CN106095188B - Control method and electronic equipment - Google Patents

Abstract

The application provides a control method and electronic equipment, which are used for solving the technical problem that the false triggering rate of a flexible screen of the electronic equipment is high. The method comprises the following steps: determining a current first deformation form of the flexible display screen; determining a screen interference part of the flexible display screen in the first deformation state based on the first deformation state; generating an adjustment instruction based on the screen disturbance portion; and responding to the adjusting instruction so as to reduce the interference of the screen interference part when the flexible display screen is in the first deformation state.

Description

Control method and electronic equipment

Technical Field

The present invention relates to the field of computer technologies, and in particular, to a control method and an electronic device.

Background

With rapid development of technology and increasingly intense market competition, the performance and appearance of electronic devices have been greatly improved, wherein flexible screens are increasingly applied to more and more electronic devices. Compared with the traditional screen, the flexible display screen is strong in flexibility and bendable, the durability is greatly higher than that of the traditional screen, the probability of accidental damage of equipment can be reduced, the flexible display screen is lighter and thinner in size relative to the traditional screen, the power consumption is lower than that of the original device, and the cruising ability of the equipment is improved.

At present, in the process of using the flexible screen by a user, the flexible screen may be bent to meet different use requirements of the user.

However, during the bending process, the bent screen portion may gradually approach to other portions of the flexible screen, or even contact with each other, and as the distance decreases, the charges of the bent screen portion may generate electrostatic interference with the charges of the display screen that is close to the bent screen portion.

Therefore, the false triggering rate of the flexible screen of the electronic equipment in the prior art is high.

Disclosure of Invention

The application provides a control method and electronic equipment, which are used for solving the technical problem that the false triggering rate of a flexible screen of the electronic equipment is high.

In one aspect, the present application provides a control method, including the steps of:

determining a current first deformation form of the flexible display screen;

determining a screen interference part of the flexible display screen in the first deformation state based on the first deformation state;

generating an adjustment instruction based on the screen disturbance portion;

and responding to the adjusting instruction so as to reduce the interference of the screen interference part when the flexible display screen is in the first deformation state.

Optionally, if the first deformation form is that the flexible display screen is in a curled form, determining, based on the first deformation form, that the flexible display screen is in a screen interference portion in the flexible display screen in the first deformation form includes:

determining a curling coefficient corresponding to the flexible display screen in the curling state;

determining screen portions of the flexible display screen that are in an overlapping state based on the curl coefficient;

determining the screen part in the overlapped state as a screen interference part in the flexible display screen under the first deformation state.

Optionally, the determining, based on the curling factor, a screen portion in an overlapped state in the flexible display screen includes:

determining a curl length corresponding to the flexible display screen in the curled configuration based on the curl coefficient;

calculating a length difference between the curled length and an original length of the flexible display screen;

determining a first screen portion and a second screen portion in an overlapping state in the flexible display screen based on the length difference.

Optionally, if the first deformation form is that the flexible display screen is in the folded form, determining, based on the first deformation form, that the flexible display screen is in the screen interference portion in the flexible display screen in the first deformation form includes:

determining a screen folding part corresponding to the folding state in the flexible display screen in the folding state;

and determining the screen folding part as a screen interference part in the flexible display screen under the first deformation state.

Optionally, the determining, based on the first deformation form, that the flexible display screen is in a screen interference portion in the flexible display screen in the first deformation form includes:

determining a screen part corresponding to an antenna device of which the power of an antenna in the flexible display screen is lower than a preset power in the first deformation state;

determining the screen portion as a screen interference portion in the flexible display screen when the flexible display screen is in the first deformation state.

Optionally, the generating an adjustment instruction based on the screen interference part includes:

generating an adjustment instruction for disabling an input function of the screen interference portion; and/or

Generating an adjustment instruction for disabling a response function of the screen interference portion; and/or

Generating an adjustment instruction for increasing the transmission power of the antenna of the screen interference portion.

Optionally, after responding to the adjustment instruction, the method further comprises:

determining a screen area in a shielding state in the screen interference part under the first deformation state;

and forbidding the display function of the screen area in the shielding state.

In another aspect, the present application is an electronic device comprising:

the flexible display screen comprises a flexible display layer and a flexible touch induction layer, wherein the flexible touch induction layer can be deformed synchronously with the flexible display layer;

the controller is used for determining a current first deformation form of the flexible display screen, and determining a screen interference part of the flexible display screen in the first deformation form based on the first deformation form; generating an adjustment instruction based on the screen disturbance portion; and responding to the adjusting instruction so as to reduce the interference of the screen interference part when the flexible display screen is in the first deformation state.

Optionally, if the first deformation state is that the flexible display screen is in a curled state, the processor is configured to:

determining a curling coefficient corresponding to the flexible display screen in the curling state;

determining screen portions of the flexible display screen that are in an overlapping state based on the curl coefficient;

determining the screen part in the overlapped state as a screen interference part in the flexible display screen under the first deformation state.

Optionally, the processor is configured to:

determining a curl length corresponding to the flexible display screen in the curled configuration based on the curl coefficient;

calculating a length difference between the curled length and an original length of the flexible display screen;

determining a first screen portion and a second screen portion in an overlapping state in the flexible display screen based on the length difference.

Optionally, if the first deformation state is that the flexible display screen is in a folded state, the processor is configured to:

determining a screen folding part corresponding to the folding state in the flexible display screen in the folding state;

and determining the screen folding part as a screen interference part in the flexible display screen under the first deformation state.

Optionally, if the first deformation state is that the flexible display screen is in a folded state, the processor is configured to:

determining a screen part corresponding to an antenna device of which the power of an antenna in the flexible display screen is lower than a preset power in the first deformation state;

determining the screen portion as a screen interference portion in the flexible display screen when the flexible display screen is in the first deformation state.

Optionally, the processor is configured to:

generating an adjustment instruction for disabling an input function of the screen interference portion; and/or

Generating an adjustment instruction for disabling a response function of the screen interference portion; and/or

Generating an adjustment instruction for increasing the transmission power of the antenna of the screen interference portion.

Optionally, the processor is configured to:

after responding to the adjusting instruction, determining a screen area in a shielding state in the screen interference part in the first deformation state, and prohibiting a display function of the screen area in the shielding state.

In another aspect, the present application provides an electronic device comprising:

the first determining module is used for determining a current first deformation form of the flexible display screen;

the second determining module is used for determining a screen interference part of the flexible display screen in the first deformation state based on the first deformation state;

the generating module is used for generating an adjusting instruction based on the screen interference part;

and the response module is used for responding to the adjustment instruction so as to reduce the interference of the screen interference part when the flexible display screen is in the first deformation state.

In the application, the current first deformation form of the flexible form screen is determined, the screen interference part of the flexible display screen in the flexible display screen under the first deformation form can be determined, the adjustment instruction can be generated based on the screen interference part, and the interference of the screen interference part is reduced when the flexible display screen is in the first deformation form by responding to the adjustment instruction, so that the phenomenon of mistaken input caused by electrostatic interference between screens in the process of bending the flexible display screen is avoided, the mistaken response of the electronic equipment is prevented, the false triggering rate of the electronic equipment is reduced, and the user experience is improved.

Drawings

FIG. 1 is a main flow chart of a control method according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a flexible display screen in a rolled configuration according to an embodiment of the invention

FIG. 3 is a block diagram of an electronic device in an embodiment of the invention;

fig. 4 is a block diagram of an electronic device in an embodiment of the invention.

Detailed Description

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

In this embodiment of the present invention, the electronic device may be a device with a flexible display screen, such as a PC (personal computer), a notebook, a PAD (PAD), a mobile phone, or even a wearable device, and the present invention is not limited thereto.

Alternatively, the flexible display screen of the electronic device may be integrated with the electronic device, or may be a separate component that is separate and connectable to the electronic device, such as a separate display screen connected to the electronic device. During the use of the electronic device by a user, the flexible display screen may be changed in form by an external force, such as being rolled, folded, etc.

Of course, a plurality of applications, such as a game application, a map application, and the like, may also be installed in the electronic device.

In practical applications, corresponding content in the electronic device can be displayed through the flexible display screen of the electronic device, such as displaying a desktop of the electronic device, or displaying a display interface corresponding to an application installed in the electronic device, such as a display interface of a map application.

In addition, the term "and/or" herein is only one kind of association relationship describing an associated object, and means that there may be three kinds of relationships, for example, a and/or B, which may mean: a exists alone, A and B exist simultaneously, and B exists alone. In addition, the character "/" herein generally indicates that the former and latter related objects are in an "or" relationship.

Preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

As shown in fig. 1, an embodiment of the present invention provides a control method, which may be described as follows.

S11: and determining the current first deformation form of the flexible display screen.

In an embodiment of the invention, the flexible display screen may be an Organic Light-Emitting display (OLED). The OLED is very thin and can be arranged on flexible materials such as plastic or metal foils, the OLED adopts a plastic substrate, a protective film is pasted on the back of the panel by means of a thin film packaging technology, and the panel can be bent and is not easy to break.

In practical applications, the flexible display screen may have a plurality of deformation forms, such as rolling or folding, etc. The user can cause the form of the flexible display screen to change through external force, and when the form of the flexible display screen changes, the position and even the shape of at least one part of the flexible display screen deform. Therefore, the same display screen in the flexible display screen may have different states under different deformation forms.

For example, for a rectangular flexible display screen, if a user bends the upper left corner of the flexible display screen, other parts are not bent, the flexible display screen is in a deformation form 1, and if the user bends the upper right corner, other parts are not bent, the flexible display screen is in a deformation form 2; in the deformation form 1, the upper left corner of the flexible display screen is bent, and the upper right corner and other parts are in an unbent state, while in the deformation form 2, the upper right corner is in a bent state, and the upper left corner and other parts are in an unbent state.

In the embodiment of the present invention, the first deformation form of the flexible display screen may be that the flexible display screen is in a rolled state, for example, the flexible display screen is rolled into a cylindrical shape, or the first deformation form may also be that the flexible display screen is in a folded state, for example, the flexible display screen is folded in half, and the specific form may be determined according to the actual situation, which is not limited in the present invention.

In practical applications, the electronic device may detect the deformation of the flexible display screen through a corresponding sensor. For example, the pressure sensor detects and detects the pressure change value of each screen part when the flexible display screen is in a folded state, and then the bending degree of the flexible display screen can be determined according to the pressure change value, for example, a certain corresponding relation can be provided between the pressure change value and the bending radian, and the deformation form of the flexible display screen can be determined according to the determined pressure change value, for example, the flexible display screen is folded in half to form an angle of 90 degrees, and the like.

S12: and determining a screen interference part of the flexible display screen in the first deformation state based on the first deformation state.

In the embodiment of the present invention, the interference portion of the flexible display screen may refer to a screen portion in the flexible display screen that has interference due to the current deformation form in the first deformation form, such as electrostatic interference, antenna interference, and the like, so as to possibly cause a false touch of the screen portion, and even cause a response of the electronic device to the false touch.

Hereinafter, a method of determining the screen interference portion when the first deformation form of the flexible display screen is a different deformation form will be mainly described.

The first condition is as follows: if the first deformation state is that the flexible display screen is in a curling state. At this time, the process of S12 may include: determining a corresponding curling coefficient of the flexible display screen in the curling state, and further determining a screen part in an overlapped state in the flexible display screen based on the curling coefficient, so that the screen part in the overlapped state is determined as a screen interference part in the flexible display screen in the first deformation state of the flexible display screen.

The curling factor may represent a degree of curling of the flexible display screen in the curled configuration, and the curling factor in the embodiment of the present invention may be a radius corresponding to the curled configuration of the flexible display screen.

In practical applications, the respective parameters may be detected by respective sensors and calculated to determine the radius of the flexible display screen. For example, for a rectangular flexible display screen, two sides of the screen corresponding to the longer side of the flexible display screen may be provided with sensors, and the sensors may detect and determine a distance between two ends of the screen during the curling process of the flexible display screen, and then the radius corresponding to the curled flexible display screen may be calculated based on the distance and the arc length (i.e., the length of the longer side of the flexible display screen).

Of course, those skilled in the art may calculate and obtain the curling factor of the flexible display screen in the curled configuration by other methods, which is not particularly limited by the embodiment of the present invention.

Furthermore, based on the determined radius of the flexible display screen in the rolled configuration, the screen portion of the flexible display screen in the overlapped state can be determined. The overlapped state may refer to a state in which the screens in the flexible display screen are in contact with each other or are very close to each other (e.g. less than 1mm) due to the curling deformation, or even are shielded. So that the screen portion in the overlapped state can be determined as the screen interference portion of the flexible display screen in the first deformation state.

Alternatively, when determining the screen portions in the overlapped state based on the curl coefficient, the process may be: determining a curling length corresponding to the flexible display screen in a curling state based on the curling coefficient, calculating a length difference value between the curling length and an original length of the flexible display screen, and determining a first screen part and a second screen part in an overlapped state in the flexible display screen based on the length difference value; wherein the screen length of the first screen portion and the second screen portion may have the same value as the length difference.

The curled length of the flexible display screen in the curled configuration may refer to a circumference of a curled cylinder formed by the flexible display screen. Generally, when the flexible display screen is in the rolled configuration, a portion of the flexible display screen overlaps, so that the flexible display screen has a shorter length than the original length of the flexible display screen in the normal configuration (i.e., no deformation).

In practical application, the curling length of the flexible display screen in the curling form can be known through the curling coefficient, so that the corresponding length difference value, namely the length of the overlapped screen, can be determined according to the curling length and the original length.

For example, the original length of the flexible display screen is L without deformation₀The test determines that the curl coefficient of the flexible display screen in the curled state is radius r, the corresponding curl length is denoted as L, L is 2 pi r, and the length difference between before and after curling is s is L₀-2 π r, so s is the length of the screen in the overlapped state of the flexible display screen in the rolled state.

The first screen portion and the second screen portion in the flexible display screen in the overlapped state can be determined based on the length difference, and the first screen portion and the second screen portion can be screen portions near opposite side edges in the flexible display screen. For example, for a rectangular flexible display screen, the first screen portion and the second screen portion may be screen portions near the left and right edges, and when external forces are applied to the screen portions at the left and right edges, respectively, the flexible display screen is deformed, and the first screen portion and the second screen portion gradually approach to cause the flexible display screen to form a curled shape.

As shown in fig. 2, which is a schematic diagram of a flexible display screen in a rolled state, wherein a numeral 21 represents a first screen portion, a numeral 22 represents a second screen portion, and a letter s is an overlapping area of the first screen portion and the second screen portion.

Of course, fig. 2 is only a schematic diagram, in an actual application of the first screen portion and the second screen portion in the rolled state, when the flexible display screen is in the rolled state, in the overlapped screen portions, if the screen portion near the center of the circle is taken as the first screen portion, the screen portion at the outer side portion in the overlapped portion is taken as the second screen portion, and similarly, if the screen portion near the center of the circle is taken as the second screen portion, the overlapped screen portion at the outer side of the cylinder is taken as the first screen portion.

Case two: the first deformation state is that the flexible display screen is in a folding state. At this time, the process of S12 may include: and determining a screen folding part corresponding to the folding state in the flexible display screen in the folding state, and determining the screen folding part as a screen interference part in the flexible display screen in the first deformation state of the flexible display screen.

In practical applications, the electronic device may detect and determine a corresponding screen folding portion when the flexible display screen is in the folded state through a corresponding sensor, where the screen folding portion may refer to a corresponding folding portion in the screen when the flexible display screen is folded and deformed.

For example, the flexible display screen is laid on a plane parallel to a horizontal plane, and if the upper left screen portion (i.e., the triangular screen area) of the flexible display screen is turned over, for example, the flexible display screen is turned over to be perpendicular to the horizontal plane, the flexible display screen may be considered to be in the first deformation state, and the electronic device may determine the turned-over triangular screen area as the screen folding portion corresponding to the current state.

Of course, in practical applications, if the angle of the folded screen portion is larger when the flexible display screen is in the folded state, for example, the folded angle exceeds a preset angle (e.g., 150 °, 160 °, etc.), it may also shield a corresponding portion of the flexible display screen, for example, when the left-hand corner screen area in the above example is folded by 160 ° (similar to horizontal), it may also shield a corresponding screen area of the horizontally placed flexible display screen, and at this time, the shielded screen portion corresponding to the folded screen portion may be determined as the interfered screen interference portion together.

Case three: when the antenna is disposed in the flexible display screen, when the flexible display screen is deformed, for example, for the antenna disposed along the periphery of the flexible display screen, electromagnetic interference between the antennas may be caused when the flexible display screen is rolled or folded, and even the transmission/reception function of the electronic device may be affected.

At this time, the process of S12 may be: and determining a screen part corresponding to the antenna device with the power of the antenna lower than the preset power in the flexible display screen in the first deformation state, and determining the screen part as a screen interference part in the flexible display screen in the first deformation state.

Of course, in practical applications, the methods for determining the screen interference portion in advance under the above-mentioned several conditions can be combined without conflict, for example, in the rolling configuration, the screen portion in the folded state and the screen portion in the antenna interference state can be determined as the screen interference portion.

S13: an adjustment instruction is generated based on the screen disturbance portion.

In the embodiment of the present invention, the generated adjustment instruction may be an adjustment instruction for prohibiting an input function of the screen interfering portion, and/or an adjustment instruction for prohibiting a response function of the screen interfering portion; and/or an adjustment instruction for increasing the transmission power of the antenna of the screen interference portion.

S14: and responding to the adjusting instruction so as to reduce the interference of the screen interference part when the flexible display screen is in the first deformation state.

In the embodiment of the invention, after the screen interference part is determined, the position and the area size of the screen interference part in the flexible display screen can be determined, so that the screen interference part in the flexible display screen can be adjusted through the response of the electronic equipment to the adjustment instruction, for example, the interference of the screen interference part is reduced by inhibiting the input function (namely, touch sensing function) and/or the response function of the screen interference part, even increasing the antenna emission function of the screen interference part, and the like, and the screen interference part does not respond to other parts.

In practical application, when the screen interference part in the flexible display screen is adjusted based on the adjustment instruction, the adjustment can be performed on a partial area or a whole area of the screen interference part, that is, the electronic device can selectively adjust the screen interference part through the adjustment instruction, so that the flexibility of the adjustment mode of the electronic device is improved.

For example, in the case that the first deformed configuration of the flexible display screen is the rolled configuration, if the determined screen interference portion includes the first screen portion and the second screen portion as shown in fig. 2, the first screen portion is located at the outer side of the roll. At this time, the touch function and the response function of the first screen portion and the second screen portion may be simultaneously prohibited according to the adjustment instruction, or only the touch function and the response function of the first screen portion (i.e., the screen portion that is blocked in the overlapped state) may be prohibited, and the touch function and the response function of the second screen portion (that is, outside the roll) may not be prohibited, and so on.

Or, in the second case, the touch function and the response function of the folded-back screen portion may be prohibited, and even the touch function and the response function of a screen area (e.g., a projection portion of the folded-back screen portion in the flexible display screen) corresponding to the folded-back screen portion in the flexible display screen may be prohibited.

It should be noted that, in practical applications, when the related functions of the screen interference portion are adjusted, the actually adjusted screen portion may be larger than the screen interference portion due to the capacitance effect at the edge of the screen itself. For example, in the case of a moment, the length of the actually adjusted screen portion may be slightly larger than the length (i.e., s) of the overlapping area, and besides, when the curling factor changes, the electronic device may dynamically calculate the overlapping length, thereby dynamically changing the area where the screen touch is disabled.

Optionally, after S14, it is further determined that the screen area in the screen interference part in the first deformation form is in the shielding state, and at least the display function of the screen area in the shielding state is prohibited.

For example, the display function of the folded-over screen portion and the projection of the folded-over screen portion onto the corresponding screen portion in the flexible display screen is disabled, or the display function of the first screen portion in fig. 2 is disabled, and so on.

Therefore, it can be seen from the above description that, by responding to the generated adjustment instruction, the use of the related functions of the screen interference region is adjusted, thereby preventing the false triggering of the flexible display screen in the first deformation state, reducing the interference to the screen interference portion, and improving the reliability of the electronic device.

As shown in fig. 3, the embodiment of the invention discloses an electronic device, which comprises a flexible display screen 10 and a processor 20.

In an embodiment of the present invention, the flexible display screen 10 may include a flexible display layer and a flexible touch sensing layer, and the flexible touch sensing layer and the flexible display layer can be deformed synchronously, such as being curled, folded, and the like, under an external force.

The processor 20 may be configured to determine a current first deformation form of the flexible display screen 10, and based on the first deformation form, determine a screen interference portion in the flexible display screen 10 when the flexible display screen 10 is in the first deformation form; generating an adjustment instruction based on the screen disturbance portion; and responding to the adjustment instruction, so that when the flexible display screen 10 is in the first deformation state, the interference of the screen interference part is reduced.

Optionally, if the first deformation state is that the flexible display screen is in a curled state, the processor 20 is configured to:

determining a corresponding curling coefficient of the flexible display screen 10 in the curled state;

determining a screen portion in an overlapped state in the flexible display screen 10 based on the curling coefficient;

determining the screen portion in the overlapped state as a screen interference portion in the flexible display screen 10 when the flexible display screen 10 is in the first deformation state.

Optionally, the processor 20 is configured to: determining a corresponding curl length of the flexible display screen 10 in the curled configuration based on the curl coefficient; calculating a length difference between the curled length and an original length of the flexible display screen 10; based on the length difference, a first screen portion and a second screen portion in an overlapped state in the flexible display screen 10 are determined.

Optionally, the processor 20 is configured to: determining a screen folding portion of the flexible display screen 10 corresponding to the folding state in the folding state; determining the screen folding portion as a screen interference portion in the flexible display screen 10 when the flexible display screen 10 is in the first deformation state.

Optionally, if the first deformation state is that the flexible display screen is in the folded state, the processor 20 is configured to: determining a screen portion corresponding to an antenna device in which the power of an antenna in the flexible display screen 10 is lower than a preset power in the first deformation state; determining the screen portion as a screen interference portion in the flexible display screen 10 when the flexible display screen 10 is in the first deformation form.

Optionally, the processor 20 is configured to:

generating an adjustment instruction for disabling an input function of the screen interference portion; and/or

Generating an adjustment instruction for disabling a response function of the screen interference portion; and/or

Generating an adjustment instruction for increasing the transmission power of the antenna of the screen interference portion.

Optionally, the processor 20 is configured to determine, after responding to the adjustment instruction, a screen area in an occlusion state in the screen interference part in the first deformation state, and prohibit a display function of the screen area in the occlusion state.

As shown in fig. 4, an embodiment of the present invention discloses an electronic device, which includes a first determining module 201, a second determining module 202, a generating module 203, and a responding module 204.

The first determining module 201 may be configured to determine a current first deformation form of the flexible display screen.

The second determining module 202 may be configured to determine, based on the first deformation form, a screen interference portion of the flexible display screen in the first deformation form.

The generating module 203 may be configured to generate an adjustment instruction based on the screen disturbance portion.

The response module 204 may be configured to respond to the adjustment instruction, so as to reduce interference of the screen interference portion when the flexible display screen is in the first deformation state.

Optionally, if the first deformation state is that the flexible display screen is in a rolled state, the second determining module 202 may be configured to: determining a curling coefficient corresponding to the flexible display screen in the curling state; determining screen portions of the flexible display screen that are in an overlapping state based on the curl coefficient; determining the screen part in the overlapped state as a screen interference part in the flexible display screen under the first deformation state.

Optionally, the second determining module 202 is specifically configured to:

determining a curl length corresponding to the flexible display screen in the curled configuration based on the curl coefficient;

calculating a length difference between the curled length and an original length of the flexible display screen;

determining a first screen portion and a second screen portion in an overlapping state in the flexible display screen based on the length difference.

Optionally, in another embodiment, if the first deformation state is that the flexible display screen is in the folded state, the second determining module 202 may be configured to determine that the flexible display screen is in the folded state

Determining a screen folding part corresponding to the folding state in the flexible display screen in the folding state;

and determining the screen folding part as a screen interference part in the flexible display screen under the first deformation state.

Optionally, in another embodiment, the second determining module 202 may be configured to: determining a screen part corresponding to an antenna device of which the power of an antenna in the flexible display screen is lower than a preset power in the first deformation state; determining the screen portion as a screen interference portion in the flexible display screen when the flexible display screen is in the first deformation state.

Optionally, the generating module 203 may be configured to:

generating an adjustment instruction for disabling an input function of the screen interference portion; and/or

Generating an adjustment instruction for disabling a response function of the screen interference portion; and/or

Generating an adjustment instruction for increasing the transmission power of the antenna of the screen interference portion.

Optionally, the electronic device may further include a generating module 203, configured to determine a screen area in the screen interference portion in the first deformation state and prohibit a display function of the screen area in the shielding state.

Various changes and specific examples of the control method in the foregoing embodiments of fig. 1-2 are also applicable to the electronic device of this embodiment, and those skilled in the art can clearly know the implementation method of the electronic device in this embodiment through the foregoing detailed description of the authentication method, so that details are not described here for brevity of the description.

As will be appreciated by one skilled in the art, embodiments of the present invention may be provided as a method, system, or computer program product. Accordingly, the present invention may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present invention may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.

The present invention is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to embodiments of the invention. It will be understood that each flow and/or block of the flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

Specifically, the computer program instructions corresponding to the control method in the embodiment of the present application may be stored on a storage medium such as an optical disc, a hard disc, a usb disk, or the like, and when the computer program instructions corresponding to the control method in the storage medium are read or executed by an electronic device, the method includes the following steps:

determining a current first deformation form of the flexible display screen;

determining a screen interference part of the flexible display screen in the first deformation state based on the first deformation state;

generating an adjustment instruction based on the screen disturbance portion;

and responding to the adjusting instruction so as to reduce the interference of the screen interference part when the flexible display screen is in the first deformation state.

Optionally, if the first deformation state is that the flexible display screen is in the curled state, the computer instructions and the steps: determining, based on the first deformation form, that the flexible display screen is in a screen interference portion in the flexible display screen in the first deformation form, where the corresponding instructions, when executed, include the following steps:

determining a curling coefficient corresponding to the flexible display screen in the curling state;

determining screen portions of the flexible display screen that are in an overlapping state based on the curl coefficient;

determining the screen part in the overlapped state as a screen interference part in the flexible display screen under the first deformation state.

Optionally, the computer instructions further comprise the steps of: determining screen portions of the flexible display screen that are in an overlapping state based on the curl coefficient, the corresponding instructions when executed comprising the steps of:

determining a curl length corresponding to the flexible display screen in the curled configuration based on the curl coefficient;

calculating a length difference between the curled length and an original length of the flexible display screen;

determining a first screen portion and a second screen portion in an overlapping state in the flexible display screen based on the length difference.

Optionally, if the first deformation state is that the flexible display screen is in the folded state, the computer instructions perform the following steps: determining, based on the first deformation form, that the flexible display screen is in a screen interference portion in the flexible display screen in the first deformation form, where the corresponding instructions, when executed, include the following steps:

determining a screen folding part corresponding to the folding state in the flexible display screen in the folding state;

and determining the screen folding part as a screen interference part in the flexible display screen under the first deformation state.

Optionally, the computer instructions further comprise the steps of: determining, based on the first deformation form, that the flexible display screen is in a screen interference portion in the flexible display screen in the first deformation form, where the corresponding instructions, when executed, include the following steps:

determining a screen part corresponding to an antenna device of which the power of an antenna in the flexible display screen is lower than a preset power in the first deformation state;

determining the screen portion as a screen interference portion in the flexible display screen when the flexible display screen is in the first deformation state.

Optionally, the computer instructions further comprise the steps of: generating an adjustment instruction based on the screen disturbance component, the corresponding instruction when executed comprising the steps of:

generating an adjustment instruction for disabling an input function of the screen interference portion; and/or

Generating an adjustment instruction for disabling a response function of the screen interference portion; and/or

Generating an adjustment instruction for increasing the transmission power of the antenna of the screen interference portion.

Optionally, the storage medium further stores other computer instructions, and the computer instructions perform the following steps: the method is executed after the instruction corresponding to the adjusting instruction is executed, and the method comprises the following steps:

determining a screen area in a shielding state in the screen interference part under the first deformation state;

and forbidding the display function of the screen area in the shielding state.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (11)

1. A method of controlling, the method comprising:

determining a current first deformation form of the flexible display screen;

determining a screen interference part of the flexible display screen in the first deformation state based on the first deformation state;

generating an adjustment instruction based on the screen disturbance portion;

responding to the adjusting instruction, so that when the flexible display screen is in the first deformation state, the interference of the screen interference part is reduced; wherein,

if the first deformation form is that the flexible display screen is in a curled form, determining, based on the first deformation form, that the flexible display screen is in a screen interference part in the flexible display screen in the first deformation form, including:

determining a curling coefficient corresponding to the flexible display screen in the curling state;

determining screen portions of the flexible display screen that are in an overlapping state based on the curl coefficient;

determining the screen part in the overlapped state as a screen interference part in the flexible display screen under the first deformation state;

the determining, based on the curl coefficient, screen portions of the flexible display screen that are in an overlapping state includes:

determining a curl length corresponding to the flexible display screen in the curled configuration based on the curl coefficient;

calculating a length difference between the curled length and an original length of the flexible display screen;

and determining a first screen part and a second screen part in an overlapped state in the flexible display screen based on the length difference so as to generate corresponding adjusting instructions based on the first screen part and the second screen part.

2. The method of claim 1, wherein if the first deformation state is the flexible display screen in the folded state, the determining the screen interference portion of the flexible display screen in the first deformation state based on the first deformation state comprises:

determining a screen folding part corresponding to the folding state in the flexible display screen in the folding state;

and determining the screen folding part as a screen interference part in the flexible display screen under the first deformation state.

3. The method of claim 1, wherein the determining that the flexible display screen is in a screen disturbance portion of the flexible display screen in the first deformed configuration based on the first deformed configuration comprises:

determining a screen part corresponding to an antenna device of which the power of an antenna in the flexible display screen is lower than a preset power in the first deformation state;

determining the screen portion as a screen interference portion in the flexible display screen when the flexible display screen is in the first deformation state.

4. The method of any of claims 1-3, wherein the generating adjustment instructions based on the screen disturbance component comprises:

generating an adjustment instruction for disabling an input function of the screen interference portion; and/or

Generating an adjustment instruction for disabling a response function of the screen interference portion; and/or

Generating an adjustment instruction for increasing the transmission power of the antenna of the screen interference portion.

5. The method of claim 4, wherein after responding to the adjustment instruction, the method further comprises:

determining a screen area in a shielding state in the screen interference part under the first deformation state;

and forbidding the display function of the screen area in the shielding state.

6. An electronic device, comprising:

the flexible display screen comprises a flexible display layer and a flexible touch induction layer, wherein the flexible touch induction layer can be deformed synchronously with the flexible display layer;

the processor is used for determining a current first deformation form of the flexible display screen, and determining a screen interference part of the flexible display screen in the first deformation form based on the first deformation form; generating an adjustment instruction based on the screen disturbance portion; responding to the adjusting instruction, so that when the flexible display screen is in the first deformation state, the interference of the screen interference part is reduced; wherein,

if the first deformation state is that the flexible display screen is in a curled state, the processor is configured to:

determining a curling coefficient corresponding to the flexible display screen in the curling state;

determining screen portions of the flexible display screen that are in an overlapping state based on the curl coefficient;

determining the screen part in the overlapped state as a screen interference part in the flexible display screen under the first deformation state;

the processor is configured to:

determining a curl length corresponding to the flexible display screen in the curled configuration based on the curl coefficient;

calculating a length difference between the curled length and an original length of the flexible display screen;

and determining a first screen part and a second screen part in an overlapped state in the flexible display screen based on the length difference so as to generate corresponding adjusting instructions based on the first screen part and the second screen part.

7. The electronic device of claim 6, wherein if the first deformed configuration is the flexible display screen in the folded configuration, the processor is configured to:

determining a screen folding part corresponding to the folding state in the flexible display screen in the folding state;

and determining the screen folding part as a screen interference part in the flexible display screen under the first deformation state.

8. The electronic device of claim 6, wherein if the first deformed configuration is the flexible display screen in the folded configuration, the processor is configured to:

determining a screen part corresponding to an antenna device of which the power of an antenna in the flexible display screen is lower than a preset power in the first deformation state;

determining the screen portion as a screen interference portion in the flexible display screen when the flexible display screen is in the first deformation state.

9. The electronic device of any of claims 6-8, wherein the processor is to:

generating an adjustment instruction for disabling an input function of the screen interference portion; and/or

Generating an adjustment instruction for disabling a response function of the screen interference portion; and/or

Generating an adjustment instruction for increasing the transmission power of the antenna of the screen interference portion.

10. The electronic device of claim 9, wherein the processor is to:

after responding to the adjusting instruction, determining a screen area in a shielding state in the screen interference part in the first deformation state, and prohibiting a display function of the screen area in the shielding state.

11. An electronic device, comprising:

the first determining module is used for determining a current first deformation form of the flexible display screen;

the second determining module is used for determining a screen interference part of the flexible display screen in the first deformation state based on the first deformation state;

the generating module is used for generating an adjusting instruction based on the screen interference part;

the response module is used for responding to the adjustment instruction so as to reduce the interference of the screen interference part when the flexible display screen is in the first deformation state; wherein,

if the first deformation state is that the flexible display screen is in a curled state, a second determining module is used for: determining a curling coefficient corresponding to the flexible display screen in the curling state; determining screen portions of the flexible display screen that are in an overlapping state based on the curl coefficient; determining the screen part in the overlapped state as a screen interference part in the flexible display screen under the first deformation state; wherein,

the second determining module is specifically configured to:

determining a curl length corresponding to the flexible display screen in the curled configuration based on the curl coefficient;

calculating a length difference between the curled length and an original length of the flexible display screen;

and determining a first screen part and a second screen part in an overlapped state in the flexible display screen based on the length difference, so that the generating module generates corresponding adjusting instructions based on the first screen part and the second screen part.

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