CN111831459A - Dual-system remote control method, device, system mainboard and intelligent all-in-one machine - Google Patents

Abstract

The invention discloses a dual-system remote control method, a dual-system remote control device, a system mainboard and an intelligent all-in-one machine, wherein the method comprises the following steps: receiving a first key event sent by an intelligent pen controller through a first operating system; when the currently presented operating system is determined to be a second operating system, converting the first key event into a second key event according to the protocol of the second operating system, wherein the second key event is a key event which can be identified by the second operating system, and the second operating system and the first operating system are different types of operating systems; and forwarding the second key event to the second operating system so that the second operating system executes the response operation associated with the first key event. The different types of operating systems are controlled by the same intelligent pen in a cross-system mode, the intelligent pen does not need to be switched in the control process, and remote control operation of a user is facilitated; the failure of key control is avoided, and the consistency of key control is improved.

Description

Dual-system remote control method, device, system mainboard and intelligent all-in-one machine

Technical Field

The invention relates to the field of data processing, in particular to a dual-system remote control method, a dual-system remote control device, a system mainboard and an intelligent all-in-one machine.

Background

With the development of science and technology, intelligent all-in-one equipment is increasingly applied to the fields of modern education, meetings and the like. In order to meet the requirements of users, the Windows operating system and the android operating system are configured in the smart all-in-one machine equipment on the market, that is, two different main boards are configured respectively to realize two operating systems.

In order to facilitate the user to control the intelligent all-in-one machine, in the prior art, an intelligent pen is also configured for the intelligent all-in-one machine device. A smart pen is typically comprised of a receiver and a smart pen controller. During the use, the receiver is connected on corresponding mainboard, and the user controls through the button on the intelligent pen controller, for example turns over the page or leaf, turns over the page or leaf down, broadcast etc..

For remote control of two different types of operating systems (e.g., Windows, android), in the prior art, a receiver is often inserted into a corresponding interface to remotely control a current operating system through a smart pen.

In the prior art, chinese patent application with publication number CN107506245A discloses a method for remotely controlling multiple systems, which mainly adopts a scheme that a first operating system receives a remote control signal generated by a user operating a remote control device, and adaptively determines a function of a remote control pen key according to a current operating interface, for example, "comment" of the remote control key may be configured as "switch", if the current interface is a main system, the remote control key is determined as "comment" function, and if the current interface is an auxiliary system, the remote control key is determined as "switch" function. Although the control of different systems can be realized by the same intelligent pen, the method requires adaptive change of the key function of the intelligent pen, for example, the 'annotating' function needs to be configured with the 'switching' function at the same time, which brings inconvenience to the operation of a user, and the user experience is affected because two functions need to be remembered at the same time; moreover, after systems are switched back and forth, a user cannot determine which system is currently running, misoperation is possibly caused, and the consistency problem still exists; in addition, the implementation of the scheme requires that the two operating systems are the same type of operating system, for example, both operating systems are android systems, so that information transmission and forwarding can be performed, and the limitation is large.

Therefore, how to control the currently presented system by using the same intelligent pen becomes a technical problem to be solved urgently aiming at two different types of operating systems in the intelligent all-in-one machine equipment.

Disclosure of Invention

Based on the above situation, the main object of the present invention is to provide a dual-system remote control method, device, system motherboard and smart all-in-one machine, so as to use the same smart pen to control the currently presented system for two different types of operating systems in the smart all-in-one machine.

In order to achieve the purpose, the technical scheme adopted by the invention is as follows:

according to a first aspect, the embodiment of the invention discloses a dual-system remote control method, which is used for an intelligent all-in-one machine, and comprises the following steps:

receiving a first key event sent by an intelligent pen controller through a first operating system, wherein the first key event represents the remote control operation of the intelligent all-in-one machine; acquiring a currently presented operating system based on a first key event; when the currently presented operating system is determined to be a second operating system, converting the first key event into a second key event according to the protocol of the second operating system, wherein the second key event is a key event which can be identified by the second operating system, and the second operating system and the first operating system are different types of operating systems; and forwarding the second key event to the second operating system so that the second operating system executes response operation associated with the first key event.

Optionally, after acquiring the currently presented operating system based on the first key event, the remote control method further includes: and after the currently presented operating system is determined to be the first operating system, sending the first key event to the first operating system so that the first operating system executes response operation associated with the first key event.

Optionally, the first operating system and the second operating system interact with the touch system data respectively; and forwarding the second key event to the second operating system so that the second operating system executes response operation associated with the first key event, and forwarding the second key event to the touch system so that the touch system sends the second key event to the second operating system.

Optionally, the obtaining of the currently presented operating system in response to the first key event includes: reading a current signal source based on a first key event; and determining the operating system corresponding to the current signal source as the currently presented operating system.

Optionally, converting the first key event into the second key event according to a protocol of the second operating system includes: analyzing the first key event according to a protocol of a first operating system to obtain analyzed key event data; and converting the analyzed key event data into a second key event according to the protocol of the second operating system.

Optionally, the first operating system is an android system, and the second operating system is a Windows system.

According to a second aspect, the embodiment of the invention discloses a dual-system remote control device, which is used for an intelligent all-in-one machine, and comprises:

the event receiving module is used for receiving a first key event sent by the intelligent pen controller through a first operating system, and the first key event represents the remote control operation of the intelligent all-in-one machine; the system acquisition module is used for acquiring the currently presented operating system based on the first key event; the event conversion module is used for converting the first key event into a second key event according to the protocol of the second operating system after the currently presented operating system is determined to be the second operating system, wherein the second key event is a key event which can be identified by the second operating system, and the second operating system and the first operating system are different types of operating systems; and the event forwarding module is used for forwarding the second key event to the second operating system so as to enable the second operating system to execute response operation related to the first key event.

According to a third aspect, the embodiment of the invention discloses a dual-system mainboard for an intelligent all-in-one machine, wherein the system mainboard is detachably connected with a receiver of an intelligent pen and is used for receiving a first key event through the receiver of the intelligent pen, and the first key event represents the remote control operation of the intelligent all-in-one machine; the system mainboard includes:

a processor for executing a program to implement the method disclosed in any of the above first aspects.

According to a fourth aspect, an embodiment of the present invention discloses a storage medium, in which instructions are stored, the instructions being configured to be executed to implement the method disclosed in any of the first aspect above.

According to a fifth aspect, the embodiment of the invention discloses an intelligent all-in-one machine, which comprises:

a first system motherboard configured to run a first operating system, the first operating system running instructions implementing the method disclosed in any of the above first aspects; a second system motherboard configured to run a second operating system; and the display screen is respectively connected with the first system mainboard and the second system mainboard and is used for respectively displaying the data sent by the first system mainboard and the second system mainboard.

Optionally, the method further comprises: the receiver of the intelligent pen is detachably connected with the first system mainboard; the first system mainboard receives a first key event sent by the intelligent pen controller through a receiver of the intelligent pen.

According to the dual-system remote control method, the dual-system remote control device, the dual-system main board and the intelligent all-in-one machine disclosed by the embodiment of the invention, a first key event sent by the intelligent pen controller is received through the first operating system, the first key event represents the remote control operation on the intelligent all-in-one machine, after the first key event is received, the currently presented operating system is obtained, and after the currently presented operating system is determined to be a second operating system, the first key event is converted into a second key event according to the protocol of the second operating system, so that the second operating system can identify the key event, and then the second key event is forwarded to the second operating system, so that the second operating system executes the response operation related to the first key event. Compared with the prior art, aiming at different operating systems, the mode that the receiver needs to be inserted into the corresponding interface for remote control (because protocols among the operating systems of different types cannot be directly communicated) is realized, the scheme of the embodiment of the invention realizes that the operating systems of different types are controlled by the same intelligent pen across systems, and in the control process, the intelligent pen does not need to be switched, namely, a user does not need to frequently plug the receiver of the intelligent pen into different systems for remote control operation, thereby facilitating the remote control operation of the user; in the scheme of the embodiment of the invention, after the currently presented operating system is determined to be the second operating system, the first key event is converted into the second key event according to the protocol of the second operating system, so that the first key event can be read by the second operating system, namely, the consistency of key control is improved, and the user experience is improved.

As an optional scheme, after receiving the first key event with the first operating system and determining that the currently presented operating system is the first operating system, the first key event may be sent to the first operating system, so that the first operating system may directly execute a response operation associated with the first key event without performing a conversion of the key event, thereby improving timeliness of a key event response.

As an optional scheme, since the first operating system and the second operating system respectively interact with the touch system, the first operating system forwards the second key event to the touch system, so that the touch system sends the second key event to the second operating system, thereby eliminating the need for direct data interaction between the first operating system and the second operating system, reducing the possible compatibility problem, and further improving the accuracy of key event processing.

Other advantages of the present invention will be described in the detailed description, and those skilled in the art will understand the technical features and technical solutions presented in the description.

Drawings

Embodiments according to the present invention will be described below with reference to the accompanying drawings. In the figure:

fig. 1 is a flowchart of a remote control method for a dual system of an all-in-one smart machine disclosed in this embodiment;

fig. 2 is a schematic diagram illustrating a data interaction principle between a first operating system and a second operating system according to the present embodiment;

fig. 3 is a schematic structural diagram of a remote control device for a dual system of a smart all-in-one machine disclosed in this embodiment;

fig. 4 is a schematic diagram of a system motherboard for a dual system of an all-in-one smart machine disclosed in this embodiment;

fig. 5 is a schematic diagram of a structural principle of the smart all-in-one machine disclosed in this embodiment.

Detailed Description

In order to control a currently presented system by using the same smart pen for two different types of operating systems in a smart all-in-one device, specifically, two different main boards are used for the two systems on the smart all-in-one device, and protocols between the systems cannot be directly communicated, so that in the prior art, when a smart pen is used for remote control, a system interface of a currently running program needs to be determined, and a receiver is inserted into a corresponding interface, so as to realize remote control of the current operating system by the smart pen.

The present embodiment discloses a dual-system remote control method for an intelligent all-in-one machine, please refer to fig. 1, which is a flowchart of the dual-system remote control method for the intelligent all-in-one machine disclosed in the present embodiment, and the dual-system remote control method includes:

and S101, receiving a first key event sent by the intelligent pen controller through a first operating system. In this embodiment, the first key event is referred to as a remote control operation performed on the smart all-in-one machine, and the first key event may be, for example, page up, page down, annotation, playing, and the like. As an example, when the display screen of the smart phone is currently playing the PPT, the presenter may send a first key event of "page down" through the smart pen controller, so that the display screen of the smart phone starts to present the next PPT page. In a specific embodiment, the first operating system may be an android system or a Windows system, and in this embodiment, the first operating system is preferably an android system. It should be noted that, in the specific implementation process, other operating systems suitable for running on the smart all-in-one machine may also be the first operating system of this embodiment.

And step S103, acquiring the currently presented operating system based on the first key event. In a specific embodiment, the smart all-in-one machine is configured with two different types of operating systems, namely a first operating system and a second operating system, or may be multiple different types of operating systems. The first operating system and the second operating system can multiplex the display screen of the intelligent all-in-one machine in a time-sharing mode, namely, the display screen of the intelligent all-in-one machine displays the display data sent by the first operating system or the second operating system in a time-sharing mode. In this embodiment, after receiving a first key event sent by the smart pen controller through the first operating system, the operating system currently presented is queried in response to the first key event, that is, whether the currently presented data is the first operating system or the second operating system.

Step S105, after the operating system which is currently presented is determined to be the second operating system, the first key event is converted into the second key event according to the protocol of the second operating system. In this embodiment, the second operating system and the first operating system are different types of operating systems, and the second operating system may be an android system or a Windows system. It should be noted that, in the specific implementation process, other operating systems suitable for running on the smart all-in-one machine may also be the second operating system of this embodiment. The second key event is a key event recognizable by the second operating system, and specifically, the first key event is converted into the second key event according to a protocol of the second operating system, so that the converted second key event can be recognized by the second operating system.

In a specific embodiment, in step S105, the converting the first key event into the second key event according to the protocol of the second operating system includes: analyzing the first key event according to a protocol of a first operating system to obtain analyzed key event data; and converting the analyzed key event data into a second key event according to the protocol of the second operating system. Because the first key event is received based on the first operating system, the first key event can be analyzed according to the protocol of the first operating system to obtain analyzed key event data, and then the second key event is obtained by converting according to the protocol of the second operating system, so that the second key event can be identified by the second operating system.

And step S107, forwarding the second key event to a second operating system. In this embodiment, since the second key event is converted from the first key event, after the second key event is forwarded to the second operating system, the second operating system may perform a response operation associated with the first key event. Since the currently presented operating system is the second operating system, the response operation executed by the second operating system is also directed to the currently presented data, for example, page up, page down, annotate, play, and the like are performed on the currently presented data.

According to the dual-system remote control method disclosed by the embodiment, a first key event sent by an intelligent pen controller is received through a first operating system, the first key event represents that the intelligent all-in-one machine is remotely controlled, after the first key event is received, the currently presented operating system is obtained, after the currently presented operating system is determined to be a second operating system, the first key event is converted into a second key event according to the protocol of the second operating system, the second operating system can identify the key event, and then the second key event is forwarded to the second operating system, so that the second operating system executes response operation associated with the first key event. Compared with the prior art, aiming at different operating systems, the receiver needs to be inserted into corresponding interfaces for remote control (because protocols among the operating systems of different types cannot be directly communicated), the scheme of the embodiment realizes that the operating systems of different types are controlled by the same intelligent pen across systems, and in the control process, the intelligent pen does not need to be switched, namely, a user does not need to frequently plug the receiver of the intelligent pen into different systems for remote control operation, so that the remote control operation of the user is facilitated. And, the failure of key control is avoided, specifically, in the prior art, if the user forgets to switch the smart pen receiver, the key control will fail when the user uses the smart pen controller, resulting in frustration in user use, but in the scheme of this embodiment, after determining that the currently presented operating system is the second operating system, the first key event is converted into the second key event according to the protocol of the second operating system, so that the first key event can be read by the second operating system, that is, the consistency of key control is improved, and the user experience is improved.

In an optional embodiment, after determining that the currently presented operating system is the first operating system, sending the first key event to the first operating system. The first key event is received based on the first operating system, so that the first operating system can directly identify the first key event, and after the first operating system receives the first key event, the response operation associated with the first key event can be directly executed without format conversion, thereby improving the timeliness of key event response.

In an optional embodiment, please refer to fig. 2, which is a schematic diagram illustrating a data interaction principle of a first operating system and a second operating system disclosed in this embodiment, the first operating system and the second operating system interact with data of a touch system respectively, that is, the first operating system and the second operating system multiplex the touch system in a time-sharing manner, so that the first operating system and the second operating system can implement touch operation through the same touch system. In step S107, when the second key event is forwarded to the second operating system, the second key event is forwarded to the touch system, so that the touch system sends the second key event to the second operating system. That is, after the first operating system converts the first key event into the second key event, the second key event is forwarded to the touch system, and then the touch system sends the second key event to the second operating system.

In this embodiment, since the first operating system and the second operating system respectively interact with the touch system, the first operating system forwards the second key event to the touch system, so that the touch system sends the second key event to the second operating system, thereby eliminating the need for direct data interaction between the first operating system and the second operating system, reducing the possible compatibility problem, and further improving the accuracy of key event processing.

In a specific embodiment, when step S103 is executed, determining the currently presented operating system based on the first key event includes: reading a current signal source in response to a first key event; and determining the operating system corresponding to the current signal source as the currently presented operating system. In this embodiment, the current signal source is an operating system that currently provides a signal source to the display screen, and in an optional embodiment, when the first operating system and the second operating system respectively interact with the touch system data, the current signal source may be determined by collecting data of the touch system, that is, the current signal source is the first operating system or the second operating system. After the current signal source is read, it can be determined with which signal source the display screen performs data interaction, and therefore, the operating system corresponding to the current signal source can be determined as the currently presented operating system.

The embodiment also discloses a dual-system remote control device for a smart all-in-one machine, please refer to fig. 3, which is a schematic structural diagram of the dual-system remote control device for the smart all-in-one machine disclosed in the embodiment, and the remote control device includes: an event receiving module 301, a system acquiring module 302, an event converting module 303 and an event forwarding module 304, wherein:

the event receiving module 301 is configured to receive a first key event sent by the smart pen controller through a first operating system, where the first key event represents a remote control operation on the smart all-in-one machine; the system obtaining module 302 is configured to determine a currently presented operating system based on the first key event; the event conversion module 303 is configured to, after determining that the currently presented operating system is a second operating system, convert the first key event into a second key event according to a protocol of the second operating system, where the second key event is a key event that can be recognized by the second operating system, and the second operating system and the first operating system are different types of operating systems; the event forwarding module 304 is configured to forward the second key event to the second operating system, so that the second operating system performs a response operation associated with the first key event.

In an alternative embodiment, the event forwarding module 304 is further configured to, after determining that the currently presented operating system is the first operating system, send the first key event to the first operating system, so that the first operating system performs a response operation associated with the first key event.

In an optional embodiment, the first operating system and the second operating system respectively interact with data of the touch system; the event forwarding module 304 is further specifically configured to forward the second key event to the touch system, so that the touch system sends the second key event to the second operating system.

In an alternative embodiment, the system acquisition module 302 includes: the signal source reading unit is used for responding to the first key event to read the current signal source; and the determining unit is used for determining the operating system corresponding to the current signal source as the currently presented operating system.

In an alternative embodiment, the event conversion module 303 includes: the analysis unit is used for analyzing the first key event according to a protocol of the first operating system to obtain analyzed key event data; and the conversion unit is used for converting the analyzed key event data into a second key event according to the protocol of the second operating system.

In an alternative embodiment, the first operating system is an android system, and the second operating system is a Windows system.

The embodiment further discloses a dual-system motherboard for an intelligent all-in-one machine, please refer to fig. 4, which is a schematic diagram of the dual-system motherboard for the intelligent all-in-one machine disclosed in the embodiment, and the system motherboard 400 includes: a processor 401, wherein the processor 401 is configured to execute a program to implement the method disclosed in any of the above embodiments; the system motherboard 400 is detachably connected to the receiver of the smart pen, and is configured to receive a first key event via the receiver of the smart pen, where the first key event indicates a remote operation of the smart all-in-one machine. Specifically, the system main board 400 may be detachably connected to the receiver of the smart pen through, for example, a USB interface or a miniUSB interface.

The present embodiment also discloses a storage medium, in which instructions are stored, the instructions being configured to be executed to implement the method disclosed in any of the above embodiments.

The embodiment further discloses an all-in-one machine, please refer to fig. 5, which is a schematic diagram of a structural principle of the all-in-one machine disclosed in the embodiment, and the all-in-one machine includes: a first system motherboard 501, a second system motherboard 502, and a display screen 503, wherein:

the first system motherboard 501 is configured to run a first operating system, and the first operating system runs instructions to implement the method disclosed in any of the above embodiments; second system motherboard 502 is configured to run a second operating system; the display screen 503 is connected to the first system motherboard and the second system motherboard, respectively, to display data sent by the first system motherboard and the second system motherboard, respectively.

In an optional embodiment, the method further comprises: the receiver of the intelligent pen is detachably connected with the first system mainboard; the first system mainboard receives a first key event sent by the intelligent pen controller through a receiver of the intelligent pen.

According to the dual-system remote control method, the dual-system remote control device, the dual-system main board and the intelligent all-in-one machine disclosed in the embodiment, the first operating system is used for receiving the first key event sent by the intelligent pen controller, the first key event represents that the intelligent all-in-one machine is remotely controlled, after the first key event is received, the currently presented operating system is obtained, after the currently presented operating system is determined to be the second operating system, the first key event is converted into the second key event according to the protocol of the second operating system, so that the second operating system can identify the key event, and then the second key event is forwarded to the second operating system, so that the second operating system executes the response operation associated with the first key event. Compared with the prior art, the method has the advantages that the receiver needs to be inserted into the corresponding interface for remote control aiming at different operating systems, the scheme of the embodiment realizes that different types of operating systems are controlled by the same intelligent pen in a system-crossing manner, and the intelligent pen does not need to be switched in the control process, namely, the user does not need to frequently plug the intelligent pen receiver into different systems for remote control operation, so that the remote control operation of the user is facilitated; and, the failure of key control has been avoided, specifically, in the prior art, if forget to switch the smart pen receiver, when the user uses the smart pen controller, the key control will fail, resulting in frustration of the user, and in the scheme of this embodiment, after determining that the operating system currently presented is the second operating system, the protocol of the first key event according to the second operating system is converted into the second key event, so that the first key event can be read by the second operating system, the failure of key control has been avoided, that is, the consistency of key control has been improved, and user experience has been improved.

It will be appreciated by those skilled in the art that the above-described preferred embodiments may be freely combined, superimposed, without conflict.

It will be understood that the embodiments described above are illustrative only and not restrictive, and that various obvious and equivalent modifications and substitutions for details described herein may be made by those skilled in the art without departing from the basic principles of the invention.

Claims (10)

1. A dual-system remote control method is used for an intelligent all-in-one machine, and is characterized by comprising the following steps:

receiving a first key event sent by an intelligent pen controller through a first operating system, wherein the first key event represents the remote control operation of the intelligent all-in-one machine;

acquiring a currently presented operating system based on the first key event;

when the currently presented operating system is determined to be a second operating system, converting the first key event into a second key event according to the protocol of the second operating system, wherein the second key event is a key event which can be identified by the second operating system, and the second operating system and the first operating system are different types of operating systems; and

and forwarding the second key event to the second operating system so as to enable the second operating system to execute the response operation associated with the first key event.

2. The remote control method of claim 1, wherein after said obtaining a currently presented operating system based on the first key event, the remote control method further comprises:

and after the currently presented operating system is determined to be the first operating system, sending the first key event to the first operating system so that the first operating system executes response operation associated with the first key event.

3. The remote control method of claim 1, wherein the first operating system and the second operating system interact with touch system data, respectively;

and in the process of forwarding the second key event to the second operating system so as to enable the second operating system to execute the response operation associated with the first key event, forwarding the second key event to the touch system so as to enable the touch system to send the second key event to the second operating system.

4. A remote control method as recited in any of claims 1-3, wherein said obtaining a currently presented operating system based on the first key event comprises:

reading a current signal source in response to the first key event;

and determining the operating system corresponding to the current signal source as the currently presented operating system.

5. A remote control method as recited in any of claims 1-3, wherein said translating the first key event to a second key event according to the protocol of the second operating system comprises:

analyzing the first key event according to the protocol of the first operating system to obtain analyzed key event data;

and converting the analyzed key event data into the second key event according to the protocol of the second operating system.

6. The remote control method according to any one of claims 1 to 5, wherein the first operating system is an android system, and the second operating system is a Windows system.

7. A dual-system remote control device for an intelligent all-in-one machine, the remote control device comprising:

the event receiving module is used for receiving a first key event sent by the intelligent pen controller through a first operating system, wherein the first key event represents the remote control operation of the intelligent all-in-one machine;

the system acquisition module is used for acquiring the currently presented operating system based on the first key event;

the event conversion module is used for converting the first key event into a second key event according to the protocol of the second operating system after the currently presented operating system is determined to be the second operating system, wherein the second key event is a key event which can be identified by the second operating system, and the second operating system and the first operating system are different types of operating systems; and

and the event forwarding module is used for forwarding the second key event to the second operating system so as to enable the second operating system to execute response operation related to the first key event.

8. A dual-system mainboard is used for an intelligent all-in-one machine, is detachably connected with a receiver of an intelligent pen and is used for receiving a first key event through the receiver of the intelligent pen, and the first key event represents the remote control operation of the intelligent all-in-one machine; characterized in that, the system mainboard includes:

a processor for executing a program to implement the method of any one of claims 1 to 6.

9. An intelligent all-in-one machine, comprising:

a first system motherboard configured to run a first operating system, the first operating system running instructions implementing the method of any of claims 1-6;

a second system motherboard configured to run a second operating system;

and the display screen is respectively connected with the first system mainboard and the second system mainboard and is used for respectively displaying the data sent by the first system mainboard and the second system mainboard.

10. The smart kiosk of claim 9 further comprising:

the receiver of the intelligent pen is detachably connected with the first system mainboard;

and the first system mainboard receives a first key event sent by the intelligent pen controller through the receiver of the intelligent pen.

Images