JP-2026075571-A - Image processing methods, apparatus, electronic devices, media, and display devices

Abstract

[Problem] This disclosure discloses an image processing method, apparatus, electronic device, medium, and display device. [Solution] The image processing device includes at least one input module, an image processing module, a synchronization module, and a plurality of output modules. Each input module is used to collect a display image signal. The image processing module is used to determine the number of output modules and, based on the number of output modules, to determine each display sub-image signal corresponding to the display image signal. The synchronization module is used to determine a synchronization signal corresponding to each display sub-image signal. The plurality of output modules are used to transmit each display sub-image signal to a display terminal based on the synchronization signal. Thus, this disclosure realizes the division of a display image signal and the display of multiple display sub-image signals in different display sub-areas of a display terminal using multiple synchronization signals. [Selection Diagram] Figure 2

Inventors

• ツァン ジーケン
• ユー ジアンフェン

Assignees

• エックスジー テック ピーティーイー リミテッド

Dates

Publication Date

20260508

Application Date

20250328

Priority Date

20241022

Claims (10)

1. An image processing apparatus comprising at least one input module, an image processing module, a synchronization module, and a plurality of output modules, Each of the aforementioned input modules is used to collect the image signal to be displayed. The image processing module is used to determine the number of output modules and, based on the number of output modules, to determine each sub-image signal that corresponds to the image signal to be displayed. The synchronization module is used to determine the synchronization signal corresponding to each of the sub-image signals to be displayed. An image processing apparatus in which the plurality of output modules are used to transmit each of the sub-image signals to be displayed to a display terminal based on the synchronization signal.
2. The image processing module is used to determine each sub-image signal to be displayed, corresponding to the image signal to be displayed, based on the number of output modules. The image processing module determines the number of input modules, The apparatus according to claim 1, wherein if the image processing module determines that the number of output modules does not match the number of input modules, the apparatus further comprises dividing the image signals to be displayed, collected by the plurality of input modules, based on the number of output modules, and obtaining each sub-image signal to be displayed that matches the number of output modules.
3. The image processing module is used to determine each sub-image signal to be displayed, corresponding to the image signal to be displayed, based on the number of output modules. The image processing module determines the number of input modules, The apparatus according to claim 1, wherein the image processing module determines that the number of output modules matches the number of input modules, and each of the image signals collected by each of the input modules that are to be displayed are designated as the sub-image signals that are to be displayed.
4. The plurality of output modules are used to transmit each of the sub-image signals to be displayed to a display terminal based on the synchronization signal. The apparatus according to claim 1, wherein the plurality of output modules transmit each of the sub-image signals to be displayed to a plurality of sequence controllers of the display terminal based on the synchronization signal, and the plurality of sequence controllers simultaneously drive the display terminal to display each of the sub-image signals to be displayed.
5. The synchronization module includes a plurality of clock generators based on a common clock supply source, and the number of the plurality of clock generators is the same as the number of the plurality of output modules. The synchronization module is used to determine the synchronization signal corresponding to each of the sub-image signals that are to be displayed. The apparatus according to any one of claims 1 to 4, wherein each clock generator in the synchronization module generates a corresponding synchronization signal for each sub-image signal to be displayed.
6. A display device comprising a display terminal and an image processing apparatus according to any one of claims 1 to 4, The display terminal includes multiple sequence controllers and screens, and the number of sequence controllers is the same as the number of output modules in the image processing device. Each of the sequence controllers in the display terminal acquires a sub-image signal to be displayed and drives the screen to display the sub-image signal.
7. The display device according to claim 6, wherein each sequence controller drives a display sub-region at a different position on the screen to display each of the sub-image signals that are to be displayed.
8. The steps include: collecting an image signal to be displayed using at least one input module; The image processing module determines the number of output modules, and based on the number of output modules, determines each sub-image signal to be displayed that corresponds to the image signal to be displayed. The synchronization module determines a synchronization signal corresponding to each of the sub-image signals that are to be displayed, An image processing method comprising the step of having a plurality of output modules transmit each of the sub-image signals to be displayed to a display terminal based on the synchronization signal.
9. A computer-readable storage medium storing a computer program for performing the method described in claim 8 above.
10. Processor and The processor includes a memory for storing executable instructions, The processor is an electronic device used to read the executable instructions from the memory and execute the instructions to realize the method according to claim 8.

Description

This disclosure relates to the field of display technology, and more particularly to image processing methods, apparatus, electronic devices, media, and display devices. To provide consumers with a more comfortable viewing experience, ultra-wide screens have emerged. For example, in smart cabin display systems, ultra-wide screens with a display width exceeding 4096 or 8192 pixels exist. However, due to factors such as chip cost, the display width supported by the chip driving the screen display is limited. When displaying content on an ultra-wide screen, problems such as image distortion, incomplete display, or performance degradation occur, limiting the expansion of ultra-wide screen width. Therefore, satisfying the demand for ultra-widescreen displays is a technical challenge that needs to be addressed urgently in order to popularize the application of ultra-widescreen displays. This is a diagram of the display system to which this disclosure applies.This is a schematic diagram of an image processing apparatus provided by one exemplary embodiment of the present disclosure.This is a schematic diagram of a display device provided by one exemplary embodiment of the present disclosure.This is a schematic flowchart of an image processing method provided by another exemplary embodiment of the present disclosure.A structural diagram of an electronic device provided by an exemplary embodiment of this disclosure. The following describes exemplary embodiments of this disclosure with reference to the drawings. Clearly, the embodiments described are only a selection of embodiments of this disclosure, not all embodiments, and it should be understood that this disclosure is not limited to the exemplary embodiments described herein. Please note that the relative arrangement of components and steps, numerical expressions, and numerical values described in these embodiments do not limit the scope of this disclosure unless specifically stated otherwise. The embodiments of this disclosure can be applied to electronic devices such as terminal devices, computer systems, and servers, and can operate with many other general-purpose or dedicated computing system environments or configurations. Examples of well-known terminal devices, computing systems, environments, and/or configurations suitable for use with electronic devices such as terminal devices, computer systems, and servers include, but are not limited to, personal computer systems, server computer systems, thin clients, thick clients, handheld or laptop devices, microprocessor-based systems, set-top boxes, programmable consumer electronics, network PCs, small computer systems, large computer systems, and distributed cloud computing technology environments including any of the above systems. Electronic devices such as terminals, computer systems, and servers can be described in the general context of executable instructions (e.g., program modules) of a computer system that are executed by that computer system. Typically, program modules include routines, programs, object programs, components, logic, and data structures, which perform specific tasks or realize specific abstract data types. Computer systems/servers are implemented in a distributed cloud computing environment, where tasks are executed by remote processing devices linked by communication networks. In a distributed cloud computing environment, program modules reside on storage media of local or remote computing systems, including storage devices. (Summary of this disclosure) In smart cabin display systems and other liquid crystal display systems, ultra-wide screens with display widths exceeding 4096 or 8192 pixels exist. However, the display width supported by the chip driving the screen display is limited; for example, it can only support display widths smaller than 4096 pixels. This results in problems such as image distortion, incomplete display, or performance degradation when displaying content on ultra-wide screens, limiting the expansion of ultra-wide screen widths. To be understood, the ultra-wide screen referred to in this disclosure is a screen whose display width exceeds the display width supported by a single sequence controller. The technical solution of this disclosure involves installing an image processing device in an SOC system, wherein the image processing module in the image processing device divides the image signal that is the target of display and needs to be displayed on an ultra-wide screen into a plurality of sub-image signals that are the target of display, and the plurality of output modules transmit the plurality of sub-image signals that are the target of display to the display terminal in synchronization based on a plurality of synchronization signals, thereby realizing the simultaneous display of the plurality of sub-image signals in different display sub-areas of the display terminal, and the plurality of display sub-areas form a completed display area, thereby realizing the