JP6746096B2 - Power information management device and power information management method - Google Patents

Description

The present invention relates to a power information management device and a power information management method for managing power information.

A power supply device capable of supplying power to another device is known. A specific configuration of this type of power supply device is described in Patent Document 1, for example.

Patent Document 1 discloses a portable device including two ports that can be daisy-chained with an upstream external device and a downstream external device. The portable device described in Patent Document 1 includes a battery that charges electric power supplied from an upstream external device. The electric power charged in the battery is supplied to the downstream external device.

JP, 2013-223269, A

In the portable device described in Patent Document 1, when power is supplied to a downstream external device and the power consumption required to drive the downstream external device exceeds the power that the portable device can supply, A situation may occur in which an external device cannot be driven. This is because there are various devices that can be connected in the daisy chain, and the order of connection is not specified.

The present invention has been made in view of the above circumstances, and an object thereof is to provide a power information management device and a power information management method that can efficiently supply power to a plurality of devices. ..

A power information management apparatus according to an embodiment of the present invention is a power information management apparatus that can be connected to a plurality of external devices, and is connected to one of the plurality of external devices and communicates with and is connected to the connected external device. At least one communication connection unit capable of power feeding or one-way power feeding, a power information management unit, a power information acquisition unit that acquires power information from any one of a plurality of external devices, and power of the pair of devices. Based on the information, one of the pair of devices includes a power determination unit that determines whether or not the power required by the other can be supplied to the other, and a notification unit that notifies the determination result by the power determination unit. ..

Further, in one embodiment of the present invention, the notifying unit notifies the result of the determination, for example, when one determines that the power required by the other can be supplied to the other.

Further, in one embodiment of the present invention, the communication connection unit is, for example, daisy-chain connected to a plurality of external devices, and a part of the electric power received from the external power source or the external device upstream of the plurality of external devices is It can be supplied to the downstream external device.

In addition, in an embodiment of the present invention, the power determination unit may change the order of the daisy chain connection in a state where the power information management apparatus is daisy chain connected to at least two external devices, for example, so as to change the pair of devices. One determines whether or not the number of combinations of a pair of devices capable of supplying the power required by the other to the other increases. In this case, when the power determination unit determines that the number of combinations will increase, the notification unit notifies the order of the daisy chain connection in which the number of combinations will increase.

Further, in one embodiment of the present invention, the power determination unit determines which of the power information management device and the at least two external devices is in a state where the power information management device is daisy-chain connected to the at least two external devices. By changing one of the connection destinations from the device of the current connection destination to another device, one of the pair of devices can supply the electric power required by the other to the other. Determine whether the number will increase. In this case, when the power determination unit determines that the number of combinations will increase, the notification unit notifies another device that the number of combinations will increase.

Further, in one embodiment of the present invention, the power information includes, for example, available power information indicating the power that each of the pair of devices can supply to another device, and power consumption indicating the power consumption of each of the pair of devices. Information and including.

In one embodiment of the present invention, the power consumption information acquired from one of the pair of devices is, for example, the sum of the power consumption of one device and the power consumption of another device connected to the one device. Indicates.

Moreover, in one embodiment of this invention, the alerting|reporting part transmits the determination result by an electric power determination means to at least 1 of several external devices, for example.

A power information management method according to an embodiment of the present invention is a power information management method in a power information management apparatus that is connected to communicate with a plurality of external devices and to be capable of mutual power supply or one-way power supply. And a power information acquisition step of acquiring power information from any one of a plurality of external devices, and one of the pair of devices requests the other to the other based on the power information of the pair of devices. A power determination step of determining whether or not power can be supplied, a notification step of reporting a determination result by the power determination unit,
including.

Further, in the embodiment of the present invention, the notifying step notifies the result of the determination, for example, when one determines that the other one can supply the power required by the other.

According to an embodiment of the present invention, there is provided a power information management device and a power information management method capable of accurately and efficiently supplying power to a plurality of devices.

It is a block diagram which shows the structure of the system which has a power information management apparatus which concerns on one Embodiment of this invention. It is a figure which shows the flowchart of the electric power information management process performed in one Embodiment of this invention. It is a figure which shows the flowchart of the electric power information management process performed in the modification of one Embodiment of this invention.

Hereinafter, a power information management apparatus according to an embodiment of the present invention will be described with reference to the drawings.

FIG. 1 is a schematic diagram showing a configuration of a system including a power information management device (hereinafter referred to as “device”) 10 according to an embodiment of the present invention. Two devices 20 and 30 are connected to the power information management device 10.

The devices 10 to 30 can supply and receive power according to the result of communication between the devices, and, for example, devices compatible with USB (Universal Serial Bus)-PD (Power Delivery). Is. Specific examples of the device include a digital single-lens reflex camera, a mirrorless single-lens camera, a compact digital camera, a video camera, a camcorder, a desktop PC, a notebook PC, a monitor, a tablet terminal, a PHS (Personal Handy phone System), a smartphone, a smart watch, Examples include feature phones, game machines, music players, TVs, car navigations, projectors, various peripheral devices such as printers and storages, strobes, GPS units, various accessories such as external viewfinders, and the like. In the example of FIG. 1, the device 10 is a desktop PC, the device 20 is a monitor such as a liquid crystal display, and the device 30 is a printer.

As shown in FIG. 1, each of the devices 10 to 30 includes a CPU 100, two USB connectors 120, a memory 130, a UI (User Interface) 140, and a power supply connector 150. The devices 20 and 30 also include a display unit 160. In the present embodiment, for the sake of convenience, a device-specific configuration (for example, a solid-state image sensor or a photographing lens when the device is a photographing device, an HDD when the device is a desktop PC, a flash lamp when the device is a strobe) is used. And a trigger circuit, and a general structure such as an image forming unit and a print sheet transport mechanism when the device is a printer), a housing, etc. Description will be appropriately omitted or simplified.

The power connector 150 is connected to an external power source such as a commercial power source or an external battery. The UI 140 of each of the devices 10 to 30 includes various operating means for the user to operate the device. For example, when the user operates the UI 140 (power switch), power supplied from the outside via the power connector 150 is supplied to various circuits in the device.

Upon receiving the power, the CPU 100 accesses the memory 130, reads the control program, loads the control program into the work area, and executes the loaded control program, thereby centrally controlling the entire apparatus.

The devices 10 to 30 can communicate with each other via the USB cable 200 connected to the USB connector 120. The USB connector 120 is a USB-PD compatible connector, for example, a USB Type-C connector. The USB cable 200 is a USB-PD compatible cable, for example, a USB Type-C cable. Therefore, each of the devices 10 to 30 can perform not only communication via the USB cable 200 but also mutual power supply or one-way power supply. When the devices are connected to each other via the USB cable 200, the host (power supply side) is set according to a user operation or automatically. Illustratively, when the device 10 and the device 20 are connected via the USB cable 200, the device 10 is set as the host. The CPU 100 of the device 20 issues a power supply request to the host (device 10) in response to a user operation or automatically.

The CPU 100 of each of the devices 10 to 30 holds a plurality of types of power profiles that define the power supplied to other devices. The following shows an example of a power profile held by the CPU 100.
(Example of power profile)
PROFILE POWER VOLTAGE CURRENT
PROFILE0 RESERVED
PROFILE1 10W 5V 2A
PROFILE2 18W 12V 1.5A
PROFILE3 36W 12V 3A
PROFILE4 60W 20V 3A
PROFILE5 100W 20V 5A
For example, when the power profile of the device 10 is set to PROFILE4, the device 10 can supply up to 60 W of power to the device connected to the USB connector 120. The power profile held by the CPU 100 may be different for each device.

When receiving the power supply request from the device 20, the CPU 100 of the device 10 subtracts the operating power required for the operation of the device 10 from the power received from the external power source (commercial power source or external battery), and calculates the subtracted value. Select a power profile that satisfies the power. For example, when the power consumption of the device 10 is 100 W and the device 10 can receive sufficient power (for example, 200 W or more) from the external power source, any power profile of PROFILE1 to PROFILE5 can be selected. At this time, the power consumption of the device 20 is 50 W, and when the device 20 requests its own power consumption from the device 10, the CPU 100 of the device 10 causes the PROFILE4 or PROFILE5 capable of supplying 50 W or more from the above power profile group. Is selected and set as a power profile between the device 10 and the device 20. As a result, the device 10 is driven by the electric power received from the external power source and supplies 50 W of electric power to the device 20. Since device 20 can be driven by the electric power received from device 10, power connector 150 of device 20 does not need to be connected to an external power source.

Further, the devices 10 to 30 can be connected in a daisy chain in series by a USB cable 200 as shown in FIG. In this case, electric power can be sequentially supplied from the device on the upstream side of the daisy chain connection to the device on the downstream side. Specifically, the most upstream device 10 can supply electric power to the downstream device 20. Further, the device 20 can supply electric power to the downstream device 30.

Further, when the device 10 has two USB connectors 120, the devices 20 and 30 can be directly connected to the device 10. In this case, the device 10 can supply power to both the downstream device 20 and the downstream device 30.

Here, consider a case where the power supply of the apparatus 10 is 100 W, the power consumption of the apparatus 20 is 50 W, the power supply of the apparatus 20 is 50 W, the power consumption of the apparatus 30 is 30 W, and the power supply of the apparatus 30 is 30 W. .. In this case, when the devices 10 to 30 are daisy-chained in the order of the device 10, the device 20, and the device 30, the device 10 uses the power of 80 W (50 W+30 W) required to drive both the device 20 and the device 30 on the downstream side. ) Can be supplied. Further, the device 20 can supply the downstream device with the surplus power 50W obtained by subtracting the power consumption 50W of itself (device 20) from the power 100W that can be received from the upstream device 10. However, due to the specifications of the device 20, the maximum value of the power that can be supplied is up to 50W. In this example, since the surplus power of the device 20 is the same as the power that can be supplied by the device 20, the device 20 can supply 50 W, which is the maximum value of the power that can be supplied, to the downstream device 30. Further, the device 30 can receive the power of 50 W from the device 20 and the power consumption of the device 30 is 30 W, so the device 30 can be driven by the power received from the device 20. Therefore, the device 20 and the device 30 can be driven by the electric power sequentially supplied from the device 10 even if they are not connected to the external power source.

Further, when the device 20 and the device 30 are directly connected to the device 10, the device 20 and the device 30 can be driven by the electric power received from the device 10 even if they are not connected to the external power source.

On the other hand, when the devices 10 to 30 are daisy chained in the order of the device 10, the device 30, and the device 20, the device 30 cannot supply the electric power required to drive the device 20 downstream. Therefore, the device 20 needs to be driven by an external power supply. Further, if the device 20 does not have the power supply connector 150 and power can be received only from the USB connector 120, the device 20 cannot be used.

In this way, whether or not each device needs to be connected to the external power supply changes depending on the connection method of the plurality of devices and the order of the daisy chain connection. Also, depending on the specifications of each device, there may be a device that cannot be used due to insufficient power. Therefore, in this embodiment, electric power is accurately and efficiently supplied to each device, and the occurrence of power shortage of the device is suppressed.

FIG. 2 is a diagram showing a flowchart of the power information management process executed by the CPU 100 of the device 10 when the device 30 and the device 20 are sequentially connected to the device 10. The device that executes the power information management process is not limited to the device 10, and another device such as the device 20 or the device 30 may execute the power information management process. Illustratively, the power information management process may be executed by a device set by the user, or may be executed by a device with the smallest power consumption in the standby state among the devices 10 to 30. The device with the lowest power consumption in the standby state is automatically detected from a plurality of devices based on the communication result between the devices, for example.

[S101 in FIG. 2]
In this processing step S101, the user connects the device 30 to the device 10 via the USB cable 200. The device 10 is connected to an external power source and is driven by the electric power received from the external power source.

[S102 in FIG. 2]
In this processing step S102, the power information of the device 30 is transmitted from the device 30 to the device 10 via the USB cable 200. The power information includes the power consumption of the device 30 and the power that can be supplied.

[S103 of FIG. 2]
In this processing step S103, it is determined whether or not the device 10 can supply the power required by the device 30. The power required by the device 30 is the power consumption of the device 30. For example, when the power that can be supplied by the device 10 is 100 W and the power consumption of the device 30 is 100 W or less, it is determined that the power can be supplied (S103: YES). On the other hand, when the power consumption of the device 30 is larger than 100 W, it is determined that the power cannot be supplied (S103: NO).

[S104 of FIG. 2]
This processing step S104 is executed when it is determined in processing step S103 that the device 10 cannot supply the power required by the device 30 (S103: NO). In this processing step S104, the power profile of the device 10 for the device 30 is set to PROFILE1, which has the smallest available power, for example. As a result, the device 10 and the device 30 can communicate with each other via the USB cable 200, but the device 10 does not supply the device 30 with the electric power required to drive the device 30. Therefore, in order to drive the device 30, it is necessary to connect the device 30 to an external power source.

[S105 of FIG. 2]
In this processing step S105, the fact that the device 10 cannot supply the power required by the device 30 (that is, the determination result of the processing step S103) is notified. For example, consider a case where the device 10 is a desktop PC and the device 30 is a monitor including a display unit 160. In this case, if the device 10 and the device 30 are connected to an external power source and are in a drivable state, the determination result of the processing step S103 is transmitted from the device 10 to the device 30 in the present processing step S105. The device 30 displays the received determination result on the display unit 160. Further, when the device 10 is a device including the display unit 160 such as a notebook PC, a monitor, or a smartphone, the device 10 may display the determination result on its own display unit 160 in this processing step S105. Further, when the device 10 or the device 30 includes a speaker, the determination result may be notified by voice using the speaker. Alternatively, the device 10 may send the determination result to an external device that is network-connected to the device 10.

[S106 of FIG. 2]
This processing step S106 is executed when it is determined in the processing step S103 that the device 10 can supply the power required by the device 30 (S103: YES). In this processing step S106, the power profile of the device 10 is set so that the device 10 can supply power to the device 30. For example, when the power consumption of the device 30 is 30 W, the power profile is set to any of PROFILE3 to PROFILE5 whose power is 30 W or more. As a result, the device 30 can be driven by the electric power received from the device 10.

[S107 of FIG. 2]
In this processing step S107, the user connects the device 20 to the device 30 via the USB cable 200. As a result, the device 10, the device 30, and the device 20 are daisy-chained in this order. At this time, the device 10 becomes the most upstream device, and the device 20 becomes the most downstream device.

[S108 of FIG. 2]
In this processing step S108, the power information of the device 20 is transmitted from the device 20 to the device 10 via the USB cable 200 and the device 30. The power information includes the power consumption of the device 20 and the power that can be supplied.

[S109 of FIG. 2]
In this processing step S109, it is determined whether or not the device 10 can supply the power required by the device 30 and the device 20. The power required by the devices 30 and 20 is the total power consumption of the devices 30 and 20. For example, when the power that can be supplied by the device 10 is 100 W and the total power consumption of the device 30 and the device 20 is 100 W or less, it is determined that the power can be supplied (S109: YES). On the other hand, when the total power consumption of the device 30 and the device 20 is larger than 100 W, it is determined that the power cannot be supplied (S109: NO).

The power information of the device 20 is transmitted to the device 10 in the processing step S108, and it is determined whether the device 10 can supply the total power consumption of the devices 30 and 20 in the processing step S109. It is not limited to this. For example, the power information of the device 20 may be transmitted to the device 30, and the device 30 may request the device 10 to sum the power consumptions of the device 30 and the device 20. In this case, in processing step S109, it is determined whether or not the device 10 can supply the power requested by the device 30.

[S110 of FIG. 2]
This processing step S110 is executed when it is determined in processing step S109 that the device 10 cannot supply the power required by the devices 30 and 20 (S109: NO). In this processing step S110, the power profile of the device 30 for the device 20 is set to PROFILE1, which has the smallest power, for example. As a result, the device 30 and the device 20 can communicate with each other via the USB cable 200, but the device 30 does not supply the device 20 with the electric power required to drive the device 20. Therefore, in order to drive the device 20, it is necessary to connect the device 20 to an external power source. At this time, the device 30 can be driven by the electric power received from the device 10.

[S111 of FIG. 2]
In this processing step S111, the CPU 100 of the device 10 notifies that the device 30 cannot supply the power required by the device 20 (that is, the determination result of the processing step S109). Specifically, the CPU 100 of the device 10 transmits the determination result to the device including the display unit 160 among the devices 10 to 30. The device including the display unit 160 displays the received determination result on the display unit 160. In addition, when the device 20 includes the display unit 160 and the determination result is displayed on the display unit 160, the device 20 needs to be connected to an external power source and be in a drivable state. If any of the devices 10 to 30 has a speaker, the determination result may be notified by voice using this speaker. Alternatively, the device 10 may send the determination result to an external device that is network-connected to the device 10.

[S112 of FIG. 2]
This processing step S112 is executed when it is determined in processing step S109 that the device 10 can supply the electric power required by the device 30 and the device 20 (S109: YES). In this processing step S112, it is determined whether or not the device 30 can supply the power required by the device 20. The power required by the device 20 is the power consumption of the device 20. For example, when the power that can be supplied by the device 30 is 30 W and the power consumption of the device 20 is 30 W or less, it is determined that the power can be supplied (S112: YES). On the other hand, when the power consumption of the device 20 is larger than 30 W, it is determined that the power cannot be supplied (S112: NO).

[S113 in FIG. 2]
This processing step S113 is executed when it is determined in the processing step S112 that the device 30 can supply the power required by the device 20 (S112: YES). In this processing step S113, the power profile of the device 30 is set so that the device 30 can supply power to the device 20. For example, when the power consumption of the device 20 is 50 W, the power profile of the device 30 for the device 20 is set to PROFILE4 or PROFILE5 whose power is 50 W or more. In addition, the power profile of the device 10 is set so that the device 10 can supply the total power consumption of the device 30 and the device 20. For example, when the power consumption of the device 20 is 50 W and the power consumption of the device 30 is 30 W, the power profile of the device 10 for the device 30 is set to PROFILE5 in which the power is 80 W or more. Accordingly, the device 20 can be driven by the electric power received from the device 30. Further, the device 30 can be driven by the electric power received from the device 10. Therefore, the device 30 and the device 20 can be driven without being connected to the external power supply.

[S114 of FIG. 2]
This processing step S114 is executed when it is determined in processing step S112 that the device 30 cannot supply the power required by the device 20 (S112: NO). In process step S114, contrary to process step S112, it is determined whether or not the device 20 can supply the power required by the device 30. The power required by the device 30 is the power consumption of the device 30. For example, when the power that can be supplied by the device 20 is 50 W and the power consumption of the device 30 is 50 W or less, it is determined that the power can be supplied (S114: YES). On the other hand, when the power consumption of the device 30 is greater than 50 W, it is determined that the power cannot be supplied (S114: NO). When it is determined that the device 20 can supply the power required by the device 30 (S114: YES), the process proceeds to step S115. When it is determined that the device 20 cannot supply the power required by the device 30 (S114: NO), the process proceeds to step S110.

[S115 of FIG. 2]
This processing step S115 is executed when it is determined in processing step S114 that the device 20 can supply the power required by the device 30 (S114: YES). In this processing step S115, the power profile of the device 30 for the device 20 is set to PROFILE1, which has the smallest power, for example. As a result, the device 30 and the device 20 can communicate with each other via the USB cable 200, but the device 30 does not supply the device 20 with the electric power required to drive the device 20. Therefore, in order to drive the device 20, it is necessary to connect the device 20 to an external power source. At this time, the device 30 can be driven by the electric power received from the device 10.

[S116 of FIG. 2]
In this processing step S116, the CPU 100 of the device 10 notifies that the device 20 and the device 30 can be driven by the power supplied from the device 10 by changing the connection order of the devices 10 to 30.

When the processing step S116 is executed, the devices 10 to 30 are daisy-chained in the order of the device 10, the device 30, and the device 20. Further, the device 30 can be driven by the electric power supplied from the device 10. However, the device 20 cannot be driven by the electric power received from the device 30. Therefore, among the devices 10 to 30, the combination of devices that can be driven by the power supplied by the USB-PD is only the combination of the devices 10 and 30. However, the power that can be supplied from the device 20 is larger than the power consumption of the device 30. Therefore, by connecting the devices 10 to 30 in the order of the device 10, the device 20, and the device 30 in order, The device 30 can be driven by the power supplied, and the device 30 can be driven by the power supplied from the device 20. Therefore, in this case, among the devices 10 to 30, there are two combinations of devices that can be driven by the power supplied by the USB-PD, a combination of the devices 10 and 20, and a combination of the devices 20 and 30. As described above, the number of combinations of devices that can be driven by the power supplied by the USB-PD is increased, so that the power supplied from the most upstream device can be efficiently used and it is necessary to connect to an external power supply. The number of devices can be reduced.

In the processing step S116, for example, among the devices 10 to 30, a device or a device including the display unit 160 is provided for a sentence or a drawing that recommends that the devices 10 to 30 be connected in a daisy chain in the order of the device 10, the device 20, and the device 30. Send to. The device including the display unit 160 displays the received text or drawing on the display unit 160. If any of the devices 10 to 30 is equipped with a speaker, the contents recommending that the devices 10 to 30 be connected in a daisy chain in the order of the device 10, the device 20, and the device 30 are notified using the speaker. May be. Alternatively, the device 10 may transmit information that recommends that the devices 10 to 30 be daisy-chained in the order of the device 10, the device 20, and the device 30 to an external device network-connected to the device 10.

The user changes the order of the daisy chain connection of the devices 10 to 30 based on the content notified in the processing step S116. As a result, the electric power supplied from the device 10 can be used accurately and efficiently.

The above is a description of exemplary embodiments of the present invention. The embodiments of the present invention are not limited to those described above, and various modifications are possible within the scope of the technical idea of the present invention. For example, the contents of an embodiment of the present application also include appropriate combinations of the embodiments and the like explicitly described in the specification or the obvious embodiments and the like.

For example, in the power information management process shown in FIG. 2, the device 20 and the device 30 are not connected to the device 10 at the start of the process, but the present invention is not limited to this. For example, the process shown in FIG. 2 may be started in the state where the device 30 is connected to the device 10 or the state where the device 20 is further connected to the device 30.

Further, in the above-described embodiment, the case where three devices, devices 10 to 30, are connected has been described, but the present invention is not limited to this. For example, even when four or more devices are connected by USB-PD, an accurate and efficient connection order can be determined based on the power information (suppliable power and power consumption) of each device. .. An accurate and efficient connection order is, for example, the connection order in which the number of combinations of devices that can be driven by the power supplied by the USB-PD is the largest.

Further, in the above-described embodiment, the content recommending the change of the order of the daisy chain connection of the devices 10 to 30 is notified in the processing step S106 of the flowchart of the power information management processing shown in FIG. 2, but the present invention is not limited to this. Not done. FIG. 3 shows a flowchart of a power information management process according to a modified example of the embodiment of the present invention. Of the processing steps S201 to S216 shown in FIG. 3, the steps other than the processing step S214 and the processing step S216 are the same as the processing steps S101 to S116 shown in FIG.

In processing step S214 of FIG. 3, it is determined whether the device 10 can supply the power required by the device 20. The power required by the device 20 is the power consumption of the device 20. The device 10 supplies power to the device 30 when the processing step S214 is executed. Therefore, for example, when the original power that can be supplied to the device 10 is 100 W and the power consumption of the device 30 is 30 W, the power that can be supplied to the device 10 in the processing step S214 is 100 W from the original power of the device 30. The power is 70 W after subtracting the power consumption of 30 W. Therefore, when the power consumption of the device 20 is 70 W or less, it is determined that the power can be supplied (S214: YES). On the other hand, when the power consumption of the device 20 is larger than 70 W, it is determined that the power cannot be supplied (S214: NO).

In processing step S216 of FIG. 3, the CPU 100 of the device 10 notifies that the device 20 and the device 30 can be driven by the power supplied from the device 10 by changing the connection destination of the device 20. Specifically, in process step S216, a sentence or a drawing recommending that the device 20 is connected to the unused USB connector 120 of the device 10 is transmitted to the device including the display unit 160 among the devices 10 to 30. .. The device including the display unit 160 displays the received text or drawing on the display unit 160.

The user changes the connection destination of the device 20 from the current USB connector 120 of the device 30 to the USB connector 120 of the device 10 based on the content notified in the processing step S216. As a result, the devices 20 and 30 can be driven by the electric power received from the device 10.

When the device 20 and the device 30 are connected to the two USB connectors 120 of the device 10, the device 20 and the device 30 are connected in parallel to the device 10. Therefore, in this case, the connection of the devices 10 to 30 is not a daisy chain connection. As described above, the connection method notified to the user is not limited to the daisy chain connection as long as the connection is accurate and efficient.

10 to 30 device 100 CPU
120 USB connector 130 Memory 140 UI
150 power connector 160 display 200 USB cable

Claims (9)

A power information management device connectable to a plurality of external devices,
Is connected to one of said plurality of external devices, and the connected external device and the communication and mutual power supply or one-way feeding at least one communication connection unit capable,
From a pair of any one of the power information management device and the plurality of external devices, a power information acquisition unit that acquires power information,
Based on the power information of the pair of devices, with respect to one and the other of said pair of device, and determines power determination unit whether power can be supplied to the other requests,
A notification unit for notifying the determination result by the power determination unit,
Equipped with
The communication connection unit is daisy chain connected to the plurality of external devices, and a part of electric power received from an external power source or an upstream external device of the plurality of external devices is used as a downstream external device of the plurality of external devices. Can be supplied to the device,
In the state where the power information management device is daisy chain connected to at least two external devices, the power determination unit switches the order of the daisy chain connections, so that one of the pair of devices is different from the other. It is determined whether the number of combinations of the pair of devices capable of supplying the power required by the other increases,
The notification unit, when the power determination unit determines that the number of the combinations is increased, you notify the order of daisy-chaining the number of combinations increases,
Power information management device. A power information management device that can be connected to a plurality of external devices,
Is connected to one of said plurality of external devices, and the connected external device and the communication and mutual power supply or one-way feeding at least one communication connection unit capable,
From a pair of any one of the power information management device and the plurality of external devices, a power information acquisition unit that acquires power information,
Based on the power information of the pair of devices, with respect to one and the other of said pair of device, and determines power determination unit whether power can be supplied to the other requests,
A notification unit for notifying the determination result by the power determination unit,
Equipped with
The communication connection unit is daisy chain connected to the plurality of external devices, and a part of electric power received from an external power source or an upstream external device of the plurality of external devices is used as a downstream external device of the plurality of external devices. Can be supplied to the device,
The power determination unit, when the power information management device is daisy-chained with at least two external devices, currently determines the connection destination of any one of the power information management device and the at least two external devices. Whether the number of combinations of the pair of devices that enables one of the pair of devices to supply the electric power required by the other to the other by changing from the device to which the device is connected to another device. Determine whether
The notification unit, when the power determination unit determines that the number of the combinations is increased, you notify the other devices which the number of the combinations is increased,
Power information management device. The notification unit, with respect to the one is the other, if the other is determined to be feeding the power to request, to notify the result of the determination,
The power information management device according to claim 1 or 2 . The power information is
Suppliable power information indicating the power that each of the pair of devices can supply to other devices,
Power consumption information indicating the power consumption of each of the pair of devices,
The power information management device according to any one of claims 1 to 3 . The power consumption information obtained from one of the pair of device shows the sum of the power consumption of other devices connected to the power and the one device of said one device,
The power information management device according to claim 4 . The notification unit transmits a determination result by the power determination unit to at least one of the plurality of external devices,
The power information management device according to any one of claims 1 to 5 . A power information management method in a power information management device connected to a plurality of external devices so as to be capable of communication and mutual power supply or one-way power supply,
From a pair of any one of the power information management device and the plurality of external devices, a power information acquisition step of acquiring power information,
Based on the power information of the pair of devices, with respect to one and the other of said pair of device, and a power determination step of determining whether power can be supplied to the other requests,
A notification step of notifying the determination result in the power determination step ,
Only including,
The power information management device is daisy chain connected to the plurality of external devices, and a part of the electric power received from an external power source or an upstream external device of the plurality of external devices is connected to a downstream side of the plurality of external devices. Can be supplied to external devices,
In the power determining step, when the power information management device is daisy chain connected to at least two external devices, the order of the daisy chain connection is switched so that one of the pair of devices is connected to the other. , Determining whether or not the number of combinations of the pair of devices capable of supplying the power required by the other increases,
In the notification step, when it is determined in the power determination step that the number of combinations increases, the order of daisy chain connection in which the number of combinations increases is notified ,
Power information management method. A power information management method in a power information management device connected to a plurality of external devices so that they can communicate with each other and mutually feed or unidirectionally feed,
From a pair of any one of the power information management device and the plurality of external devices, a power information acquisition step of acquiring power information,
Based on the power information of the pair of devices, with respect to one and the other of said pair of device, and a power determination step of determining whether power can be supplied to the other requests,
A notification step of notifying the determination result in the power determination step ,
Only including,
The power information management device is daisy chain connected to the plurality of external devices, and a part of the electric power received from an external power source or an upstream external device of the plurality of external devices is connected to a downstream side of the plurality of external devices. Can be supplied to external devices,
In the power determination step, in a state in which the power information management device is daisy chain connected to at least two external devices, one of the connection destinations of the power information management device and the at least two external devices is Is the number of combinations of the pair of devices that allows one of the pair of devices to supply the power required by the other to the other by changing from the currently connected device to another device? Determine whether or not
In the notification step, if it is determined in the power determination step that the number of combinations increases, the other device that increases the number of combinations is notified,
Power information management method. At the notification step, with respect to the one is the other, if the other is determined to be feeding the power to request, to notify the result of the determination,
The power information management method according to claim 7 or 8 .

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