JP6620864B1 - Power control apparatus and program - Google Patents

Abstract

Power is supplied from a power supply device having a maximum suppliable power among a plurality of connected power supply devices. A power control device includes an acquisition unit and a power supply control unit. The acquisition unit 20A acquires suppliable power information of each of the plurality of power supply devices 12 connected via each of the plurality of connection terminals 22. The power supply control unit 20 </ b> B sets the voltage of the power supplied from the first power supply device as the power supply device 12 indicating the maximum suppliable power information to the first power supply device among the plurality of power supply devices 12. The voltage of the power supplied from at least one of the plurality of power supply devices 12 is controlled so as to be higher than the voltage of the power supplied from the second power supply device other than the power supply device. [Selection diagram] Fig. 1

Description

  Embodiments described herein relate generally to a power control apparatus and a program.

  2. Description of the Related Art A device that includes a plurality of connection terminals and that is supplied with power from a power supply device such as an AC adapter connected to each of the plurality of connection terminals is known. In addition, a technology is disclosed in which when a power supply apparatus is connected, a voltage to be transmitted is determined by executing negotiation with the power supply apparatus, and the connected power supply apparatus is requested to transmit the determined voltage.

Japanese Patent Laying-Open No. 2006-149045 Special table 2014-5286687 gazette Japanese Utility Model Publication No.59-138336 JP-A-2006-140211

  However, an error range is included in the voltage of the power supplied from the power supply apparatus. For this reason, even if it is a case where transmission of the same voltage is requested | required to several connected electric power feeders, a mutually different voltage may be supplied from these several electric power feeders. When different voltages are supplied, power is supplied from a power supply device that supplies a higher voltage due to electrical characteristics. For this reason, in some cases, power is supplied from a power supply device other than the power supply device having the highest suppliable power among the plurality of connected power supply devices.

  Thus, one of the problems of the present invention is to supply power from a power supply device having the maximum supply power among a plurality of connected power supply devices.

  The power control device according to the first aspect of the present invention includes: an acquisition unit that acquires suppliable power information of each of a plurality of power supply devices connected via each of a plurality of connection terminals; and a plurality of the power supply devices The voltage of the power supplied from the first power supply device as the power supply device indicating the maximum suppliable power information is supplied from a second power supply device other than the first power supply device among the plurality of power supply devices. A power supply control unit that controls a voltage of power supplied from at least one of the plurality of power supply apparatuses so as to be larger than a voltage of power. According to such a configuration, for example, power can be supplied from a power supply device having the maximum supply power among a plurality of connected power supply devices.

  Further, the program according to the second aspect of the present invention includes a step of obtaining suppliable power information of each of a plurality of power feeding devices connected via each of a plurality of connection terminals, and among the plurality of power feeding devices, The voltage of the power supplied from the first power supply device as the power supply device indicating the maximum suppliable power information is supplied from a second power supply device other than the first power supply device among the plurality of power supply devices. A program for causing a computer to execute a step of controlling a voltage of power supplied from at least one of the plurality of power supply devices so as to be larger than a voltage of power. According to such a configuration, for example, an effect similar to the effect exhibited by the power control device can be obtained.

  According to the above aspect of the present invention, it is possible to supply power from a power supply device having the maximum supply power among a plurality of connected power supply devices.

FIG. 1 is a schematic diagram illustrating an example of an information processing apparatus according to an embodiment. FIG. 2A is a schematic diagram illustrating an example of a terminal of the power supply apparatus according to the embodiment. FIG. 2B is a schematic diagram illustrating an example of the connection terminal according to the embodiment. FIG. 3A is a schematic diagram illustrating an example of a voltage of power supplied from the power supply apparatus according to the embodiment. FIG. 3B is a schematic diagram illustrating an example of a voltage of power supplied from the power supply apparatus according to the embodiment. FIG. 4 is a flowchart illustrating an example of an information processing procedure executed by the power control apparatus according to the embodiment. FIG. 5 is a schematic diagram illustrating an example of a relationship between a voltage and a current of the power supply apparatus according to the embodiment. FIG. 6 is a schematic diagram illustrating an example of a relationship between a voltage and a current of the power supply apparatus according to the embodiment. FIG. 7 is a schematic diagram illustrating an example of a relationship between a voltage and a current of the power feeding device according to the embodiment. FIG. 8 is a schematic diagram illustrating an example of a relationship between voltage and current of the power supply apparatus according to the embodiment. FIG. 9 is a schematic diagram illustrating an example of a relationship between a voltage and a current of the power feeding device according to the embodiment. FIG. 10 is a flowchart illustrating an example of an information processing procedure executed by the power control apparatus according to the embodiment. FIG. 11 is a schematic diagram illustrating an example of power supplied to the power supply target device of the embodiment.

  Hereinafter, exemplary embodiments of the present disclosure will be disclosed. The configuration of the embodiment shown below, and the operations and effects brought about by the configuration are examples.

  FIG. 1 is a schematic diagram illustrating an example of an information processing apparatus 10 according to the present embodiment.

  The information processing apparatus 10 is an electronic device that operates when supplied with power. The information processing apparatus 10 is, for example, a notebook personal computer or a tablet terminal.

  The information processing device 10 includes a power control device 20, a plurality of connection terminals 22, a switching unit 24, a power supply circuit 26, a CPU (Central Processing Unit) 28, a voltage control unit 30, and a peripheral circuit 32. Prepare.

  The connection terminal 22 is a connector to which power is supplied from the power supply device 12. The information processing apparatus 10 is supplied with power from the power supply apparatus 12 connected to the connection terminal 22.

  In the present embodiment, the information processing apparatus 10 will be described as an example in which the information processing apparatus 10 includes two connection terminals 22 (a connection terminal 22A and a connection terminal 22B). That is, in the information processing apparatus 10, the power feeding apparatus 12 is connected to each of the two connection terminals 22. The information processing apparatus 10 may be configured to include a plurality of connection terminals 22 and may be configured to include three or more connection terminals 22. That is, the information processing apparatus 10 may have a configuration in which three or more power supply apparatuses 12 are connected.

  The power supply apparatus 12 is an apparatus that supplies power to the information processing apparatus 10. The power supply device 12 includes, for example, a USB cable corresponding to a USB PD (Universal Serial Bus Power Delivery) standard and an AC adapter that supplies power via a terminal 14 (USB terminal), a cable and a terminal compatible with the EIAJ polarity unified plug standard An AC adapter that supplies power via the power supply 14. The power supply device 12 is not limited to an AC adapter, and may be a DC adapter.

  FIG. 2A is a schematic diagram illustrating an example of the terminal 14 of the power supply device 12 corresponding to the USB PD standard. In FIG. 2A, as an example of the terminal 14, USB Implementers Forum, Inc. A USB Type-C connector promoted by (USB-IF) is shown. Note that the terminal 14 is not limited to a USB Type-C connector. For example, the terminal 14 may be a USB Type-A connector.

  Returning to FIG. The power feeding device 12 is connected to the information processing device 10 by inserting the terminal 14 of the cable of the power feeding device 12 into the connection terminal 22 of the information processing device 10.

  FIG. 2B is a schematic diagram illustrating an example of the connection terminal 22 provided in the information processing apparatus 10. FIG. 2B shows a USB Type-C connector corresponding to the USB PD standard as an example of the connection terminal 22. Note that the connection terminal 22 is not limited to a USB Type-C connector. For example, the connection terminal 22 may be a USB Type-B connector.

  In the present embodiment, a case where all of the plurality of power supply apparatuses 12 connected to the information processing apparatus 10 are AC adapters compatible with the USB PD 3.0 standard will be described as an example. In the present embodiment, a case where both the terminal 14 of the cable of the power supply apparatus 12 and the connection terminal 22 of the information processing apparatus 10 are USB Type-C terminals will be described as an example.

  Note that the type of the power feeding device 12 connected to the information processing device 10 is not limited. That is, some of the plurality of power supply apparatuses 12 connected to the information processing apparatus 10 may be AC adapters compatible with the USB PD standard, or all of the plurality of power supply apparatuses 12 support the USB PD standard. An AC adapter may be used. Further, all of the plurality of power supply apparatuses 12 connected to the information processing apparatus 10 may be AC adapters that are not compatible with the USB PD standard.

  Returning to FIG. In the present embodiment, a configuration in which a power feeding device 12A and a power feeding device 12B are connected to the information processing device 10 as the power feeding device 12 will be described as an example. Specifically, a configuration in which the power supply device 12A is connected to the connection terminal 22A of the information processing device 10 and the power supply device 12B is connected to the connection terminal 22B of the information processing device 10 will be described as an example. Note that when the power feeding device 12A and the power feeding device 12B are collectively described, they are simply referred to as the power feeding device 12.

  The switching unit 24 has a plurality of diodes corresponding to each of the plurality of connection terminals 22 provided in the information processing apparatus 10. As described above, in the present embodiment, the information processing apparatus 10 includes two connection terminals 22 (a connection terminal 22A and a connection terminal 22B). For this reason, the case where the switching unit 24 includes a diode 24A and a diode 24B as diodes will be described as an example.

  The anode of the diode 24A is connected to the connection terminal 22A. The cathode of the diode 24A is connected to the power supply circuit 26 via the output terminal 24C. For this reason, the diode 24A is configured to be able to supply the power supplied from the power feeding device 12A connected via the connection terminal 22A to the power supply circuit 26 via the output end 24C.

  The anode of the diode 24B is connected to the connection terminal 22B. The cathode of the diode 24B is connected to the power supply circuit 26 via the output terminal 24C. For this reason, the diode 24B is configured to be able to supply the power supplied from the power feeding device 12B connected via the connection terminal 22B to the power supply circuit 26 via the same output terminal 24C as the diode 24A.

  As described above, the switching unit 24 is configured to supply the power output from the diode 24A and the diode 24B to the power supply circuit 26 via the same output terminal 24C. For this reason, when the voltage of the power supplied from the power supply apparatus 12A to the diode 24A and the voltage of the power supplied from the power supply apparatus 12B to the diode 24B are the same value (voltage value), the switching unit 24 Then, the power supplied from both power supply apparatuses 12 is supplied to the power supply circuit 26. When the voltage supplied from the power supply device 12A to the diode 24A is different from the voltage supplied from the power supply device 12B to the diode 24B, the switching unit 24 supplies the voltage from the power supply device 12 having a large voltage. The supplied electric power is supplied to the power supply circuit 26.

  For this reason, the switching unit 24 is configured to be able to supply power having the highest voltage to the power supply circuit 26 among the power supplied to each of the diode 24A and the diode 24B. In other words, the switching unit 24 is configured to be able to supply the power supplied from the power supply device 12 that supplies the largest voltage among the power supply devices 12 connected to the plurality of connection terminals 22 to the power supply circuit 26. . In addition, since the switching unit 24 has the above-described configuration, even when the magnitude relationship between the voltages of the power supplied from the power feeding device 12A and the power feeding device 12B varies, the power feeding device having a large voltage without interruption. 12 can supply power to the power supply circuit 26.

  The power supply circuit 26 supplies the power supplied from the switching unit 24 to the power supply target device.

  The power supply target device is an electronic device mounted on the information processing apparatus 10 to which power supplied from the power supply device 12 is supplied. In other words, the power supply target device is an electronic device that operates with the power supplied from the power supply device 12.

  The power supply target device is, for example, the CPU 28. Note that the power supply target device may further include an electronic device other than the CPU 28.

  Further, the power supply circuit 26 may further have a function of monitoring whether the voltage supplied to the power supply target device is less than the minimum voltage at which the power supply target device can operate.

  The CPU 28 controls the information processing apparatus 10. For example, the CPU 28 executes a predetermined process by executing a program installed in advance. The information processing apparatus 10 may be configured to include a GPU (Graphics Processing Unit) instead of the CPU 28.

  The voltage control unit 30 communicates with the power supply apparatus 12 connected to the information processing apparatus 10 and controls the voltage of power supplied from the power supply apparatus 12. The voltage control unit 30 controls the voltage of power supplied from the power supply apparatus 12 to the information processing apparatus 10 by requesting the connected power supply apparatus 12 to transmit a specific voltage.

  The voltage control unit 30 is provided for each connection terminal 22. As described above, in the present embodiment, the information processing apparatus 10 includes two connection terminals 22 (a connection terminal 22A and a connection terminal 22B). Therefore, in the present embodiment, the information processing apparatus 10 includes a voltage control unit 30A and a voltage control unit 30B as the voltage control unit 30. The voltage control unit 30A communicates with the power feeding device 12A via the connection terminal 22A and controls the voltage of power supplied from the power feeding device 12A. The voltage control unit 30B communicates with the power supply apparatus 12B via the connection terminal 22B, and controls the voltage of power supplied from the power supply apparatus 12B. When the voltage control unit 30A and the voltage control unit 30B are collectively described, they are simply referred to as the voltage control unit 30.

  Further, the voltage control unit 30 specifies the suppliable power information of the power feeding device 12 connected via the connection terminal 22.

  The supplyable power information is information indicating the supplyable power of the power supply apparatus 12. The voltage control unit 30 specifies power supply power information of the power supply device 12 by communicating with the power supply device 12 connected via the connection terminal 22 and the terminal 14.

  For example, when the terminal 14 of the power supply apparatus 12 is connected to the connection terminal 22, the voltage control unit 30 transmits and receives a BMC (Bi-phase Marked Coding) message to and from the power supply apparatus 12 according to the USB PD standard, and negotiates. Execute. The negotiation may also be referred to as power negotiation. By this negotiation, the voltage control unit 30 determines the initial value of the voltage and current of the power supplied from the connected power supply device 12. Then, the voltage control unit 30 specifies the power represented by the product of the determined voltage and current as the suppliable power information of the power feeding device 12.

  The voltage control unit 30 stores information indicating the voltage determined as the initial value in a memory such as a RAM (Random Access Memory) (not shown). Further, the voltage control unit 30 outputs the specified suppliable power information to the power control device 20 via a bus such as I2C (Inter-Integrated Circuit).

  The above processing is executed by each of the voltage control unit 30A and the voltage control unit 30B. For this reason, the voltage as the initial value for the power feeding device 12A is stored in the voltage control unit 30A. Further, the voltage control unit 30 </ b> A outputs the suppliable power information of the power feeding device 12 </ b> A to the power control device 20. Similarly, the voltage control unit 30B stores a voltage as an initial value for the power feeding device 12B. Further, the voltage control unit 30 </ b> B outputs the suppliable power information of the power feeding device 12 </ b> B to the power control device 20.

  The peripheral circuit 32 compares the voltage of the power supplied from each of the plurality of power supply apparatuses 12 to the switching unit 24 and outputs the comparison result to the power control apparatus 20.

  Specifically, the peripheral circuit 32 is connected to each of a bus connecting the connection terminal 22A and the anode of the diode 24A, and a bus connecting the anode of the connection terminal 22B and the diode 24B. The peripheral circuit 32 measures the voltages flowing in these buses, thereby obtaining each of the voltage of power supplied from the power supply device 12A to the diode 24A and the voltage of power supplied from the power supply device 12B to the diode 24B. To detect. Then, the peripheral circuit 32 outputs a comparison result obtained by comparing the detection results to the power control device 20.

  For example, the peripheral circuit 32 is configured by a circuit that compares and inverts the voltage of power supplied from the power supply apparatus 12A to the switching unit 24 and the voltage of power supplied from the power supply apparatus 12B to the switching unit 24 using a comparator. The

  The power control device 20 controls the voltage of power supplied from each of the plurality of power feeding devices 12 connected to the information processing device 10 to the information processing device 10. The power control apparatus 20 is, for example, an embedded controller (EC: Embedded Controller).

  The power control device 20 includes an acquisition unit 20A and a power supply control unit 20B. Part or all of the acquisition unit 20A and the power supply control unit 20B may be realized by, for example, causing a processing device such as a CPU to execute a program, that is, by software, or by hardware such as an IC (Integrated Circuit). You may implement | achieve and it may implement | achieve combining software and hardware.

  The acquisition unit 20 </ b> A acquires the suppliable power information of each of the plurality of power feeding apparatuses 12 connected via each of the plurality of connection terminals 22. In the present embodiment, the acquisition unit 20A acquires the suppliable power information of the power feeding apparatus 12A from the voltage control unit 30A. In addition, the acquisition unit 20A acquires the suppliable power information of the power feeding device 12B from the voltage control unit 30B.

  Note that the acquisition unit 20A may acquire the suppliable power information of each of the power feeding device 12A and the power feeding device 12B by another method. For example, the acquiring unit 20A may acquire suppliable power information from information input by an operation instruction from the user. In this case, the user may input the suppliable power information of the power supply apparatus 12 connected to the information processing apparatus 10 using an input device such as a keyboard. And the power control apparatus 20 should just acquire the suppliable electric power information of the electric power feeder 12 by receiving the input suppliable electric power information from an input device. In addition, the acquisition unit 20A may acquire the suppliable power information of the power feeding apparatus 12 by reading the suppliable power information acquired by a method other than the above.

  The power supply control unit 20 </ b> B controls the voltage of power supplied from at least one of the plurality of power supply devices 12 according to each suppliable power information of the plurality of power supply devices 12 connected to the information processing device 10. .

  In the present embodiment, the power supply control unit 20B has a plurality of power supply devices in which the voltage of power supplied from the first power supply device as the power supply device 12 indicating the maximum suppliable power information among the plurality of power supply devices 12 is the plurality of power supply devices. The voltage of the power supplied from at least one of the plurality of power supply apparatuses 12 is controlled so as to be larger than the voltage of the power supplied from the second power supply apparatus other than the first power supply apparatus.

  First, the power supply control unit 20 </ b> B identifies the power supply device 12 indicating the maximum suppliable power information among the plurality of power supply devices 12 connected to the information processing device 10 as the first power supply device. In addition, the power supply control unit 20 </ b> B identifies a power supply device 12 other than the first power supply device among the plurality of power supply devices 12 connected to the information processing device 10 as the second power supply device.

  As described above, in the present embodiment, it is assumed that the two power supply devices 12, the power supply device 12 </ b> A and the power supply device 12 </ b> B, are connected to the information processing device 10. For this reason, in the present embodiment, the power feeding control unit 20B identifies the power feeding device 12 having the larger suppliable power indicated by the suppliable power information among the power feeding device 12A and the power feeding device 12B as the first power feeding device. To do. In addition, the power feeding control unit 20B identifies the power feeding device 12 having the smaller suppliable power indicated by the suppliable power information among the power feeding device 12A and the power feeding device 12B as the second power feeding device. In the following description, the power supply device 12 specified as the first power supply device among the plurality of power supply devices 12 may be simply referred to as the first power supply device. Similarly, the power feeding device 12 specified as the second power feeding device among the plurality of power feeding devices 12 may be simply referred to as a second power feeding device.

  The power supply control unit 20B supplies power from at least one of the power supply device 12A and the power supply device 12B so that the voltage of power supplied from the first power supply device is larger than the voltage of power supplied from the second power supply device. To control the voltage of the power.

  Control of the voltage of the power supplied from each of the power feeding device 12A and the power feeding device 12B may be executed by controlling the voltage control unit 30A.

  Specifically, the power supply control unit 20B transmits instruction information to at least one of the voltage control unit 30A and the voltage control unit 30B. The instruction information includes a voltage value of a voltage for requesting the power feeding device 12 to transmit power. The voltage control unit 30 that has received the instruction information from the power supply control unit 20B requests the connected power supply apparatus 12 (the power supply apparatus 12A and the power supply apparatus 12B) to transmit the voltage having the voltage value included in the received instruction information. With this process, the power supply apparatus 12 (the power supply apparatus 12A and the power supply apparatus 12B) supplies the information processing apparatus 10 with the voltage having the voltage value requested by the control of the power supply control unit 20B.

  In addition, the power supply control unit 20B includes a plurality of power supply devices connected to the information processing device 10 such that the voltage of power supplied from the first power supply device is larger than the voltage of power supplied from the second power supply device. What is necessary is just to control the voltage of the electric power supplied from at least 1 of 12.

  For example, the power supply control unit 20B reduces the voltage of the power supplied from the second power supply device, so that the voltage of the power supplied from the first power supply device is larger than the voltage of the power supplied from the second power supply device. Control to be. That is, the power supply control unit 20B sets the voltage of the power supplied from the second power supply device so that the voltage of the power supplied from the second power supply device is less than the voltage of the power supplied from the first power supply device. Control.

  In addition, for example, the power supply control unit 20B increases the voltage of the power supplied from the first power supply device, so that the voltage of the power supplied from the second power supply device becomes the voltage of the power supplied from the first power supply device. You may control so that it may become less. Further, the power supply control unit 20B is supplied from the second power supply device by combining the increase in the voltage of the power supplied from the first power supply device and the decrease in the voltage of the power supplied from the second power supply device. It may be controlled so that the voltage of the power to be less than the voltage of the power supplied from the first power supply device.

  In the present embodiment, the power supply control unit 20B reduces the voltage of the power supplied from the second power supply device, so that the power voltage supplied from the first power supply device is supplied from the second power supply device. A mode in which the voltage is controlled to be larger than the voltage will be described as an example.

  It is preferable that the power supply control unit 20B controls the voltage of the power supplied from the second power supply device so that the power supply control unit 20B gradually decreases toward a voltage lower than the voltage of the power supplied from the first power supply device. By reducing the voltage of the electric power supplied from the second power supply device in a stepwise manner, it is possible to suppress errors that occur due to a sudden drop in the voltage of the electric power supplied from the second power supply device.

  In addition, what is necessary is just to predetermine the voltage value for every step to reduce. For example, it is assumed that the power supply control unit 20B decreases the voltage in accordance with the USB PD3.0 or later standard. In this case, the power supply control unit 20B may control the voltage control unit so that the voltage of the power supplied from the second power supply device is decreased stepwise by 20 mV.

  For example, it is assumed that the power feeding device 12A is specified as the first power feeding device and the power feeding device 12B is specified as the second power feeding device. In this case, the power supply control unit 20B provides instruction information indicating that the voltage of the power supplied from the power supply device 12B, which is the second power supply device, is reduced by 20 mV from the currently supplied voltage via the I2C bus or the like. Output to the voltage control unit 30B. Then, the power supply control unit 20B uses the comparison result of the power voltages supplied from the power supply device 12A and the power supply device 12B to the switching unit 24 received from the peripheral circuit 32, and specifies the power supply specified as the second power supply device. Until it is determined that the voltage of power supplied from the device 12B to the diode 24B of the switching unit 24 is lower than the voltage of power supplied from the power supply device 12A specified as the first power feeding device to the diode 24A of the switching unit 24, The output of the instruction information to the control unit 30B may be continued.

  The voltage of the power supplied from the second power supply device may be less than the voltage of the power supplied from the first power supply device, but is preferably a voltage exceeding the predetermined minimum operating voltage. The minimum operating voltage may be a lower limit value of a voltage necessary for the power supply target device to operate. That is, it is preferable that the voltage of the power supplied from the second power supply device is less than the voltage of the power supplied from the first power supply device and exceeds the minimum operating voltage of the CPU 28.

  The voltage of the power supplied from the second power feeding device may be 0V. That is, the power supply control unit 20B may control the voltage control unit 30 that communicates with the second power supply device so that the voltage of the power supplied from the second power supply device becomes 0V. However, in this case, if power supply from the first power supply apparatus to the information processing apparatus 10 is interrupted due to removal of the first power supply apparatus or the like, power is not supplied to the information processing apparatus 10. For this reason, the power supply control unit 20B has a voltage of power supplied from the second power supply device so that the voltage is less than the voltage of power supplied from the first power supply device and exceeds the minimum operating voltage of the CPU 28. Is preferably controlled.

  Here, the voltage of the power supplied from the power supply device 12 includes a predetermined error range. That is, even when the voltage control unit 30 requests the power supply apparatus 12 to transmit a voltage having a predetermined voltage value, the voltage of the power actually supplied from the power supply apparatus 12 is ± several% with respect to the predetermined voltage value. The voltage may be in the error range. For example, the allowable value of the error range is defined in the USB PD standard.

  Therefore, the power supply control unit 20B includes a plurality of power supply devices 12 so that the minimum value of the voltage of power supplied from the first power supply device is larger than the maximum value of the voltage of power supplied from the second power supply device. It is preferable to control the voltage of power supplied from at least one. That is, the power supply control unit 20B determines that the minimum value (minimum voltage) including the error range of the power voltage supplied from the first power supply device is the maximum value including the error range of the power voltage supplied from the second power supply device. It is preferable to control the voltage of power supplied from at least one of the plurality of power feeding devices 12 so as to be greater than (maximum voltage).

  In other words, in the power supply control unit 20B, the difference between the voltage requesting power transmission to the first power supply device and the voltage requesting power transmission to the second power supply device is a value exceeding the error range. As described above, it is preferable to control the voltage for requesting the power feeding device 12 to transmit power.

  FIG. 3A illustrates an example of voltage of power supplied from each of the power feeding device 12A and the power feeding device 12B when each of the power feeding device 12A and the power feeding device 12B is connected to the connection terminal 22 (connection terminal 22A, connection terminal 22B). It is a schematic diagram which shows. In FIG. 3A, each of a power supply device 12A having a suppliable power of 100 W and a power supply device 12B having a suppliable power of 60 W is connected to each of the connection terminal 22A and the connection terminal 22B of the information processing device 10. Showed the condition.

  For example, the power supply device 12A and the power supply device 12B are connected, and each of the voltage control unit 30A and the voltage control unit 30B is set to 20V as an initial value of a voltage for requesting power transmission to each of the power supply device 12A and the power supply device 12B. Assume that you have decided.

  In this case, the voltage control unit 30A requests the power feeding apparatus 12A to transmit a voltage of 20V. Then, for example, a voltage in the voltage range A1 of 20 V ± 1 V (19 V to 21 V) including the error range is supplied from the power supply apparatus 12A to the information processing apparatus 10.

  Similarly, the voltage control unit 30B requests the power feeding device 12B to transmit a voltage of 20V. Then, for example, a voltage in a voltage range B1 of 20 V ± 1 V (19 V to 21 V) including an error range is supplied from the power supply apparatus 12B to the information processing apparatus 10.

  Then, the power supply control unit 20B specifies the power supply device 12A as the first power supply device because the power that can be supplied from the power supply device 12A is 100W and the power that can be supplied from the power supply device 12B is 60W. It specifies as a 2nd electric power feeder. In this case, the power supply control unit 20B determines that the minimum value of the voltage of the power supplied from the power supply device 12A specified as the first power supply device is the maximum of the voltage of the power supplied from the power supply device 12B specified as the second power supply device. The voltage of the power supplied from the power feeding device 12B is reduced so as to be larger than the value.

  FIG. 3B illustrates the power supply device 12A and the power supply device 12B when the power supply control unit 20B controls the voltage of the power supplied from the power supply device 12B to be less than the voltage of the power supplied from the power supply device 12A. It is a schematic diagram which shows an example of the voltage of the electric power supplied from each.

  According to the error range, the power supply control unit 20B is configured so that the maximum value of the voltage range of the power supplied from the power supply device 12B is less than the minimum value 19V of the voltage range A1 (19V to 20B) of the power supply device 12A. A voltage value (17V in FIG. 3B) for requesting power transmission to the power feeding device 12B is set. At this time, the power supply control unit 20B sets a voltage value that satisfies the condition and exceeds the minimum operating voltage (for example, 10 V) of the CPU 28. Then, the power supply control unit 20B transmits the instruction information to the voltage control unit 30B so as to request the power supply device 12B to transmit the voltage of 17V. The voltage control unit 30B requests the power feeding device 12B to transmit a voltage of 17V.

  Then, for example, a voltage in a voltage range B2 of 16.2 V to 17.9 V including an error range is supplied from the power supply apparatus 12B to the information processing apparatus 10. Therefore, in the information processing apparatus 10, the maximum value of the voltage range B2 (17.9V in FIG. 3B) is less than the minimum value (19V in FIG. 3B) of the voltage range A1 of the power supplied from the power supply apparatus 12A. The voltage in the range is supplied from the power feeding device 12B.

  In this way, the power supply control unit 20B allows the second power supply device such that the minimum value of the voltage of power supplied from the first power supply device is larger than the maximum value of the voltage of power supplied from the second power supply device. It is preferable to control the voltage of the power supplied from.

  Returning to FIG. By controlling the voltage of power supplied from the power supply device 12 (power supply device 12A, power supply device 12B) by the power supply control unit 20B, the power supply control unit 20B is connected to the power supply device 12 specified as the first power supply device in the switching unit 24. The diode (for example, the diode 24A) is supplied with power having a voltage higher than that of the diode (for example, the diode 24B) connected to the power supply apparatus 12 specified as the second power supply apparatus.

  As described above, the switching unit 24 including the diode 24A and the diode 24B is configured to be able to supply power having the highest voltage to the power supply circuit 26 among the power supplied to each of the diode 24A and the diode 24B. ing.

  For this reason, the CPU 28 to which power is supplied from the power supply circuit 26 is supplied from the first power supply device that is the power supply device 12 having the maximum supply power among the plurality of power supply devices 12 connected to the information processing device 10. Power is supplied.

  For this reason, in this Embodiment, compared with the case where the control of the said voltage is not performed with respect to electric power supply object apparatuses, such as CPU28, it becomes possible to supply higher electric power.

  Note that the power supply control unit 20B starts from at least one of the plurality of power supply devices 12 so that the voltage of power supplied from the first power supply device is larger than the voltage of power supplied from the second power supply device. It is preferable to change the performance of the power supply target device after controlling the voltage of the supplied power.

  The performance of the power supply target device is represented by, for example, the operating frequency (clock frequency) of the CPU 28, the FSB clock, and the like. Changing the performance means changing the operating frequency, the FSB clock, or the like.

  For example, the power supply control unit 20B improves the performance of the CPU 28 by increasing the operating frequency of the CPU 28, which is the power supply target device, for the increased power. The increased power indicates a difference between the first power consumption and the second power consumption. The first power consumption is a steady state of the CPU 28 before the voltage is controlled by the power supply control unit 20B so that the voltage of the power supplied from the first power supply device is larger than the voltage of the power supplied from the second power supply device. Indicates the power consumption of the state. The steady state may be determined in advance. For example, the steady state indicates a state in which the operation is performed with a predetermined power consumption (for example, 40 W). Further, the predetermined power consumption in the steady state is a standard power assumed to be supplied to the information processing apparatus 10. The second power consumption indicates the suppliable power of the power supply apparatus 12 that indicates the largest suppliable power among the plurality of power supply apparatuses 12 connected to the information processing apparatus 10.

  The improvement of the performance of the CPU 28 may be performed by a known method. For example, the power supply control unit 20B increases the operating frequency of the CPU 28 by rewriting the turbo parameters of the CPU 28 using a PECI (Platform Environment Control Interface) single wire interface.

  Note that when the power supply control unit 20B controls the power voltage supplied from the first power supply device to be larger than the voltage of power supplied from the second power supply device, the power supply from the first power supply device is performed. May be blocked.

  The case where the power supply from the first power supply device is interrupted means that the terminal 14 of the power supply device 12 specified as the first power supply device is removed from the connection terminal 22 of the information processing device 10 or the first power supply device. In the case where the remaining amount of power stored in the power supply becomes zero, or in the case where the power supplied from the commercial power source or the like to the first power supply device is cut off.

  The power supply control unit 20 </ b> B may determine the interruption of the power supply from the first power supply device using the comparison result received from the peripheral circuit 32. For example, it is assumed that the power feeding device 12A is specified as the first power feeding device and the power feeding device 12B is specified as the second power feeding device. In this case, in the power supply control unit 20B, the comparison result received from the peripheral circuit 32 indicates that the voltage of power supplied from the power supply device 12A to the switching unit 24 is higher than the voltage of power supplied from the power supply device 12B to the switching unit 24. What is necessary is just to judge interruption | blocking of the electric power supply from 12 A of electric power feeders, when it switches from a state to a low state. That is, the power supply control unit 20B may determine that the power supply from the first power supply device is interrupted when detecting the inversion of the comparator of the peripheral circuit 32.

  Then, when the power supply from the first power supply device is interrupted, the power supply control unit 20B controls the voltage of the power supplied from the second power supply device to be an initial value.

  As described above, the initial value is the initial voltage determined by the voltage control unit 30 that communicates with the power supply device 12 when the power supply device 12 specified as the second power supply device is connected to the information processing device 10. Value. By controlling the voltage of the power supplied from the second power supply device to be an initial value, even if the power supply from the first power supply device is interrupted, the power supply target device such as the CPU 28 Thus, it is possible to continue the supply of power that enables these power supply target devices to operate.

  Here, before the power supply from the first power supply apparatus is interrupted, the power supply control unit 20B improves the performance of the CPU 28 by increasing the operating frequency of the CPU 28 that is the power supply target device. There is. In this case, if the power supply from the first power supply device is interrupted, it is difficult for the second power supply device that can supply less power than the first power supply device to supply power that can maintain the performance of the CPU 28. .

  Therefore, when the power supply from the first power supply device is interrupted, the power supply control unit 20B controls the CPU 28 so that the power consumption is equal to or less than the first threshold, and the voltage of the power supplied from the second power supply device. Is preferably controlled to an initial value. The power supply control unit 20B preferably controls the CPU 28 so that the power consumption exceeds the first threshold after performing the control.

  The first threshold may be the power consumption of the CPU 28 when operating with the performance before the performance is improved by the process of the power supply control unit 20B. For example, the first threshold may be the power consumption of the CPU 28 in the steady state.

  The first threshold may be power consumption when the CPU 28 is operated at the lowest operating frequency. In this case, the power supply control unit 20B asserts an instruction signal for operating the CPU 28 at the lowest operating frequency to the CPU 28, thereby controlling the CPU 28 so that the power consumption is equal to or less than the first threshold value. The power supply control unit 20B may execute the above-described control by acquiring information indicating the lowest operating frequency, which is predetermined in the standard of the CPU 28 or the like.

  At this time, the power supply control unit 20B rewrites the turbo parameter of the CPU 28 so that the operating frequency of the CPU 28 is returned to the operating frequency before the change (for example, the operating frequency in the steady state).

  Then, the power feeding control unit 20B outputs instruction information indicating that the voltage of the power supplied from the second power feeding device is an initial value to the voltage control unit 30 communicating with the second power feeding device. The voltage control unit 30 that has received the instruction information requests the second power feeding device to transmit the initial voltage stored when the second power feeding device is connected. For this reason, the second power supply apparatus starts supplying the voltage indicated by the request received from the voltage control unit 30 when connected to the information processing apparatus 10.

  In this way, when the power supply from the first power feeding device is interrupted, the voltage control unit 30 does not negotiate again with the second power feeding device, but for the second power feeding device during the previous negotiation. The second power feeding device is requested to transmit the determined voltage of the initial value.

  For this reason, it can suppress that the electric power supplied from a 2nd electric power feeder is reset and the electric power supply from a 2nd electric power feeder is interrupted when the voltage control part 30 performs negotiation again. .

  When the voltage control unit 30 requests the power feeding device 12 to transmit the initial voltage, the voltage control unit 30 transmits a completion signal to the power control device 20. The power supply control unit 20B that has received the completion signal ends assertion of the instruction signal for operating at the lowest operating frequency to the CPU. Then, the power supply control unit 20B controls the CPU 28 so that the power consumption exceeds the first threshold value.

  As described above, when the power supply from the first power supply device is interrupted, the power supply control unit 20B sets the power consumption of the CPU 28 to the first threshold value or less and sets the voltage of the power supplied from the second power supply device to the initial value. Then, the power consumption of the CPU 28 is controlled to exceed the first threshold.

  For this reason, the power supply control unit 20B can suppress malfunction of the CPU 28 and load on the CPU 28 due to fluctuations in the supplied power.

  Next, an example of an information processing procedure executed by the power control apparatus 20 according to the present embodiment will be described.

  FIG. 4 is a flowchart illustrating an example of an information processing procedure executed by the power control apparatus 20.

  First, the power control device 20 detects the connection of the plurality of power feeding devices 12 (step S100). The power control device 20 detects the connection of the plurality of power supply devices 12 by specifying that the voltage control unit 30 detects the connection of the plurality of power supply devices 12. In this flowchart, description will be made on the assumption that two power supply apparatuses 12 (power supply apparatus 12A and power supply apparatus 12B) are connected to the information processing apparatus 10.

  Next, the acquiring unit 20A acquires the suppliable power information of each of the two power feeding devices 12 whose connection is detected in step S100 (step S100). The acquiring unit 20 </ b> A acquires the suppliable power information of the power feeding device 12 specified by the negotiation from each of the plurality of voltage control units 30. Specifically, the acquiring unit 20A acquires the suppliable power information of the power feeding device 12A and the suppliable power information of the power feeding device 12B.

  Next, the acquiring unit 20A determines whether the suppliable power indicated by the suppliable power information of each of the two power feeding apparatuses 12 acquired in step S102 is the same (step S104). In FIG. 4, Wa indicates the suppliable power of the power feeding device 12 </ b> A, and Wb indicates the suppliable power of the power feeding device 12 </ b> B.

  If it is determined that they are the same (step S104: Yes), this routine is terminated.

  Specifically, the case where it is determined in step S104 that they are the same is the relationship between the voltage and current as initial values determined by the negotiation of each of the power feeding device 12A and the power feeding device 12B is shown in FIG. This is the case. FIG. 5 is a schematic diagram illustrating an example of the relationship between the voltage and current as initial values of each of the power feeding device 12A and the power feeding device 12B. In FIG. 5, Va indicates a voltage determined as an initial value of the power feeding device 12A. Ib indicates a current determined as an initial value of the power feeding device 12A. In FIG. 5, Vb indicates a voltage determined as an initial value of the power feeding device 12B. Ib indicates a current determined as an initial value of the power feeding device 12B. As described above, the suppliable power is represented by the product of current and voltage.

  As illustrated in FIG. 5, when the power that can be supplied by the power feeding device 12A and the power feeding device 12B are the same, the power feeding control unit 20B does not perform voltage control and ends this routine.

  Returning to FIG. On the other hand, if it is determined in step S104 that the suppliable power is different (step S104: No), the process proceeds to step S106.

  In step S106, the power supply control unit 20B determines whether the suppliable power Wa of the power supply apparatus 12A is larger than the suppliable power Wb of the power supply apparatus 12B (step S106).

  If an affirmative determination is made in step S106 (step S106: Yes), the process proceeds to step S108. In step S108, the power feeding control unit 20B identifies the power feeding device 12A as the first power feeding device (step S108). At this time, the power supply control unit 20B identifies the power supply device 12B as the second power supply device.

  Next, in step S108, the power supply control unit 20B determines whether the voltage supplied from the power supply device 12A specified as the first power supply device is larger than the voltage supplied from the power supply device 12B specified as the second power supply device. It is determined whether or not (step S110). The power supply control unit 20B uses the comparison result between the voltage supplied from the power supply device 12A to the diode 24A and the voltage supplied from the power supply device 12B to the diode 24B, received from the peripheral circuit 32, in step S110. Judgment may be made.

  When the voltage supplied from the power supply device 12A specified as the first power supply device is larger than the voltage supplied from the power supply device 12B specified as the second power supply device (step S110: Yes), this routine ends.

  Specifically, in the case of making an affirmative determination in step S110, the relationship between the voltage and current as the initial values determined by negotiation of each of the power feeding device 12A and the power feeding device 12B is the relationship shown in FIG. Is the case. FIG. 6 is a schematic diagram illustrating an example of a relationship between voltage and current as initial values of each of the power feeding device 12A and the power feeding device 12B. In FIG. 6, the definitions of Va, Vb, Ia, and Ib are the same as those in FIG.

  As shown in FIG. 6, the power that can be supplied by the power feeding device 12A is larger than that of the power feeding device 12B, and the voltage supplied from the power feeding device 12A to the switching unit 24 is supplied from the power feeding device 12B to the switching unit 24. When the voltage is larger than the voltage, the power feeding control unit 20B does not execute the voltage control and ends this routine.

  Returning to FIG. If a negative determination is made in step S110 (step S110: No), the process proceeds to step S112.

  Specifically, the case of negative determination in step S110 is the relationship between the voltage and current as the initial values determined by the negotiation of each of the power feeding device 12A and the power feeding device 12B as shown in FIG. Is the case. FIG. 7 is a schematic diagram illustrating an example of a relationship between voltage and current as initial values of each of the power feeding device 12A and the power feeding device 12B. In FIG. 7, the definitions of Va, Vb, Ia, and Ib are the same as those in FIG.

  As shown in FIG. 7, the power that can be supplied from the power supply device 12A is larger than that of the power supply device 12B, and the voltage supplied from the power supply device 12A to the switching unit 24 is supplied from the power supply device 12B to the switching unit 24. If it is equal to or lower than the voltage, the process proceeds to step S112 (see FIG. 4).

  Returning to FIG. In step S112, the power supply control unit 20B controls the voltage of the power supplied from the power supply apparatus 12B so as to be less than the voltage of the power supplied from the power supply apparatus 12A (step S112). For example, the power supply control unit 20B displays the instruction information indicating that the voltage of the power supplied from the power supply device 12B, which is the second power supply device, is lowered by 20 mV from the currently supplied voltage via the I2C bus or the like. Output to the control unit 30B. The voltage control unit 30B requests the power feeding device 12B to transmit power having a voltage 20 mV lower than the currently supplied voltage. Therefore, the power feeding device 12B supplies a voltage that is 20 mV lower than the currently supplied voltage to the diode 24B via the terminal 14B and the connection terminal 22B.

  Next, the power supply control unit 20B determines whether or not the voltage of power supplied from the power supply device 12B to the diode 24B is less than the voltage of power supplied from the power supply device 12A to the diode 24A (step S114). . The power feeding control unit 20B uses the comparison result between the voltage supplied from the power feeding device 12A to the diode 24A and the voltage supplied from the power feeding device 12B to the diode 24B, received from the peripheral circuit 32, in step S114. Judgment may be made. In step S114, it is determined whether or not the voltage of power supplied from the power supply apparatus 12B to the diode 24B is less than a subtraction result obtained by subtracting the predetermined value X from the voltage of power supplied from the power supply apparatus 12A to the diode 24A. You may judge. The predetermined value X may be a value that gives a certain margin to the voltage difference between the voltage of the power supplied from the power feeding device 12A and the voltage of the power supplied from the power feeding device 12B. For example, the predetermined value X may be a value that exceeds the error range described above.

  If a negative determination is made in step S114 (step S114: No), the process returns to step S112. On the other hand, if an affirmative determination is made in step S114 (step S114: Yes), the process proceeds to step S116.

  When the voltage of the power supplied from the power feeding device 12B to the diode 24B becomes less than the voltage of the power supplied from the power feeding device 12A to the diode 24A by the processing of step S112 to step S114, the power supplied from the power feeding device 12A is changed. Then, it is supplied to the CPU 28 via the switching unit 24 and the power supply circuit 26 (step S116).

  Next, the power supply control unit 20B improves the performance of the CPU 28 by the amount of increased electric power supplied from the steady state by the processing of step S112 to step S114 (step S118). In step S <b> 118, the power supply control unit 20 </ b> B improves the performance of the CPU 28 by increasing the operating frequency of the CPU 28 by rewriting the turbo parameter of the CPU 28. Then, this routine ends.

  On the other hand, if a negative determination is made in step S106 (step S106: No), the process proceeds to step S120. In step S120, the power feeding control unit 20B identifies the power feeding device 12B as the first power feeding device (step S120). At this time, the power feeding control unit 20B specifies the power feeding device 12A as the second power feeding device.

  Next, in step S120, the power supply control unit 20B determines whether the voltage supplied from the power supply device 12B specified as the first power supply device is larger than the voltage supplied from the power supply device 12A specified as the second power supply device. It is determined whether or not (step S122). The power supply control unit 20B uses the comparison result of the voltage supplied from the power supply device 12A to the diode 24A and the voltage supplied from the power supply device 12B to the diode 24B, received from the peripheral circuit 32, in step S122. Judgment may be made.

  When the voltage supplied from the power supply device 12B specified as the first power supply device is larger than the voltage supplied from the power supply device 12A specified as the second power supply device (step S122: Yes), this routine ends.

  Specifically, in the case of affirmative determination in step S122, the relationship between the voltage and current as the initial values determined by the negotiation of each of the power feeding device 12A and the power feeding device 12B is the relationship shown in FIG. Is the case. FIG. 8 is a schematic diagram illustrating an example of a relationship between voltage and current as initial values of each of the power feeding device 12A and the power feeding device 12B. In FIG. 8, the definitions of Va, Vb, Ia, and Ib are the same as those in FIG.

  As shown in FIG. 8, the power that can be supplied from the power supply device 12B is larger than that of the power supply device 12A, and the voltage supplied from the power supply device 12B to the switching unit 24 is supplied from the power supply device 12A to the switching unit 24. When the voltage is larger than the voltage, the power feeding control unit 20B does not execute the voltage control and ends this routine.

  Returning to FIG. If a negative determination is made in step S122 (step S122: No), the process proceeds to step S124.

  Specifically, the case of negative determination in step S122 is the relationship between the voltage and current as the initial values determined by negotiation of each of the power feeding device 12A and the power feeding device 12B is as shown in FIG. Is the case. FIG. 9 is a schematic diagram illustrating an example of a relationship between voltage and current as initial values of each of the power feeding device 12A and the power feeding device 12B. In FIG. 9, the definitions of Va, Vb, Ia, and Ib are the same as those in FIG.

  As shown in FIG. 9, the suppliable power of the power supply apparatus 12B is larger than that of the power supply apparatus 12A, and the voltage supplied from the power supply apparatus 12B to the switching unit 24 is supplied from the power supply apparatus 12A to the switching unit 24. If it is equal to or lower than the voltage, a negative determination is made in step S122, and the process proceeds to step S124 (see FIG. 4).

  Returning to FIG. In step S124, the power supply control unit 20B controls the voltage of power supplied from the power supply apparatus 12A so as to be less than the voltage of power supplied from the power supply apparatus 12B (step S124). For example, the power supply control unit 20B displays the instruction information indicating that the voltage of the power supplied from the power supply device 12A, which is the second power supply device, is reduced by 20 mV from the currently supplied voltage via the I2C bus or the like. Output to the control unit 30A. The voltage control unit 30A requests the power feeding apparatus 12A to transmit power having a voltage 20 mV lower than the currently supplied voltage. For this reason, the power feeding device 12A supplies a voltage that is 20 mV lower than the currently supplied voltage to the diode 24A via the terminal 14A and the connection terminal 22A.

  Next, the power supply control unit 20B determines whether or not the voltage of the power supplied from the power supply apparatus 12A to the diode 24A is less than the voltage of the power supplied from the power supply apparatus 12B to the diode 24B (step S126). . The power supply control unit 20B uses the comparison result between the voltage supplied from the power supply device 12A to the diode 24A and the voltage supplied from the power supply device 12B to the diode 24B, received from the peripheral circuit 32, in step S126. Judgment may be made. In step S126, whether or not the voltage of the power supplied from the power supply apparatus 12A to the diode 24A is less than the subtraction result obtained by subtracting the predetermined value X ′ from the voltage of the power supplied from the power supply apparatus 12B to the diode 24B. May be judged. The predetermined value X ′ may be a value that gives a certain margin to the voltage difference between the voltage of the power supplied from the power feeding device 12 </ b> A and the voltage of the power supplied from the power feeding device 12 </ b> B. For example, the predetermined value X ′ may be a value that exceeds the error range described above.

  If a negative determination is made in step S126 (step S126: No), the process returns to step S124. On the other hand, if an affirmative determination is made in step S126 (step S126: Yes), the process proceeds to step S128.

  When the voltage of the power supplied from the power feeding device 12A to the diode 24A becomes less than the voltage of the power supplied from the power feeding device 12B to the diode 24B by the processing of step S124 to step S126, the power supplied from the power feeding device 12B is changed. Then, it is supplied to the CPU 28 via the switching unit 24 and the power supply circuit 26 (step S128).

  Next, the power supply control unit 20B improves the performance of the CPU 28 by the increased electric power increased from the steady state by the processing of Step S124 to Step S126 (Step S130). In step S <b> 130, the power supply control unit 20 </ b> B improves the performance of the CPU 28 by increasing the operating frequency of the CPU 28 by rewriting the turbo parameter of the CPU 28. Then, this routine ends.

  Next, when the power supply control unit 20B controls the voltage of the power supplied from the first power supply device to be larger than the voltage of the power supplied from the second power supply device, the power from the first power supply device An example of an information processing procedure executed by the power control apparatus 20 when the supply is interrupted will be described.

  FIG. 10 is a flowchart illustrating an example of an information processing procedure executed by the power control device 20 when power supply from the first power supply device is interrupted.

  First, the power supply control unit 20B determines whether or not the power supply from the power supply device 12 specified as the first power supply device is interrupted (step S200). The power supply control unit 20 </ b> B may determine the interruption of the power supply from the first power supply device using the comparison result received from the peripheral circuit 32.

  When it is not determined to shut off the power supply (step S200: No), this routine ends. On the other hand, if it is determined that the power supply from the first power supply apparatus is interrupted (step S200: Yes), the process proceeds to step S202.

  In step S202, the power supply control unit 20B controls the CPU 28 so that the power consumption is equal to or less than the first threshold (step 202). The power supply control unit 20B asserts an instruction signal for causing the CPU 28 to operate at the lowest operating frequency to the CPU 28, thereby controlling the CPU 28 so that the power consumption is equal to or less than the first threshold value.

  Next, the power supply control unit 20B communicates instruction information indicating that the voltage of the power supplied from the second power supply device is an initial value with the power supply device 12 specified as the second power supply device. 30 (step S204). The voltage control unit 30 that has received the instruction information requests the power supply apparatus 12 to transmit the voltage of the initial value stored when the power supply apparatus 12 specified as the second power supply apparatus is connected. For this reason, the second power supply apparatus starts supplying the voltage having the voltage value indicated in the request received from the voltage control unit 30 when connected to the information processing apparatus 10.

  Next, the power supply control unit 20B determines whether or not the voltage of the power supplied from the power supply device 12 specified as the second power supply device has reached the initial value (step S206). If a negative determination is made in step S206 (step S206: No), the process returns to step S204. If a positive determination is made in step S206 (step S206: Yes), the process proceeds to step S208.

  In step S208, the power supply control unit 20B ends the assertion to the CPU 28 of the instruction signal for starting the operation at the lowest operating frequency, which is started in step S202, so that the power consumption exceeds the first threshold value. Is controlled (step S208). Then, this routine ends.

  As described above, the power control apparatus 20 of the present embodiment includes the acquisition unit 20A and the power supply control unit 20B. The acquisition unit 20 </ b> A acquires the suppliable power information of each of the plurality of power feeding apparatuses 12 connected via each of the plurality of connection terminals 22. The power supply control unit 20 </ b> B is configured such that the voltage of power supplied from the first power supply device as the power supply device 12 indicating the maximum suppliable power information among the plurality of power supply devices 12 is the first of the plurality of power supply devices 12. The voltage of the power supplied from at least one of the plurality of power supply devices 12 is controlled so as to be larger than the voltage of the power supplied from the second power supply device other than the power supply device.

  As described above, the power supply control unit 20B according to the present embodiment is configured such that the voltage of the power supplied from the power supply device 12 indicating the maximum suppliable power information among the plurality of connected connection terminals 22 is the power supply device 12. The voltage of the supplied electric power is controlled so as to be larger than the voltage of the electric power supplied from the other power supply device 12.

  Due to the nature of electricity, when power of different voltages is supplied at the same time, power of high voltage is preferentially supplied. For this reason, the power supply control unit 20 </ b> B can perform control so that power is supplied from the power supply device 12 having the maximum suppliable power among the plurality of connected power supply devices 12.

  Therefore, the power control apparatus 20 according to the present embodiment can supply power from the power supply apparatus 12 having the maximum supplyable power among the plurality of connected power supply apparatuses 12.

  Moreover, the power control apparatus 20 of this Embodiment can supply electric power from the power supply apparatus 12 of the largest suppliable electric power among the several power supply apparatuses 12 connected. For this reason, it becomes possible to supply higher power to the power supply target device that operates with the power supplied from the power supply device 12.

  The power control device 20 controls any voltage so that the minimum value of the voltage of the first power supply device is larger than the maximum value of the voltage of the second power supply device. It is possible to reliably supply high-voltage power to the power supply target device.

  Since the power control device 20 controls the voltage of the second power feeding device that is lower than the voltage of the first power feeding device, it is possible to supply high voltage power to the power supply target device with easy voltage control.

  The power control device 20 can suppress errors that occur due to a sudden drop in the voltage of the second power supply device by gradually reducing the voltage of the second power supply device.

  The power control device 20 performs control so that the voltage of the second power feeding device exceeds the minimum operating voltage (for example, the minimum voltage at which the power supply target device operates). Thereby, even if supply of the electric power from the 1st electric power feeder stops, such as when the 1st electric power feeder is removed, electric power control device 20 is an electric power supply object apparatus by the electric power supplied from the 2nd electric power feeder. Can be continued.

  Since the power control device 20 controls the voltage of the power supplied from the power supply device 12 via the diodes 24A and 24B and the common output terminal 24C, the power control device 20 can reverse the power supplied from the power supply device 12 with a simple configuration. Can be suppressed.

  The power control device 20 changes the performance of the power supply target device after controlling the voltage of the power supplied by the power supply device 12, and thus can change the performance according to the power supplied to the power supply target device.

  The power control device 20 controls the voltage of the power supplied from the second power supply device to the initial value determined at the time of connection, so that even when the power of the first power supply device is cut off, the power supply device 20 Operable power can be supplied.

  When the power from the first power supply device is cut off, the power control device 20 sets the power consumption of the power supply target device to the first threshold value or less and sets the voltage of the second supply device to the initial value. Thereby, the power control apparatus 20 can operate an electric power supply object apparatus with the electric power from the 2nd electric power feeder with a low voltage.

  When the power from the first power supply device is cut off, the power control device 20 sets the power consumption of the power supply target device to the first threshold value or less, sets the voltage of the second supply device to the initial value, and then sets the power supply target device. Is controlled to exceed the first threshold value. As a result, the power control device 20 can improve the performance of the power supply target device according to the power from the second supply device having a low voltage, and can suppress malfunctions due to fluctuations in the power.

  FIG. 11 is a schematic diagram illustrating an example of power supplied to a power supply target device provided in the information processing apparatus 10. In FIG. 11, ROP indicates Rest of Power, and indicates devices other than the CPU 28 among the power supply target devices provided in the information processing apparatus 10.

  For example, it is assumed that the power consumption in the steady state of the power supply target device provided in the information processing apparatus 10 is 40 W. In a steady state, the maximum value of power that can be used by the CPU 28 is the maximum value of power that is used by a power supply target device other than the CPU 28 from a reference power (for example, 40 W) that is assumed to be supplied to the information processing apparatus 10. To be within the range of the result of subtracting.

  Then, it is assumed that the information processing apparatus 10 is connected to a power supply apparatus 12A having a suppliable power of 100W and a power supply apparatus 12B having a suppliable power of 60W. Then, it is assumed that the voltage of the initial value required for the power feeding device 12A and the power feeding device 12B is set by the negotiation by the voltage control unit 30 when the power feeding device 12A and the power feeding device 12B are connected.

  In the conventional technology, even when both the power supply device 12A and the power supply device 12B are requested to transmit the voltage of the same initial value, the voltage of the power supplied from the power supply device 12 having a small suppliable power can be supplied. In some cases, the voltage is higher than the voltage of the power supplied from the power supply device 12 having a large power. This is because an error range is included in the voltage of the supplied power as described above. For this reason, in the related art, power may be supplied from the 60 W power supply device 12B among the 100 W power supply device 12A and the 60W power supply device 12B. In this case, in the conventional technology, 60 W of power is supplied to the power supply target device such as the CPU 28, and therefore, the increase in the supplied power is 20 W, for example. That is, in the prior art, the power supply target device can use only the supplied 60 W of power.

  On the other hand, in the present embodiment, the power control device 20 causes the voltage of power supplied from the power supply device 12A having a large supplyable power to be larger than the voltage of power supplied from the power supply device 12B having a small supplyable power. In addition, the voltage of the supplied power is controlled. For this reason, in this Embodiment, electric power is supplied from 12 A of electric power feeders whose suppliable electric power is 100W. For this reason, in this Embodiment, since 100 W of electric power is supplied to electric power supply object apparatuses, such as CPU28, the increase in the supplied electric power will be 60 W, for example. That is, in the present embodiment, the power supply target device can use 100 W of power.

  For this reason, in addition to the above effects, the power control apparatus 20 of the present embodiment can supply larger power to the power supply target device than when the voltage control of the present embodiment is not performed. Further, as the supplied power increases, the power supply target device can increase the usable power and improve the performance.

  In the present embodiment, power supply control unit 20B controls each of voltage control unit 30A and voltage control unit 30B, thereby controlling the voltage of power supplied from each of power supply device 12A and power supply device 12B. The form to perform was demonstrated. However, the power supply control unit 20B only needs to control the voltage of the power supplied from each of the power supply device 12A and the power supply device 12B, and can control the voltage via the voltage control unit 30 (voltage control unit 30A, voltage control unit 30B). It is not limited. For example, the power feeding control unit 20B may directly communicate with each of the power feeding device 12A and the power feeding device 12B via the connection terminal 22 and the terminal 14. In this case, the power supply control unit 20B performs the negotiation and the control of the voltage of the power supplied from each of the power supply device 12A and the power supply device 12B by directly communicating with the power supply device 12A and the power supply device 12B. Good.

  In the above-described embodiment, the program for executing the information processing is a file in an installable format or an executable format, and is a CD-ROM, flexible disk (FD), CD-R, DVD (Digital Versatile). It may be configured to be recorded and provided on a computer-readable recording medium such as a disk (Disk) or a USB (Universal Serial Bus) memory, or may be configured to be provided or distributed via a network such as the Internet. Good. Various programs may be provided by being incorporated in advance in a ROM or the like.

  In the above-described embodiment, the program for executing the information processing has a module configuration including the functional units described above. As actual hardware, for example, a CPU (processor circuit) is a ROM or By reading and executing the cooperation support program from the HDD, the above-described functional units are loaded onto the RAM (main memory), and the above-described functional units are generated on the RAM (main memory). . Note that part or all of the functional units described above can be realized using dedicated hardware such as ASIC (Application Specific Integrated Circuit) or FPGA (Field-Programmable Gate Array).

  In addition, although embodiment was described above, the said embodiment is shown as an example and is not intending limiting the range of invention. The above-described novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. The above embodiments are included in the scope and gist of the invention, and are also included in the invention described in the claims and the equivalents thereof.

  12, 12A, 12B ... power feeding device, 20 ... power control device, 20A ... acquisition unit, 20B ... power feeding control unit, 22,22A, 22B ... connection terminal, 24A, 24B ... diode, 28 ... CPU

Claims (11)

An acquisition unit that acquires suppliable power information of each of the plurality of power feeding devices connected via each of the plurality of connection terminals;
Among the plurality of power supply devices, the voltage of the power supplied from the first power supply device as the power supply device indicating the maximum suppliable power information is other than the first power supply device among the plurality of power supply devices. A power supply control unit that controls the voltage of power supplied from at least one of the plurality of power supply devices so as to be larger than the voltage of power supplied from the second power supply device;
A power control apparatus comprising: The power supply control unit
From at least one of the plurality of power supply devices such that the minimum value of the voltage of power supplied from the first power supply device is larger than the maximum value of the voltage of power supplied from the second power supply device. Control the voltage of the supplied power,
The power control apparatus according to claim 1. The power supply control unit
Controlling the voltage of the power supplied from the second power feeding device so that the voltage of the power supplied from the second power feeding device is less than the voltage of the power supplied from the first power feeding device;
The power control apparatus according to claim 1 or 2. The power supply control unit
Controlling the voltage of the power supplied from the second power feeding device so as to decrease stepwise toward a voltage lower than the voltage of the power supplied from the first power feeding device.
The power control apparatus according to claim 3. The power supply control unit
The second power feeding so that the voltage of the power supplied from the second power feeding device is less than the voltage of the power supplied from the first power feeding device and exceeds a predetermined minimum operating voltage. Control the voltage of power supplied from the device,
The power control apparatus according to claim 3 or 4. The power supply control unit
The first power supply device that supplies power to the power supply target device via the first diode and the output end, and the second that supplies power to the power supply target device via the second diode and the output end. Controlling the voltage of power supplied from at least one of the power supply devices;
The power control apparatus according to any one of claims 1 to 5. The power supply control unit
The voltage of power supplied from at least one of the plurality of power supply devices so that the voltage of power supplied from the first power supply device is larger than the voltage of power supplied from the second power supply device. After controlling
Change the performance of the power supply target device,
The power control apparatus according to claim 3. The power supply control unit
When power supply from the first power supply device is interrupted, control is performed so that the voltage of power supplied from the second power supply device is set to an initial value determined at the time of connection to the connection terminal.
The power control apparatus according to claim 6 or 7. The power supply control unit
When power supply from the first power supply device is interrupted, the power supply target device is controlled so that power consumption is equal to or lower than a first threshold, and the voltage of power supplied from the second power supply device is Control to the initial value,
The power control apparatus according to claim 8. The power supply control unit
When power supply from the first power supply device is cut off, the power supply target device is controlled so that power consumption is equal to or less than the first threshold, and the voltage of power supplied from the second power supply device is set. After controlling to be the initial value, the power supply target device is controlled such that power consumption exceeds the first threshold value.
The power control apparatus according to claim 9. Obtaining suppliable power information of each of the plurality of power feeding devices connected via each of the plurality of connection terminals;
Among the plurality of power supply devices, the voltage of the power supplied from the first power supply device as the power supply device indicating the maximum suppliable power information is other than the first power supply device among the plurality of power supply devices. Controlling the voltage of power supplied from at least one of the plurality of power supply devices so as to be larger than the voltage of power supplied from the second power supply device;
A program that causes a computer to execute.

Images