CN107690612B - Display control method and electronic equipment - Google Patents

Abstract

A display control method and an electronic device are provided, wherein the display control method comprises the steps of receiving a split screen display instruction of a user (S101), responding to the split screen display instruction to divide a display screen into at least two split screen display areas (S102), further dividing a plurality of windows to be displayed into split screen display queues corresponding to the split screen display areas respectively (S103), and controlling the at least two split screen display areas to display window interfaces in the corresponding split screen display queues respectively (S104). Therefore, the method and the electronic equipment can divide the display screen into a plurality of split-screen display areas, and further display different window interfaces simultaneously and respectively.

Description

Display control method and electronic equipment

Technical Field

The embodiment of the invention relates to the technical field of communication, in particular to a display control method and electronic equipment.

Background

The window opening mode of a display screen of the existing electronic equipment is usually a full-screen mode, different windows are arranged in a full-screen displayed window, when a user needs to switch different page contrasts, the user cannot split the screen, and only the page contrasts can be switched by adopting a screen sliding mode or a mode of returning to click the next page. Especially, for the current electronic device, which usually includes multiple Applications (APPs), when the electronic device executes an application, usually only a single application can be started at the same time for operation and execution, when multiple applications need to be executed simultaneously, the executed application needs to be reduced to a background application column, and different applications are switched by calling the background application column, which increases the operation burden of the user.

Disclosure of Invention

The embodiment of the invention provides a display control method and electronic equipment, which can realize split-screen display of a plurality of window interfaces.

In order to solve the above technical problem, a first technical solution adopted in the embodiments of the present invention is: there is provided a display control method including: receiving a split-screen display instruction of a user; responding to a split screen display instruction to divide a display screen into at least two split screen display areas; dividing a plurality of window interfaces to be displayed into at least two split-screen display queues corresponding to the split-screen display areas respectively; and controlling at least two split screen display areas to respectively display the window interfaces in the corresponding split screen display queues, and further displaying icons corresponding to the window interfaces in the corresponding split screen display queues at the preset position of each split screen display area.

Wherein the step of dividing the display screen into at least two split-screen display areas in response to the split-screen display instruction comprises: and responding to the split-screen display instruction to divide the display screen into at least two split-screen display areas which are arranged side by side and are equal to each other in size.

The step of dividing a plurality of window interfaces to be displayed into at least two split-screen display queues corresponding to the split-screen display areas respectively comprises the following steps: receiving a queue allocation instruction of a user; and responding to the queue distribution instruction to distribute the window interface specified by the user to the corresponding split-screen display queue.

The step of dividing a plurality of window interfaces to be displayed into at least two split-screen display queues corresponding to the split-screen display areas respectively comprises the following steps: and sequentially distributing the plurality of window interfaces to at least two split-screen display queues in sequence.

The step of controlling at least two split screen display areas to respectively display the window interfaces in the corresponding split screen display queue comprises the following steps: and displaying one window interface in the corresponding split-screen display queue in each split-screen display area.

Wherein, the step of controlling at least two sub-screen display areas to respectively display the window interfaces in the corresponding sub-screen display queue further comprises: receiving a picture designation instruction of a user, wherein the picture designation instruction is used for selecting a window interface to be displayed from a split-screen display queue; and responding to the picture designation instruction to select a window interface designated by the user from the split-screen display queue, and displaying the window interface in the split-screen display area corresponding to the split-screen display queue where the window interface is positioned.

Wherein, the step of controlling at least two sub-screen display areas to respectively display the window interfaces in the corresponding sub-screen display queue further comprises: receiving a window switching instruction of a user; and responding to the window switching instruction to adjust the window interface appointed by the user from one split screen display queue to another split screen display queue, and further displaying the window interface by a split screen display area corresponding to the another split screen display queue.

Wherein, the display control method further comprises: and distributing the newly added window interfaces according to the number of the existing window interfaces in the split-screen display queue.

The method for distributing the newly added window interfaces according to the number of the existing window interfaces in the split-screen display queue comprises the following steps: and distributing the newly added window interfaces to the split-screen display queue with the least number of the existing window interfaces.

Wherein, the display control method further comprises: receiving a full screen display instruction of a user; responding to a full-screen display instruction to combine at least two split-screen display areas into a full-screen display area; merging at least two split-screen display queues into a full-screen display queue; and controlling the full-screen display area to display the window interface in the full-screen display queue.

In order to solve the above technical problem, a second technical solution adopted in the embodiments of the present invention is: the electronic equipment comprises a communication bus, a display screen, an input device, a processor and a memory, wherein the display screen, the input device, the processor and the memory are respectively connected with the communication bus, programs are stored in the memory, the processor is used for executing the programs, and the programs comprise: the input device receives a split-screen display instruction of a user, the processor responds to the split-screen display instruction to divide the display screen into at least two split-screen display areas, and further divides a plurality of window interfaces to be displayed into at least two split-screen display queues corresponding to the split-screen display areas respectively, the processor further controls the at least two split-screen display areas to display the window interfaces in the corresponding split-screen display queues respectively, and further displays icons corresponding to the window interfaces in the corresponding split-screen display queues at preset positions of the split-screen display areas.

The processor responds to the split-screen display instruction to divide the display screen into at least two split-screen display areas which are arranged side by side and are equal to each other in size.

The input device further receives a queue distribution instruction of a user, and the processor responds to the queue distribution instruction to distribute the window interface specified by the user to the corresponding split-screen display queue.

The processor sequentially distributes the plurality of window interfaces to at least two split-screen display queues according to the sequence.

The processor controls at least two split-screen display areas to display one window interface in the corresponding split-screen display queue in each split-screen display area.

The input device further receives a picture designation instruction of a user, the picture designation instruction is used for selecting a window interface to be displayed from the split-screen display queue, the processor responds to the picture designation instruction to select the window interface designated by the user from the split-screen display queue, and controls a split-screen display area corresponding to the split-screen display queue where the window interface designated by the user is located to display the window interface designated by the user.

The input device receives a window switching instruction of a user, the processor responds to the window switching instruction to adjust a window interface designated by the user from one split-screen display queue to another split-screen display queue, and then the split-screen display area corresponding to the other split-screen display queue is controlled to display the window interface designated by the user.

And the processor further allocates the newly added window interfaces according to the number of the existing window interfaces in the split-screen display queue.

And the processor allocates the newly added window interfaces to the split-screen display queue with the least number of the existing window interfaces.

The input device further receives a full-screen display instruction of a user, the processor responds to the full-screen display instruction to combine at least two split-screen display areas into a full-screen display area, and further combines at least two split-screen display queues into a full-screen display queue, so that the full-screen display area is controlled to display a window interface in the full-screen display queue.

The embodiment of the invention has the beneficial effects that: according to the display control method provided by the embodiment of the invention, the display screen is divided into the plurality of split screen display areas through the split screen display instruction of the user, the window interfaces to be displayed are respectively divided into the plurality of split screen display queues corresponding to the split screen display areas, and the split screen display areas are further controlled to respectively correspondingly display the window interfaces in the split screen display queues, so that the display screen is divided into the plurality of split screen display areas, the display screen can display the plurality of window interfaces in a split screen mode at the same time, and the user operation experience is improved.

Drawings

FIG. 1 is a flow chart illustrating a display control method according to a first embodiment of the present invention;

FIG. 2 is a schematic view of a scene of a split-screen display window interface of a display screen according to an embodiment of the present invention;

FIG. 3 is a flowchart illustrating a display control method according to a second embodiment of the present invention;

FIG. 4 is a diagram illustrating a scene of switching a split-screen display window according to an embodiment of the present invention;

FIG. 5 is a schematic view of a scene of switching a split-screen display window according to another embodiment of the present invention;

FIG. 6 is a flowchart illustrating a display control method according to a third embodiment of the present invention;

FIG. 7 is a diagram illustrating a scenario in which a window interface is added to a split-screen display queue according to an embodiment of the present invention;

FIG. 8 is a flowchart illustrating a display control method according to a fourth embodiment of the present invention;

FIG. 9 is a diagram illustrating a scenario where a display screen is switched from a split-screen display window to a full-screen display window according to an embodiment of the present invention;

fig. 10 is a schematic structural diagram of an electronic device according to an embodiment of the invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The invention provides a display control method and electronic equipment.

Referring to fig. 1, fig. 1 is a flowchart illustrating a display control method according to a first embodiment of the invention. As shown in fig. 1, the display control method provided in this embodiment includes:

s101: and receiving a split screen display instruction of a user.

The split-screen display instruction may be a preset gesture action made by a user or triggering a preset physical key or virtual key, for example, the user may issue the split-screen display instruction by touching a blank area of the screen or sliding an edge position of the screen.

S102: the display screen 100 is divided into at least two split-screen display areas in response to the split-screen display instruction.

After receiving a split-screen display instruction of a user, the display screen 100 is divided into at least two split-screen display areas in response to the split-screen display instruction. The number of the split-screen display areas may be preset by the user, for example, the display screen 100 is divided into two, four, six, etc. split-screen display areas, and if the number of the split-screen display areas is large, the display screen 100 may be set to be displayed in a manner of scrolling up and down or left and right.

In the embodiment, the display screen 100 may be divided into at least two sub-screen display areas that are arranged side by side and equal to each other in response to the sub-screen display instruction, as shown in fig. 2, the display screen 100 is divided into two sub-screen display areas that are arranged side by side and equal to each other, i.e., a I-region sub-screen display area 101 and a II-region sub-screen display area 102.

In other embodiments, at least two split-screen display areas may be divided into different sized split-screen display areas, such as adjusting the display screen 100 to be one larger and one smaller split-screen display areas. In other embodiments, after receiving the split-screen display instruction, the display screen 100 may pop up a setting menu to set the number of split-screen display areas, and display a corresponding number of to-be-displayed window interfaces on a split screen after the setting is completed, where the number of split-screen display areas is set to be at least two.

S103: and respectively dividing a plurality of window interfaces to be displayed into at least two split screen display queues corresponding to the split screen display areas.

In this embodiment, a plurality of window interfaces to be displayed are sequentially allocated to at least two split-screen display queues in sequence. Continuing with FIG. 2, the A, B, C three window interfaces to be displayed are divided into an I area 101 of the display screen 100 and the D, E, F three window interfaces to be displayed are divided into a II area 102 of the display screen 100.

In other embodiments, the window interface designated by the user may also be allocated to the corresponding split-screen display queue by receiving a queue allocation instruction of the user, for example, the window interfaces may be classified by their application properties and allocated to the designated split-screen display queue.

S104: and controlling at least two split screen display areas to respectively display the window interfaces in the corresponding split screen display queues.

In this embodiment, one window interface in the corresponding split-screen display queue is displayed in each split-screen display area, and an icon corresponding to the window interface in the corresponding split-screen display queue is further displayed at a predetermined position of the split-screen display area. As shown in fig. 2, a window interface a is displayed in the I area 101, a window interface D is displayed in the II area 102, A, B, C window interface icons in the split-screen display queue are displayed in the I area status bar, D, E, F window interface icons in the split-screen display queue are displayed in the II area status bar, and a user can switch the window interface displayed in the current split-screen display area by clicking the window interface icon in the status bar.

In other embodiments, the screen designation instruction may be used to select a window interface to be displayed from the split-screen display queue by receiving a screen designation command of the user, select the window interface designated by the user from the split-screen display queue in response to the screen designation command, and further display the window interface in the split-screen display area corresponding to the split-screen display queue in which the designated window interface is located.

In other embodiments, an adjustment operation instruction input by a user may be further obtained, and the size of the current respective display window of the at least two split-screen display areas is adjusted according to the adjustment operation instruction, for example, the current respective display window is adjusted to two split-screen display areas, one large split-screen display area and one small split-screen display area, so as to meet different requirements.

Therefore, the display control method of this embodiment may divide the display screen 100 into a plurality of split-screen display areas, and divide the plurality of window interfaces into split-screen display queues corresponding to different split-screen display areas, so as to implement split-screen display of different window interfaces and improve user experience.

Referring to fig. 3, fig. 3 is a flowchart illustrating a display control method according to a second embodiment of the invention. As shown in fig. 3, the display control method of the present embodiment includes:

s301: and receiving a split screen display instruction of a user.

S302: the display screen 100 is divided into at least two split-screen display areas in response to the split-screen display instruction.

S303: and respectively dividing a plurality of window interfaces to be displayed into at least two split screen display queues corresponding to the split screen display areas.

S304: and controlling at least two split screen display areas to respectively display the window interfaces in the corresponding split screen display queues.

Steps S301 to S304 are similar to steps S101 to S104 of the above embodiments, and are not repeated herein.

The difference from the above-described embodiment is that the display control method of the present embodiment further includes:

s305: and receiving a window switching instruction of a user.

S306: and responding to the window switching instruction to adjust the window interface appointed by the user from one split screen display queue to another split screen display queue, and further displaying the window interface by a split screen display area corresponding to the another split screen display queue.

In this embodiment, after one window interface in the corresponding split-screen display queue is displayed in each split-screen display area, a window switching instruction of a user is further received. The window switching instruction may be a preset gesture action made on the split-screen display area or the blank area of the display screen 100 or a preset area, such as clicking, touching, sliding the split-screen display area or the blank area of the display screen 100.

In response to a window switching instruction input by a user, as shown in fig. 4, a designated window interface B is selected from the split-screen display queue of the I area 101, and is dragged to the split-screen display queue of the II area 102, so that the split-screen display area II area 102 corresponding to the split-screen display queue of the II area 102 displays the window interface B.

In other embodiments, the currently displayed window interface in one of the split-screen display areas and the window interfaces in the corresponding split-screen display queue may also be switched, for example, as shown in fig. 5, the window interface B in the split-screen display queue of the I-zone 101 is switched to the current display window in the corresponding split-screen display area in response to a window switching instruction, so as to replace the window interface a in the current split-screen display area.

Therefore, the window interface of the display area can be freely switched, and the operation experience of the user is further improved.

Referring to fig. 6, fig. 6 is a flowchart illustrating a display control method according to a third embodiment of the invention. The display control method of the embodiment includes:

s601: and receiving a split screen display instruction of a user.

S602: the display screen 100 is divided into at least two split-screen display areas in response to the split-screen display instruction.

S603: and respectively dividing a plurality of window interfaces to be displayed into at least two split screen display queues corresponding to the split screen display areas.

S604: and controlling at least two split screen display areas to respectively display the window interfaces in the corresponding split screen display queues.

Steps S601 to S604 are similar to steps S101 to S104 of the above embodiments, and are not repeated herein.

The difference from the first embodiment is that the display control method of the present embodiment further includes:

s605: and distributing the newly added window interfaces according to the number of the existing window interfaces in the split-screen display queue.

S606: and distributing the newly added window interfaces to the split-screen display queue with the least number of the existing window interfaces.

In this embodiment, if a window interface is newly added, the newly added window interface is directly allocated to the split-screen display queue with the smallest number of existing window interfaces, so that the split-screen operation arrangement logic of the display screen 100 is simple and clear, and the defect of insufficient space for switching the label at the lower side due to too many windows at one side can be avoided. After step S606, the process may further return to step S604, and control at least two split-screen display areas to respectively display window interfaces in corresponding split-screen display queues, where one split-screen display queue includes a newly added window interface.

In other embodiments, if the number of window interfaces in the split-screen display queue is consistent, the newly added window interface is allocated to the preset split-screen display queue, and as shown in fig. 7, the newly added window interface G is allocated to the I-division screen display area 101.

Or, in other embodiments, a split-screen display area may be added to the existing split-screen display area to separately display the newly added window interface.

Further, in other embodiments, one of the window interfaces may also be selected from the split-screen display queue corresponding to the existing split-screen display area, and a deletion operation is performed, that is, the selected window interface is deleted from the split-screen display queue.

In addition, in other embodiments, one of the window interfaces may be selected from one of the split-screen display queues, and the window interface may be switched to be displayed in a full screen.

Therefore, the method and the device can add the newly opened window into the split-screen display queue without affecting the arrangement logic of the opened window, and improve the user experience.

Referring to fig. 8, fig. 8 is a flowchart illustrating a display control method according to a fourth embodiment of the invention. The display control method of the embodiment includes:

s801: and receiving a split screen display instruction of a user.

S802: the display screen 100 is divided into at least two split-screen display areas in response to the split-screen display instruction.

S803: and respectively dividing a plurality of window interfaces to be displayed into at least two split screen display queues corresponding to the split screen display areas.

S804: and controlling at least two split screen display areas to respectively display the window interfaces in the corresponding split screen display queues.

Steps S801 to S804 are similar to steps S101 to S104 of the above embodiment, and are not repeated herein.

The difference from the first embodiment is that the display control method of the present embodiment further includes:

s805: and receiving a full-screen display instruction of a user.

S806: and combining at least two split-screen display areas into one full-screen display area in response to the full-screen display instruction.

S807: and combining at least two split-screen display queues into a full-screen display queue.

S808: and controlling the full-screen display area to display the window interface in the full-screen display queue.

When the split-screen display areas respectively display the window interfaces in the corresponding split-screen display queues, if a preset gesture action made by a user is received or a preset physical key or virtual key is triggered to issue a full-screen display instruction, combining at least two split-screen display areas into one full-screen display area in response to the full-screen display instruction, and combining at least two corresponding split-screen display queues into one full-screen display queue, so as to control the full-screen area to display the window interfaces in the full-screen display queue, as shown in fig. 9, further realize that a plurality of window interfaces are displayed in the full-screen of the display screen 100 in a thumbnail mode without losing information of the opened window interfaces, facilitate centralized operation of the window interfaces, and improve the operation efficiency.

In other embodiments, when a plurality of window interfaces are displayed in a full screen mode, one of the window interfaces can be further clicked to display the window interface in the full screen mode, the rest of the window interfaces are stored in a status bar of the current window interface, and the current window interface displayed in the full screen mode can be replaced by clicking the window interface in the status bar, so that the operation of a user is facilitated.

Further, after step S808, it may return to step S801 to receive a split-screen display instruction of the user, thereby performing split-screen display.

Therefore, the full-screen split-screen free switching can be achieved, the switching operation is convenient, the full-screen split-screen display requirement of a user is met, and the screen utilization rate is optimized.

Referring to fig. 10, fig. 10 is a schematic structural diagram of an electronic device according to an embodiment of the invention. As shown in fig. 10, the electronic device 200 of the present embodiment includes a communication bus 205, and a display 201, an input device 202, a processor 203, and a memory 204 respectively connected to the communication bus 205, wherein the memory 204 stores a program, and the processor 203 is configured to execute the program. The electronic device 200 of the present embodiment may implement all the steps or a part of the steps in the display control method of the above-described embodiment.

The display screen 201 may display one or more window interfaces in a full screen manner, or display a plurality of window interfaces in a split screen manner, and a user may set the number of split screen display areas of the display screen 201, for example, two, four, or six equal split screen display areas.

The input device 202 is used for receiving various operation instructions of a user, such as receiving a split-screen display instruction, a queue assignment instruction, a screen designation instruction, a window switching instruction, a full-screen display instruction, and the like input by the user.

The split-screen display instruction and the full-screen display instruction can be preset gesture actions made by a user or trigger preset physical keys or virtual keys.

The window switching instruction refers to adjusting a designated window interface from one split-screen display queue to another split-screen display queue, which may be a preset gesture action made on a split-screen display area or a blank area or a preset area of the display screen 201, such as clicking, touching, sliding the split-screen display area or the blank area of the display screen 201.

The queue allocation instruction is used for allocating the selected window interface to a specified split-screen display queue, and the picture designation instruction is used for displaying the selected window interface in a split-screen display area.

The processor 203 responds to various operation instructions to perform corresponding operations. For example, the processor 203 may divide the display screen 201 into at least two split-screen display areas in response to the split-screen display instruction, for example, divide the display screen 201 into at least two split-screen display areas that are arranged side by side and are equal to each other in response to the split-screen display instruction, and divide the display screen 201 into two split-screen display areas I and II that are arranged side by side and are equal to each other in response to the split-screen display instruction, as shown in fig. 2.

Further, the processor 203 may also allocate a window interface designated by a user to a corresponding split-screen display queue in response to the queue allocation instruction, or sequentially and respectively divide a plurality of window interfaces to be displayed into at least two split-screen display queues in sequence.

Further, the processor 203 may further control at least two split-screen display areas to respectively display one of the window interfaces in the corresponding split-screen display queue in each split-screen display area in response to the screen designation instruction. Or selecting a window interface appointed by the user from the split screen display queue, and further controlling the split screen display area corresponding to the split screen display queue where the appointed window interface is positioned to display.

Further, the processor 203 may adjust the window interface specified by the user from one split-screen display queue to another split-screen display queue in response to the window switching instruction, and further control the split-screen display area corresponding to the another split-screen display queue to display the specified window interface.

Further, the processor 203 may further combine at least two split-screen display areas into one full-screen display area in response to the full-screen display instruction, and further combine at least two split-screen display queues into one full-screen display queue, thereby controlling the full-screen display area to display the window interface in the full-screen display queue.

The processor 203 may also allocate the newly added window interfaces according to the number of the existing window interfaces in the split-screen display queue, for example, allocate the newly added window interfaces to the split-screen display queue with the smallest number of the existing window interfaces.

Optionally, the electronic device is a robotic teach pendant.

The Memory 204 may be a usb disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk or an optical disk, and other various media capable of storing program codes.

Therefore, the electronic device 200 of this embodiment can implement the display control method of the above embodiment, where the electronic device includes a display screen 201, an input device 202, and a processor 203, the input device 202 can receive various operation instructions of a user, and the processor 203 can divide the display screen 201 into at least two split-screen display areas, and can further divide a plurality of window interfaces to be displayed into at least two split-screen display queues corresponding to the split-screen display areas, so as to further control the at least two split-screen display areas to display window interfaces in the corresponding split-screen display queues, thereby implementing different window interfaces in split-screen display.

In summary, the display control method and the electronic device provided in the embodiments of the present invention can divide a display screen into a plurality of sub-screen display areas, so as to respectively display different window interfaces, thereby improving user experience.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes performed by the present specification and drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (12)

1. A display control method, wherein the display control method comprises:

receiving a split-screen display instruction of a user;

responding to the split-screen display instruction to divide the display screen into at least two split-screen display areas;

sequentially distributing a plurality of window interfaces to be displayed to at least two split-screen display queues corresponding to the split-screen display areas;

controlling the at least two split-screen display areas to respectively display the window interfaces in the corresponding split-screen display queues, and further displaying icons corresponding to the window interfaces in the corresponding split-screen display queues at preset positions of each split-screen display area;

receiving a picture designation instruction of a user, wherein the picture designation instruction is used for selecting a window interface to be displayed from the split-screen display queue;

responding to the image designation instruction to select the window interface designated by the user from the split-screen display queue and displaying the window interface in the split-screen display area corresponding to the split-screen display queue where the window interface is positioned,

and allocating newly added window interfaces according to the number of the existing window interfaces in the split-screen display queue, and allocating the newly added window interfaces to the split-screen display queue with the least number of the existing window interfaces.

2. The method of claim 1, wherein the step of dividing the display screen into at least two split-screen display regions in response to the split-screen display instruction comprises:

and responding to the split-screen display instruction to divide the display screen into the at least two split-screen display areas which are arranged side by side and are equal to each other in size.

3. The method of claim 1, wherein the step of dividing the plurality of window interfaces to be displayed into at least two split-screen display queues corresponding to the split-screen display areas respectively comprises:

receiving a queue allocation instruction of a user;

responding to the queue distribution instruction to distribute the window interface specified by the user to the corresponding split-screen display queue.

4. The method of claim 1, wherein the step of controlling the at least two split-screen display areas to respectively display the window interfaces in the corresponding split-screen display queue comprises:

and displaying one window interface in the corresponding split-screen display queue in each split-screen display area.

5. The method of claim 1, wherein the step of controlling the at least two split-screen display areas to respectively display the window interfaces in the corresponding split-screen display queue further comprises:

receiving a window switching instruction of a user;

and responding to the window switching instruction to adjust the window interface appointed by the user from one split screen display queue to another split screen display queue, and further displaying the window interface by the split screen display area corresponding to the another split screen display queue.

6. The method of claim 1, wherein the display control method further comprises:

receiving a full screen display instruction of a user;

responding to the full-screen display instruction to combine the at least two split-screen display areas into a full-screen display area;

merging the at least two split-screen display queues into a full-screen display queue;

and controlling the full-screen display area to display the window interface in the full-screen display queue.

7. An electronic device, wherein the electronic device comprises a communication bus, and a display screen, an input device, a processor and a memory which are respectively connected with the communication bus, wherein the memory stores a program, the processor is used for executing the program, and the program comprises:

the input device receives a split-screen display instruction of a user, the processor responds to the split-screen display instruction to divide the display screen into at least two split-screen display areas, and further sequentially distributes a plurality of window interfaces to be displayed to at least two split-screen display queues corresponding to the split-screen display areas, the processor further controls the at least two split-screen display areas to respectively display the window interfaces in the corresponding split-screen display queues, and further displays icons corresponding to the window interfaces in the corresponding split-screen display queues at preset positions of each split-screen display area,

the input device further receives a picture designation instruction of a user, the picture designation instruction is used for selecting a window interface to be displayed from the split-screen display queue, the processor responds to the picture designation instruction to select the window interface designated by the user from the split-screen display queue and controls the split-screen display area corresponding to the split-screen display queue where the window interface designated by the user is located to display the window interface designated by the user,

the processor further allocates the newly added window interfaces according to the number of the existing window interfaces in the split-screen display queue, and allocates the newly added window interfaces to the split-screen display queue with the smallest number of the existing window interfaces.

8. The electronic device of claim 7, wherein the processor divides the display screen into the at least two split screen display regions arranged side-by-side and equally large to each other in response to the split screen display instruction.

9. The electronic device of claim 7, wherein the input device further receives a user's queue assignment instruction, and the processor assigns the user-specified window interface to the corresponding split-screen display queue in response to the queue assignment instruction.

10. The electronic device of claim 7, wherein the processor controls the at least two split-screen display areas to display one of the window interfaces in the corresponding split-screen display queue within each of the split-screen display areas.

11. The electronic device of claim 7, wherein the input device receives a window switching instruction from a user, and the processor adjusts the window interface specified by the user from one split-screen display queue to another split-screen display queue in response to the window switching instruction, so as to control the split-screen display area corresponding to the another split-screen display queue to display the window interface specified by the user.

12. The electronic device of claim 7, wherein the input device further receives a full screen display command from a user, and the processor merges the at least two split screen display areas into one full screen display area in response to the full screen display command, and further merges the at least two split screen display queues into one full screen display queue, thereby controlling the full screen display area to display the window interface in the full screen display queue.

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