CN113467689A - Bendable electronic equipment and interface adaptation method thereof - Google Patents

Abstract

The application discloses electronic equipment, including treater, flexible display screen and angle sensor ware, treater and flexible display screen and angle sensor ware electric connection, flexible display screen includes first screen and an at least second screen. The angle sensor is arranged on the second screen. A processor: controlling the flexible display screen to display a display window, wherein the display window at least covers the first screen; acquiring a bending angle between the first screen and the second screen sensed by the angle sensor; and when the desktop adaptation mode of the electronic equipment is the self-response adaptation mode, adjusting the size of the display window according to the bending angle and adjusting the display content layout in the display window according to the size of the display window. The application also discloses an interface adaptation method. According to the method and the device, the size of the display window can be adjusted according to the bending angle, the display content layout in the display window can be adjusted according to the size of the display window, and the user experience is enhanced.

Description

Bendable electronic equipment and interface adaptation method thereof

Technical Field

The application relates to the field of graphical user interface control, in particular to a bendable electronic device based on a flexible display screen and an interface adaptation method thereof.

Background

The flexible display screen is used as a new generation display screen behind the liquid crystal display screen, is made of soft materials, can be deformed and bent, and brings novel use experience to users. However, the interface adaptation method applied to the non-bendable electronic device in the prior art cannot satisfy the bendable electronic device.

Disclosure of Invention

The embodiment of the application discloses bendable electronic equipment and an interface adaptation method thereof, and aims to solve the problems.

The embodiment of the application discloses electronic equipment of can buckling, including treater, flexible display screen and angle sensor ware, the treater with flexible display screen with angle sensor ware electric connection, flexible display screen includes first screen and sets up the second screen of first screen one side, the second screen can be relative around the bent axle first screen is crooked. The processor controls the flexible display screen to display a display window, and the display window at least covers the first screen; acquiring a bending angle between the display surface of the first screen and the display surface of the second screen sensed by the angle sensor; and when the desktop adaptation mode of the electronic equipment is the self-response adaptation mode, adjusting the size of the display window according to the bending angle and adjusting the layout of the display content in the display window according to the size of the display window.

The embodiment of the application discloses an interface adaptation method, is applied to a bendable electronic equipment, electronic equipment includes flexible display screen and angle sensor, flexible display screen includes first screen and sets up the second screen of first screen one side, the second screen can be relative around the bent axle first screen is crooked. The interface adaptation method comprises the steps of controlling the flexible display screen to display a display window, wherein the display window at least covers the first screen; acquiring a bending angle between the first screen and the second screen sensed by the angle sensor; and when the desktop adaptation mode of the electronic equipment is the self-response adaptation mode, adjusting the size of the display window according to the bending angle and adjusting the display content layout in the display window according to the size of the display window.

A computer-readable storage medium is disclosed in an embodiment of the present application, which stores a computer program that, when executed by a processor, implements the steps of the interface adaptation method.

According to the bendable electronic equipment and the interface adaptation method thereof, when the desktop adaptation mode of the electronic equipment is the self-response adaptation mode, the size of the display window can be adjusted according to the bending angle sensed by the angle sensor, and the display content layout in the display window can be adjusted according to the size of the display window. Therefore, the display window and the display content layout in the display window can be adapted according to different bending angles, and the user experience is enhanced.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in 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 application, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a block diagram of a bendable electronic device according to an embodiment of the present disclosure.

Fig. 2 is a schematic structural diagram of an electronic device in a first embodiment of the present application.

Fig. 3 is a schematic structural diagram of an electronic device in a second embodiment of the present application.

Fig. 4 is a schematic structural diagram of an electronic device in a third embodiment of the present application.

Fig. 5A to 8B are schematic diagrams illustrating a state where the electronic device is in a self-response adaptation mode according to an embodiment of the present application.

Fig. 9A to 12B are schematic diagrams illustrating a state where the electronic device is in a non-self-response adaptation mode according to an embodiment of the present application.

Fig. 13 is a flowchart of an interface adapting method applied to an electronic device in an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, 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 application.

The terms "comprises" and "comprising," and any variations thereof, in the description and claims of this invention and the above-described drawings are intended to cover non-exclusive inclusions. For example, a process, method, system, article, or apparatus that comprises a list of steps or elements is not limited to only those steps or elements listed, but may alternatively include other steps or elements not listed, or inherent to such process, method, article, or apparatus. The terms "first," "second," and "third," etc. in the description and claims of this application and the above-described drawings are used for distinguishing between different objects and not for describing a particular order.

Please refer to fig. 1, which is a block diagram of an electronic device 100 according to an embodiment of the present application. The electronic device 100 may be, but is not limited to, a mobile phone, a tablet computer, an electronic reader, a wearable electronic device, and the like, and the embodiment of the present application is not limited thereto. The electronic device 100 includes, but is not limited to, a processor 10, and a memory 20, a flexible display 30 and an angle sensor 40 electrically connected to the processor 10, respectively. It should be understood by those skilled in the art that fig. 1 is only an example of the electronic device 100 and does not constitute a limitation to the electronic device 100, and the electronic device 100 may include more or less components than those shown in fig. 1, or combine some components, or different components, for example, the electronic device 100 may further include an input/output device, a network access device, a bus, etc.

The Processor 10 may be a Central Processing Unit (CPU), other general purpose Processor, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), an off-the-shelf Programmable Gate Array (FPGA) or other Programmable logic device, discrete Gate or transistor logic device, discrete hardware component, etc. The general purpose processor may be a microprocessor or the processor may be any conventional processor or the like. The processor is a control center of the electronic device 100, and various interfaces and lines are used to connect various parts of the whole electronic device 100.

The memory 20 may be used for storing the computer programs and/or modules, and the processor 10 implements various functions of the electronic device 100 by running or executing the computer programs and/or modules stored in the memory 20 and calling data stored in the memory 20. The memory 20 may mainly include a program storage area and a data storage area, wherein the program storage area may store an operating system, application programs (such as a sound playing function, an image playing function, etc.) required by a plurality of functions, and the like; the storage data area may store data (such as audio data, a phonebook, etc.) created according to the use of the electronic device, and the like. In addition, the memory 20 may include a high speed random access memory, and may also include a non-volatile memory, such as a hard disk, a memory, a plug-in hard disk, a Smart Media Card (SMC), a Secure Digital (SD) Card, a Flash memory Card (Flash Card), a plurality of magnetic disk storage devices, a Flash memory device, or other volatile solid state storage devices.

Referring to fig. 2, fig. 2 is a schematic structural diagram of an electronic device 100 according to a first embodiment of the present application. The flexible display screen 30 includes a first screen 31 and a second screen 33. The second screen 33 is located at one side of the first screen 31. The second screen 33 may be bent around a bending axis with respect to the first screen 31. In an embodiment, the second screen 33 is formed by bending and extending from one side of the first screen 31, that is, the first screen 31 and the second screen 33 are formed by bending a large screen along a corresponding bending line.

Referring to fig. 3, fig. 3 is a schematic structural diagram of an electronic device 100a according to a second embodiment of the present application. In this embodiment, the first screen 31 and the second screen 33 are connected on one side, that is, the first screen 31 and the second screen 33 are connected by two separate screens.

At least one angle sensor 40 is correspondingly arranged on each second screen 33. The angle sensor 40 senses a bending angle of the display surface of the first screen 31 and the display surface of the second screen 33.

It can be understood that, when the second screen 33 and the first screen 31 are completely unfolded, that is, the display surface of the second screen 33 and the display surface of the first screen 31 are located at the same horizontal plane, the bending angle sensed by the angle sensor 40 is 0 degree. When the second screen 33 is bent to a position where the display surface of the second screen 33 at the end away from the first screen 31 is parallel to the display surface of the first screen 31, the bending angle sensed by the angle sensor 40 is 180 degrees. When the second screen 33 is bent with respect to the first screen 31, the bending angle sensed by the angle sensor 40 is varied between 0 and 180 degrees.

Referring to fig. 5A and 5B, the processor 10 controls the flexible display 30 to display a display window D1, wherein the display window D1 covers at least the first screen 31. The processor 10 acquires the bending angle between the display surface of the first screen 31 and the display surface of the second screen 33 sensed by the angle sensor 40. When the angle sensor 40 senses the bending angle change and the desktop adaptation mode of the electronic device 100 is the self-response adaptation mode, the processor 10 adjusts the size of the display window D1 according to the bending angle sensed by the angle sensor 40 and adjusts the display content layout in the display window D1 according to the size of the display window D1.

Specifically, the display window D1 refers to an area of the flexible display 30 for displaying content. The display window D1 may cover the whole screen of the flexible display 30, or may cover a part of the screen of the flexible display 30, but covers at least the whole screen of the first screen 31. The display content includes, but is not limited to, application icons located on a desktop, interface content of an application program, and the like. The application icon may be various application icons, such as a communication application icon, and may include, but is not limited to, a call application icon, a short message application icon, and an instant message application icon, which may include, but is not limited to: a QQ application icon, a WeChat application icon, a microblog application icon, and the like. The interface content of the application program refers to content displayed after the application icons are clicked to enter the corresponding application program.

For convenience of description, a direction parallel to the axis of the second screen 33 is defined as a width direction W, and a direction perpendicular to the width direction W and parallel to the display surface of the first screen 31 is defined as a length direction L. In the present embodiment, the display window D1 completely covers the corresponding screen portion of the flexible display screen 30 in the width direction W regardless of whether the display window D1 covers the entire screen of the flexible display screen 30 in the length direction L. Of course, in other embodiments, the display window D1 may also partially cover the flexible touch display screen 30 in the width direction W.

When the desktop adaptation mode of the bendable electronic device 100 is the self-response adaptation mode, the bendable electronic device can adjust the size of the display window D1 according to the bending angle sensed by the angle sensor 40 and adjust the display content layout in the display window D1 according to the size of the display window D1. Therefore, the electronic device 100 can adapt the display content layout in the display window D1 and the display window D1 according to different bending angles, thereby enhancing the user experience.

Further, the memory 20 stores a corresponding relationship between a preset bending angle and the size of the display window D1, and the processor 10 adjusts the size of the display window D1 according to the corresponding relationship and the bending angle sensed by the angle sensor 40. It is understood that the correspondence may be linear, non-linear, stepped, etc., and is not limited thereto.

Therefore, each bending angle or each bending angle interval can correspond to one display window D1 with a corresponding size, so that the size of the display window D1 can be dynamically adjusted according to the change of the bending angle, and better user experience is achieved.

Specifically, when the angle sensor 40 senses that the bending angle between the display surface of the second screen 33 and the display surface of the first screen 31 is greater than a first threshold value, such as at 180 degrees, that is, the flexible display screen 30 is in the fully bent state, the processor 10 adjusts the size of the display window D1 to be consistent with the size of the display area of the first screen 31. When the angle sensor 40 senses that the bending angle between the display surface of the second screen 33 and the display surface of the first screen 31 is smaller than a second threshold value, for example, at 0 degree, that is, the flexible display screen 30 is in the fully unfolded state, the processor 10 adjusts the size of the display window D1 to be consistent with the sum of the sizes of the display areas of the first screen 31 and the second screen 33. Specifically, when the angle sensor 40 senses that the bending angle between the display surface of the second screen 33 and the display surface of the first screen 31 is close to 0 degree from 180 degrees, that is, the flexible display screen 30 is in the unfolding transition state, the processor 10 gradually adjusts the size of the display window D1 from the display area equivalent to the first screen 31 to be consistent with the sum of the sizes of the display areas of the first screen 31 and the second screen 33.

Referring to fig. 4, fig. 4 is a schematic structural diagram of an electronic device 100b according to a third embodiment of the present application. Wherein the flexible display screen 30 includes a first screen 31, a second screen 33, and a third screen 35. The second screen 33 is located between the first screen 31 and the third screen 35, and the second screen 33 corresponds to a bending region of the flexible display screen 30 in a bending state, that is, the first screen 31, the second screen 33, and the third screen 35 are formed by bending a large screen along corresponding bending lines.

The angle sensor 40 senses a bending angle between the display surface of the first screen 31 and the display surface of the third screen 35. The bending angle is a bending angle between the display surface of the first screen 31 and the display surface of the third screen 35. When the angle sensor 40 senses that the bending angle between the display surface of the third screen 35 and the display surface of the first screen 31 is greater than a first threshold, such as 180 degrees, the processor 10 adjusts the size of the display window D1 to be consistent with the size of the display area of the first screen 31. When the angle sensor 40 senses that the bending angle between the display surface of the third screen 35 and the display surface of the first screen 31 is smaller than a second threshold, for example, at 0 degree, the processor 10 adjusts the size of the display window D1 to be consistent with the sum of the sizes of the display areas of the first screen 31, the second screen 33, and the third screen 35. When the angle sensor 40 senses that the bending angle between the display surface of the third screen 35 and the display surface of the first screen 31 is close to 0 degree from 180 degrees, the processor 10 gradually adjusts the size of the display window D1 from the display area equivalent to the first screen 31 to be consistent with the sum of the sizes of the display areas of the first screen 31, the second screen 33 and the third screen 35.

Further, when the processor 10 senses the bending angle change by the angle sensor 40, the electronic device 100 also selects a currently applicable desktop adaptation mode. Wherein the desktop adaptation mode is one of an auto-response adaptation mode and a non-auto-response adaptation mode. The self-response adaptation mode refers to a layout in which display content located within the display window D1 may be automatically adjusted according to the size of the display window D1. The non-response adaptation mode refers to a state in which the layout of the display content located within the display window D1 cannot be automatically adjusted according to the size of the display window D1.

Specifically, when the electronic device 100 is currently in the desktop state, the processor 10 determines by default that the corresponding desktop adaptation mode is the self-response adaptation mode. That is, when the electronic device 100 is currently in the desktop state, the processor 10 controls the display window D1 to enter the self-response adaptation mode by default, controls the display content, such as a plurality of application icons, in the display window D1, and adjusts the layout in the display window D1 according to the size of the display window D1.

Specifically, the processor 10 determines that the desktop adaptation mode is the self-response adaptation mode when the adaptation attribute of all the applications currently running in the foreground on the electronic device 100 and located in the display window D1 are self-response. When the processor 10 controls the display window D1 to enter the self-response adaptation mode and the display window D1 displays a plurality of display contents, such as a plurality of application icons, the display window D1 is controlled to perform the icon self-response adaptation of the plurality of applications in the display window D1 according to the change of the size of the display window D1, wherein the self-response adaptation comprises at least one of icon spacing and icon size. The "icon spacing" refers to a spacing between a plurality of icons that are displayed in a row in the display window D1. The "icon size" refers to the size of each icon within the display window D1.

When the processor 10 controls the display window D1 to enter the self-response adaptation mode and the display window D1 displays a display interface of an application program, the display interface is controlled to perform self-response adaptation, where the self-response adaptation includes at least one of line spacing, column spacing, word size, picture size, layout change, navigation of content at the first level, navigation of content at the second level, and newly-added related filling content adaptation.

The "line pitch" refers to a line pitch between a plurality of display contents that are displayed in a row in the display window D1. The "column pitch" refers to a column pitch between a plurality of display contents that are displayed in a row in the display window D1. The "word space" refers to a word space between a plurality of words in the display window D1. The "word size" refers to the size of the words in the display window D1. The "picture size" refers to the size of each picture displayed in the display window D1. The "navigating the content of the first hierarchy level" refers to pre-stored content classified as the first hierarchy level. The "navigating the content of the second hierarchy" refers to pre-stored content categorized as the second hierarchy. For example, the pictures of the picture application program are divided into a plurality of levels, wherein the first level comprises life, travel and the like, and the second level comprises a first picture taking place, a second picture taking place and the like. The "navigating the content of the second hierarchy" refers to displaying the content of the first hierarchy, e.g., life, travel, etc. The "navigating the content of the second hierarchy" refers to displaying the content of the second hierarchy, for example, specifically displaying a specific picture of the second hierarchy of "life", for example, a life picture of the first photographing place, a life picture of the second photographing place, and the like. The "newly adding related filler content" means that new display content is added in a predetermined order in the display window D1 for display according to the size of the display window D1. The phrase "being added in a predetermined order to be displayed in the display window D1" means that a plurality of display contents are sequentially added in a line-by-line or column-by-column filling manner. For example, in one embodiment, when 16 pictures including four rows and four columns are currently displayed in the display window D1, the order of the four pictures in the first row is 1, 2, 3, and 4, the order of the four pictures in the second row is 5, 6, 7, and 8, and so on. When the display window D1 is enlarged to display five or four rows of pictures, the 16 pictures fill the first row, the second row, and the third row in sequence, and new display contents are added to the fourth row from left to right in sequence for display. Of course, the above-mentioned filling method is only a preferable method, and other filling methods, such as inserting a new display content between every two adjacent original display contents, or moving the original display content backward and moving the new display content forward, can be applied to this embodiment.

Specifically, the processor 10 determines that the desktop adaptation mode is the non-self-response adaptation mode when the adaptation attribute of at least one application program currently running in the foreground on the electronic device 10 and located in the display window D1 is non-self-response.

Referring to fig. 5A to 8B, fig. 5A to 8B are schematic diagrams illustrating a state that the electronic device 100 is in a self-response adaptation mode according to an embodiment of the present application.

Specifically, please refer to fig. 5A to 5B first, and fig. 5A to 5B are schematic diagrams illustrating a state in which a folding angle between the display surface of the first screen 31 and the display surface of the third screen 35 is 180 degrees according to an embodiment of the present application. In this state, the display window D1 occupies the entire screen of the first screen 31. The window boundary line E1 of the display window D1 is just an edge line of the first screen 31 connecting the second screen 33. The display window D1 displays the date and time, a plurality of application icons, and the like.

Specifically, please refer to fig. 6A to 6B, and fig. 6A to 6B are schematic diagrams illustrating a state in which a folding angle between the display surface of the first screen 31 and the display surface of the third screen 35 is greater than 90 degrees according to an embodiment of the present application. Unlike the state in which the folding angle is 180, the display window D1 occupies the entire screen of the first screen 31 and a partial screen of the second screen 33. The window boundary line E1 of the display window D1 is shifted to the left from the first screen 31 in a direction approaching the second screen 33. The time of day within the display window D1 is shifted left in a direction approaching the second screen 33 with the movement of the region boundary surface E1. The column spacing between the plurality of application icons located within the display window D1 increases as the window boundary line E1 moves to the left.

Specifically, please refer to fig. 7A to 7B, and fig. 7A to 7B are schematic views illustrating a state in which a folding angle between the display surface of the first screen 31 and the display surface of the third screen 35 is smaller than 90 degrees according to an embodiment of the present application. Unlike the state where the folding angle is greater than 90, the display window D1 occupies the entire screens of the first and second screens 31 and 33 and a partial screen of the third screen 35. The window boundary line E1 of the display window D1 moves continuously leftward from within the second screen 33 to within the third screen 35. The time of day located within the display window D1 continues to move left as the region boundary surface E1 moves left. The column spacing between application icons located within the display window D1 continues to increase as the window boundary line E1 moves to the left.

Specifically, please refer to fig. 8A to 8B, and fig. 8A to 8B are schematic diagrams illustrating a state in which a folding angle between the display surface of the first screen 31 and the display surface of the third screen 35 is 0 degree according to an embodiment of the present application. Unlike the state in which the folding angle is less than 90, the display window D1 occupies the entire screens of the first screen 31, the second screen 33, and the third screen 35. The window boundary line E1 of the display window D1 moves from inside the third screen 35 to the left to the edge of the third screen. The date and time within the display window D1 moves to the upper left of the third screen 35 as the window boundary line E1 moves to the left. The column spacing between application icons located within the display window D1 continues to increase as the window boundary line E1 moves to the left.

Therefore, the bendable electronic device 100 can automatically adapt the display content layout in the display window D1 and the display window D1 according to different bending angles, and enhance the user experience.

Referring to fig. 9A to 12B, fig. 9A to 12B are schematic diagrams illustrating a state that the electronic device 100 is in a non-self-response adaptation mode according to an embodiment of the present application.

The processor 10 controls the flexible display 30 to display a graphical user interface G1 (shown in fig. 11B). The graphical user interface G1 includes a bottom wallpaper G11 and an upper interface G12. When the display window D1 is controlled to enter a non-self-response adaptation mode and the display window D1 is increased from small to large, the processor 10 controls the bottom wallpaper G11 to perform self-response adaptation along with the change of the size of the display window D1, and controls the content on the upper interface G12 to be kept unchanged. The processor 10 controls the upper interface G12 to adjust the display content layout thereon to fit the display window D1 when the size of the display window D1 reaches a maximum.

Further, the display window D1 includes a first screen display region D11 and a non-first screen display region D12. Wherein the first screen display region D11 refers to a region of the display window D1 corresponding to the first screen 31, and the non-first screen display region D12 refers to a region of the display window D1 corresponding to the second screen 33 and/or the third screen 35. The first screen display region D11 and the non-first screen display region D12 are demarcated by a hidden region boundary B1. When the processor 10 controls the display window D1 to perform the non-self-response type adaptation, the processor controls the bottom wallpaper G11 in the first screen display area D11 to be displayed with the first display attribute, and controls the bottom wallpaper G11 in the non-first screen display area D12 to be displayed with the second display attribute.

Further, in the process of controlling the size of the display window D1 to increase from small to large, the processor 10 controls the display attribute of the underlying wallpaper G11 in the non-first-screen display area D12 to gradually change from the second display attribute to the first display attribute. The processor 10 controls the underlying wallpaper G11 within the non-first screen display area D12 to be displayed with the first display attribute when the processor 10 controls the size of the display window D1 to increase to a maximum value. Wherein the first display attribute comprises high definition and high display brightness, and the second display attribute comprises low definition and low display brightness. That is, in the process of controlling the size of the display window D1 to increase from small to small, the processor 10 controls the underlying wallpaper G11 in the non-first-screen display area D12 to change from blurred to clear and dark to bright.

Specifically, please refer to fig. 9A to 9B first, and fig. 9A to 9B are schematic diagrams illustrating a state in which a folding angle between the display surface of the first screen 31 and the display surface of the third screen 35 is 180 degrees according to an embodiment of the present application. In this state, the display window D1 occupies the entire screen of the first screen 31. The window boundary line E1 of the display window D1 is just an edge line of the first screen 31 connecting the second screen 33. Obviously, the display window D1 includes only the first screen display region D11. The display window D1 displays the date and time, a plurality of application icons, and the like.

Specifically, please refer to fig. 10A to 10B, and fig. 10A to 10B are schematic diagrams illustrating a state in which a folding angle between the display surface of the first screen 31 and the display surface of the third screen 35 is greater than 90 degrees according to an embodiment of the present application. Unlike the state in which the folding angle is 180, the display window D1 occupies the entire screen of the first screen 31 and a partial screen of the second screen 33. The window boundary line E1 of the display window D1 is shifted to the left from the first screen 31 in a direction approaching the second screen 33. The display window D1 includes a first screen display region D11 and a non-first screen display region D12. The time of day and the column spacing between the plurality of application icons within the first screen display area D11 remain unchanged as the window boundary line E1 moves to the left. The processor 10 controls the bottom wallpaper G11 within the first screen display region D11 to be displayed with the first display attribute, and controls the display attribute of the bottom wallpaper G11 within the non-first screen display region D12 to be gradually changed from the second display attribute to the first display attribute as the window boundary line E1 of the display window D1 moves to the left.

Specifically, please refer to fig. 11A to 11B, and fig. 11A to 11B are schematic views illustrating a state in which a folding angle between the display surface of the first screen 31 and the display surface of the third screen 35 is smaller than 90 degrees according to an embodiment of the present application. Unlike the state where the folding angle is greater than 90, the display window D1 occupies the entire screens of the first and second screens 31 and 33 and a partial screen of the third screen 35. The window boundary line E1 of the display window D1 moves continuously leftward from within the second screen 33 to within the third screen 35. The display window D1 includes a first screen display region D11 and a non-first screen display region D12. The time of day and the column spacing between the plurality of application icons within the first screen display area D11 remain unchanged as the window boundary line E1 moves to the left. The processor 10 controls the underlying wallpaper G11 within the first screen display area D11 to be displayed with a first display attribute. The processor 10 controls the display attribute of the underlying wallpaper G11 within the non-first screen display region D12 to be further gradually changed from the second display attribute to the first display attribute as the window boundary line E1 of the display window D1 moves to the left.

Specifically, please refer to fig. 12A to 12B, and fig. 12A to 12B are schematic diagrams illustrating a state in which a folding angle between the display surface of the first screen 31 and the display surface of the third screen 35 is 0 degree according to an embodiment of the present application. Unlike the state in which the folding angle is less than 90, the display window D1 occupies the entire screens of the first screen 31, the second screen 33, and the third screen 35. The window boundary line E1 of the display window D1 moves from inside the third screen 35 to the left to the edge of the third screen. The display window D1 includes a first screen display region D11 and a non-first screen display region D12. The time of day and the plurality of application icons located within the first screen display area D11 are rearranged and displayed on the entire screen of the display window D1. The processor 10 controls the bottom wallpaper G11 within the first screen display region D11 and the bottom wallpaper G11 within the non-first screen display region D12 to be displayed with the first display attribute.

Please refer to fig. 13, which is a flowchart illustrating an interface adapting method according to an embodiment of the present application. The interface adaptation method is applied to the electronic device 100, and the execution sequence is not limited to the sequence shown in fig. 13. The method comprises the following steps:

step 1301, controlling the flexible display screen 30 to display a display window D1, wherein the display window D1 at least covers the first screen 31.

Step 1303, obtaining a bending angle between the display surface of the first screen 31 and the display surface of the second screen 33 sensed by the angle sensor 40.

Step 1305, when the interface adaptation mode is the self-response adaptation mode, adjusting the size of the display window D1 according to the bending angle sensed by the angle sensor 40 and adjusting the display content layout in the display window D1 according to the size of the display window D1.

Specifically, the "adjusting the size of the display window D1 according to the bending angle sensed by the angle sensor 40" includes:

calling a corresponding relation between a pre-stored preset bending angle and the size of the display window D1; and

adjusting the size of the display window D1 according to the corresponding relationship and the bending angle sensed by the angle sensor 40.

Specifically, the "adjusting the size of the display window according to the bending angle sensed by the angle sensor 40" includes:

when the angle sensor 40 senses that the bending angle between the display surface of the second screen 33 and the display surface of the first screen 31 is greater than a first threshold, such as 180 degrees, adjusting the size of the display window D1 to be consistent with the size of the display area of the first screen 31; or

When the angle sensor 40 senses that the bending angle between the display surface of the second screen 33 and the display surface of the first screen 31 is smaller than a second threshold value, such as at 0 degree, adjusting the size of the display window D1 to be consistent with the sum of the sizes of the display areas of the first screen 31 and the second screen 33; or

When the angle sensor 40 senses that the bending angle between the display surface of the second screen 33 and the display surface of the first screen 31 is close to 0 degree from 180 degrees, the size of the display window D1 is gradually adjusted from the display area equivalent to the first screen 31 to be consistent with the sum of the sizes of the display areas of the first screen 31 and the second screen 33.

Further, the flexible display screen 30 further includes a third screen 35, the at least one second screen 33 is connected between the third screen 35 and the first screen 31, the angle sensor 40 senses a bending angle between the display surface of the first screen 31 and the display surface of the third screen 35, and the "adjusting the size of the display window D1 according to the bending angle sensed by the angle sensor 40" specifically includes:

when the angle sensor 40 senses that the bending angle between the display surface of the third screen 35 and the display surface of the first screen 31 is greater than a first threshold, such as 180 degrees, adjusting the size of the display window D1 to be consistent with the size of the display area of the first screen 31; or

When the angle sensor 40 senses that the bending angle between the display surface of the third screen 35 and the display surface of the first screen 31 is smaller than a second threshold value, such as at 0 degree, adjusting the size of the display window D1 to be consistent with the sum of the sizes of the display areas of the first screen 31, the second screen 33 and the third screen 35; and

when the angle sensor 40 senses that the bending angle between the display surface of the third screen 35 and the display surface of the first screen 31 is close to 0 degree from 180 degrees, the size of the display window D1 is gradually adjusted from the display area equivalent to the first screen 31 to be consistent with the sum of the sizes of the display areas of the first screen 31, the second screen 33 and the third screen 35.

Further, the interface adaptation method further comprises the following steps:

when the angle sensor 40 is determined to sense the bending angle change, a currently applicable desktop adaptation mode is selected, wherein the desktop adaptation mode is one of a self-response adaptation mode and a non-self-response adaptation mode.

Further, the interface adaptation method further comprises the following steps:

when determining that the electronic device 100 is currently in a desktop state or the adaptation attributes of all applications currently running in the foreground on the electronic device 100 and located in the display window D1 are self-responses, determining that the corresponding desktop adaptation mode is a self-response adaptation mode; and

when the adaptation attribute of at least one application program currently running in the foreground on the electronic device 10 and located in the display window D1 is non-self-response, determining that the corresponding desktop adaptation mode is the non-self-response adaptation mode.

Further, the interface adaptation method further comprises the following steps:

when the display window D1 is controlled to enter a self-response adaptation mode, the display window D1 is controlled to perform self-response adaptation on the display content in the display window D1 according to the change of the size of the display window D1, wherein the self-response adaptation comprises at least one of line spacing, column spacing, word size, icon spacing, icon size, picture size, layout change, navigation of content of a first level, navigation of content of a second level and newly added related filling content.

The flexible display 30 displays a graphical user interface G1, the graphical user interface G1 includes a bottom wallpaper G11 and an upper interface G12, the interface adaptation method further includes the steps of:

controlling the display window D1 to enter a non-self-response adaptation mode, and when the size of the display window D1 changes, controlling the bottom wallpaper G11 to perform self-response adaptation along with the change of the size of the display window D1, and controlling the content on the upper interface G12 to be kept unchanged;

when the size of the display window D1 coincides with the size of the entire display area of the flexible display screen 30, the upper interface G12 is controlled to adjust the layout of each interface element thereon.

The display window D1 includes a first screen display region D11 and a non-first screen display region D12. A hidden area boundary is provided between the first screen display area D11 and the non-first screen display area D12. Further, the interface adaptation method comprises the following steps:

when the display window D1 is controlled to perform non-self-response type adaptation, the bottom wallpaper G11 in the first screen display area D11 is controlled to be displayed with a first display attribute, and the bottom wallpaper G11 in the non-first screen display area D12 is controlled to be displayed with a second display attribute.

Further, the interface adaptation method further comprises the following steps:

when the size of the display window D1 is increased from small to large, the display attribute of the bottom wallpaper G11 in the non-first-screen display area D12 is controlled to be gradually changed from the second display attribute to the first display attribute; controlling the bottom wallpaper G11 within the non-first screen display area D12 to be displayed with the first display attribute when the size of the display window D1 is consistent with the size of the entire display area of the flexible display screen 30, wherein the first display attribute comprises high definition and high display brightness, and the second display attribute comprises low definition and low display brightness. The gradual transition is smaller as the difference between the second display attribute and the first display attribute of the display window D1 gradually increases.

In some embodiments, the present application further provides a computer readable storage medium, which stores program instructions for the processor 10 to execute any of the method steps of fig. 13 after invoking execution, so as to control the flexible display 30 to display a display window D1, wherein the display window D1 at least covers the first screen 31; acquiring a bending angle between the first screen 31 and the second screen 33 sensed by the angle sensor 40; and when the desktop adaptation mode of the electronic device 100 is the self-response adaptation mode, adjusting the size of the display window D1 according to the bending angle sensed by the angle sensor 40 and adjusting the display content layout in the display window D1 according to the size of the display window D1. In some embodiments, the computer storage medium is the memory 20, and may be any storage device capable of storing information, such as a memory card, a solid-state memory, a micro hard disk, an optical disk, and the like.

The application discloses electronic equipment's flexible display screen has the state of expandes completely, folding transition state and fold completely state, and the angle of buckling under each state is different. The processor adjusts the size of the display window according to the bending angle sensed by the angle sensor and adjusts the display content layout in the display window according to the size of the display window, so that better user experience is achieved.

It should be noted that, for simplicity of description, the above-mentioned embodiments of the method are described as a series of acts or combinations, but those skilled in the art should understand that the present application is not limited by the order of acts described, as some steps may be performed in other orders or simultaneously according to the present application. Further, those skilled in the art should also appreciate that the embodiments described in the specification are preferred embodiments and that the acts and modules referred to are not necessarily required in this application. In the above embodiments, the descriptions of the respective embodiments have respective emphasis, and for parts that are not described in detail in a certain embodiment, reference may be made to related descriptions of other embodiments. The steps in the method of the embodiment of the application can be sequentially adjusted, combined and deleted according to actual needs. The foregoing detailed description of the embodiments of the present application has been presented to illustrate the principles and embodiments of the present application, and the above description of the embodiments is only provided to help understand the method and the core concept of the present application; meanwhile, for a person skilled in the art, according to the idea of the present application, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present application.

Claims (16)

1. The utility model provides an electronic equipment that can buckle, includes treater, flexible display screen and angle sensor ware, the treater with flexible display screen with angle sensor ware electric connection, flexible display screen includes first screen and sets up the second screen of first screen one side, the second screen can be relative around the bent axle first screen is crooked, its characterized in that, the treater:

controlling the flexible display screen to display a display window, wherein the display window at least covers the first screen;

acquiring a bending angle between the display surface of the first screen and the display surface of the second screen sensed by the angle sensor; and

when the desktop adaptation mode of the electronic equipment is a non-self-response adaptation mode, adjusting the size of the display window according to the bending angle and maintaining the layout of the display content in the display window unchanged in the size adjustment process of the display window.

2. The electronic device of claim 1, further comprising a memory electrically connected to the processor, wherein the memory stores a corresponding relationship between a preset bending angle and a size of a display window, and the processor adjusts the size of the display window according to the corresponding relationship and the bending angle sensed by the angle sensor.

3. The electronic device according to claim 2, wherein when the angle sensor senses that a bending angle between the display surface of the second screen and the display surface of the first screen is 180 degrees, the size of the display window is consistent with the size of the display area of the first screen; or

When the angle sensor senses that the bending angle between the display surface of the second screen and the display surface of the first screen is 0 degree, the size of the display window is consistent with the sum of the sizes of the display areas of the first screen and the second screen; or

When the angle sensor senses that the bending angle between the display surface of the second screen and the display surface of the first screen approaches 0 degree from 180 degrees, the size of the display window is gradually adjusted to be consistent with the sum of the sizes of the display areas of the first screen and the second screen from a display area equal to the size of the first screen.

4. The electronic device of claim 2, wherein the flexible display screen further comprises a third screen, the at least one second screen is connected between the third screen and the first screen, the angle sensor senses a bending angle between the first screen and the third screen,

when the angle sensor senses that the bending angle between the display surface of the third screen and the display surface of the first screen is 180 degrees, the size of the display window is consistent with the size of the display area of the first screen; or

When the angle sensor senses that the bending angle between the display surface of the third screen and the display surface of the first screen is 0 degree, the size of the display window is consistent with the sum of the sizes of the display areas of the first screen, the second screen and the third screen; or

When the angle sensor senses that the bending angle between the display surface of the third screen and the display surface of the first screen approaches 0 degree from 180 degrees, the size of the display window is gradually adjusted to be consistent with the sum of the sizes of the display areas of the first screen, the second screen and the third screen from a display area equal to the size of the first screen.

5. The electronic device of claim 1, wherein the processor determines that the corresponding desktop adaptation mode is a non-self-responding adaptation mode when it is determined that an adaptation attribute of an application currently running in the foreground on the electronic device and located within the display window is non-self-responding.

6. The electronic device of claim 1, wherein the processor controls the flexible display to display a graphical user interface, the graphical user interface comprising an underlying wallpaper and an overlying interface, the processor controls the underlying wallpaper to increase following an increase of the display window when in a non-self-response adaptation mode and the display window increases in size from small to small, controls content on the overlying interface to remain unchanged, and controls the overlying interface to adjust a layout of content thereon when the size of the display window coincides with a size of an entire display area of the flexible display.

7. The electronic device of claim 6, wherein the display window includes a first screen display area and a non-first screen display area with a hidden area boundary therebetween, the processor controls an underlying wallpaper within the first screen display area to be displayed with a first display attribute and controls an underlying wallpaper within the non-first screen display area to be displayed with a second display attribute.

8. The electronic device of claim 7, wherein the processor controls the display properties of the underlying wallpaper within the non-first screen display area to gradually transition from the second display properties to the first display properties as the display window increases from small to large, and controls the underlying wallpaper within the non-first screen display area to be displayed with the first display properties as the size of the display window coincides with the size of the entire display area of the flexible display screen, wherein the first display properties include high definition and high display brightness, and the second display properties include low definition and low display brightness.

9. An interface adaptation method is applied to a bendable electronic device, the electronic device comprises a flexible display screen and an angle sensor, the flexible display screen comprises a first screen and a second screen arranged on one side of the first screen, and the second screen can be bent around a bending shaft relative to the first screen; the interface adaptation method is characterized by comprising the following steps:

controlling the flexible display screen to display a display window, wherein the display window at least covers the first screen;

acquiring a bending angle between the first screen and the second screen sensed by the angle sensor; and

when the desktop adaptation mode of the electronic equipment is a non-self-response adaptation mode, adjusting the size of the display window according to the bending angle and maintaining the display content layout in the display window unchanged in the size adjustment process of the display window.

10. The interface adaptation method of claim 9, wherein the interface adaptation method comprises:

calling a corresponding relation between a pre-stored preset bending angle and the size of a display window; and

and adjusting the size of the display window according to the corresponding relation and the bending angle sensed by the angle sensor.

11. The interface adaptation method of claim 10, wherein the interface adaptation method comprises:

when the angle sensor senses that the bending angle between the display surface of the second screen and the display surface of the first screen is 180 degrees, the size of the display window is consistent with the size of the display area of the first screen; or

When the angle sensor senses that the bending angle between the display surface of the second screen and the display surface of the first screen is 0 degree, the size of the display window is consistent with the sum of the sizes of the display areas of the first screen and the second screen; or

When the angle sensor senses that the bending angle between the display surface of the second screen and the display surface of the first screen approaches 0 degree from 180 degrees, the size of the display window is gradually adjusted to be consistent with the sum of the sizes of the display areas of the first screen and the second screen from a display area equal to the size of the first screen.

12. The interface adaptation method of claim 10, wherein the flexible display screen further comprises a third screen, the at least one second screen is connected between the third screen and the first screen, the angle sensor senses a bending angle between the first screen and the third screen, the interface adaptation method comprising:

when the angle sensor senses that the bending angle between the display surface of the third screen and the display surface of the first screen is 180 degrees, the size of the display window is consistent with the size of the display area of the first screen; or

When the angle sensor senses that the bending angle between the display surface of the third screen and the display surface of the first screen is 0 degree, the size of the display window is consistent with the sum of the sizes of the display areas of the first screen, the second screen and the third screen; and

when the angle sensor senses that the bending angle between the display surface of the third screen and the display surface of the first screen approaches 0 degree from 180 degrees, the size of the display window is gradually adjusted to be consistent with the sum of the sizes of the display areas of the first screen, the second screen and the third screen from a display area equal to the size of the first screen.

13. The interface adaptation method of claim 9, further comprising: when the adaptation attribute of an application program which is currently running in the foreground on the electronic equipment and is positioned in the display window is determined to be non-self-response, determining that the corresponding desktop adaptation mode is the non-self-response adaptation mode.

14. The interface adaptation method of claim 9, wherein the flexible display screen displays a graphical user interface, the graphical user interface including a bottom wallpaper and an upper interface, the interface adaptation method further comprising:

entering a non-self-response adaptation mode in the display window, and controlling the bottom wallpaper to increase along with the increase of the display window when the size of the display window is increased from small to small, and controlling the content on the upper interface to keep unchanged;

and when the size of the display window is consistent with the size of the whole display area of the flexible display screen, controlling the upper-layer interface to adjust the content layout on the upper-layer interface.

15. The interface adaptation method of claim 14, wherein the display window includes a first screen display area and a non-first screen display area with a hidden area boundary therebetween, the interface adaptation method comprising:

and controlling the bottom wallpaper in the first screen display area to be displayed with a first display attribute, and controlling the bottom wallpaper in the non-first screen display area to be displayed with a second display attribute.

16. The interface adaptation method of claim 15, wherein the interface adaptation method comprises:

when the size of the display window is increased from small to large, controlling the display attribute of the bottom wallpaper in the non-first screen display area to be gradually changed from the second display attribute to the first display attribute;

when the size of the display window is consistent with the size of the whole display area of the flexible display screen, controlling the bottom wallpaper in the non-first screen display area to be displayed with the first display attribute, wherein the first display attribute comprises high definition and high display brightness, and the second display attribute comprises low definition and low display brightness.

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