CN113687708B - Remote startup and shutdown system and method - Google Patents

Abstract

The application provides a remote startup and shutdown system and a method thereof, wherein the remote startup and shutdown system comprises a computer remote management module, an IoT server and a server, wherein the computer remote management module is configured on a notebook computer and is bound with software, and the IoT server records identity information of the computer remote management module; the power supply management unit receives and executes an on/off instruction from the computer remote management module; the IoT server sends a power-on/power-off instruction to the power management unit according to the computer remote management module with the bound software; the software is configured to the terminal to execute the on/off instruction sent to the IoT server; the power management unit of the notebook computer receives the power-on/power-off instruction from the computer remote management module and executes power-on/power-off, and as long as the computer is powered on and the area where the computer is located is covered by the network signal, the power management unit can carry out remote power-off in the state that the operating system is completely powered off without system setting, and only the network signal is needed.

Description

Remote startup and shutdown system and method

Technical Field

The embodiment of the application relates to the technical field of information security, in particular to a remote power on/off system and a remote power on/off method.

Background

With the continuous enhancement of network communication technology, the remote office is a more and more common enterprise requirement, and employees can remotely connect to the office machine of the company at home to remotely operate the office machine of the company to complete the task of the company. Before operating the computer, it is first necessary to keep the computer in an operating state. However, when no one is in the company, the computer is in the off state, and at this time, the computer needs to be remotely turned on to perform remote office work. At present, software is set to sleep and remotely wake up through an operating system, but the application range is limited under the condition of an external network.

Disclosure of Invention

In order to solve at least one of the above technical problems, embodiments of the present application provide a remote power on/off system and method.

In a first aspect, an embodiment of the present application provides a remote power on/off system, including:

the computer remote management module is configured on a notebook computer and bound with software, and the notebook computer is configured with a network card;

an IoT server, wherein the IoT server records the identity information of the computer remote management module;

the power management unit is configured on a notebook computer, receives a power-on/off instruction sent to the computer remote management module by the IoT server and executes the power-on/off;

and the software is configured at the terminal and sends an on/off instruction to the IoT server, and the IoT server sends the on/off instruction to the power management unit according to the computer remote management module bound by the software.

In one possible implementation manner, the power on/off system further includes:

and the authentication server records the information of binding the notebook computer and the software.

In one possible implementation manner, the recording, by the authentication server, information about binding between the notebook computer and the software includes:

and the computer remote management module sends the identification numbers of the mainboard, the network card, the CPU and the power management unit to software for authentication, connection establishment and identity binding.

In one possible implementation, the authentication server authenticates the user identity, and the identity confirmation allows the software to send an on/off instruction to the IoT server.

In a possible implementation manner, the software sends an on/off instruction to an IoT server, the IoT server searches for a network card address bound to the software, the IoT server sends the on/off instruction to a network card of the notebook computer, and the network card sends the on/off instruction to the power management unit after receiving the on/off instruction.

In one possible implementation, the computer remote management module includes:

the 4G \5G power management unit is powered by the power management unit;

and the main module sends the received power on/off instruction to the power management unit, and executes power on/off after the power management unit receives the power on/off instruction.

In one possible implementation manner, the main module sends the received power on/off command to the power management unit in a UART protocol.

In a second aspect, an embodiment of the present application provides a remote power on/off method, including:

the IoT server sends a power-on/off instruction to the power management unit according to the computer remote management module with the bound software; the software is configured at the mobile phone end to execute the on/off instruction sent to the IoT server;

and the power management unit of the notebook computer receives the power on/off instruction sent to the computer remote management module by the IoT server and executes the power on/off.

In one possible implementation, the remote power on/off method further includes:

the computer remote management module sends the identification number of the main board, the network card, the CPU and the power management unit to software for authentication, connection establishment and identity binding, the authentication server authenticates the identity of a user, and the identity confirmation allows the software to send a power-on/off instruction to an IoT server.

In the remote power on/off system and the method provided by the embodiment of the application, the remote power on/off system comprises a computer remote management module, a network card and a remote management module, wherein the computer remote management module is configured on a notebook computer and is bound with software; the IoT server records the identity information of the computer remote management module; the power supply management unit receives and executes an on/off instruction from the computer remote management module; the IoT server sends a power-on/off instruction to the power management unit according to the computer remote management module with the bound software; the IoT server sends a power-on/off instruction to the power management unit according to the computer remote management module with the bound software; the software is configured to the terminal to execute the on/off instruction sent to the IoT server; the power management unit of the notebook computer receives a power on/off instruction sent to the computer remote management module by the IoT server and executes power on/off, and as long as the computer is powered on and the area where the computer is located is covered by a network signal, the remote power off can be performed in a state that the operating system is completely powered off without system setting, and only the network signal is needed.

It should be understood that what is described in this summary section is not intended to limit key or critical features of the embodiments of the application, nor is it intended to limit the scope of the application. Other features of the present application will become apparent from the following description.

Drawings

The above and other features, advantages and aspects of various embodiments of the present application will become more apparent by referring to the following detailed description when taken in conjunction with the accompanying drawings. In the drawings, the same or similar reference numerals denote the same or similar elements.

Fig. 1 shows a schematic structural diagram of a remote power on/off system of an embodiment of the present application;

FIG. 2 shows a schematic structural diagram of a computer remote management module (4G) of an embodiment of the present application;

fig. 3 shows a flowchart of a remote power on/off method according to an embodiment of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application.

In order to facilitate understanding of the embodiments of the present application, some terms referred to in the embodiments of the present application are first explained.

(1) 4G _ PMU 4G Power Management Unit (PMU)

(2) RF LTE PA: LTE radio frequency Power Amplifier (Power Amplifier)

(3) PMU Power Management Unit (PMU)

(4) MCU (micro controller Unit, MCU), also called single Chip Microcomputer (Signal Chip Microcomputer).

(5) LTE RF FEM: LTE radio frequency front end unit (Fron-end Modules)

(6) RF Transceiver: radio frequency transceiver

(7) USIM: global user identification card (Universal Subscriber Identity Module)

In the related art, software is used for setting an operating system to sleep and remotely awakening, but needs to be in an external network condition. The application has the innovation point that the remote shutdown can be carried out in the state that the operating system is completely shut down without system setting, and only 4G \5G network signals are needed.

The present application is described below with specific examples, and it should be noted that the descriptions in the examples of the present application are only for clearly illustrating the technical solutions in the examples of the present application, and do not limit the technical solutions provided in the examples of the present application. The remote power on/off system and the method provided by the embodiment of the application are also applicable to other scenes similar to or similar to the remote power on/off system and the method.

Fig. 1 shows a schematic structural diagram of a remote power on/off system according to an embodiment of the present application.

Referring to fig. 1, the remote power on/off system includes:

the computer remote management module 20 is configured on a notebook computer and is bound with software, and the notebook computer is configured with a network card; the network card can be a 4G \5G network card;

specifically, the software is configured to execute the following procedures on the terminal:

and sending a power-on/off instruction to the IoT server.

The terminal is a control terminal for sending the startup and shutdown instruction to the IoT server, and the terminal includes but is not limited to: a mobile phone, a digital broadcast receiver, a PDA (personal digital assistant), a PAD (tablet computer), a PMP (portable multimedia player), a vehicle terminal (e.g., a car navigation terminal), etc., and a mobile terminal such as a digital TV, a desktop computer, etc., without being limited in particular.

An IoT server 40, wherein the IoT server 40 records the identity information of the computer remote management module;

a power management unit 60, where the power management unit 60 receives and executes a power on/off instruction sent to the computer remote management module 20 by the IoT server;

and software configured at the terminal, sending an on/off instruction to the IoT server 40, where the IoT server 40 issues the on/off instruction to the power management unit 60 according to the computer remote management module 20 to which the software is bound.

In the remote power on/off system provided in the embodiment of the present application, the remote power on/off system includes a computer remote management module 20, which is configured on a notebook computer and is bound with software, wherein the notebook computer is configured with a network card; the IoT server 40 records the identity information of the computer remote management module; the power management unit 60 receives and executes the on/off instruction sent to the computer remote management module by the IoT server; the IoT server 40 issues a power on/off instruction to the power management unit 60 according to the computer remote management module to which the software has been bound, and the IoT server 40 issues a power on/off instruction to the power management unit 60 according to the computer remote management module to which the software has been bound; the software is configured on a terminal to execute and send an on/off instruction to an IoT server; the power management unit 60 of the notebook computer receives the power on/off instruction from the remote management module of the computer and executes power on/off, and in the embodiment of the application, as long as the computer is powered on and the area where the computer is located is covered by the 4G \5G network signal, the remote power off can be performed in the state that the operating system is completely powered off without system setting, and only the 4G \5G network signal is needed.

Specifically, the remote power on/off system further includes:

and the authentication server 10 records the information of binding the notebook computer and the software.

The step of recording the information of binding the notebook computer and the software by the authentication server 10 includes:

the computer remote management module sends the identification number of the main board, the network card, the CPU and the power management unit to software for authentication, connection establishment and identity binding, the authentication server authenticates the identity of a user, and the identity confirmation allows the software to send an on/off instruction to an IoT server.

In some embodiments, the software sends an on/off instruction to an IoT server, the IoT server searches for a network card address bound to the software, the IoT server sends the on/off instruction to a network card of the notebook computer, and the network card sends the on/off instruction to the power management unit 60 after receiving the on/off instruction.

In some embodiments, the computer remote management module comprises:

a 4G _ PMU (4G power management unit), an RF LTE PA (radio frequency amplifier), an LTE RF FEM (radio frequency front end module), and a main module;

the main module sends the received power on/off command to the power management unit 60, and executes power on/off after the power management unit 60 receives the power on/off command.

In some embodiments, the master module sends the received power on/off command to the power management unit 60 in the UART protocol.

Fig. 2 shows a schematic structural diagram of a computer remote management module according to an embodiment of the present application.

Referring to fig. 2, the computer remote management module (4G module) includes:

the power management system is used for providing power for a hard disk and other components of the notebook computer; the system comprises a 4G _ PMU (4G power management unit) and a PMU (power management unit), wherein the 4G _ PMU supplies power for an RF LTE PA (radio frequency amplifier), an RF front-end module LTE RF FEM (radio frequency front-end module), an RF Transceiver and Baseband, and the PMU (power management unit) supplies power for the 4G _ PMU (4G power management unit); it should be noted that this power supply method is merely exemplary, and the power consumption components of the notebook computer may also be directly supplied with power by the PMU (power management unit).

The RF Transceiver and Baseband are core components of the main module, the main module sends the received power on/off command to the power management unit 60, and the power management unit 60 executes power on/off after receiving the power on/off command; the RF LTE PA (radio frequency amplifier) and the LTE RF FEM (radio frequency front-end module) are connected with the main antenna to provide amplification, receiving and transmitting of signals, and the signals are sent to the main module. The main module transmits the received data to the power management unit 60 in the UART protocol. When the power management unit 60 receives the data containing the control command (e.g., power on/off command), it automatically starts the power on/off of the notebook computer. The computer remote management module (4G module) can also comprise an MCU (micro control unit) which is configured between the main module and the power management unit.

Specifically, taking the computer remote management module as a 4G module as an example, first, software sends an on/off instruction to an IoT server, the IoT server searches for an address of a 4G network card bound to the software, the IoT server sends the on/off instruction to the 4G network card of a notebook computer, and after receiving the on/off instruction, the 4G network card sends the on/off instruction to the power management unit 60 of the notebook computer.

As shown in fig. 3, fig. 3 is a flowchart illustrating a remote power on/off method according to an embodiment of the present application, and as shown in fig. 3, the remote power on/off method includes:

s20, the IoT server sends an on/off command to the power management unit 60 according to the computer remote management module to which the software is bound; the software is configured to the terminal to execute the on/off instruction sent to the IoT server; among them, the terminal includes but is not limited to: a mobile terminal such as a mobile phone, a notebook computer, a digital broadcast receiver, a PDA (personal digital assistant), a PAD (tablet computer), a PMP (portable multimedia player), a car terminal (e.g., car navigation terminal), etc., and a digital TV, a desktop computer, etc., are not particularly limited.

S40, the power management unit 60 of the notebook computer receives and executes the on/off command sent to the computer remote management module 20 from the IoT server.

In this embodiment, the IoT server issues an on/off instruction to the power management unit 60 according to the computer remote management module to which the software is bound; the software is configured to the terminal to execute the on/off instruction sent to the IoT server; the power management unit 60 of the notebook computer receives and executes the power on/off command sent to the computer remote management module by the IoT server. As long as the computer is powered on and the area where the computer is located is covered by the 4G \5G network signal, the remote power-off can be carried out in the state that the operating system is completely powered off without system setting, and only the 4G \5G network signal is needed.

In some embodiments, the remote power on/off method further comprises:

the computer remote management module sends the identification numbers of the main board, the network card, the CPU and the hard disk hardware to software for authentication, connection establishment and identity binding, the authentication server authenticates the identity of the user, and the identity is confirmed to allow the software to send a power-on/off instruction to an IoT server.

The following describes the beneficial effects of the remote power on/off method of the present invention in a preferred embodiment:

the method realizes the conditions of remote startup and shutdown in the shutdown state of the equipment:

the notebook computer is provided with a 4G module;

IMS APP software (hereinafter IMS APP);

an IoT server;

a 4G cellular network;

and (4) an authentication server.

S1, the authentication server records the information of the binding between the notebook computer and the IMS APP;

s2, 4G _ PMU supplies power to a radio frequency amplifier (RF LTE PA), a radio frequency front end module (LTE RF FEM) and a main module, and the PMU (power management unit) supplies power to the 4G _ PMU (4G power management unit) and keeps on line;

s3, the IoT server records the identity information of the 4G modules carried by all the notebook computers;

s4, the user passes the user name, the password and the IMS APP bound before;

s5, the authentication server authenticates the user identity, and the identity confirmation allows the IMS APP to send a power on/off instruction to the IoT server;

s6, the IoT server searches for the 4G network card address bound with the IMS APP;

s7, the IoT server sends a startup and shutdown instruction to the self 4G network card of the notebook computer;

s8, 4G network card receives the power on/off command and then sends the power on/off command to the main module, and the main module sends the received data to the power management unit 60 in the UART protocol;

after receiving the power on/off command, the power management unit 60 of the notebook computer executes the power on/off operation, as long as the computer is powered on and the area where the computer is located is covered by the 4G \5G network signal, the remote power off can be performed in the state that the operating system is completely powered off without system setting, and only the 4G \5G network signal is needed.

The flowchart and block diagrams in the figures illustrate the architecture, functionality, and operation of possible implementations of systems, methods and computer program products according to various embodiments of the present invention. In this regard, each block in the flowchart or block diagrams may represent a module, segment, or portion of code, which comprises one or more executable instructions for implementing the specified logical function(s). It should also be noted that, in some alternative implementations, the functions noted in the block may occur out of the order noted in the figures. For example, two blocks shown in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. It will also be noted that each block of the block diagrams and/or flowchart illustration, and combinations of blocks in the block diagrams and/or flowchart illustration, can be implemented by special purpose hardware-based systems which perform the specified functions or acts, or combinations of special purpose hardware and computer instructions.

The above description is only a preferred embodiment of the application and is illustrative of the principles of the technology employed. It will be appreciated by a person skilled in the art that the scope of the invention as referred to in the present application is not limited to the embodiments with a specific combination of the above-mentioned features, but also covers other embodiments with any combination of the above-mentioned features or their equivalents without departing from the inventive concept. For example, the above features may be replaced with (but not limited to) features having similar functions disclosed in the present application.

Claims (2)

1. A remote power on/off system, comprising:

the computer remote management module is configured on a notebook computer and bound with software, and the notebook computer is configured with a network card;

an IoT server, wherein the IoT server records the identity information of the computer remote management module;

the remote computer management module comprises a Power Management Unit (PMU), a 4G _ PMU, a radio frequency amplifier, a radio frequency front end module and a main module, wherein the PMU receives an on/off instruction sent to the remote computer management module by the IoT server and executes the on/off operation;

software configured on a notebook computer; and the number of the first and second groups,

an authentication server;

the authentication server records the information of binding the notebook computer and the software; the computer remote management module sends the identification numbers of the mainboard, the network card, the CPU and the power management unit to the software for authentication, connection establishment and identity binding;

the 4G _ PMU supplies power to the radio frequency amplifier, the radio frequency front end module and the main module, and the power management unit PMU supplies power to the 4G _ PMU and keeps on-line;

the IOT server records the identity information of a computer remote management module carried by the notebook computer;

the user passes the user name, the password and the software bound before;

the authentication server authenticates the identity of the user, and the identity is confirmed to allow the software to send a power-on/power-off instruction to the IOT server;

the IOT server searches a network card address bound with the software;

the IOT server sends a startup and shutdown instruction to a network card of the notebook computer;

the network card sends the startup/shutdown instruction to the main module after receiving the startup/shutdown instruction, and the main module sends the received data to the PMU (power management unit) in a UART (universal asynchronous receiver/transmitter) protocol mode.

2. A remote power on and off method, comprising:

the IoT server sends a power-on/off instruction to the power management unit according to the computer remote management module with the bound software; the software is configured at the mobile phone end to execute the on/off instruction sent to the IoT server; the remote computer management module comprises a Power Management Unit (PMU), a 4G _ PMU, a radio frequency amplifier, a radio frequency front end module and a main module, wherein the PMU receives an on/off instruction sent to the remote computer management module by the IoT server and executes the on/off operation;

the power management unit PMU receives an on/off instruction sent to the computer remote management module by the IoT server and executes the on/off operation, the IoT server searches for a network card address bound with the software, the IoT server sends the on/off instruction to a network card of the notebook computer, and the network card sends the on/off instruction to the power management unit after receiving the on/off instruction;

the authentication server records the information of binding the notebook computer and the software; the computer remote management module sends the identification numbers of the mainboard, the network card, the CPU and the power management unit PMU to the software for authentication, connection establishment and identity binding;

the 4G _ PMU supplies power to the radio frequency amplifier, the radio frequency front end module and the main module, and the power management unit PMU supplies power to the 4G _ PMU and keeps on-line;

the IOT server records the identity information of a computer remote management module carried by the notebook computer;

the user passes the user name, the password and the previously bound software;

the authentication server authenticates the identity of the user, and the identity confirmation allows the software to send a power-on/power-off instruction to the IOT server;

the IOT server searches a network card address bound with the software;

the IOT server sends a startup and shutdown instruction to a network card of the notebook computer;

the network card receives the power-on/off instruction and then sends the power-on/off instruction to the main module, and the main module sends the received data to the PMU (power management unit) in a UART (universal asynchronous receiver/transmitter) protocol mode.

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