CN111324322B - Multi-picture pre-monitoring configuration method, device, system and computer readable medium - Google Patents

Abstract

The embodiment of the invention discloses a multi-picture pre-monitoring configuration method, a device, a system and a computer readable medium. The multi-picture pre-monitoring configuration method comprises the following steps: responding to the first user operation instruction to display a layout panel, a display panel and a signal source panel; selecting a target picture display window from at least one picture display window of the display panel in response to a second user operation instruction; setting a layout type of a target picture display window on a layout panel in response to a third user operation instruction; and responding to a fourth user operation instruction to drag a target video signal source in at least one video signal source corresponding to the target video processing device in the signal source panel to a target picture sub-window in the target picture display window so as to configure the video signal source of the target picture sub-window. The embodiment of the invention can realize flexible and diverse configuration of the layout patterns of the multi-picture pre-monitoring interface and enrich the display effect of the multi-picture pre-monitoring interface.

Description

Multi-picture pre-monitoring configuration method, device, system and computer readable medium

Technical Field

The present invention relates to the field of display technologies, and in particular, to a multi-screen pre-monitoring configuration method, a multi-screen pre-monitoring configuration device, a multi-screen pre-monitoring configuration system, and a computer readable medium.

Background

The video processing device is mainly applied to performance occasions, so that the display safety is particularly important, and the output picture of the video processing device must be preconfigured and previewed to be presented to the audience after being confirmed without errors. With the continuous development of display technology, video processing equipment is continuously updated and perfected, the carrying capacity of the video processing equipment is continuously improved, and input sources are developed into more than ten input sources and even hundreds of input sources from the original single input source. In order to utilize hardware resources to the maximum extent, the video processing device outputs pictures of a plurality of input sources to a viewer for viewing through one output port after being configured and pre-monitored. Most video processing devices at present only support configuration of a multi-picture pre-monitoring interface through hardware, and even if a few video processing devices support configuration through software, the video processing devices only have a simple amplifying function. The prior multi-picture pre-monitoring interface has fixed layout, single style, incapability of adjusting after configuration and poor display effect.

Disclosure of Invention

Therefore, the embodiment of the invention provides a multi-picture pre-monitoring configuration method, a device, a system and a computer readable medium, which realize flexible and diverse configuration of layout patterns of a multi-picture pre-monitoring interface and enrich the display effect of the multi-picture pre-monitoring interface.

In one aspect, the present invention provides a multi-screen pre-monitoring configuration method, including: displaying a layout panel, a display panel and a signal source panel in response to a first user operation instruction, wherein the display panel comprises at least one picture display window, the at least one picture display window corresponds to at least one video processing device one by one, each picture display window comprises a plurality of picture sub-windows, and the signal source panel comprises at least one video signal source associated with the at least one video processing device; selecting a target picture display window from the at least one picture display window of the display panel in response to a second user operation instruction; setting the layout type of the target picture display window on the layout panel in response to a third user operation instruction, and sending the set layout type data of the target picture display window to target video processing equipment corresponding to the target picture display window; and responding to a fourth user operation instruction, dragging a target video signal source in at least one video signal source corresponding to the target video processing device in the signal source panel to a target picture sub-window in the target picture display window to configure the video signal source of the target picture sub-window, and sending video signal source configuration data of the target picture sub-window to the target video processing device.

In one embodiment of the invention, the plurality of picture sub-windows within the target picture display window includes a plurality of video signal source picture display sub-windows and at least one video output source picture display sub-window.

In one embodiment of the present invention, the layout types include an up-down layout type in which the plurality of video signal source picture display sub-windows and the at least one video output source picture display sub-window are distributed up-down, and a left-right layout type in which the plurality of video signal source picture display sub-windows and the at least one video output source picture display sub-window are distributed left-right.

In one embodiment of the present invention, the at least one video output source picture display sub-window includes a pre-monitor output signal source picture display sub-window and/or a currently playing signal source picture display sub-window.

In one embodiment of the present invention, the multi-screen pre-monitoring configuration method further includes: and responding to a fifth user operation instruction to move the target picture sub-window to a target position in the target picture display window, and sending the position data of the moved target picture sub-window to the target video processing equipment.

In one embodiment of the present invention, the multi-screen pre-monitoring configuration method further includes: and amplifying or restoring the target picture sub-window in response to a sixth user operation instruction, and transmitting the scaled size data of the target picture sub-window to the target video processing equipment.

In one embodiment of the present invention, the multi-screen pre-monitoring configuration method further includes: and responding to a seventh user operation instruction to play the video signal source in the target picture display sub-window.

On the other hand, the multi-picture pre-monitoring configuration device provided by the embodiment of the invention comprises: a panel display module, configured to display a layout panel, a display panel, and a signal source panel in response to a first user operation instruction, where the display panel includes at least one picture display window, the at least one picture display window corresponds to at least one video processing device one by one, each of the picture display windows includes a plurality of picture sub-windows, and the signal source panel includes at least one video signal source associated with the at least one video processing device; a window selection module for selecting a target picture display window from the at least one picture display window of the display panel in response to a second user operation instruction; a layout setting module, configured to set a layout type of the target screen display window on the layout panel in response to a third user operation instruction, and send layout type data of the set target screen display window to a target video processing device corresponding to the target screen display window; and the video source configuration module is used for responding to a fourth user operation instruction, dragging a target video signal source in at least one video signal source corresponding to the target video processing device in the signal source panel to a target picture sub-window in the target picture display window so as to configure the video signal source of the target picture sub-window, and sending the video signal source configuration data of the target picture sub-window to the target video processing device.

In one embodiment of the present invention, the multi-screen pre-monitor configuration device further includes: and the position moving module is used for responding to a fifth user operation instruction to move the target picture sub-window to the target position in the target picture display window and sending the position data of the moved target picture sub-window to the target video processing equipment.

In one embodiment of the present invention, the multi-screen pre-monitor configuration device further includes: and the window scaling module is used for responding to a sixth user operation instruction to enlarge or restore the target picture sub-window and transmitting the scaled size data of the target picture sub-window to the target video processing equipment.

In one embodiment of the present invention, the multi-screen pre-monitor configuration device further includes: and the video source playing module is used for responding to a seventh user operation instruction to play the video signal source in the target picture display sub-window.

In still another aspect, an embodiment of the present invention provides a multi-screen pre-monitoring configuration system, including: the system comprises a memory and a processor, wherein the memory stores a computer program, and the processor executes the multi-picture pre-monitoring configuration method when running the computer program.

In yet another aspect, an embodiment of the present invention provides a computer-readable medium having computer-executable instructions for performing a method of the foregoing multi-screen pre-monitor configuration method.

The technical scheme can have one or more of the following advantages or beneficial effects: the flexible and various configuration of the layout patterns of the multi-picture pre-monitoring interface is realized through software, the display effect of the multi-picture pre-monitoring interface is enriched, and the multi-picture pre-monitoring interface is more humanized.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a flowchart of a multi-frame pre-monitor configuration method according to an embodiment of the invention.

Fig. 2 is a schematic diagram of a screen configuration interface according to an embodiment of the invention.

Fig. 3 is a schematic diagram of a display panel in the screen configuration interface in fig. 2.

Fig. 4 is a schematic diagram of another display panel in the screen configuration interface in fig. 2.

Fig. 5 is a schematic diagram of a layout panel in the screen configuration interface in fig. 2.

Fig. 6 is a schematic diagram of a signal source panel in the screen configuration interface in fig. 2.

FIG. 7 is a schematic diagram of a zoom button in the pre-monitor output signal source display sub-window of FIG. 3.

FIG. 8 is a schematic diagram of a play button in the pre-monitor output signal source display sub-window of FIG. 3.

Fig. 9 is a schematic structural diagram of a multi-frame pre-monitor configuration device according to another embodiment of the invention.

Fig. 10 is a schematic structural view of a computer readable medium according to still another embodiment of the present invention.

FIG. 11 is a schematic diagram of a multi-frame pre-monitor configuration system according to another embodiment of the present invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Fig. 1 is a flow chart of a multi-screen pre-monitoring configuration method according to an embodiment of the invention. The multi-picture pre-monitoring configuration method comprises the following steps:

s11: displaying a layout panel, a display panel and a signal source panel in response to a first user operation instruction, wherein the display panel comprises at least one picture display window, the at least one picture display window corresponds to at least one video processing device one by one, each picture display window comprises a plurality of picture sub-windows, and the signal source panel comprises at least one video signal source associated with the at least one video processing device;

s13: selecting a target picture display window from the at least one picture display window of the display panel in response to a second user operation instruction;

s15: setting the layout type of the target picture display window on the layout panel in response to a third user operation instruction, and sending the set layout type data of the target picture display window to target video processing equipment corresponding to the target picture display window;

s17: and responding to a fourth user operation instruction, dragging a target video signal source in at least one video signal source corresponding to the target video processing device in the signal source panel to a target picture sub-window in the target picture display window to configure the video signal source of the target picture sub-window, and sending video signal source configuration data of the target picture sub-window to the target video processing device.

In order to facilitate understanding of the present invention, the following describes in detail the steps of the multi-screen pre-monitoring configuration method according to the present embodiment with reference to fig. 2 to 8.

Specifically, the multi-screen pre-monitor configuration method of the present embodiment typically refers to performing pre-monitor configuration of a plurality of screens of a video processing apparatus in multi-screen pre-monitor configuration software such as V-Can. The video processing device may be one or more video processing devices, i.e. the pre-monitoring configuration of the input and output frames of at least one video processing device may be completed. The video multi-picture pre-monitoring configuration software is installed on a computer, for example. Before multi-picture pre-monitoring, the computer is connected with the video processing equipment. The multi-picture pre-monitor configuration software acquires connected video processing apparatus information such as the number of video processing apparatuses, video signal source information of each video processing apparatus, and the like. The multi-picture pre-monitoring configuration software responds to the corresponding operation of the user to complete relevant setting, and sends the set parameters such as layout type data, position data, video signal source configuration data and the like to corresponding video processing equipment to complete multi-picture pre-monitoring configuration of input pictures and output pictures on the video processing equipment.

As shown in fig. 2, the screen configuration interface 1 is displayed in response to a user operation instruction such as a button operation instruction and the display panel 11, the layout panel 13, and the signal source panel 15 are displayed in the screen configuration interface 1.

In view of the above, as shown in fig. 3, the display panel 11 is used to display picture windows of a plurality of video signal sources of the video processing apparatus. The display panel 11 includes at least one picture display window 111. The number of picture display windows 111 depends on the number of video processing devices connected to the computer. The screen display windows 111 are in one-to-one correspondence with the video processing apparatuses. For example, when the video processing apparatus connected to the computer is 1 screen, 1 screen display window 111 is displayed in the display panel 11 as shown in fig. 1. When the video processing apparatus connected to the computer is 2, the display panel 11 displays 2 screen display windows 111 as shown in fig. 4. As shown in fig. 3, each of the picture display windows 111 includes a plurality of picture sub-windows. The plurality of picture sub-windows includes a plurality of video signal source picture display sub-windows 1111 and at least one video output source picture display sub-window. The plurality of video signal source picture display sub-windows 1111 in the picture display window 111 are in one-to-one correspondence with input pictures of the video processing apparatus, and at least one video output source picture display sub-window is in one-to-one correspondence with at least one output picture of the video processing apparatus. The video signal source picture display sub-window 1111 is for displaying pictures of a plurality of video signal sources of the video processing apparatus, respectively. The number of video signal source picture display sub-windows 1111 is greater than or equal to the number of video signal sources of the video processing apparatus corresponding to the picture display window 111. If the number of video signal source picture display sub-windows 1111 is greater than the number of video signal sources of the video processing apparatus corresponding to the picture display window 111, then "none" is displayed within the excessive video signal source picture display sub-windows 1111 (as shown in fig. 3). The number of the at least one video output source frame display sub-window is two, for example, respectively, a current playing signal source (or PGM (Program) signal source, which is generally a signal source currently output for display on a screen) frame display sub-window 1133 and a pre-monitor output signal source (or PVW (Preview) signal source, which is generally used as a next playing signal source after pre-monitor) frame display sub-window 1131. Of course, the at least one video output source frame display sub-window may be the only pre-monitor output signal source frame display sub-window 1131.

As shown in fig. 5, the layout panel 13 is used to set the layout type (layout style) of the screen display window 111 corresponding to the video processing apparatus. The layout type of the picture display window 111 typically refers to an arrangement of a plurality of video signal source picture display sub-windows and at least one video output source picture display sub-window within the picture display window 111. The layout types include, for example, an up-down layout type and a left-right layout type. Of course, there are other types, such as upper, middle, lower, etc., and the present invention is not limited thereto. The up-down layout type is that a plurality of video signal source picture display sub-windows and at least one video output source picture display sub-window are distributed up and down, for example, the plurality of video signal source picture display sub-windows are arranged at the upper part of the picture display window 111, the at least one video output source picture display sub-window is arranged at the lower part of the target picture display window 111, or the plurality of video signal source picture display sub-windows are arranged at the lower part of the picture display window 111, and the at least one video output source picture display sub-window is arranged at the upper part of the picture display window 111. The left-right layout type is that a plurality of video signal source picture display sub-windows and at least one video output source picture display sub-window are distributed left and right, for example, the plurality of video signal source picture display sub-windows are arranged at the left part of the picture display window 111, the at least one video output source picture display sub-window is arranged at the right part of the target picture display window 111, or the plurality of video signal source picture display sub-windows are arranged at the right part of the picture display window 111, and the at least one video output source picture display sub-window is arranged at the left part of the target picture display window 111. The layout panel 13 includes a plurality of buttons for setting the layout type of the screen display window 111, an up-down layout button 131, a left-right layout button 133, and the like. The multi-picture pre-monitoring configuration software responds to the user operation instruction to complete the corresponding layout setting. Further, after entering the screen configuration interface 1, the multi-screen pre-monitor configuration software presets a layout type for each screen display window 111. Further, the layout type preset by the multi-screen pre-monitor configuration software for each screen display window 111 is an up-down layout type.

The signal source panel 15 includes at least one video signal source associated with at least one video processing device. For example, as shown in FIG. 6, the signal source panel 15 includes 4 video signal sources A-DP, B-HDMI, C-SDI, and D-USB of the video processing device J6-1. The source panel 15 lists all video sources associated with each video processing apparatus, respectively, by video processing apparatus, for example, the video processing apparatus J6-1 in fig. 6 has the following 4 video sources. In addition, the source panel 15 includes a combined video source list, collectively listing all video sources. Further, after entering the screen configuration interface 1, the multi-screen pre-monitor configuration software presets a video signal source of a target video processing device corresponding to each of the screen display windows 111 in the display panel 11 for each of the screen sub-windows.

Then, one target screen display window 111 is selected from at least one screen display window 111 in the display panel in response to a selected operation instruction by the user.

Then, the layout type of the target screen display window 111 is set on the layout panel 13 in response to a button operation instruction by the user. After the setting is completed, the layout type data of the set target screen display window 111 is transmitted to the target video processing apparatus corresponding to the target screen display window 111 to display the corresponding screen layout style on the target video processing apparatus. For example, clicking the up-down layout button 131 in the layout panel 13 causes the plurality of video signal source screen display sub-windows and the at least one video output source screen display sub-window in the target screen display window 111 to be distributed up-down, or clicking the left-right layout button 133 in the layout panel 13 causes the plurality of video signal source screen display sub-windows and the at least one video output source screen display sub-window in the target screen display window 111 to be distributed left-right. And finally, the layout type data of the set target picture display window 111 is sent to target video processing equipment corresponding to the target picture display window 111, so that an input picture and an output picture on the target video processing equipment form a picture pre-monitoring interface with the same layout type as the target picture display window 111. Therefore, the user can set the layout types of the plurality of picture display windows corresponding to the video processing equipment through the multi-picture pre-monitoring configuration software, so that the flexible configuration of the multi-picture pre-monitoring interface layout style is realized, and the user experience is better. In addition, when a plurality of video processing apparatuses are connected to the computer, layout setting can be performed one by one on the plurality of screen display windows 111 corresponding to the plurality of video processing apparatuses. The layout types of the picture display windows 111 corresponding to the plurality of video processing apparatuses may be different or the same. Therefore, the multi-picture pre-monitoring interface configuration of a plurality of video processing devices can be realized.

Finally, a target video signal source of at least one video signal source corresponding to the target video processing device in the signal source panel 15 is dragged into a target picture sub-window (1111 or 1131 or 1133, etc.) in the target picture display window 111 in response to a user operation instruction, for example, a selection, dragging operation instruction, to configure the video signal source of the target picture sub-window 111, and video signal source configuration data of the target picture sub-window 111 is sent to the target video processing device corresponding to the target picture sub-window (1111 or 1131 or 1133), so as to configure the same video signal source for a picture window corresponding to the target picture sub-window in a multi-picture pre-monitoring interface of the target video processing device. It should be noted that the target video signal sources in the multiple picture sub-windows (1111 or 1131 or 1133) in the same target picture display window 111 may be the same or different. Thus, the configuration of the multi-picture pre-monitoring interface of the target video processing equipment is completed. Through different configurations, multiple pre-monitoring effects can be realized in the multi-picture pre-monitoring interface of the target video processing equipment, and the problems that the multi-picture pre-monitoring interface in the prior art is single in style and cannot be adjusted are solved.

In addition, a target screen sub-window (1111 or 1131 or 1133) of the plurality of screen sub-windows is moved to a target position in the target screen display window 111 in response to a user operation instruction such as a drag operation instruction, and position data of the target position of the target screen sub-window is transmitted to the target video processing apparatus, and the position movement of the corresponding screen window in the multi-screen pre-monitor interface of the target video processing apparatus is completed to realize the position configuration of the screen window.

Further, as shown in fig. 7, each of the screen sub-windows (1111 or 1131 or 1133) includes a zoom button. Further, the zoom button is located in the upper right corner of the screen child window (within the dashed box in fig. 7). The zoom button, which triggers the target screen sub-window (1111 or 1131 or 1133) for example, enlarges or restores the target screen sub-window (1111 or 1131 or 1133) in response to a user operation instruction, and transmits the size data of the target screen sub-window after zooming to the target video processing apparatus. Specifically, the zoom button is triggered in response to a user operation instruction, and the target screen child window (1111 or 1131 or 1133) is enlarged from the initial size to the maximum size of the screen display window 111; or trigger a zoom button in response to a user operation instruction to restore the target screen child window (1111 or 1131 or 1133) from the maximum size of the screen display window 111 to the initial size. And then the scaled size data of the target picture sub-window is sent to the target video processing equipment so as to realize the size configuration of the corresponding picture window on the target video processing equipment.

In addition, each of the screen sub-windows (1111 or 1131 or 1133) further includes a play button. In this way, the user can preview and display the target video signal source in the target picture sub-window in real time by playing the target video signal source, once the problem is found, the pre-monitoring configuration of the target video signal source can be realized immediately, in addition, the input picture and the output picture of the video processing device can be pre-monitored directly on a computer provided with multi-picture pre-monitoring configuration software, and a monitor is saved.

In summary, the embodiment of the invention realizes flexible and diverse configuration of the layout patterns of the multi-picture pre-monitoring interface through software, enriches the display effect of the multi-picture pre-monitoring interface, and makes the pre-monitoring interface more humanized; in addition, the embodiment of the invention realizes the real-time preview and display of the pre-monitored picture by scaling the video signal sources of the picture sub-window and the play picture sub-window, saves monitors, saves cost and improves user experience. In addition, the method can support simultaneous pre-monitoring of a plurality of video processing devices, and improves the utilization rate of the devices.

As shown in fig. 9, a multi-screen pre-monitor configuration apparatus 200 is provided in another embodiment of the present invention. Specifically, the multi-screen pre-monitor configuration apparatus 200 includes a panel display module 210, a window selection module 230, a layout setting module 250, and a video source configuration module 270.

The panel display module 210 is configured to display a layout panel, a display panel, and a signal source panel in response to a first user operation instruction, where the display panel includes at least one picture display window, the at least one picture display window corresponds to at least one video processing device one by one, each of the picture display windows includes a plurality of picture sub-windows, and the signal source panel includes at least one video signal source associated with the at least one video processing device.

A window selection module 230 for selecting a target screen display window from the at least one screen display window of the display panel in response to a second user operation instruction

A layout setting module 250, configured to set a layout type of the target screen display window on the layout panel in response to a third user operation instruction, and send the set layout type data of the target screen display window to a target video processing device corresponding to the target screen display window.

And the video source configuration module 270 is configured to respond to a fourth user operation instruction, drag a target video signal source in at least one video signal source corresponding to the target video processing device in the signal source panel to a target picture sub-window in the target picture display window to configure the video signal source of the target picture sub-window, and send the video signal source configuration data of the target picture sub-window to the target video processing device.

Further, the multi-screen pre-monitor configuration device 200 further includes a position moving module (not shown in the figure). The position moving module is used for responding to a user operation instruction to move the target picture sub-window to the target position in the target picture display window, and sending the position data of the target picture sub-window after the movement to the target video processing equipment.

Further, the multi-screen pre-monitor configuration device 200 further includes a window scaling module. The window scaling module is used for responding to a user operation instruction to enlarge or restore the target picture sub-window and sending the scaled size data of the target picture sub-window to the target video processing equipment.

Further, the multi-screen pre-monitor configuration device 200 further includes an amplifying module (not shown in the figure). The enlargement module is used for enlarging or restoring the target picture sub-window in response to a user operation instruction, such as a button operation instruction, and sending the size data of the target picture sub-window after being zoomed to the target video processing equipment.

Further, the multi-screen pre-monitor configuration device 200 further includes a playing module (not shown in the figure). The playing module is used for responding to user operation instructions such as playing button operation instructions to play the video signal source in the target picture display sub-window.

The specific implementation process and technical effects of the multi-screen pre-monitoring configuration device 200 and each module in the embodiment of the present invention refer to the foregoing embodiments, and are not repeated here.

As shown in fig. 10, a computer readable medium 300 storing computer executable instructions 310 for performing the multi-screen pre-monitor configuration method according to the above embodiment is provided in a further embodiment of the present invention.

The computer-readable medium 300 may include, for example: magnetic media (e.g., hard disk, floppy disk, and magnetic strips), optical media (e.g., CDROM disks and DVDs), magneto-optical media (e.g., optical disks), and hardware devices that are specially constructed for storing and performing computer-executable instructions (e.g., read-only memory (ROM), random Access Memory (RAM), flash memory, etc.). The computer-readable medium 300 is used to store computer-executable instructions 310 for the multi-screen pre-monitor configuration method of the foregoing implementation example. During operation of the computer, the computer reads computer-executable instructions 310 from the computer-readable medium 300 to implement the multi-picture pre-monitor configuration of the input pictures and the output pictures of the video processing apparatus, and the functions of real-time preview and presentation of the pre-monitor pictures.

As shown in fig. 11, a multi-screen pre-monitor configuration system 500 is provided in accordance with another embodiment of the present invention. The multi-picture pre-monitor configuration system 500 includes a memory 510 and a processor 530 coupled to the memory 510. The memory 510 may be, for example, a non-volatile memory, on which the computer program 511 is stored. Processor 530 may comprise, for example, an embedded processor. The processor 530 executes the multi-screen pre-monitor configuration method of the previous embodiment while running the computer program 511.

In the several embodiments provided in this application, it should be understood that the disclosed systems, apparatuses, and methods may be implemented in other ways. For example, the apparatus embodiments described above are merely illustrative, e.g., the division of the units is merely a logical function division, and there may be additional divisions in actual implementation, e.g., multiple units or components may be combined or integrated into another system, or some features may be omitted, or not performed. Alternatively, the coupling or direct coupling or communication connection shown or discussed with each other may be an indirect coupling or communication connection via some interfaces, devices or units, which may be in electrical, mechanical or other form.

The units described as separate units may or may not be physically separate, and units shown as units may or may not be physical units, may be located in one place, or may be distributed on multiple network units. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of this embodiment.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and are not limiting; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (12)

1. A multi-screen pre-monitor configuration method, comprising:

displaying a layout panel, a display panel and a signal source panel in response to a first user operation instruction, wherein the display panel comprises at least one picture display window, the at least one picture display window corresponds to at least one video processing device one by one, each picture display window comprises a plurality of picture sub-windows, and the signal source panel comprises at least one video signal source associated with the at least one video processing device;

selecting a target picture display window from the at least one picture display window of the display panel in response to a second user operation instruction; wherein the plurality of picture sub-windows in the target picture display window comprise a plurality of video signal source picture display sub-windows and at least one video output source picture display sub-window;

setting the layout type of the target picture display window on the layout panel in response to a third user operation instruction, and sending the set layout type data of the target picture display window to target video processing equipment corresponding to the target picture display window; and

and responding to a fourth user operation instruction, dragging a target video signal source in at least one video signal source corresponding to the target video processing device in the signal source panel to a target picture sub-window in the target picture display window to configure the video signal source of the target picture sub-window, and sending video signal source configuration data of the target picture sub-window to the target video processing device.

2. The multi-picture pre-monitor configuration method according to claim 1, wherein the layout types include an up-down layout type in which the plurality of video signal source picture display sub-windows and the at least one video output source picture display sub-window are distributed up-down, and a left-right layout type in which the plurality of video signal source picture display sub-windows and the at least one video output source picture display sub-window are distributed left-right.

3. The multi-picture pre-monitor configuration method of claim 1, wherein the at least one video output source picture display sub-window comprises a pre-monitor output signal source picture display sub-window and/or a currently playing signal source picture display sub-window.

4. The multi-screen pre-monitor configuration method according to claim 1, further comprising:

and responding to a fifth user operation instruction to move the target picture sub-window to a target position in the target picture display window, and sending the position data of the moved target picture sub-window to the target video processing equipment.

5. The multi-screen pre-monitor configuration method according to claim 1, further comprising:

and amplifying or restoring the target picture sub-window in response to a sixth user operation instruction, and transmitting the scaled size data of the target picture sub-window to the target video processing equipment.

6. The multi-screen pre-monitor configuration method according to claim 1, further comprising:

and responding to a seventh user operation instruction to play the video signal source in the target picture display sub-window.

7. A multi-screen pre-monitor configuration device, comprising:

a panel display module, configured to display a layout panel, a display panel, and a signal source panel in response to a first user operation instruction, where the display panel includes at least one picture display window, the at least one picture display window corresponds to at least one video processing device one by one, each of the picture display windows includes a plurality of picture sub-windows, and the signal source panel includes at least one video signal source associated with the at least one video processing device;

a window selection module for selecting a target picture display window from the at least one picture display window of the display panel in response to a second user operation instruction; wherein the plurality of picture sub-windows in the target picture display window comprise a plurality of video signal source picture display sub-windows and at least one video output source picture display sub-window;

a layout setting module, configured to set a layout type of the target screen display window on the layout panel in response to a third user operation instruction, and send layout type data of the set target screen display window to a target video processing device corresponding to the target screen display window; and

and the video source configuration module is used for responding to a fourth user operation instruction, dragging a target video signal source in at least one video signal source corresponding to the target video processing device in the signal source panel to a target picture sub-window in the target picture display window so as to configure the video signal source of the target picture sub-window, and sending the video signal source configuration data of the target picture sub-window to the target video processing device.

8. The multi-screen pre-monitor configuration device according to claim 7, further comprising:

and the position moving module is used for responding to a fifth user operation instruction to move the target picture sub-window to the target position in the target picture display window and sending the position data of the moved target picture sub-window to the target video processing equipment.

9. The multi-screen pre-monitor configuration device according to claim 7, further comprising:

and the window scaling module is used for responding to a sixth user operation instruction to enlarge or restore the target picture sub-window and transmitting the scaled size data of the target picture sub-window to the target video processing equipment.

10. The multi-screen pre-monitor configuration device according to claim 7, further comprising:

and the video source playing module is used for responding to a seventh user operation instruction to play the video signal source in the target picture display sub-window.

11. A multi-screen pre-monitor configuration system, comprising: a memory storing a computer program, and a processor executing the multi-screen pre-monitor configuration method according to any one of claims 1 to 6 when the computer program is run.

12. A computer readable medium having computer executable instructions for performing a multi-picture pre-monitor configuration method, the multi-picture pre-monitor configuration method according to any one of claims 1 to 6.