit 5 is operating, is determined in advance. The determination is performed using the set third detection threshold value (2.2 V). The third detection threshold value is used to determine whether or not there is a main battery capacity that can be activated by loading the nonvolatile data into the main system 4 in an unloaded state before the activation. Is set to be able to.

The electromotive force of a nickel-metal hydride battery or the like as a main battery is reduced by discharge. However, when the discharge is stopped, there is a characteristic that the lowered electromotive force is recovered.
Further, the electromotive force of the main battery decreases as the remaining capacity of the main battery decreases, and the reduced electromotive force is restored when no load or low load state continues. For this reason, even if the electromotive force of the main battery in the no-load state or the low-load state before starting the main system 4 is higher than the minimum operating voltage of the main system 4, the remaining capacity of the main battery 1 is insufficient. In this case, the main battery electromotive force interrupts the minimum operating voltage during the activation of the main system 4, and the main system 4 is forcibly shut down. If the shutdown occurs during the startup, the loading of the non-volatile data into the main system 4 or the saving of the non-volatile data from the main system 4 is interrupted, thereby causing an error in which the non-volatile data is destroyed. .

Therefore, the third detection threshold value is set to a value that allows for a reduction in electromotive force when the main battery 1 is loaded. In this embodiment, a first detection threshold (2.2 V) higher than the second detection threshold (2.0 V) is used as the third detection threshold. That is, the first voltage detection and the third voltage detection share the same detection threshold (2.2 V). Therefore, the above-described first to third voltage detections are performed using the first and second two types of detection thresholds (2.2 V and 2.0 V).

In the fourth voltage detection, whether or not the electromotive force of the main battery 1 is equal to or lower than the operable voltage of the real-time clock circuit 5 is determined by a preset fourth detection threshold (for example, 1.8 V). Use to detect. The fourth detection threshold is set to a value equal to or slightly higher than the lowest operating voltage of the real-time clock circuit 5 (1.8 V). When the main battery electromotive force becomes equal to or less than the fourth detection threshold, the operation of the real-time clock circuit 5 cannot be guaranteed. Therefore, in this case, the real-time clock circuit is initialized to prevent an error due to clock data deviation (step S7).

Here, the operating power of the main system 4 and the power supply control circuit 7 is not directly from the main battery 1 but the main battery 1
Is supplied from the DC-DC converter 3 which boosts the electromotive force. The operating power supply of the real-time clock circuit 5 is the same as that of the DC-DC converter 3 during operation.
The boosted power is supplied by the C-DC converter 3 and is supplied directly from the main battery 1 when the operation of the DC-DC converter 3 is stopped.

The main system 4 is detected by the second voltage detection.
Is performed, the main battery electromotive force further falls below the second detection threshold value (2.0 V) by this shutdown process. During this period, the predetermined operation is performed by the operation of the DC-DC converter 3. Voltage operating power is supplied. Thereby, the operating voltage (3.3 V) of the shutdown processing of the main system 4 and the control circuit that controls the shutdown processing is secured. That is, the second detection threshold value is set so that the second voltage detection is performed at least where the shutdown processing can be performed.

After the shutdown processing, the operation of the DC-DC converter 3 is continued for a predetermined time. Thereby, the electromotive force of the main battery 1 reduced by the shutdown processing is recovered. After waiting for a time (for example, 60 seconds) for the electromotive force of the main battery 1 to recover, the operation of the DC-DC converter 3 is stopped (see FIG. 2). Thereby, even after the operation of the DC-DC converter 3 is stopped, the real-time clock circuit 5 can continue the operation by the recovered electromotive force. Therefore, the main battery 1 can be used up to the point where its remaining capacity is just before the operation of the main system 4 stops.

As described above, according to the present embodiment,
The sub-battery for the real-time clock circuit 5 is not required, and the utilization rate of the main battery 1 can be increased to reduce the size, weight, and cost of the device. When the main battery 1 is a secondary battery having a memory effect such as a nickel-metal hydride battery, the discharge can be sufficiently performed before recharging, so that the memory effect that hasten the deterioration of the main battery 1 is suppressed. In addition to the above, deterioration of the main battery 1 due to repeated charging with a longer charging interval can be suppressed.

It should be noted that the present invention is not limited to the above embodiment, and various changes can be made.

For example, the technology according to the present embodiment can be applied not only to mail terminals but also to portable information devices such as mobile phones and PDAs.

[0037]

As described above, in the portable electronic device according to the present invention, even if the built-in main battery, which is the main battery, is used until the electromotive force becomes lower than the operable voltage of the main system,
Since the electromotive force necessary for the operation of the real-time clock circuit can be obtained from the built-in main battery, the sub-battery for the real-time clock circuit is not required, and the utilization rate of the main battery is increased to reduce the size and weight of the device. Cost reduction can be achieved.

[Brief description of the drawings]

FIG. 1 is a block circuit diagram showing an embodiment of a portable electronic device to which the technology of the present invention is applied.

FIG. 2 is a waveform chart of a main part of the portable electronic device shown in FIG.

FIG. 3 is a flowchart of a control procedure in a main part of the portable electronic device shown in FIG. 1;

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Main battery also serving as sub-battery 2 Charging circuit 3 DC-DC converter 4 Main system 5 Real-time clock circuit (RTC) 6 Main battery voltage monitoring circuit 7 Power control circuit

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 2F002 AA01 AA04 AE01 GA06 2G016 CB12 CC03 CC04 CC07 CC09 CC12 CC23 CE01 CE31 5B011 DA06 DA13 DB04 EB02 GG04 KK02 5K027 AA11 BB14 BB15 CC08 GG02 GG03 HH27

Claims (5)

[Claims] 1. A portable electronic device comprising at least a main system and a real-time clock circuit and operating both with a built-in main battery, wherein the operation power of the real-time clock circuit is supplied by a main battery for supplying the operation power of the main system. Supply, and set the operable voltage of the real-time clock circuit lower than the operable voltage of the main system, and when the electromotive force of the main battery falls below the operable voltage of the main system, the main system A portable electronic device comprising: a control unit that shuts off power supply to the real-time clock circuit and continues power supply to the real-time clock circuit. 2. A control means for saving volatile data in the main system in a non-volatile storage means prior to the stop of the operation of the main system, and detecting the power supply to the main system in a state where power is supplied to the main system. When the electromotive force of the main battery becomes equal to or less than a preset detection threshold, the control unit stops the operation of the main system by shutting off the power after performing the save operation. The portable electronic device according to claim 1, wherein: 3. A control means for loading volatile data in the main system from a non-volatile storage means when the main system is started, and detecting the power supply to the main system in a state where power supply to the main system is shut off. And control means for executing a start-up process of the main system including the load when the electromotive force of the main battery becomes equal to or greater than a preset detection threshold value. The portable electronic device according to claim 2. 4. A voltage monitoring means for detecting whether or not the electromotive force of the main battery is equal to or lower than an operable voltage of the real-time clock circuit; and a case where the voltage monitoring means detects a state lower than the operable voltage. And control means for initializing the real-time clock circuit.
A portable electronic device according to any one of the above. 5. A DC-DC converter for converting the electromotive force of the main battery to a predetermined voltage and supplying the voltage to the main system, the control means, and the real-time clock circuit, and detecting a predetermined value of the electromotive force of the main battery. When the voltage falls below the threshold value, the operation of the main system is stopped by shutting off the power supply, and the operation of the DC-DC converter is stopped after waiting for a period of time from the stop of the operation until the electromotive force of the main battery recovers. And control means for continuing the operation of the real-time clock circuit with the recovered electromotive force of the main battery.
A portable electronic device according to any one of the above.