JP2020140536A - Control device, information processing system, and program - Google Patents

Abstract

To appropriately switch the power supply state of a terminal device according to control from an information processing device.SOLUTION: A control device for controlling power supply to a terminal device includes: a power supply controller that is connectable to the terminal device via cable, and performs power supply to the terminal device and information communication with the terminal device via the cable; a power supply command acquisition unit that receives a wakeup command to start the terminal device from an information processing device; a power supply switch control unit that, when receiving the wakeup command, gives the power supply controller an instruction to output a switch push signal to switch the state of a power supply switch of the terminal device to the terminal device; and a power supply command mask unit that masks the wakeup command in the case of receiving the wakeup command when the terminal device is in a start state.SELECTED DRAWING: Figure 12

Description

The present invention relates to control devices, information processing systems and programs.

In recent years, the use of tablet computers (hereinafter referred to as tablets) for education has been studied in schools and the like. In such a case, the tablet is stored and managed in a dedicated rack installed in the classroom, for example. Before the start of class, students remove the tablet from the rack, activate the removed tablet, and start using it at their own seat. After class, students shut down their tablets, store the shut down tablets in a rack, and connect them to the controls in the rack via cables.

Then, the control device in the rack charges the stored tablet via the cable. In addition, the information processing device in the rack accepts remote control and the like via the network, updates software to the stored tablet, and performs maintenance on the tablet.

International Publication No. 2018/096798

By the way, when starting maintenance of the tablet, the control device in the rack turns on the power switch of the tablet in response to a command from a higher-level information processing device. When the maintenance of the tablet is completed, the control device in the rack turns off the power switch of the tablet in response to a command from a higher-level information processing device.

However, since the power switch of the tablet is a push switch that performs an alternate operation, the signal for turning on the power switch and the signal for turning off the power switch are usually the same. Therefore, when the tablet is shut down and a command to turn off the power switch is received from a higher-level information processing device, the control device turns on the power switch of the tablet. On the contrary, when the tablet is activated and a command to turn on the power switch is received from a higher-level information processing device, the control device turns off the power switch of the tablet.

The disclosed technology has been made in view of the above, and an object of the present invention is to provide a control device, an information processing system, and a program that appropriately switch the power state of the terminal device according to the control from the information processing device. To do.

The control device according to the first aspect of the present invention is a control device that controls power supply to the terminal device, is connectable to the terminal device via a cable, and supplies power to the terminal device via the cable. A power supply controller that performs information communication with the terminal device, a power command acquisition unit that receives a wakeup command for activating the terminal device from the information processing device, and a power supply of the terminal device when the wakeup command is received. The power switch control unit that gives an instruction to output a switch push signal for switching the switch state to the terminal device to the power supply controller, and the wakeup command when the terminal device receives the wakeup command in the activated state. It is equipped with a power command mask unit that masks up commands.

The information processing system according to the second aspect of the present invention includes a terminal device and a control device that controls power supply to the terminal device, and the control device can be connected to the terminal device via a cable. , A power supply controller that supplies power to the terminal device via the cable and performs information communication with the terminal device, a power command acquisition unit that receives a wakeup command for activating the terminal device from the information processing device, and the wakeup. When a command is received, the power switch control unit that gives an instruction to output a switch push signal for switching the state of the power switch of the terminal device to the terminal device to the power supply controller, and the terminal device are in the activated state. When the wake-up command is received in the above, the power command mask unit for masking the wake-up command is provided.

The program according to the third aspect of the present invention is a program executed by a processor included in a control device that controls power supply to the terminal device, and the control device can be connected to the terminal device via a cable. A power command acquisition unit that includes a power supply controller that supplies power to the terminal device via the cable and performs information communication with the terminal device, and receives a wake-up command for activating the terminal device from the information processing device. When the wake-up command is received, the power switch control unit that gives an instruction to output the switch push signal for switching the state of the power switch of the terminal device to the terminal device to the power supply controller, and the above. When the terminal device receives the wake-up command in the activated state, it functions as a power command mask unit that masks the wake-up command.

According to the control device according to the first aspect of the present invention, the power supply state of the terminal device can be appropriately switched according to the control from the information processing device.

According to the information processing system according to the second aspect of the present invention, the power supply state of the terminal device can be appropriately switched according to the control from the information processing device.

According to the program according to the third aspect of the present invention, the power supply state of the terminal device can be appropriately switched according to the control from the information processing device.

FIG. 1 is a diagram showing an information processing system. FIG. 2 is a diagram showing the appearance of the charging cabinet. FIG. 3 is an enlarged view of a peripheral portion of the terminal device housed in the charging cabinet. FIG. 4 is a block diagram showing a configuration of a charging cabinet in which a terminal device is housed, together with a school server and a wireless communication device. FIG. 5 is a diagram showing a flow of power supply to the terminal device. FIG. 6 is a diagram showing a flow of information when the information processing device controls the terminal device via a cable. FIG. 7 is a diagram showing a flow of information when the information processing device transmits / receives information to / from the terminal device via wireless communication. FIG. 8 is a diagram showing a flow of information when the terminal device accesses the school server. FIG. 9 is a diagram showing a configuration when the charging cabinet includes a plurality of charging control devices. FIG. 10 is a diagram showing a hardware configuration of a charge control device together with a plurality of terminal devices. FIG. 11 is a diagram showing a hardware configuration of the terminal device and a hardware configuration of the terminal control unit in the charge control device. FIG. 12 is a diagram showing a functional configuration of the charging side communication processor according to the first embodiment. FIG. 13 is a flowchart showing a processing flow of the charging side communication processor according to the first embodiment. FIG. 14 is a diagram showing a functional configuration of the charging side communication processor according to the second embodiment. FIG. 15 is a sequence diagram showing a processing flow of the charging side communication processor according to the second embodiment. FIG. 16 is a diagram showing a functional configuration of the charging side communication processor according to the third embodiment. FIG. 17 is a flowchart showing a processing flow of the charging side communication processor according to the third embodiment. FIG. 18 is a diagram showing a functional configuration of the charging side communication processor according to the fourth embodiment. FIG. 19 is a flowchart showing a processing flow of the charging side communication processor according to the fourth embodiment. FIG. 20 is a diagram showing a functional configuration of the processing circuit according to the fifth embodiment. FIG. 21 is a flowchart showing the flow of the first processing of the processing circuit according to the fifth embodiment. FIG. 22 is a flowchart showing a second processing flow of the processing circuit according to the fifth embodiment.

The information processing system 10 according to the embodiment will be described below. The disclosed technology is not limited by this embodiment. Further, the configurations having the same function in the plurality of embodiments are designated by the same reference numerals, and duplicate description will be omitted.

(First Embodiment)
First, the information processing system 10 according to the first embodiment will be described.

FIG. 1 is a diagram showing an information processing system 10 according to the first embodiment. In the present embodiment, the information processing system 10 is a system for supporting lessons in a school. The information processing system 10 is not limited to supporting lessons at school, and may be applied to other environments. The information processing system 10 may be applied to any environment as long as it is an environment in which a large number of participants work or learn while operating a computer, such as in a company, a seminar, or a conference. ..

The information processing system 10 includes a plurality of terminal devices 20, a school server 22, a wireless communication device 24, and a charging cabinet 26.

Each of the plurality of terminal devices 20 is a tablet-type or notebook-type computer. The terminal device 20 has an information input function, an output function, and an information processing function. The terminal device 20 has a secondary battery and can be operated by the electric power charged in the secondary battery. Therefore, the terminal device 20 can be carried by the user. In addition, the terminal device 20 has a wireless communication function, and can perform information communication with other devices without using a communication cable.

The school server 22 is a server-type computer, and is accessed from a plurality of terminal devices 20 via an internal network. Further, the school server 22 restricts access from a device on the external network to a device on the internal network, or restricts access from a device on the internal network to a device on the external network, for example.

The wireless communication device 24 is provided outside the charging cabinet 26. The wireless communication device 24 is connected to the internal network by wire. The wireless communication device 24 is connected to each of the plurality of terminal devices 20 by wireless communication. The wireless communication device 24 allows the terminal device 20 connected by wireless communication to access another device on the internal network.

The charging cabinet 26 houses a plurality of terminal devices 20 inside. The terminal device 20 housed inside the charging cabinet 26 can be taken out by the user.

The charging cabinet 26 charges the terminal device 20 housed inside. Further, the charging cabinet 26 can start or shut down the power supply of the terminal device 20 housed inside. The charging cabinet 26 can communicate with the terminal device 20 housed inside by wire. Further, the charging cabinet 26 can also wirelessly communicate with the terminal device 20 in a state where the terminal device 20 housed therein is activated.

Further, the charging cabinet 26 is connected to the internal network. The charging cabinet 26 can operate and communicate with the terminal device 20 housed inside in response to an instruction from an external device.

In such an information processing system 10, each of the plurality of terminal devices 20 is taken out from the charging cabinet 26 by the student before the start of the lesson. During class, the terminal device 20 is used by the student. During the lesson, the terminal device 20 accesses the school server 22 via the wireless communication device 24. As a result, during the lesson, the terminal device 20 can download the material data from the school server 22 and make the student refer to it. Further, during the lesson, the terminal device 20 can upload the information input by the student (for example, the answer to the problem) to the server 22 in the school.

Further, each of the plurality of terminal devices 20 is housed in the charging cabinet 26 after the lesson is completed. The charging cabinet 26 charges the stored terminal device 20 by the start of the next lesson. As a result, the charging cabinet 26 can prevent the terminal device 20 from becoming inoperable due to running out of charge during the lesson.

Further, the charging cabinet 26 operates the stored terminal device 20 in response to a remote control from an external device or the like. Then, the charging cabinet 26 causes the stored terminal device 20 to update the program or install the program in response to a remote control from an external device or the like. As a result, the charging cabinet 26 allows a maintenance worker at a remote location to maintain the terminal device 20.

FIG. 2 is a diagram showing the appearance of the charging cabinet 26. The charging cabinet 26 has a storage area 28 inside. The plurality of terminal devices 20 are stored at predetermined positions in the storage area 28.

Further, the charging cabinet 26 has a charging control device 30 and an information processing device 32. The charge control device 30 executes charge control and communication control for the stored terminal device 20. Further, the information processing device 32 communicates with another device via the internal network. In addition, the information processing device 32 controls the charge control device 30 and wirelessly communicates with the stored terminal device 20.

FIG. 3 is an enlarged view of a peripheral portion of the terminal device 20 housed in the charging cabinet 26. The terminal device 20 housed in the charging cabinet 26 is connected to the charging control device 30 via a cable 34.

The cable 34 can be attached to the terminal device 20. During the storage operation, the terminal device 20 is manually attached to the cable 34 by the user. Further, at the time of removal work, the terminal device 20 is manually removed from the cable 34 by the user.

The cable 34 complies with a standard that defines specifications for power supply and information communication between two devices. In the present embodiment, the cable 34 is a USB Type-C cable conforming to the USB (Universal Serial Bus) -C standard. According to this standard, power can be supplied as well as information is communicated between two devices.

FIG. 4 is a block diagram showing the configuration of the charging cabinet 26 in which the terminal device 20 is housed together with the school server 22 and the wireless communication device 24. The charging cabinet 26 includes a charging control device 30, an information processing device 32, a plurality of cables 34, and a power tap 36.

The charge control device 30 is connected to one or more terminal devices 20 via a cable 34. For each of the one or a plurality of cables 34, one terminal is connected to the charge control device 30, and the other terminal can be connected to the terminal device 20.

The charge control device 30 executes charge control and communication control for each of the one or a plurality of terminal devices 20. The configuration of the charge control device 30 will be described in more detail in FIGS. 10 and 10 and later.

The information processing device 32 is a computer having a communication function and an information processing function. The information processing device 32 is connected to the internal network and performs information communication with other devices on the internal network. In addition, the information processing device 32 performs information communication with other devices on the external network via the school server 22.

Further, the information processing device 32 is connected to the charge control device 30 via the internal communication cable 38. As a result, the information processing device 32 can control the charge control device 30.

The internal communication cable 38 connects the information processing device 32 and the charge control device 30. The internal communication cable 38 is a USB Type-A to C cable conforming to the USB-C standard. The internal communication cable 38 is not limited to this, and may be a cable conforming to other standards.

Further, the information processing device 32 includes an internal wireless communication device 40. The internal wireless communication device 40 is connected to each of one or a plurality of terminal devices 20 housed in the charging cabinet 26 by wireless communication. As a result, the information processing device 32 can transmit and receive information by wireless communication with each of the one or a plurality of terminal devices 20 housed in the charging cabinet 26. The internal wireless communication device 40 may be provided inside the information processing device 32 or may be provided outside the information processing device 32.

The power strip 36 is connected to a commercial AC power outlet provided in the classroom via an AC cable. Further, the power tap 36 has a plurality of sub power outlets. An AC cable for supplying AC power to the information processing device 32 is connected to the sub power outlet of the power tap 36. As a result, the information processing device 32 can operate using AC power as a power source.

Further, an AC cable for supplying AC power to the charge control device 30 is connected to the sub power outlet of the power tap 36. As a result, the charge control device 30 can operate using AC power as a power source. The charge control device 30 and the information processing device 32 may receive DC power from an AC adapter that converts AC power into DC power.

FIG. 5 is a diagram showing a flow of power supply to the terminal device 20 in a state where the terminal device 20 is housed in the charging cabinet 26. The charge control device 30 receives power from a commercial AC power outlet and supplies DC power to the terminal device 20 connected to the cable 34.

The charge control device 30 can change the combination of voltage and current supplied to each of the one or a plurality of terminal devices 20 connected to the cable 34 according to the control from the information processing device 32. As a result, the charge control device 30 can supply power to the plurality of terminal devices 20 within the range of power that can be supplied by the commercial AC power outlet. Further, the charge control device 30 may perform rotary charging in which some terminal devices 20 are sequentially charged according to the control from the information processing device 32.

FIG. 6 is a diagram showing a flow of information when the information processing device 32 controls the terminal device 20 via the cable 34 in a state where the terminal device 20 is housed in the charging cabinet 26.

The information processing device 32 gives various commands to the charge control device 30 via the internal communication cable 38. As a result, the information processing device 32 can control the operation of one or more terminal devices 20 connected to the cable 34. Further, the information processing device 32 receives various notifications from the charge control device 30 via the internal communication cable 38. As a result, the information processing device 32 can detect the state of one or a plurality of terminal devices 20 connected to the cable 34.

FIG. 7 is a diagram showing a flow of information when the information processing device 32 transmits / receives information to / from the terminal device 20 via wireless communication in a state where the terminal device 20 is housed in the charging cabinet 26.

When the terminal device 20 housed in the charging cabinet 26 is activated, the internal wireless communication device 40 of the information processing device 32 provides the terminal device 20 with an access point (first access point) for wireless communication. To do. The information processing device 32 can send and receive information to and from the terminal device 20 housed in the charging cabinet 26 via the first access point.

Further, the information processing device 32 can download data from another device on the external network and transmit the downloaded data to the terminal device 20 housed in the charging cabinet 26 via the first access point. As a result, the information processing device 32 can have the terminal device 20 install the program or have the terminal device 20 update the program.

FIG. 8 is a diagram showing a flow of information when the terminal device 20 accesses the school server 22 in a state where the terminal device 20 is taken out from the charging cabinet 26.

When taken out from the charging cabinet 26, the terminal device 20 connects to the access point (second access point) provided by the wireless communication device 24 by wireless communication. Unlike the internal wireless communication device 40, the wireless communication device 24 is provided outside the charging cabinet 26. Therefore, when taken out of the charging cabinet 26, the terminal device 20 can be connected to the school server 22 on the internal network via a second access point outside the charging cabinet 26.

FIG. 9 is a diagram showing a configuration when the charging cabinet 26 includes a plurality of charging control devices 30. The charging cabinet 26 may have a plurality of charging control devices 30. In the present embodiment, the plurality of charge control devices 30 are cascade-connected by the internal communication cable 38. The information processing device 32 may be individually (parallel) connected to each of the plurality of charge control devices 30.

FIG. 10 is a diagram showing the hardware configuration of the charge control device 30 together with the plurality of terminal devices 20. The charge control device 30 includes an upper conversion unit 42, a device control unit 44, and a plurality of terminal control units 46.

The upper conversion unit 42 is connected to the information processing device 32 via the internal communication cable 38. The upper conversion unit 42 converts the signal format between the signal line of the internal communication cable 38 and the signal line input / output by the device control unit 44 and the plurality of terminal control units 46.

In the present embodiment, the device control unit 44 and the plurality of terminal control units 46 input / output signals in the RS485 format. Therefore, in the present embodiment, the upper conversion unit 42 converts the signal format between USB-C and RS485.

When the device control unit 44 and the plurality of terminal control units 46 input / output USB-C signals, the charge control unit 30 does not have to have the upper conversion unit 42. Further, the upper conversion unit 42 may convert not only RS485 but also other formats.

The device control unit 44 has a processor circuit or the like inside. The device control unit 44 controls the entire charge control device 30.

Each of the plurality of terminal control units 46 can be connected to the terminal device 20 via the cable 34. Each of the plurality of terminal control units 46 executes charge control and communication control for the terminal device 20 connected via the corresponding cable 34. Each of the plurality of terminal control units 46 may be connected to a plurality of terminal devices 20 via a plurality of cables 34.

Further, each of the plurality of terminal control units 46 receives a command from the information processing device 32 via the upper conversion unit 42. Each of the plurality of terminal control units 46 can also execute charge control and communication control in response to a command received from the information processing device 32. Further, each of the plurality of terminal control units 46 notifies the information processing device 32 via the upper conversion unit 42 of the status of the terminal device 20 connected via the corresponding cable 34 and the like.

FIG. 11 is a diagram showing a hardware configuration of the terminal device 20 and a hardware configuration of the terminal control unit 46 in the charge control device 30.

Each of the plurality of terminal control units 46 included in the charge control device 30 includes a charge side PD controller 52 (power supply controller), a charge side communication processor 54, a lower conversion unit 56, and a charge side power supply unit 58.

The charging side PD controller 52 can be connected to the terminal device 20 via the cable 34. The charging-side PD controller 52 performs power supply and information communication in accordance with a standard that defines specifications for power supply and information communication using the cable 34.

In the present embodiment, the charging side PD controller 52 performs power supply and information communication with the terminal device 20 in a manner compliant with the USB-C standard. In the present embodiment, the charging side PD controller 52 transmits and receives a VDM (Vendor Defined Messaging) signal to and from the terminal device 20 via the CC (Configuration Cannel) signal line in the cable 34 conforming to the USB-C standard.

When the charging side PD controller 52 is connected to the terminal device 20 via the cable 34, the charging side PD controller 52 executes a sequence (power delivery sequence) predetermined in the standard with the terminal device 20 to execute the terminal device 20. Determine the combination of voltage and current to supply to. In the present embodiment, the charging side PD controller 52 determines the combination of voltage and current supplied to the terminal device 20 by executing the power delivery sequence defined by the USB-C standard. Then, the charging-side PD controller 52 gives an instruction to the charging-side power supply unit 58 to supply the power of the determined combination of voltage and current to the terminal device 20.

The charging side communication processor 54 includes a CPU (Central Processing Unit), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like, and controls the charging side PD controller 52. The charging-side communication processor 54 expands, for example, a program stored in advance in the ROM into the RAM, and controls according to the program. Further, the charging side communication processor 54 receives a command from the information processing device 32 via the lower conversion unit 56 and the upper conversion unit 42 according to the program. Further, the charging side communication processor 54 notifies the information processing device 32 of the information via the lower conversion unit 56 and the upper conversion unit 42 according to the program.

The lower conversion unit 56 is connected to the upper conversion unit 42 via a bus. The lower conversion unit 56 converts the signal format between the signal line of the bus connected to the upper conversion unit 42 and the signal line input / output by the charging side communication processor 54.

In the present embodiment, the charging side communication processor 54 inputs / outputs a signal in a UART (Universal Asynchronous Receiver / Transmitter) format. Therefore, in this embodiment, the lower conversion unit 56 converts the signal format between RS485 and UART.

When the charging side communication processor 54 inputs / outputs the RS485 signal, the terminal control unit 46 does not have to have the lower conversion unit 56. Further, the lower conversion unit 56 may convert not only RS485 but also other formats.

The charging side power supply unit 58 receives electric power from a power converter that converts AC voltage into direct current. The charging side power supply unit 58 supplies electric power of the combination of voltage and current specified to the terminal device 20 via the cable 34 according to the instruction from the charging side PD controller 52.

The terminal device 20 includes a terminal-side PD controller 62 (power supply controller), a terminal-side communication processor 64, a processing circuit 66, a wireless communication unit 68, a battery 70, a terminal-side power supply unit 72, and a power switch 74. Has.

The terminal-side PD controller 62 can be connected to the charge control device 30 via the cable 34. The terminal-side PD controller 62 receives power supply and performs information communication in accordance with a standard that defines specifications for power supply and information communication using the cable 34.

In the present embodiment, the terminal-side PD controller 62 receives power supply from the charge control device 30 in a manner compliant with the USB-C standard, and also performs information communication. In the present embodiment, the terminal-side PD controller 62 transmits and receives a VDM signal to and from the charge control device 30 via the CC signal line in the cable 34 conforming to the USB-C standard.

When the terminal-side PD controller 62 is connected to the charge control device 30 via the cable 34, the terminal-side PD controller 62 is charged by executing a sequence (power delivery sequence) predetermined in the standard with the charge control device 30. The combination of voltage and current received from the control device 30 is determined. In the present embodiment, the terminal-side PD controller 62 determines the combination of voltage and current received from the charge control device 30 by executing the power delivery sequence defined by the USB-C standard. Then, the terminal-side PD controller 62 gives an instruction to the terminal-side power supply unit 72 to determine and receive the electric power of the combination of voltage and current from the charge control device 30.

The terminal-side communication processor 64 includes a CPU, ROM, RAM, and the like, and controls the terminal-side PD controller 62. The terminal-side communication processor 64 expands, for example, a program stored in advance in the ROM into the RAM, and controls according to the program. For example, the terminal-side communication processor 64 gives the processing circuit 66 information about the charge control device 30 connected via the cable 34 and the like. Further, the terminal-side communication processor 64 controls the state of the power switch 74 based on the information received from the charge control device 30 via the cable 34.

The processing circuit 66 includes a CPU, ROM, RAM, and the like, and executes overall control of the terminal device 20. The processing circuit 66 expands a program stored in advance in the ROM into the RAM, and controls according to the program. The processing circuit 66 gives a command to the terminal-side communication processor 64 or acquires information from the terminal-side communication processor 64 according to the execution of the program. Further, the processing circuit 66 controls the wireless communication unit 68 according to the execution of the program.

The wireless communication unit 68 performs wireless communication according to the control by the processing circuit 66. In the present embodiment, the wireless communication unit 68 wirelessly communicates with the wireless communication device 24 and the internal wireless communication device 40. Then, the wireless communication unit 68 relays information communication between the processing circuit 66 and another device.

The battery 70 is a secondary battery. The battery 70 supplies electric power to each circuit included in the terminal device 20.

The terminal-side power supply unit 72 receives electric power from the battery 70, and supplies the electric power received from the battery 70 to each circuit such as the processing circuit 66 and the wireless communication unit 68 via the power switch 74. The terminal-side PD controller 62, the terminal-side communication processor 64, and the terminal-side power supply unit 72 are constantly supplied with electric power regardless of the power supply state of the terminal device 20.

Further, the terminal-side power supply unit 72 can also receive electric power from the charge control device 30 via the cable 34 in accordance with the instruction from the terminal-side PD controller 62. In this case, the terminal-side power supply unit 72 supplies the electric power received from the charge control device 30 to each circuit such as the processing circuit 66 and the wireless communication unit 68 via the power switch 74. Further, the terminal-side power supply unit 72 charges the battery 70 by supplying the electric power received from the charge control device 30 to the battery 70 via the cable 34.

In the on state, the power switch 74 supplies the power output from the terminal-side power supply unit 72 to each circuit such as the processing circuit 66 and the wireless communication unit 68. The power switch 74 cuts off the power supply to each circuit such as the processing circuit 66 and the wireless communication unit 68 in the off state.

The power switch 74 is a push switch that performs an alternate operation. For example, the power switch 74 switches the state when the power button provided on the housing is pressed by the user. For example, the power switch 74 switches to the on state when the power button is pressed in the off state. Further, the power switch 74 switches to the off state when the power button is pressed in the on state.

The power switch 74 also switches the state by a signal from the circuit inside the terminal device 20. In the present embodiment, the terminal-side communication processor 64 can switch the state of the power switch 74.

FIG. 12 is a diagram showing a functional configuration of the charging side communication processor 54 according to the first embodiment.

The charging-side communication processor 54 according to the first embodiment includes a power supply state management unit 112, a power supply command acquisition unit 114, a power supply switch control unit 116, a power supply status notification unit 118, and a power supply command mask unit 120. The charging side communication processor 54 functions as a power supply state management unit 112, a power supply command acquisition unit 114, a power switch control unit 116, a power supply status notification unit 118, and a power supply command mask unit 120 by executing a predetermined program.

The power state management unit 112 manages whether the power state of the terminal device 20 is the activated state or the non-activated state based on the information received from the terminal device 20 via the cable 34. For example, the charging side PD controller 52 receives a VDM signal from the terminal device 20 via the cable 34, and acquires the power supply state of the terminal device 20 from the received VDM signal. The power supply state management unit 112 acquires the power supply state of the terminal device 20 from the charging side PD controller 52.

The activated state is a state in which the power switch 74 of the terminal device 20 is turned on and the processing circuit 66 (main storage device and CPU) is operating normally. The startup state is also referred to as the S0 state.

The non-started state is a state other than the started state. The power supply state management unit 112 manages the shutdown state, the hibernation state, and the sleep state separately as the non-start state.

The shutdown state is a state in which the power switch 74 of the terminal device 20 is off and power is not supplied to circuits other than the circuits that are always activated. The circuit that is always activated includes, for example, a terminal-side PD controller 62, a terminal-side communication processor 64, and a terminal-side power supply unit 72. The shutdown state is also referred to as the G3 state.

The hibernate state is a state in which the power switch 74 of the terminal device 20 is off and the storage contents of the main storage device of the processing circuit 66 are copied to the non-volatile auxiliary storage device. The non-volatile auxiliary storage device is, for example, a hard disk or a flash memory. The hibernate state is also a state in which power is not supplied to circuits other than the circuits that are always activated. The hibernation state is also referred to as the S4 state.

The sleep state is a state in which the power switch 74 of the terminal device 20 is turned on, and power is not supplied to circuits other than the processing circuit 66 (main storage device and CPU) and the circuit that is always activated. The sleep state is also referred to as the S3 state. In the sleep state, power is supplied to the main storage device of the processing circuit 66, but the CPU may not be operating.

The power command acquisition unit 114 receives a wake-up command for activating the terminal device 20 from the information processing device 32. Further, the power command acquisition unit 114 receives a shutdown command for shutting down the terminal device 20 from the information processing device 32.

The power switch control unit 116 gives an instruction to output a switch push signal to the terminal device 20 to the charging side PD controller 52 when the power command acquisition unit 114 receives a wakeup command or a shutdown command. The switch push signal is a signal for switching the state of the power switch 74 of the terminal device 20.

Here, when the charging side PD controller 52 receives an instruction to output the switch push signal to the terminal device 20, the charging side PD controller 52 transmits the switch push signal to the terminal device 20 via the cable 34. The terminal-side PD controller 62 of the terminal device 20 acquires the switch push signal transmitted from the charging-side PD controller 52. The terminal-side communication processor 64 of the terminal device 20 switches the state of the power switch 74 when the terminal-side PD controller 62 acquires the switch push signal. For example, when the power switch 74 acquires the switch push signal in the on state, the terminal-side communication processor 64 switches the power switch 74 to the off state. Further, when the switch push signal is acquired while the power switch 74 is in the off state, the terminal-side communication processor 64 switches the power switch 74 to the on state.

When the power state of the terminal device 20 managed by the power state management unit 112 changes, the power state notification unit 118 notifies the information processing device 32 of the changed power state. As a result, the power supply status notification unit 118 can notify the information processing device 32 of the power supply status of the terminal device 20.

For example, in the power status notification unit 118, when the terminal device 20 is in the activated state and the power command acquisition unit 114 receives the shutdown command, the power status of the terminal device 20 is changed after the terminal device 20 changes from the activated state to the non-activated state. The notification information indicating the status is returned to the information processing device 32. As a result, the power supply status notification unit 118 can notify the information processing device 32 that the terminal device 20 has changed to the non-started state.

For example, in the power status notification unit 118, when the terminal device 20 is in the non-started state and the power command acquisition unit 114 receives the wakeup command, the terminal device 20 changes from the non-started state to the activated state, and then the terminal device 20 The notification information indicating the power supply status of the above is returned to the information processing apparatus 32. As a result, the power supply status notification unit 118 can notify the information processing device 32 that the terminal device 20 has changed to the activated state.

The power command mask unit 120 masks the wake-up command when the terminal device 20 receives the wake-up command in the activated state. As a result, the power command mask unit 120 can control the charging side PD controller 52 so as not to output the switch push signal to the terminal device 20. Therefore, the power command mask unit 120 puts the terminal device 20 in the non-started state even when the wake-up command is transmitted from the information processing device 32 even though the terminal device 20 is in the activated state. Instead, the activated state of the terminal device 20 can be maintained.

Further, when the terminal device 20 receives the wakeup command in the activated state, the power command mask unit 120 returns the notification information indicating the power state (activated state) of the terminal device 20 to the information processing device 32. As a result, the power command mask unit 120 can notify the information processing device 32 that the terminal device 20 is already in the activated state.

Further, the power command mask unit 120 masks the shutdown command when the terminal device 20 receives the shutdown command in the non-started state. As a result, the power command mask unit 120 can control the charging side PD controller 52 so as not to output the switch push signal to the terminal device 20. Therefore, the power command mask unit 120 does not put the terminal device 20 into the activated state even when the shutdown command is transmitted from the information processing device 32 even though the terminal device 20 is in the non-started state. , The non-started state of the terminal device 20 can be maintained.

Further, when the terminal device 20 receives the shutdown command in the non-started state, the power command mask unit 120 returns the notification information indicating the power state of the terminal device 20 to the information processing device 32. As a result, the power command mask unit 120 can notify the information processing device 32 that the terminal device 20 is already in the non-started state.

FIG. 13 is a flowchart showing a processing flow of the charging side communication processor 54 according to the first embodiment. In the first embodiment, the charging side communication processor 54 executes the process in the flow as shown in FIG.

First, in S111, the charging side communication processor 54 determines whether or not a power command (wakeup command or shutdown command) has been acquired from the information processing device 32. When the charging side communication processor 54 does not acquire the power command (No in S111), the charging side communication processor 54 waits in S111 for processing. When the charging side communication processor 54 acquires the power command (Yes in S111), the charging side communication processor 54 proceeds to the process in S112.

Subsequently, in S112, the charging side communication processor 54 determines whether or not the power supply command is a wakeup command. If the charging side communication processor 54 is not a wakeup command, that is, if it is a shutdown command (No in S112), the process proceeds to S113, and if it is a wakeup command (Yes in S112), the process proceeds to S119.

In S113, the charging side communication processor 54 determines whether or not the terminal device 20 is in the activated state. When the charging side communication processor 54 is in the activated state (Yes in S113), the process proceeds to S114, and when it is not in the activated state (No in S113), the process proceeds to S117.

In S114, the charging side communication processor 54 gives an output instruction of the switch push signal to the charging side PD controller 52. As a result, the charging side PD controller 52 can transmit the switch push signal to the terminal device 20.

Subsequently, in S115, the charging side communication processor 54 determines whether or not the terminal device 20 has shut down. When the terminal device 20 does not shut down (No in S115), the charging-side communication processor 54 waits for processing in S115. When the terminal device 20 shuts down (Yes in S115), subsequently, in S116, the charging side communication processor 54 returns the notification information indicating the shutdown state to the information processing device 32. When S116 is finished, the charging side communication processor 54 ends this flow.

In S117, the charging side communication processor 54 masks the received shutdown command. As a result, the charging side communication processor 54 does not give any instruction to the charging side PD controller 52. Therefore, the charging side PD controller 52 does not transmit the switch push signal. Subsequently, in S118, the charging side communication processor 54 returns the notification information indicating the current power state of the terminal device 20 to the information processing device 32. When S118 is finished, the charging side communication processor 54 ends this flow.

On the other hand, in S119, the charging side communication processor 54 determines whether or not the terminal device 20 is in the non-activated state. When the charging side communication processor 54 is in the non-activated state (Yes in S119), the process proceeds to S120, and when it is not in the non-activated state (No in S119), the process proceeds to S123.

In S120, the charging side communication processor 54 gives an output instruction of the switch push signal to the charging side PD controller 52. As a result, the charging side PD controller 52 can transmit the switch push signal to the terminal device 20.

Subsequently, in S121, the charging side communication processor 54 determines whether or not the power state of the terminal device 20 has changed. When the power state of the terminal device 20 does not change (No in S121), the charging-side communication processor 54 waits for processing in S121. When the power supply state of the terminal device 20 changes (Yes in S121), subsequently, in S122, the charging side communication processor 54 returns the notification information indicating the current power supply state of the terminal device 20 to the information processing device 32. When S122 is completed, the charging side communication processor 54 ends this flow.

In S123, the charging side communication processor 54 masks the received wakeup command. As a result, the charging side communication processor 54 does not give any instruction to the charging side PD controller 52. Therefore, the charging side PD controller 52 does not transmit the switch push signal. Subsequently, in S124, the charging side communication processor 54 returns the notification information indicating the activation state to the information processing device 32. When S124 is finished, the charging side communication processor 54 ends this flow.

When the terminal device 20 is in the sleep state and the shutdown command is acquired, the charging side communication processor 54 may give an output instruction of the switch push signal to the charging side PD controller 52 without masking the shutdown command. As a result, the charging side communication processor 54 can shut down the terminal device 20 when the terminal device 20 is in the sleep state and the shutdown command is acquired.

Further, when the terminal device 20 is in the hibernation state and the shutdown command is acquired, the charging side communication processor 54 gives an output instruction of the switch push signal to the charging side PD controller 52 to activate the terminal device 20. After that, the charging side communication processor 54 may give an output instruction of the switch push signal to the charging side PD controller 52 again. As a result, the charging side communication processor 54 can shut down the terminal device 20 when the terminal device 20 is in the hibernation state and the shutdown command is acquired.

Further, when the charging side communication processor 54 acquires the wakeup command in the sleep state, the charging side receives a signal output instruction for transitioning the terminal device 20 from the sleep state to the activation state instead of the switch push signal output instruction. It may be given to the PD controller 52. As a result, the charging side communication processor 54 can put the terminal device 20 into the activated state when the terminal device 20 is in the sleep state and the wakeup command is acquired.

The charge control device 30 according to the first embodiment as described above has the following effects.

The charge control device 30 according to the first embodiment masks the wake-up command when the terminal device 20 receives the wake-up command in the activated state. As a result, the charge control device 30 according to the first embodiment does not use the terminal device 20 even when the information processing device 32 transmits a wake-up command even though the terminal device 20 is in the activated state. It is possible to maintain the activated state of the terminal device 20 without setting it to the activated state. Therefore, according to the charge control device 30 according to the first embodiment, the power supply state of the terminal device 20 can be appropriately switched according to the control from the information processing device 32.

Further, the charge control device 30 according to the first embodiment masks the shutdown command when the terminal device 20 receives the shutdown command in the non-started state. As a result, according to the charge control device 30 according to the first embodiment, even when the information processing device 32 transmits a shutdown command even though the terminal device 20 is in the non-started state, the terminal device 20 Can be maintained in the non-started state of the terminal device 20 without setting the in the activated state.

Further, in the charge control device 30 according to the first embodiment, when the terminal device 20 receives a shutdown command in the activated state, the power state of the terminal device 20 is changed after the terminal device 20 changes from the activated state to the non-activated state. The indicated notification information is returned to the information processing apparatus 32. Further, the charge control device 30 according to the first embodiment powers the terminal device 20 after the terminal device 20 changes from the non-started state to the activated state when the terminal device 20 receives a wakeup command in the non-activated state. The notification information indicating the status is returned to the information processing device 32. As a result, according to the charge control device 30 according to the first embodiment, the power state of the terminal device 20 can be notified to the information processing device 32.

Further, when the charge control device 30 according to the first embodiment receives a wakeup command in the activated state, the charge control device 30 returns notification information indicating the power state of the terminal device 20 to the information processing device 32. Further, when the charge control device 30 according to the first embodiment receives a shutdown command in the non-started state, the charge control device 30 returns notification information indicating the power state of the terminal device 20 to the information processing device 32. As a result, according to the charge control device 30 according to the first embodiment, the power state of the terminal device 20 can be notified to the information processing device 32.

Further, the charge control device 30 according to the first embodiment manages whether the power state of the terminal device 20 is the activated state or the non-activated state based on the information received from the terminal device 20 via the cable 34. To do. As a result, according to the charge control device 30 according to the first embodiment, the shutdown command and the wakeup command can be reliably masked.

Further, the charge control device 30 according to the first embodiment manages the shutdown state, the hibernation state, and the sleep state separately as the non-start state. As a result, according to the charge control device 30 according to the first embodiment, the shutdown command can be reliably masked.

(Second Embodiment)
Next, the information processing system 10 according to the second embodiment will be described. The information processing system 10 according to the second embodiment has the same hardware configuration as that of the first embodiment. The information processing system 10 according to the second embodiment has a different functional configuration of the charging side communication processor 54 provided in the charging control device 30 as compared with the first embodiment.

FIG. 14 is a diagram showing a functional configuration of the charging side communication processor 54 according to the second embodiment.

The charging-side communication processor 54 according to the second embodiment includes a change command acquisition unit 212, a reconnection control unit 214, and a profile change unit 216. The charging side communication processor 54 functions as a change command acquisition unit 212, a reconnection control unit 214, and a profile change unit 216 by executing a predetermined program.

The change command acquisition unit 212 receives a change command from the information processing device 32 instructing the change of the voltage to be supplied to the terminal device 20 and the current to be supplied. The change command contains information indicating the changed voltage and current combination.

When the combination of voltage and current supplied to the terminal device 20 is changed, the reconnection control unit 214 causes the charging side PD controller 52 to disconnect the power supply and information communication by the cable 34 with the terminal device 20. For example, the reconnection control unit 214 causes the charging side PD controller 52 to disconnect the power supply and information communication by the cable 34 from the terminal device 20 when the change command acquisition unit 212 receives the change command. Note that the reconnection control unit 214 may disconnect the power supply and information communication by the cable 34 from the terminal device 20 when another predetermined event occurs instead of receiving the change command. Good.

Then, the reconnection control unit 214 disconnects the power supply and information communication by the cable 34 from the terminal device 20, and then reconnects the power supply and information communication by the cable 34 from the terminal device 20.

For example, the reconnection control unit 214 causes the charging side PD controller 52 to disconnect the power supply and information communication by the cable 34 with the terminal device 20 by instructing the charging side PD controller 52 to reset. Further, for example, the reconnection control unit 214 reconnects the power supply and information communication with the terminal device 20 by the cable 34 to the charging side PD controller 52 by instructing the charging side PD controller 52 to release the reset. Let me. As a result, the reconnection control unit 214 can surely cause the charging side PD controller 52 to disconnect and reconnect the power supply and the information communication with the terminal device 20 by the cable 34. ..

The profile changing unit 216 sets the charging side PD controller 52 with a power profile indicating the combination of voltage and current that can be supplied to the terminal device 20 when the combination of voltage and current supplied to the terminal device 20 is changed. For example, the profile change unit 216 sets a power profile indicating a combination of voltage and current that can be supplied to the terminal device 20 in the charging side PD controller 52 when the change command acquisition unit 212 receives the change command.

Here, the charging side PD controller 52 executes the following procedure as a power delivery sequence. First, the charging side PD controller 52 transmits power delivery object information including one or a plurality of preset power profiles to the terminal device 20. Subsequently, the charging side PD controller 52 receives a response indicating the power profile requested by the terminal device 20 from the terminal device 20. Then, the charging side PD controller 52 starts supplying power to the terminal device 20 according to the power profile shown in the response. By executing such a procedure, the charging side PD controller 52 can determine the combination of voltage and current to be supplied to the terminal device 20.

When such a power delivery sequence is executed, the profile changing unit 216 disconnects the power supply and information communication by the cable 34 from the terminal device 20, and then performs the power supply and information communication by the cable 34 from the terminal device 20. Before reconnecting, a power profile indicating the voltage and current that can be supplied to the terminal device 20 is set in the charging side PD controller 52. As a result, the profile changing unit 216 can surely set the power profile to the charging side PD controller 52 before the charging side PD controller 52 transmits the power delivery object information to the terminal device 20.

For example, in the profile changing unit 216, after the reconnection control unit 214 instructs the charging side PD controller 52 to release the reset, and before the charging side PD controller 52 transmits the power delivery object information to the terminal device 20. The charging side PD controller 52 is set with a power profile that requests supply to the terminal device 20. As a result, the profile changing unit 216 can reliably set the power profile to the charging side PD controller 52 when the reconnection control unit 214 resets and cancels the reset with respect to the charging side PD controller 52. ..

Here, in the standard that defines the specifications for power supply and information communication using the cable 34, the charging side PD controller 52 changes the power profile while maintaining the connection between the terminal device 20 and the cable 34. Can't. For example, in the USB-C standard, the charging side PD controller 52 cannot change the power profile while maintaining the power supply and the information communication connection via the cable 34.

However, the charging-side communication processor 54 according to the second embodiment disconnects the power supply and information communication by the cable 34 with the terminal device 20. After that, the charging side communication processor 54 according to the second embodiment reconnects the power supply and the information communication by the cable 34 with the terminal device 20. Then, the charging-side communication processor 54 according to the second embodiment sets a power profile indicating a combination of voltage and current that can be supplied to the terminal device 20 when the power supply and information communication are reconnected, to the charging-side PD controller 52. Set to.

As a result, the charging side communication processor 54 can arbitrarily change the combination of voltage and current supplied to the terminal device 20. For example, the charging side communication processor 54 can set the voltage and current to be supplied to the terminal device 20 according to the instruction from the information processing device 32.

FIG. 15 is a sequence diagram showing a processing flow of the charging side communication processor 54 according to the second embodiment. In the second embodiment, the charging side communication processor 54, the charging side PD controller 52, and the terminal side PD controller 62 execute the processing in the flow as shown in FIG.

First, in S211 the charging side PD controller 52 and the terminal side PD controller 62 are physically connected by the cable 34.

Subsequently, in S212, the charging side PD controller 52 transmits power delivery object information (source PDO) including one or a plurality of power profiles set internally in advance to the terminal side PD controller 62.

In the USB-C standard, "5V / 900mA", "5V / 3A", "9V / 3A", "12V / 3A", "15V / 3A" and "20V / 3A" are defined as power profiles. .. In the USB-C standard, the charging side PD controller 52 is among "5V / 900mA", "5V / 3A", "9V / 3A", "12V / 3A", "15V / 3A" and "20V / 3A". Source PDO containing one or more power profiles that the charging PD controller 52 can supply.

Further, in the USB-C standard, the minimum voltage and the minimum current "5V / 900mA" are defined as the default power profile. It is stipulated that devices conforming to the USB-C standard must be able to supply and receive power with the default power profile.

Subsequently, in S213, the terminal-side PD controller 62 determines one of the one or more power profiles shown in the source PDO that requests reception. Then, the terminal-side PD controller 62 transmits a response indicating the determined power profile to the charging-side PD controller 52.

Subsequently, in S214, the charging-side PD controller 52 starts supplying power to the terminal-side PD controller 62 with the power profile shown in the response.

The processing from S212 to S214 is called a power delivery sequence. In the USB-C standard, the charging side PD controller 52 and the terminal side PD controller 62 cannot change the determined power profile while maintaining the connection of the cable 34 after the power delivery sequence is completed.

Subsequently, in S215, the charging side communication processor 54 acquires a change command instructing the change of the voltage to be supplied to the terminal device 20 and the current to be supplied from the information processing device 32. The change command includes a combination of voltage and current that the information processing device 32 requires to supply to the terminal device 20.

Subsequently, in S216, the charging side communication processor 54 instructs the charging side PD controller 52 to reset. When the reset instruction is received, the charging side PD controller 52 executes the reset in S217. When the reset is executed, the charging side PD controller 52 disconnects the power supply and information communication by the cable 34 with the cable 34 inserted in the connector. As a result, in S218, the charging side PD controller 52 and the terminal side PD controller 62 are pseudo-disconnected. That is, the charging side PD controller 52 and the terminal side PD controller 62 are visually connected by the cable 34, but are disconnected at the level of the internal signal line.

Subsequently, in S219, the charging side communication processor 54 instructs the charging side PD controller 52 to release the reset. Upon receiving the instruction to release the reset, the charging side PD controller 52 executes the reset release in S220. When the reset release is executed, the charging side PD controller 52 connects, for example, power supply and information communication by the cable 34. As a result, in S221, the charging side PD controller 52 and the terminal side PD controller 62 are pseudo-connected. That is, the charging-side PD controller 52 and the terminal-side PD controller 62 are connected by the cable 34 both visually and at the level of the internal signal line.

Subsequently, in S222, the charging side communication processor 54 sets the power profile to the charging side communication processor 54. The power profile set at this time indicates the voltage and current included in the change command. That is, the power profile set at this time indicates a combination of voltage and current that the information processing device 32 requires to be supplied to the terminal device 20 after the change. Subsequently, in S223, the charging side communication processor 54 internally stores the set power profile. The power profile to be set is one or more power profiles, and the default power profile source PDO "5V / 900mA" or "5V / 3A", "9V / 3A", "9V / 3A", which is predetermined in the USB-C standard. 12V / 3A ”,“ 15V / 3A ”and“ 20V / 3A ”.

Subsequently, in S224, the charging side PD controller 52 transmits the power delivery object information (source PDO) including the power profile stored in S223 to the terminal side PD controller 62.

In this case, the charging side PD controller 52 transmits the source PDO including the power profile stored in S223.

Subsequently, in S225, the terminal-side PD controller 62 determines one of the one or more power profiles shown in the source PDO that requests reception. Then, the terminal-side PD controller 62 transmits a response indicating the determined power profile to the charging-side PD controller 52.

Subsequently, in S226, the charging-side PD controller 52 starts supplying power to the terminal-side PD controller 62 with the power profile shown in the response.

In the present embodiment, the charging side communication processor 54 sets a reset instruction, a reset release instruction, and a power profile in response to the acquisition of the change command from the information processing device 32. Instead, the charging side communication processor 54 may give a reset instruction and a reset release instruction in response to the occurrence of another event.

For example, the charging side communication processor 54 may set a reset instruction, a reset release instruction, and a power profile according to the completion of charging of the terminal device 20. Further, for example, the charging side communication processor 54 may set a reset instruction, a reset release instruction, and a power profile at regular time intervals.

The charge control device 30 according to the second embodiment as described above has the following effects.

The charge control device 30 according to the second embodiment disconnects the power supply and information communication by the cable 34 from the terminal device 20, and then reconnects the power supply and information communication by the cable 34 from the terminal device 20. Then, the charge control device 30 according to the second embodiment provides the charging side PD controller 52 with a power profile indicating a combination of voltage and current that can be supplied to the terminal device 20 when the power supply and information communication are reconnected. Set. As a result, according to the charge control device 30 according to the second embodiment, the setting of the power supply to the terminal device 20 can be switched.

Further, the charge control device 30 according to the second embodiment executes a power delivery sequence with the terminal device 20. Thereby, according to the charge control device 30 according to the second embodiment, the combination of the voltage and the current supplied to the terminal device 20 can be changed.

Further, the charge control device 30 according to the second embodiment is after disconnecting the power supply and information communication by the cable 34 with the terminal device 20 and before reconnecting the power supply and information communication by the cable 34 with the terminal device 20. In addition, the power profile is set in the charging side PD controller 52. As a result, according to the charge control device 30 according to the second embodiment, the power profile can be reliably set in the charge side PD controller 52.

Further, the charging control device 30 according to the second embodiment disconnects the power supply and information communication from the charging side PD controller 52 by the cable 34 from the terminal device 20 by instructing the charging side PD controller 52 to reset. Let me. Further, the charging control device 30 according to the second embodiment instructs the charging side PD controller 52 to release the reset, so that the charging side PD controller 52 is supplied with power and information communication by the cable 34 with the terminal device 20. To reconnect. As a result, according to the charge control device 30 according to the second embodiment, the power supply and the information communication can be reliably disconnected and reconnected.

Further, the charging control device 30 according to the second embodiment sends the terminal to the charging side PD controller 52 after instructing the release of the reset and before the charging side PD controller 52 transmits the power delivery object information to the terminal device 20. Set the power profile that requires the supply to the device 20. As a result, according to the charge control device 30 according to the second embodiment, when the reconnection control unit 214 resets and releases the reset to the charging side PD controller 52, the power profile is surely set to the charging side PD. It can be set in the controller 52.

(Third Embodiment)
Next, the information processing system 10 according to the third embodiment will be described. The information processing system 10 according to the third embodiment has the same hardware configuration as the first and second embodiments. The information processing system 10 according to the third embodiment has a different functional configuration of the charging side communication processor 54 provided in the charging control device 30 as compared with the second embodiment.

FIG. 16 is a diagram showing a functional configuration of the charging side communication processor 54 according to the third embodiment.

The charging side communication processor 54 according to the third embodiment includes a change command acquisition unit 212, a reconnection control unit 214, a profile change unit 216, a sequence management unit 312, a supply power management unit 314, and a change command mask unit. It is equipped with 316. By executing a predetermined program, the charging side communication processor 54 serves as a change command acquisition unit 212, a reconnection control unit 214, a profile change unit 216, a sequence management unit 312, a power supply management unit 314, and a change command mask unit 316. Function.

The charging side communication processor 54 according to the third embodiment is configured to further include a sequence management unit 312, a power supply management unit 314, and a change command mask unit 316 as compared with the second embodiment. The charging side communication processor 54 according to the third embodiment will be described focusing on the differences from the second embodiment.

The sequence management unit 312 manages whether or not a power delivery sequence for determining the supply voltage and supply current for the terminal device 20 is being executed. For example, the sequence management unit 312 acquires and stores a notification indicating whether or not the power delivery sequence is being executed from the charging side PD controller 52.

The change command acquisition unit 212 receives a change command instructing the change of the voltage supplied from the information processing device 32 to the terminal device 20 and the current supplied. Further, in the present embodiment, the change command acquisition unit 212 refuses to receive the change command from the information processing device 32 during the execution of the power delivery sequence. The change command acquisition unit 212 determines whether or not the power delivery sequence is being executed based on the information stored by the sequence management unit 312.

As a result, the change command acquisition unit 212 is reset during the execution of the power delivery sequence, so that it is possible to prevent the charging side PD controller 52 from performing an unexpected operation. Further, since the change command acquisition unit 212 is reset during the execution of the power delivery sequence, it is possible to prevent the charging side PD controller 52 from generating an unexpected error. Therefore, according to the charge control device 30, the charging side PD controller 52 can surely execute the power delivery sequence.

Further, when the reception of the change command is refused, the change command acquisition unit 212 returns the notification information indicating that the reception of the change command is refused to the information processing apparatus 32. As a result, the change command acquisition unit 212 can notify the information processing apparatus 32 that the reception of the change command has been refused.

The power supply management unit 314 manages which power profile the charging-side PD controller 52 supplies power to the terminal device 20. For example, the supply power management unit 314 acquires and stores a notification of which power profile the charging side PD controller 52 is supplying power to after the charging side PD controller 52 executes the power delivery sequence. .. For example, in the case of the USB-C standard, the power supply management unit 314 has "5V / 900mA", "5V / 3A", "9V / 3A", "12V / 3A", "15V / 3A" or "20V / 3A". Memorize which power profile of "" is being supplied.

The change command mask unit 316 is a change command instructing that when the change command acquisition unit 212 acquires a change command, power is supplied according to the default power profile, or power is supplied according to the non-default power profile. Judge whether it is a change command that instructs.

The default power profile is a standard that defines specifications for power supply and information communication using a cable 34, and indicates a combination of voltage and current defined as a default. The non-default power profile is a standard that defines specifications for power supply and information communication using a cable 34, and indicates a non-default combination of voltage and current.

For example, the default power profile indicates the combination of the lowest voltage and the lowest current of a plurality of voltages and currents that the standard defines as available. For example, in the USB-C standard, the combination of "5V / 900mA" is the default power profile. Further, in the USB-C standard, combinations other than "5V / 900mA", that is, "5V / 3A", "9V / 3A", "12V / 3A", "15V / 3A" and "20V / 3A" are not included. This is the default power profile.

Further, when the change command acquisition unit 212 acquires the change command, the change command mask unit 316 is in a state of supplying power according to the power profile defined as the default based on the information from the supply power management unit 314. It is determined whether the power is being supplied according to the power profile defined as non-default.

Then, when the change command mask unit 316 receives the change command instructing the power supply according to the default power profile in the state where the power is supplied according to the default power profile, the change command mask unit 316 masks the change command. Further, the change command mask unit 316 masks the change command when it receives a change command instructing the power to be supplied according to the non-default power profile while the power is being supplied according to the non-default power profile. ..

If the change command is masked, the reconnection control unit 214 does not receive the change command. Therefore, when the change command is masked, the reconnection control unit 214 does not give a reset instruction and a reset release instruction to the charging side PD controller 52. Further, when the change command is masked, the profile change unit 216 does not receive the change command. Therefore, when the change command is masked, the profile change unit 216 does not set the power profile for the charging side PD controller 52.

As a result, when the change command mask unit 316 receives the change command instructing the power supply according to the default power profile in the state where the power is supplied according to the default power profile, the change command mask unit 316 supplies the power to the terminal device 20. It is possible to keep the voltage and current unchanged. Further, as a result, when the change command mask unit 316 receives the change command instructing to supply the power according to the non-default power profile in the state where the power is supplied according to the non-default power profile, the terminal device It is possible to keep the voltage and current supplied to 20 unchanged.

Therefore, according to the change command mask unit 316, it is possible to eliminate unnecessary execution of a power delivery sequence that causes the same power profile to be changed.

FIG. 17 is a flowchart showing a processing flow of the charging side communication processor 54 according to the third embodiment. In the third embodiment, the charging side communication processor 54 executes the process in the flow as shown in FIG.

First, in S311 the charging side communication processor 54 determines whether or not a change command has been acquired from the information processing device 32. If the charging side communication processor 54 does not acquire the change command (No in S311), the charging side communication processor 54 waits in S311 for processing. When the charging side communication processor 54 acquires the change command (Yes in S311), the charging side communication processor 54 proceeds to the process in S312.

Subsequently, in S312, the charging side communication processor 54 determines whether or not the power delivery sequence is being executed. When the power delivery sequence is being executed (Yes in S312), the charging-side communication processor 54 advances the process to S313, and when the power delivery sequence is not being executed (No in S312), the process proceeds to S314.

In S313, the charging side communication processor 54 refuses to receive the change command. Further, in S313, the charging side communication processor 54 may notify the information processing device 32 that it has refused to receive the change command. When S313 is finished, the charging side communication processor 54 ends this flow.

In S314, the charging side communication processor 54 determines whether or not it is a change command instructing to supply power according to the default power profile. If it is a change command instructing to supply power according to the default power profile (Yes in S314), the charging side communication processor 54 advances the process to S315. If it is not a change command instructing to supply power according to the default power profile, that is, if it is a change command instructing to supply power according to the non-default power profile (No in S314), the charging side communication processor 54 Advances the process to S318.

In S315, the charging side communication processor 54 determines whether or not the currently set power profile is the default. If the currently set power profile is the default (Yes in S315), in S316, the charging side communication processor 54 masks the change command. As a result, the charging side communication processor 54 does not execute any processing. Therefore, the charging side PD controller 52 does not execute the power delivery sequence. Then, when the processing of S316 is completed, the charging side communication processor 54 ends this flow.

If the currently set power profile is not the default, that is, if the currently set power profile is non-default (No in S315), the charging side communication processor 54 advances processing to S317. In S317, the charging side communication processor 54 causes the charging side PD controller 52 to execute a power delivery sequence so as to supply power according to the default power profile. Then, when the process of S317 is completed, the charging side communication processor 54 ends this flow.

In S318, the charging side communication processor 54 determines whether or not the currently set power profile is non-default. If the currently set power profile is non-default (Yes in S318), in S319, the charging side communication processor 54 masks the change command. As a result, the charging side communication processor 54 does not execute any processing. Therefore, the charging side PD controller 52 does not execute the power delivery sequence. Then, when the processing of S319 is completed, the charging side communication processor 54 ends this flow.

If the currently set power profile is not non-default, that is, if the currently set power profile is the default (No in S318), the charging side communication processor 54 advances processing to S320. In S320, the charging side communication processor 54 causes the charging side PD controller 52 to execute a power delivery sequence so as to supply power according to the non-default power profile indicated by the change command. Then, when the processing of S320 is completed, the charging side communication processor 54 ends this flow.

The charge control device 30 according to the third embodiment as described above has the following effects.

The charge control device 30 according to the third embodiment refuses to receive the change command during the execution of the power delivery sequence that determines the supply voltage and supply current to the terminal device 20. As a result, according to the charge control device 30 according to the third embodiment, the charging side PD controller 52 may perform an unexpected operation, or the charging side PD controller 52 may generate an unexpected error. Can be avoided. Therefore, according to the charge control device 30 according to the third embodiment, the charge side PD controller 52 can surely execute the power delivery sequence.

Further, the charge control device 30 according to the third embodiment transmits power delivery object information to the terminal device 20 in the power delivery sequence, receives a response indicating the power profile requested by the terminal device 20, and is shown in the response. The power supply to the terminal device 20 is started according to the power profile. As a result, according to the charge control device 30 according to the third embodiment, the combination of voltage and current supplied to the terminal device 20 can be changed.

Further, when the charge control device 30 according to the third embodiment refuses to receive the change command, the charge control device 30 returns to the information processing device 32 notification information indicating that the reception of the change command is refused. As a result, the information processing apparatus 32 can be notified that the reception of the change command has been refused.

Further, when the charge control device 30 according to the third embodiment receives a change command instructing to supply power according to the default power profile in a state where power is supplied according to the power profile defined as the default. , Mask the change command. As a result, according to the charge control device 30 according to the third embodiment, it is possible to eliminate unnecessary execution of a power delivery sequence that causes the same power profile to be changed.

Further, the charge control device 30 according to the third embodiment receives a change command instructing to supply power according to the non-default power profile in a state where power is supplied according to the power profile defined as non-default. If so, mask the change command. As a result, according to the charge control device 30 according to the third embodiment, it is possible to eliminate unnecessary execution of a power delivery sequence that causes the same power profile to be changed.

Also, in the third embodiment, the default power profile indicates a combination of the lowest voltage and the lowest current among the plurality of voltages and the plurality of currents defined in the standard as available. As a result, according to the charge control device 30 according to the third embodiment, the combination of the minimum voltage and the minimum current can be managed as the default power profile.

(Fourth Embodiment)
Next, the information processing system 10 according to the fourth embodiment will be described. The information processing system 10 according to the fourth embodiment has the same hardware configuration as the first to third embodiments. The information processing system 10 according to the fourth embodiment has a different functional configuration of the charging side communication processor 54 provided in the charging control device 30 as compared with the second and third embodiments.

FIG. 18 is a diagram showing a functional configuration of the charging side communication processor 54 according to the fourth embodiment.

The charging side communication processor 54 according to the fourth embodiment includes a change command acquisition unit 212, a reconnection control unit 214, a profile change unit 216, a sequence management unit 312, a cable status management unit 412, and a cable status notification unit. A 414 and a notification mask unit 416 are provided. By executing a predetermined program, the charging side communication processor 54 executes a change command acquisition unit 212, a reconnection control unit 214, a profile change unit 216, a sequence management unit 312 and a cable status management unit 412, a cable status notification unit 414, and the like. It functions as a notification mask unit 416.

The charging side communication processor 54 according to the fourth embodiment has a configuration further including a sequence management unit 312, a cable state management unit 412, a cable state notification unit 414, and a notification mask unit 416 as compared with the second embodiment. The charging-side communication processor 54 according to the fourth embodiment may further include a cable state management unit 412, a cable state notification unit 414, and a notification mask unit 416 in addition to the configuration of the third embodiment. The charging side communication processor 54 according to the fourth embodiment will be described focusing on the differences from the second embodiment and the third embodiment.

The cable state management unit 412 manages the connection state of the cable 34 between the charging side PD controller 52 and the terminal device 20. That is, the cable state management unit 412 manages whether the power supply and information communication by the cable 34 are in the connected state or the disconnected state between the charging side PD controller 52 and the terminal device 20. For example, the cable state management unit 412 acquires and stores a notification indicating whether the power supply and information communication by the cable 34 are in the connected state or the disconnected state from the charging side PD controller 52.

When the connection status of the cable 34 is changed, the cable status notification unit 414 transmits notification information indicating the connection status of the cable 34 to the information processing device 32. That is, the cable status notification unit 414 transmits notification information indicating whether the power supply and information communication by the cable 34 is in the connected state or the disconnected state between the charging side PD controller 52 and the terminal device 20.

The notification mask unit 416 masks the notification information of the connection state of the cable 34 to the information processing device 32 during the execution of the power delivery sequence that changes the combination of the voltage and the current supplied to the terminal device 20. The notification mask unit 416 determines whether or not the power delivery sequence is being executed based on the information managed by the sequence management unit 312.

When the notification information of the connection state of the cable 34 is masked, the charge control device 30 does not transmit the notification information to the information processing device 32. Therefore, the notification mask unit 416 can prevent the notification information of the connection state of the cable 34 from being transmitted to the information processing device 32 during the execution of the power delivery sequence.

The charging-side PD controller 52 according to the present embodiment disconnects the power supply and information communication by the cable 34 during execution of the power delivery sequence, and then reconnects the power supply and information communication by the cable 34. Therefore, the cable status notification unit 414 outputs the notification information twice during the execution of the power delivery sequence. However, the information processing device 32 does not perform information processing using the connection information and the disconnection information of the cable 34 during the execution of the power delivery sequence.

Therefore, the notification mask unit 416 masks the notification information of the connection state during the execution of the power delivery sequence. As a result, the notification mask unit 416 can eliminate unnecessary communication and simplify the process.

Further, after the completion of the power delivery sequence, the connection state between the charging side PD controller 52 and the terminal device 20 usually does not change. However, it is possible that the connection state of the cable 34 between the charging side PD controller 52 and the terminal device 20 may change for some reason.

Therefore, when the cable 34 changes from the connection state before the start of the sequence after the end of the power delivery sequence, the cable status notification unit 414 transmits the notification information to the information processing device 32. As a result, the cable status notification unit 414 can reliably notify the information processing device 32 of the connection status with the terminal device 20.

FIG. 19 is a flowchart showing a processing flow of the charging side communication processor 54 according to the fourth embodiment. In the fourth embodiment, the charging side communication processor 54 executes the process in the flow as shown in FIG.

First, in S411, the charging side communication processor 54 determines whether or not the execution of the power delivery sequence has been started. When the execution of the power delivery sequence has not been started (No in S411), the charging side communication processor 54 advances the process to S412. In S412, the charging side communication processor 54 determines whether or not the connection state of the cable 34 has changed. If there is no change in the connection state of the cable 34 (No in S412), the charging side communication processor 54 returns the process to S411 and starts executing the power delivery sequence or changes in the connection state of the cable 34. Wait for processing until there is. When the connection state of the cable 34 is changed (Yes in S412), the charging side communication processor 54 proceeds to the process in S413.

In S413, the charging side communication processor 54 transmits the notification information indicating the current connection state of the cable 34 to the information processing device 32. When S413 is completed, the charging side communication processor 54 ends this flow.

When the execution of the power delivery sequence is started (Yes in S411), the charging side communication processor 54 advances the process to S414. In S414, the charging side communication processor 54 acquires and stores the connection state of the cable 34 immediately before the execution of the power delivery sequence.

Subsequently, in S415, the charging side communication processor 54 masks the transmission of the notification information indicating the connection state. That is, in S415, the charging side communication processor 54 does not execute any processing.

Subsequently, in S416, the charging side communication processor 54 determines whether or not the execution of the power delivery sequence is completed. If the execution of the power delivery sequence is not completed (No in S416), the charging-side communication processor 54 waits in S416 for processing. When the execution of the power delivery sequence is completed (Yes in S416), the charging-side communication processor 54 advances the process to S417.

In S417, the charging side communication processor 54 acquires the connection state of the cable 34 immediately after the end of the power delivery sequence. Subsequently, in S418, the charging side communication processor 54 determines whether or not the connection state of the cable 34 matches immediately before the start of execution of the power delivery sequence and immediately after the end of execution. If the charging side communication processor 54 matches (Yes in S418), the charging side communication processor 54 ends this flow.

When the connection state of the cable 34 of the charging side communication processor 54 does not match immediately before the start of execution of the power delivery sequence and immediately after the end of execution (Yes in S418), the current connection state of the cable 34 in S419. The notification information indicating the above is transmitted to the information processing device 32. When S419 is completed, the charging side communication processor 54 ends this flow.

The charge control device 30 according to the fourth embodiment as described above has the following effects.

The charge control device 30 according to the fourth embodiment masks the notification information of the connection state of the cable 34 to the information processing device 32 during the execution of the power delivery sequence. As a result, according to the charge control device 30 according to the fourth embodiment, it is possible to reliably notify the connection state with the terminal device 20 and eliminate complicated processing.

Further, the charge control device 30 according to the fourth embodiment shows the connection state of the cable 34 when the connection state of the cable 34 changes from the connection state before the execution of the power delivery sequence after the end of the power delivery sequence. The notification information is transmitted to the information processing device 32. As a result, according to the charge control device 30 according to the fourth embodiment, the connection state of the terminal device 20 can be notified more reliably.

Further, the charging control device 30 according to the fourth embodiment disconnects the power supply and information communication from the charging side PD controller 52 by the cable 34 from the terminal device 20 by instructing the charging side PD controller 52 to reset. Let me. Further, the charging control device 30 according to the fourth embodiment instructs the charging side PD controller 52 to release the reset, so that the charging side PD controller 52 is supplied with power and information communication by the cable 34 with the terminal device 20. To reconnect. As a result, according to the charge control device 30 according to the fourth embodiment, the power supply and the information communication can be reliably disconnected and reconnected.

(Fifth Embodiment)
Next, the information processing system 10 according to the fifth embodiment will be described. The information processing system 10 according to the fifth embodiment has the same hardware configuration as the first to fourth embodiments.

FIG. 20 is a diagram showing a functional configuration of a processing circuit 66 included in the terminal device 20 according to the fifth embodiment.

The processing circuit 66 according to the fifth embodiment includes a cable connection determination unit 512, a device determination unit 514, and an access point control unit 516. The processing circuit 66 functions as a cable connection determination unit 512, a device determination unit 514, and an access point control unit 516 by executing a predetermined program.

The cable connection determination unit 512 manages the connection state of the cable 34 between the terminal-side PD controller 62 and the charge control device 30. That is, the cable connection determination unit 512 determines whether or not the terminal-side PD controller 62 and the charge control device 30 are connected by the cable 34. For example, the cable connection determination unit 512 acquires and stores a notification indicating whether the power supply and information communication by the cable 34 are in the connected state or the disconnected state from the terminal side PD controller 62.

When the terminal-side PD controller 62 is not connected to any device via the cable 34 and is connected to any device, the cable connection determination unit 512 tells the device determination unit 514 that it is connected to the device. Notice. Further, the cable connection determination unit 512 notifies the access point control unit 516 that the terminal side PD controller 62 is disconnected from the device when the terminal side PD controller 62 is connected to some device via the cable 34 and is disconnected. ..

The device determination unit 514 determines whether or not the device connected via the cable 34 is a predetermined charge control device 30. For example, when the device determination unit 514 is connected to the device via the cable 34, the device determination unit 514 determines whether or not the device is the charge control device 30 based on the information received via the cable 34. As a result, the terminal device 20 can reliably determine whether or not the device connected via the cable 34 is the charge control device 30.

When the device connected via the cable 34 is the charge control device 30, the device determination unit 514 transmits to the access point control unit 516 that the device connected via the cable 34 is the charge control device 30. ..

The access point control unit 516 controls the wireless communication unit 68 included in the terminal device 20. The wireless communication unit 68 communicates information via a network by wirelessly connecting to an access point.

When the access point control unit 516 is connected to the predetermined charge control device 30 via the cable 34 as a result of the determination by the device determination unit 514, the access point control unit 516 is associated with the charge control device 30 with respect to the wireless communication unit 68. Wirelessly connect to the first access point.

In the present embodiment, the first access point is provided by the internal wireless communication device 40 included in the information processing device 32. Therefore, when the access point control unit 516 is connected to the charge control device 30 via the cable 34, the access point control unit 516 wirelessly connects the wireless communication unit 68 to the internal wireless communication device 40 of the information processing device 32.

As a result, when the terminal device 20 is housed in the charging cabinet 26 and connected to the charging control device 30 via the cable 34, the terminal device 20 can be wirelessly connected to the information processing device 32. Therefore, the terminal device 20 can send and receive data via the information processing device 32 and receive remote control via the information processing device 32 while being housed in the charging cabinet 26. As described above, according to the terminal device 20, when connected to the charge control device 30 via the cable 34, it is possible to wirelessly connect to an appropriate access point.

Further, when the access point control unit 516 is disconnected from the state of being connected to the charge control device 30 via the cable 34, the access point control unit 516 has a second predetermined access point different from that of the first access point with respect to the wireless communication unit 68. Make the access point wirelessly connect. The access point control unit 516 determines whether or not the device has been disconnected from the state of being connected to the charge control device 30 via the cable 34, based on the result of the determination of the cable connection determination unit 512 and the result of the determination by the device determination unit 514.

In this embodiment, the second access point is provided by a wireless communication device 24 provided outside the charging cabinet 26. Therefore, when the terminal device 20 is disconnected from the state of being connected to the charge control device 30, the access point control unit 516 wirelessly connects the wireless communication unit 68 to the wireless communication device 24.

As a result, the terminal device 20 can be wirelessly connected to the wireless communication device 24 when it is taken out from the charging cabinet 26. Therefore, when the terminal device 20 is taken out from the charging cabinet 26, the terminal device 20 can be reliably wirelessly connected to the access point with strong radio field strength. In this way, according to the terminal device 20, when disconnected from the charge control device 30, it is possible to wirelessly connect to an appropriate access point.

Further, when the access point control unit 516 is disconnected from the state of being connected to the charge control device 30 via the cable 34, the setting information for wirelessly connecting to the first access point set in the wireless communication unit 68. May be invalidated. When the setting information is invalidated, the wireless communication unit 68 searches for surrounding access points and wirelessly connects to an appropriate access point. As a result, when the terminal device 20 is disconnected from the charge control device 30, the terminal device 20 can invalidate the wireless connection with the inappropriate access point and newly wirelessly connect to the appropriate access point.

FIG. 21 is a flowchart showing the flow of the first processing of the processing circuit 66 according to the fifth embodiment. In the fifth embodiment, the processing circuit 66 executes the process in the flow as shown in FIG.

First, in S511, the processing circuit 66 determines whether or not the terminal device 20 is connected to any device via the cable 34. If not connected (No in S511), the processing circuit 66 waits for processing in S511. When connected (Yes in S511), the processing circuit 66 advances processing to S512.

In S512, the processing circuit 66 determines whether or not it is connected to the charge control device 30 via the cable 34. When the processing circuit 66 is not connected to the charge control device 30 (No in S512), this flow ends. When the processing circuit 66 is connected to the charge control device 30 (Yes in S512), the processing proceeds to S513.

In S513, the processing circuit 66 instructs the wireless communication unit 68 to wirelessly connect to the first access point associated with the charge control device 30. In the present embodiment, the processing circuit 66 instructs the internal wireless communication device 40 of the information processing device 32 to be wirelessly connected. Then, the processing circuit 66 ends this flow when the processing of S513 is completed.

FIG. 22 is a flowchart showing a second processing flow of the processing circuit 66 according to the fifth embodiment. In the fifth embodiment, the processing circuit 66 executes the process in the flow as shown in FIG. 22 in a state where the terminal device 20 is connected to the charge control device 30 via the cable 34.

First, in S521, the processing circuit 66 determines whether or not the terminal device 20 has been disconnected from the state of being connected to the charge control device 30 via the cable 34. If it is not disconnected (No in S521), the processing circuit 66 waits for processing in S521. If disconnected (Yes in S521), the processing circuit 66 advances processing to S522.

In S522, the processing circuit 66 instructs the wireless communication unit 68 to wirelessly connect to a second access point different from the first access point. In the embodiment, the processing circuit 66 instructs the wireless communication device 24 provided outside the charging cabinet 26 to be wirelessly connected. Then, when the processing circuit 66 finishes the processing of S522, the processing circuit 66 ends this flow.

In S522, the processing circuit 66 may invalidate the setting information for wirelessly connecting to the first access point set in the wireless communication unit 68 instead of wirelessly connecting to the second access point. When the setting information is invalidated, the wireless communication unit 68 searches for surrounding access points and wirelessly connects to an appropriate access point. Even in this way, the terminal device 20 can be wirelessly connected to the access point with strong radio field strength outside the charging cabinet 26.

The terminal device 20 according to the fifth embodiment as described above has the following effects.

When the terminal device 20 according to the fifth embodiment is connected to the charge control device 30 via the cable 34, the terminal device 20 is wirelessly connected to the wireless communication unit 68 to the first access point associated with the charge control device 30. Let me. As a result, according to the terminal device 20 according to the fifth embodiment, when connected to the charge control device 30 via the cable 34, it is possible to wirelessly connect to an appropriate access point.

Further, when the terminal device 20 according to the fifth embodiment is disconnected from the state of being connected to the charge control device 30 via the cable 34, the wireless communication unit 68 is wirelessly connected to the second access point. As a result, according to the terminal device 20 according to the fifth embodiment, when the terminal device 20 is disconnected from the state of being connected to the charge control device 30 via the cable 34, it can be wirelessly connected to an appropriate access point.

Further, when the terminal device 20 according to the fifth embodiment is disconnected from the charge control device 30 from the state of being connected to the charge control device 30 via the cable 34, the wireless communication unit is connected to the wireless communication unit 68. The setting information for wirelessly connecting to the first access point set in 68 is invalidated. As a result, according to the terminal device 20 according to the fifth embodiment, it is possible to invalidate the wireless connection with the inappropriate access point and newly wirelessly connect to the appropriate access point.

Further, when the terminal device 20 according to the fifth embodiment is connected to the device via the cable 34, it determines whether or not the device is the charge control device 30 based on the information received via the cable 34. .. Thereby, according to the terminal device 20 according to the fifth embodiment, it is possible to reliably determine whether or not the device connected via the cable 34 is the charge control device 30.

(Programs, etc.)
The program executed by the charge control device 30 or the terminal device 20 of each of the above-described embodiments is a file in an installable format or an executable format, and is a CD-ROM, a flexible disk (FD), a CD-R, or a DVD (Digital). It is recorded and provided on a computer-readable recording medium such as Versatile Disk).

Further, the program executed by the charge control device 30 or the terminal device 20 of each of the above-described embodiments is stored on a computer connected to a network such as the Internet, and is provided by being downloaded via the network. You may. Further, the program executed by the charge control device 30 or the terminal device 20 of each of the above-described embodiments may be configured to be provided or distributed via a network such as the Internet. Further, the program executed by the charge control device 30 or the terminal device 20 of each of the above-described embodiments may be configured to be provided by incorporating it into a ROM or the like in advance.

Although some embodiments of the present invention have been described, these embodiments are presented as examples and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other embodiments, and various omissions, replacements, and changes can be made without departing from the gist of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are also included in the scope of the invention described in the claims and the equivalent scope thereof.

10 Information processing system 20 Terminal device 22 School server 24 Wireless communication device 26 Charging cabinet 28 Storage area 30 Charging control device 32 Information processing device 34 Cable 36 Power tap 38 Internal communication cable 40 Internal wireless communication device 42 Upper conversion unit 44 Device control Unit 46 Terminal control unit 52 Charging side PD controller 54 Charging side communication processor 56 Lower conversion unit 58 Charging side power supply unit 62 Terminal side PD controller 64 Terminal side communication processor 66 Processing circuit 68 Wireless communication unit 70 Battery 72 Terminal side power supply unit 74 Power supply Switch 112 Power status management unit 114 Power command acquisition unit 116 Power switch control unit 118 Power status notification unit 120 Power command mask unit 212 Change command acquisition unit 214 Reconnection control unit 216 Profile change unit 312 Sequence management unit 314 Supply power management unit 316 Change command Mask unit 412 Cable status management unit 414 Cable status notification unit 416 Notification mask unit 512 Cable connection judgment unit 514 Device judgment unit 516 Access point control unit

Claims (8)

A control device that controls the power supply to the terminal device.
A power supply controller that can be connected to the terminal device via a cable, supplies power to the terminal device via the cable, and performs information communication with the terminal device.
A power command acquisition unit that receives a wakeup command to activate the terminal device from the information processing device,
When the wake-up command is received, the power switch control unit that gives an instruction to output the switch push signal for switching the state of the power switch of the terminal device to the terminal device to the power supply controller.
When the terminal device receives the wake-up command in the activated state, the power command mask unit that masks the wake-up command and
A control device comprising. The power command acquisition unit further receives a shutdown command for shutting down the terminal device, and receives the shutdown command.
When the power switch control unit receives the wake-up command or the shutdown command, the power switch control unit gives an instruction to output the switch push signal to the terminal device to the power supply controller.
The control device according to claim 1, wherein the power command mask unit masks the shutdown command when the terminal device receives the shutdown command in a non-started state. Equipped with a power status notification unit
The power status notification unit is
When the terminal device receives the shutdown command in the activated state, after the terminal device changes from the activated state to the non-activated state, notification information indicating the power state of the terminal device is returned to the information processing device. And
When the terminal device receives the wake-up command in the non-started state, after the terminal device changes from the non-started state to the activated state, the information processing device sends notification information indicating the power state of the terminal device. The control device according to claim 2. The power command mask unit
When the terminal device receives the wake-up command in the activated state, it returns notification information indicating the power state of the terminal device to the information processing device.
The control device according to claim 3, wherein when the terminal device receives the shutdown command in the non-started state, the notification information indicating the power state of the terminal device is returned to the information processing device. From claim 2, the power state management unit for managing whether the power state of the terminal device is the activated state or the non-started state based on the information received from the terminal device via the cable is further provided. The control device according to any one of 4. The control device according to claim 5, wherein the power supply state management unit separately manages a shutdown state, a hibernation state, or a sleep state as the non-starting state. With the terminal device
A control device that controls the power supply to the terminal device,
With
The control device is
A power supply controller that can be connected to the terminal device via a cable, supplies power to the terminal device via the cable, and performs information communication with the terminal device.
A power command acquisition unit that receives a wakeup command to activate the terminal device from the information processing device,
When the wake-up command is received, the power switch control unit that gives an instruction to output the switch push signal for switching the state of the power switch of the terminal device to the terminal device to the power supply controller.
When the terminal device receives the wake-up command in the activated state, the power command mask unit that masks the wake-up command and
Information processing system with. A program executed by the processor of the control device that controls the power supply to the terminal device.
The control device includes a power supply controller that can be connected to the terminal device via a cable, supplies power to the terminal device via the cable, and performs information communication with the terminal device.
The processor
A power command acquisition unit that receives a wakeup command to activate the terminal device from the information processing device,
When the wake-up command is received, the power switch control unit that gives an instruction to output the switch push signal for switching the state of the power switch of the terminal device to the terminal device to the power supply controller.
When the terminal device receives the wake-up command in the activated state, the power command mask unit that masks the wake-up command and
A program that works.

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