JP3790322B2 - Battery charging device and method - Google Patents

Description

[0001]
【Technical field】
The present invention relates to a communication device capable of data communication via a communication path, and a battery-charging device and method capable of being connected using the communication path.
[0002]
BACKGROUND OF THE INVENTION
For transmission and reception of image data, parallel communication such as Centronics and SCSI (Small Computer System Interface), and serial communication such as RS232C, RS422, and USB (Universal Serial Bus) are used. In these serial communication systems, only image data is transmitted and received, and it has never been considered to charge the battery using the image data communication line. When charging a battery, a separate power cable and charging device must be connected.
[0003]
DISCLOSURE OF THE INVENTION
An object of the present invention is to provide a communication device capable of data communication through a communication path, and a battery-charging device and method capable of being connected using the communication path.
[0004]
A first invention is a communication device capable of data communication via a communication path and a charging device connectable using the communication path. The communication path includes a communication line for the data communication, a power source And a power supply line for supply, and a charging circuit for charging the battery when power is supplied through the power supply line.
[0005]
The first invention also provides a method suitable for the above charging device.
[0006]
That is, a charging device including a charging circuit using the communication path in a communication device capable of data communication via a communication path including a communication line for data communication and a power supply line for power supply And charging the battery by supplying power to the charging circuit through the power line.
[0007]
According to the first invention, the charging device can be connected to a communication device capable of data communication via a communication path using the communication path. Since this communication path includes a communication line for data communication and a power supply line for supplying power, the battery can be charged by supplying power to the charging circuit through the power supply line. It becomes. There is no need to connect a power cable separately from the communication path.
[0008]
It is preferable to determine whether charging by the charging circuit is possible based on the power supply capability of the communication device, and to charge the battery in the charging circuit when it is determined that charging is possible.
[0009]
More preferably, based on the level of power supplied from the power supply line, it is determined whether or not a power supply drop occurs in the power supply line, and the charging is performed in response to the determination that the power supply drop occurs. It is preferable to adjust so as to reduce the amount of charge in the circuit.
[0010]
When the power supply capability is low, it is possible to prevent data communication from being disabled due to a decrease in power due to charging by the charging circuit.
[0011]
A second invention is a communication device capable of data communication via a communication path and a charging device connectable using the communication path. The communication path includes a communication line for the data communication, a power source A power supply line for supplying power to the connector of the data processing device, which is driven by the attached battery and is provided with a connector for inputting power for charging the battery. A charging circuit for supplying power supplied through the line is provided.
[0012]
The second invention also provides a method suitable for the charging circuit.
[0013]
That is, a communication device capable of data communication via a communication path and a charging device connectable using the communication path. The communication path includes a communication line for data communication and a power supply for power supply. A power line, and is supplied through the power line to the connector of the data processing device which is driven by the attached battery and has a connector for inputting power for charging the battery. The battery is charged by applying a power source.
[0014]
According to the second aspect of the invention, the battery can be charged in a state where the battery is attached to the data processing device driven by the attached battery.
[0015]
[Explanation of Examples]
FIG. 1 shows an embodiment of the present invention. The charging device 10, the personal computer 30, and the communication device 40 are interconnected by a cable 20 based on IEEE Standard 1394 (IEEE Standard 1394, IEEE = The Institute of Electrical and Electronic Engineers, Inc.) (hereinafter referred to as IEEE 1394). ing. The cable 20 includes a signal line 22 for transmitting data and a power line 21 for supplying power. The cable 20 includes a ground line, but is not shown. Further, although there are four signal lines, they are shown here as a single line for easy understanding of the drawing.
[0016]
The entire operation of the charging device 10 is controlled by the CPU 11. The CPU 11 is connected to a ROM 12 in which data to be transmitted / received to / from the personal computer 30 is stored. A communication control circuit 15 for transmitting and receiving data based on IEEE 1394 is connected to the CPU 11. The communication control circuit 15 is connected to the signal line 22.
[0017]
The charging device 10 includes a charging circuit 13 for charging the battery 1. The charging circuit 13 is connected to a power supply line 21 and charges the battery 1 with power supplied from the power supply line 21. The power supply line 21 is also connected to the monitoring circuit 14 and monitors the power supplied from the power supply line 21. Data representing the state of power supplied from the power line 21 (whether it is above a certain level) is given to the CPU 11. The charging device 10 is not connected to a cable for supplying external power.
[0018]
The overall operation of the personal computer 30 is controlled by the CPU 31.
[0019]
The personal computer 30 includes a communication control circuit 33 so that data can be transmitted and received based on IEEE1394, and is connected to the cable 20. The communication control circuit 33 is controlled by the controller 32. This controller 32 is also controlled by the CPU 31.
[0020]
The personal computer 30 includes a power supply unit 34. The power supply unit 34 is supplied with an AC voltage of 100 volts when an AC outlet plug 35 is inserted into a household outlet. In the power supply unit 34, an AC voltage of 100 volts is converted from a DC voltage of 8 volts to 40 volts. The power supply unit 34 is also connected to the power supply line 21, and a converted DC voltage of 8 to 40 volts is supplied to the power supply line 21 and supplied as drive power for the charging device 10 and the communication device 40 connected by the cable 20. Is done. It goes without saying that the DC voltage converted in the power supply unit 34 is supplied to each part of the personal computer 30 as a drive voltage.
[0021]
Next, an operation in which charging by the charging device 10 is performed will be described.
[0022]
Whether the cable 20 based on IEEE 1394 is attached or detached between the charging device 10 and the personal computer 30 is monitored by the communication control circuit 15 of the charging device 10 and the communication control circuit 33 of the personal computer 30. When the cable 20 is attached between the charging device 10 and the personal computer 30, a bus reset occurs, and the self-ID packet shown in FIG. 2 is transmitted between the charging device 10 and the personal computer 30. (Of course, a self ID packet is also transmitted to and from the communication device 40).
[0023]
First to fourth four self ID packets are transmitted according to the number of ports to which the cable 20 is connected. Here, for convenience of explanation, it is assumed that one self-ID packet is transmitted.
[0024]
Referring to FIG. 2, the identifier of the self ID packet is stored in area 10 and the identifier unique to the device that transmits this self ID packet is stored in area phy ID. Data indicating that the packet is a self ID packet is stored, and in region L, data indicating whether or not the communication control circuit of the device that transmits the self ID packet is ready to receive data is stored. The gap cnt stores data related to threshold values used for determination of subaction gaps, arbitration gaps, etc. in data transfer by IEEE 1394, and the area sp stores data representing the capability related to the communication speed of data. The area del relates to a delay time that occurs when a device that has received data is transferred to another device. Data is stored, and data indicating whether it can be a bus manager or an isochronous resource manager in data transfer by IEEE1394 is stored in area c, and this apparatus supplies power to area pwr Data indicating whether or not there is capability and data indicating maximum power consumption are stored. Whether or not another device is connected to the port of this device as an upper device or a lower device in the areas p0 to p2. Is stored in the area i in the self ID packet of the device that first started the bus reset, and the data indicating whether the self ID packet will continue next is stored in the area m. Remembered.
[0025]
Such a self ID packet is transmitted between the charging device 10 and the personal computer 30 when a bus reset occurs. When the charging device 10 receives the self ID packet from the personal computer 30, the power supply capability of the personal computer 30 stored in the area pwr of the self ID packet is detected. The detected power supply capability is compared with the maximum power consumption of the charging device 10 (this data is stored in the ROM 12). If the power supply capability exceeds the maximum power consumption, the charging circuit 13 Is charged. When the power supply capability is less than the maximum power consumption, charging by the charging circuit 13 is prohibited.
[0026]
When the communication device 40 other than the charging device 10 and the personal computer 30 is connected by the IEEE 1394 cable 20, the power supply capability of the communication device 40 can be increased even though power is supplied from the personal computer 30. Representing data may be provided to charging device 10. In such a case, the power supplied from the personal computer 30 may be less than the maximum power consumption of the charging device 10. In order to avoid such a situation, in the charging apparatus 10 shown in FIG. 1, the monitoring circuit 14 monitors the power level of the power line 21. If the CPU 11 determines that a voltage drop is caused by charging by the charging circuit 13 based on the signal output from the monitoring circuit 14, the charging circuit 13 causes the charge amount to be such that no voltage drop occurs. Controlled by the CPU 11.
[0027]
In the personal computer 30 as well, the maximum power consumption stored in the area pwr of the self ID packet transmitted from the charging device 10 is compared with the power supply capability. The power supply to the charging device 10 will be stopped as necessary.
[0028]
Also in FIG. 1, it goes without saying that data (for example, data relating to the charging status) is transmitted and received between the charging apparatus 10 and the personal computer 30 through the signal line 22 included in the cable 20.
[0029]
FIG. 3 shows another embodiment, and is a block diagram showing a state in which a charging device 10A connected to the digital camera 5 and a personal computer 30 are connected to each other by an IEEE 1394 cable 20. As shown in FIG. In this figure, the same components as those shown in FIG.
[0030]
Connectors 16 and 17 are formed in the charging apparatus 10A shown in FIG. The charging device 10A and the digital camera 50 are electrically connected by the connectors 16 and 17. The connector 16 is supplied with power supplied from the charging circuit 13. The connector 17 is connected to the CPU 11.
[0031]
The digital camera 50 includes a controller 51, and data is transmitted to and received from the charging device 10A via the connector 17 (the digital camera 50 includes various circuits. The illustration is omitted because it is not particularly related to the invention). The digital camera 50 is equipped with a battery 1 as a driving power source. Both ends of the battery 1 are connected to the connector 16.
[0032]
Accordingly, by attaching the charging device 10A to the digital camera 50, the battery 1 attached to the digital camera 50 can be charged using the charging circuit 13 of the charging device 10A.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a state in which a charging device, a personal computer, and a communication device are connected by an IEEE 1394 cable according to an embodiment of the present invention.
FIG. 2 shows a format of a self ID packet.
FIG. 3 shows another embodiment, and shows the configuration of a charging device 10A and a personal computer mounted on a digital camera.
[Explanation of symbols]
1 Battery 10, 10A Charging device 11, 31 CPU
13 Charging Circuit 14 Monitoring Circuits 15 and 33 Communication Control Circuit 30 Personal Computer

Claims (8)

A communication device capable of data communication via a communication path and a charging device connectable using the communication path,
The communication path includes a communication line for the data communication and a power supply line for power supply.
A charging circuit for charging a battery by supplying power through the power line;
A power reduction determination means for determining whether or not the power supply in the power supply line is reduced by charging by the charging circuit based on the level of power supplied from the power supply line; and
Charge amount adjusting means for adjusting the charge amount in the charging circuit to be small in response to the determination that the power supply drop occurs by the power supply drop determining means;
A battery charger comprising: Based on the power supply capability of the communication device, the charging capability determining means for determining whether or not charging by the charging circuit is possible, and the battery capacity when the charging capability determining means determines that the charging is possible. Charge control means for controlling the charging circuit so as to charge
The battery charger according to claim 1, further comprising: Charging data transmitting means for transmitting data relating to charging in the charging circuit to a communication device connected by the communication path;
The battery charger according to claim 1. A communication device capable of data communication via a communication path and a charging device connectable using the communication path,
The communication path includes a communication line for the data communication and a power supply line for power supply.
A charging circuit that is driven by the attached battery and that supplies power supplied through the power line to the connector of the data processing device in which a connector for inputting power for charging the battery is formed;
A power reduction determination means for determining whether or not the power supply in the power supply line is reduced by charging by the charging circuit based on the level of power supplied from the power supply line; and
Charge amount adjusting means for adjusting the charge amount in the charging circuit to be small in response to the determination that the power supply drop occurs by the power supply drop determining means;
A battery charger comprising: A charging device including a charging circuit using the communication path is provided as a communication apparatus capable of data communication via a communication path including a communication line for data communication and a power supply line for power supply. connection,
Rows that have a charge of battery by supplying power through the power supply line to said charging circuit,
Based on the level of power supplied from the power line, it is determined whether charging by the charging circuit causes a drop in power in the power line;
In accordance with the determination that the power supply is reduced, the charging amount in the charging circuit is adjusted to be reduced.
Battery charging method. Determine whether charging by the charging circuit is possible based on the power supply capability of the communication device,
Charging the battery in response to the determination that the charging is possible,
The battery charging method according to claim 5 . Transmitting data related to charging in the charging circuit to a communication device connected by the communication path;
The battery charging method according to claim 5 . A charging device including a charging circuit using the communication path is provided as a communication apparatus capable of data communication via a communication path including a communication line for data communication and a power supply line for power supply. connection,
The battery is controlled by applying power supplied through the power supply line to the connector of the data processing apparatus that is driven by the battery that is mounted and that has a connector for inputting power for charging the battery. charge,
Based on the level of power supplied from the power line, it is determined whether charging by the charging circuit causes a drop in power in the power line;
In accordance with the determination that the power supply is reduced, the charging amount in the charging circuit is adjusted to be reduced.
Battery charging method.

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