JP2022032533A - Information processing device and program - Google Patents

Abstract

To allow for simultaneous charging operation of a plurality of terminal devices.SOLUTION: An information processing device according to an embodiment comprises: a storage unit which stores setting information on input power together with a BIOS; a control unit which outputs the setting information when the BIOS is started; and a power controller for controlling a power supply unit, which. when the setting information is entered, limits an input power supplied from the outside, by outputting to the power supply unit, a setting value of the input power, indicating an upper-limit value of a power input from an external power supply into the power supply unit, on the basis of the setting information.SELECTED DRAWING: Figure 3

Description

Embodiments of the present invention relate to information processing devices and programs.

Conventionally, in terminal devices such as tablet PCs and notebook PCs, a secondary battery that can be charged and discharged is mounted on the main body.

In the information processing device, although the input value of the electric power changes according to the charge amount of the secondary battery, the power consumed usually has the maximum rating of the attached AC adapter.

In recent years, the development of mobile terminals in the education field market and the like has been held. For this reason, there is a tendency for a plurality of mobile terminals, such as dozens of terminals, to be introduced in a predetermined environment such as an educational site. During the time when such a plurality of mobile terminals are not used, there is also an operation of storing them in a charging cabinet installed in the predetermined environment. The charging cabinet has a function of supplying electric power to each terminal device from the AC adapter. The charging cabinet is configured to take power from a general outlet.

For example, when the predetermined environment is a classroom and the number of people in one class is 40 in the classroom, a maximum of 40 terminal devices can be stored in the charging cabinet. The charging cabinet draws power from a typical 1500W outlet. If power is supplied to the terminal device at the same time for 40 units, the breaker may trip. For this reason, some charging cabinets have a function of checking the charging state of each terminal device and rotating the charging so as not to trip the breaker.

Japanese Patent No. 6562171

However, there are cases where it is not possible to introduce a charging cabinet that can confirm the charging environment of the terminal device due to budgetary reasons.

The information processing apparatus according to the first aspect of the present invention includes a storage unit that stores setting information related to input power together with a BIOS, a control unit that outputs the setting information when the BIOS is started, and a control unit.
A storage unit that stores setting information related to input power together with a BIOS and a controller that controls a power supply unit. When the setting information is input, the power supply unit inputs from an external power source based on the setting information. It is provided with a power supply controller that limits the input power supplied from the outside by outputting the set value of the input power indicating the upper limit value of the power to be supplied to the power supply unit.

In the program according to the second aspect of the present invention, the input step for inputting the setting information regarding the input power and the input power indicating the upper limit value of the power input from the outside by the power supply unit of the computer based on the setting information. By outputting the set value to the power supply unit, the computer is made to execute an output step of limiting the input power supplied from the outside.

FIG. 1 is a diagram illustrating the concept of a charging cabinet and a terminal device according to an embodiment. FIG. 2 is a diagram showing a hardware configuration example of the charging cabinet according to the embodiment. FIG. 3 is a diagram illustrating a hardware configuration of the terminal device according to the embodiment. FIG. 4 is a block diagram showing a software configuration of the power supply controller according to the embodiment. FIG. 5 is a sequence diagram showing a process at the time of starting the terminal device according to the embodiment. FIG. 6 is a flowchart showing the resetting of the input power limit value according to the operation mode in the terminal device according to the embodiment.

Hereinafter, exemplary embodiments of the present invention will be disclosed. The configurations of the embodiments shown below, as well as the actions and effects brought about by such configurations, are examples. The present invention can also be realized by configurations other than those disclosed in the following embodiments. Further, according to the present invention, it is possible to obtain at least one of various effects (including derivative effects) obtained by the configuration. The configuration of the embodiments described below, and the actions and effects brought about by the configuration are merely examples, and are not limited to the contents described below.

FIG. 1 is a diagram illustrating the concept of the charging cabinet 1 and the terminal device 100 according to the present embodiment. As shown in FIG. 1, the charging cabinet 1 includes a plug 2 for connecting to an external AC power supply of 1500 W. By connecting the plug 2 to an external AC power source via an outlet, it is possible to charge the terminal device 100 housed in the charging cabinet 1 from the AC power source.

FIG. 2 is a diagram showing a hardware configuration example of the charging cabinet 1. As shown in FIG. 2, the charging cabinet 1 includes a plug 2, a power strip 10, an AC adapter 11, and a connection I / F 20 for a terminal device 100. By connecting the plug 2 to the outlet, the charging cabinet 1 receives 1500 W of electric power from the AC power source. An AC adapter 11 is connected to the power strip 10. Power is supplied from the AC adapter 11 to the device connected to the connection I / F 20.

By housing the terminal device 100 in the charging cabinet 1, the terminal device 100 is connected to the connection I / F 20. As a result, charging of the terminal device 100 is started by the electric power flowing from the AC adapter 11.

However, even if many terminal devices 100 are connected to the charging cabinet 1, there is an upper limit of 1500 W of electric power supplied from the AC power supply. Therefore, it is necessary to control the charge amount for each of the terminal devices 100. Therefore, in the present embodiment, it is decided to set an upper limit value for the input power of the terminal device 100.

FIG. 3 is a diagram illustrating a hardware configuration of the terminal device 100. As shown in FIG. 3, the terminal device 100 includes an SPI_ROM 301, a CPU 302, a power supply controller 303, a power supply unit 304, and a Power switch 305.

SPI_ROM301 stores the unique setting value (SID) together with the BIOS. The BIOS 311 is read out when the terminal device 100 is started. Note that SPI_ROM301 is an example of non-volatile memory.

The unique setting value (SID) is an example of setting information regarding the upper limit value of the input power. The input power of the terminal device 100 is limited according to the unique setting value.

Unique setting value (SID) is standard setting value, input power 15W limit mode (sleep / power off state only), input power 20W limit mode (sleep / power off state only), input power 15W limit mode, input power 20W limit. Any one of the modes can be set. It should be noted that this embodiment shows an example of the unique setting value, and may be another embodiment as long as it is a mode in which the upper limit value of the input power is set.

The standard set value is a set value for setting the input power according to the rating of the AC power supply of the terminal device 100 as in the conventional case.

In the input power 15W limit mode, the input power from the AC power supply is limited to 15W regardless of the operation mode of the terminal device 100. In the input power 20W limit mode, the input power from the AC power supply is limited to 20W regardless of the operation mode of the terminal device 100.

In the input power 15W limit mode (sleep / power off state only), the input power from the AC power supply is limited to 15W when the operation mode of the terminal device 100 is the sleep or power off state. In the input power 20W limit mode (sleep / power off state only), the input power from the AC power supply is limited to 20W when the operation mode of the terminal device 100 is the sleep or power off state.

That is, in the case of the input power 15W limit mode or the input power 20W limit mode, the input power is limited even when the power is on, so that the remaining battery level is reduced even though the battery is being charged. Status mismatch may occur. Therefore, in the power-on state, an input power 15W limit mode (sleep / power-off state only) and an input power 20W limit mode (sleep / power-off state only) are provided as modes that do not limit the input power. When the terminal device 100 is stored in the charging cabinet 1, it goes into sleep or a power-off state, so that it is possible to prevent the power supplied from the AC power supply when the charging cabinet 1 is stored from becoming excessive.

Any method may be used as the method for setting the unique setting value (SID). The unique setting value may be set from the BIOS menu screen. Further, it may be set in advance when it is introduced into a predetermined environment such as a classroom, or it may be updated according to an instruction from another device.

If the unique setting value (SID) is not set, the same power control as usual shall be performed.

The CPU 302 controls the entire terminal device 100. When the terminal device 100 is started, the CPU 302 reads and expands the BIOS 311 from the SPI_ROM 301 via the SPI I / F. The CPU 302 activates the BIOS 311 and performs initial settings related to the activation.

Then, when the BIOS 311 is started, the CPU 302 outputs the unique setting value (SID) stored in the SPI_ROM 301 to the power supply controller 303 via the eSPI I / F.

The power supply controller 303 includes a processor 321, a ROM 322, and a RAM 323, and is a controller that controls the power supply unit 304. The processor 321 reads out a control program of the power supply unit 304 stored in the ROM 322, uses the RAM 323 as a work area, and controls reception of control signals, power supply, and power supply demand.

The power supply controller 303 and the power supply unit 304 are connected by, for example, SMBus.

FIG. 4 is a block diagram showing a software configuration of the power supply controller 303. As shown in FIG. 4, the receiving unit 401, the determination unit 402, and the power supply notification unit 403 are realized by reading out the control program.

The receiving unit 401 receives a signal from the configuration included in the terminal device 100 such as the CPU 302. For example, the receiving unit 401 inputs (receives) a unique setting value from the CPU 302.

Then, when the receiving unit 401 inputs (receives) the unique setting value, the power supply notification unit 403 outputs the input power limit value to the power supply unit 304 based on the unique setting value. The input power limit value is a set value indicating an upper limit value of the input power input from the AC power supply.

The determination unit 402 determines the operation mode of the terminal device 100 according to the control signal received by the reception unit 401. The determination of the operation mode is performed when the unique setting value is set to a mode in which the input power is different according to the operation mode of the terminal device 100.

As a mode in which the input power is different depending on the operation mode, for example, there are an input power 15W limited mode (sleep / power off state only) and an input power 20W limited mode (sleep / power off state only).

Then, each time the determination unit 402 determines that the operation mode of the terminal device 100 has been changed, the power supply notification unit 403 outputs an input power limit value corresponding to the operation mode to the power supply unit 304. The operation mode of the terminal device 100 includes, for example, a power-on state, a sleep state, and a power-off state.

For example, when the unique setting value is the input power 15W limit mode (sleep / power off state only), the power notification unit 403 sets the input power according to the AC adapter rating when the operation mode of the terminal device 100 is normal operation. The input power limit value is output to the power supply unit 304, and when the operation mode of the terminal device 100 is in the sleep or power off state, the input power limit value that sets the upper limit value of the input power to 15 W is set to the power supply unit 304. Output.

Returning to FIG. 3, the power supply unit 304 includes a processor 331, a ROM 332, and a RAM 333. The processor 331 reads the program stored in the ROM 332 and uses the RAM 333 as a work area to control the AC power supply, the system power, the battery, and the battery voltage. Further, the power supply unit 304 controls the Power switch 305. Further, the RAM 333 has a register for storing an input power limit value from the power supply controller 303.

The processor 331 of the power supply unit 304 supplies electric power to the terminal device 100 according to the instruction from the power supply controller 303. For example, when power is supplied from the AC power supply via the plug 2, the processor 331 supplies power to the terminal device 100 so as not to exceed the upper limit of the power indicated as the input power limit value.

The Power switch 305 switches the battery voltage on / off with and from the battery (not shown) according to the control from the power supply unit 304.

Next, the processing at the time of starting the terminal device 100 will be described. FIG. 5 is a sequence diagram showing the processing at the time of starting the terminal device 100.

First, when the start of the terminal device 100 starts, the CPU 302 reads out the BIOS 311 stored in the SPI_ROM 301 and starts the BIOS 311 (S501).

Then, the BIOS 311 started by the CPU 302 confirms the unique setting value stored in the SPI_ROM 301 (S502). Then, when the unique setting value is stored in the SPI_ROM 301, the BIOS 311 notifies (transmits) the unique setting value to the power controller 303 (S503).

Then, in the power controller 303, after the control program is read out, the receiving unit 401 receives the notification of the unique setting value (S503), and then the determination unit 402 determines the current operation mode of the terminal device 100. (For example, the power is turned on) is determined, and the input power limit value indicating the upper limit value of the power is specified based on the unique setting value and the operation mode (S504).

Then, the power supply notification unit 403 notifies (outputs) the specified input power limit value to the power supply unit 304, thereby limiting the input power supplied from the AC power supply (S505). That is, since the input power limit value indicating the upper limit value is stored in the register of the power supply unit 304, the power supply unit 304 controls to limit the input power so as not to exceed the upper limit value.

After that, when the power is supplied from the AC power supply, the power supply unit 304 operates according to the input power limit value (S506).

As described above, in the terminal device 100 of the present embodiment, the input power limit value corresponding to the unique set value is stored in the register of the power supply unit 304. Then, in the terminal device 100, charge control from the AC power source according to the input power limit value is performed. Thereby, the power from the AC power source can be limited to the terminal device 100.

Next, the input power according to the operation mode of the terminal device 100 when the unique setting value is the input power 15 W limited mode (sleep / power off state only) or the input power 20 W limited mode (sleep / power off state only). The resetting of the limit value will be described.

FIG. 6 is a flowchart showing the resetting of the input power limit value according to the operation mode in the terminal device 100 according to the present embodiment.

First, the receiving unit 401 receives a control signal (for example, an input / output signal from the GPIO "General-purpose input / output") from the configuration in the terminal device 100 (S601).

Next, the determination unit 402 determines the operation mode of the terminal device 100 based on the received control signal (S602). Thereby, any one of power-on, sleep, and power-off is specified as the operation mode of the terminal device 100.

Then, the power notification unit 403 corresponds to the operation mode when the unique setting value is the input power 15 W limit mode (sleep / power off state only) or the input power 20 W limit mode (sleep / power off state only). , The input power limit value is notified to the power supply unit 304 (S603). As a result, when the input power 15 W limited mode (sleep / power off state only) or the input power 20 W limited mode (sleep / power off state only), the operation mode of the terminal device 100 is in the sleep or power off state. In some cases, the input power limit is limited.

That is, in the present embodiment, power is supplied from the AC power supply according to the upper limit value of the power indicated by the input power limit value. Therefore, even in a situation where many terminal devices 100 are connected to the charging cabinet 1, since the input power limit value is set according to the situation in the terminal device 100, the plurality of terminal devices 100 are set. Simultaneous charging operation becomes possible.

As a result, it is possible to prevent the occurrence of excessive power when charging a plurality of terminal devices 100 via the charging cabinet 1.

In the present embodiment, the input power can be limited regardless of the storage location of the terminal device 100. Therefore, it is possible to simultaneously charge and operate a plurality of terminal devices 100 without adding special equipment or increasing the power supply for the charging cabinet or the like.

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.

1 ... Charging cabinet, 2 ... Plug, 10 ... Power tap, 11 ... AC adapter, 20 ... Connection I / F, 100 ... Terminal device, 301 ... SPI_ROM, 302 ... CPU, 303 ... Power controller, 304 ... Power supply unit, 305 ... Power switch, 311 ... BIOS, 321 ... Processor, 322 ... ROM, 323 ... RAM, 331 ... Processor, 332 ... ROM, 333 ... RAM, 401 ... Receiver unit, 402 ... Judgment unit, 403 ... Power notification unit.

The information processing apparatus according to the first aspect of the present invention controls a storage unit that stores setting information related to input power, a control unit that outputs the setting information in conjunction with the activation of the BIOS, and a power supply unit together with the BIOS. Based on the setting information input from the control unit , the power supply unit outputs an input power setting value indicating an upper limit value of the power input from the external power supply to the power supply unit. The power supply controller includes a power supply controller that limits the input power supplied from the outside, and each time the operation mode is changed, the power supply controller sets the input power setting value corresponding to the operation mode to the power supply unit. Output to.

In the program according to the second aspect of the present invention, the power supply unit of the computer is input from an external power source based on the input step of inputting the setting information regarding the input power in conjunction with the activation of the BIOS and the input setting information. The computer is made to execute an output step of limiting the input power supplied from the outside by outputting the set value of the input power indicating the upper limit value of the power to the power supply unit, and in the output step, the said Every time the operation mode of the computer is changed, the set value of the input power corresponding to the operation mode is output to the power supply unit .

Claims (3)

A storage unit that stores setting information related to input power together with the BIOS,
A control unit that outputs the setting information when the BIOS is started,
It is a controller that controls the power supply unit, and when the setting information is input, the input power setting value indicating the upper limit value of the power input from the external power supply by the power supply unit is set based on the setting information. A power controller that limits the input power supplied from the outside by outputting to the power supply unit,
Information processing device equipped with. Each time the operation mode of the information processing apparatus is changed, the power controller outputs the set value of the input power corresponding to the operation mode to the power supply unit.
The information processing apparatus according to claim 1. An input step for inputting setting information related to input power, and
Based on the setting information, the power supply unit of the computer limits the input power supplied from the outside by outputting the setting value of the input power indicating the upper limit value of the power input from the external power supply to the power supply unit. Output step and
A program for causing the computer to execute.

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