WO2019000288A1 - Touch response method and device - Google Patents

Abstract

A touch response method and device, the method comprising: acquiring a deformation position of a touch screen and a first deformation amplitude at the deformation position (S101); acquiring a first touch response parameter corresponding to the first deformation amplitude (S102); setting the touch response parameter at the deformation position as the first touch response parameter (S103); and responding to a touch operation on the touch screen according to the first touch response parameter (S104). The solution can effectively improve the touch response capability of the touch screen at a deformation position and improve the touch response efficiency of the touch screen.

Description

Touch response method and device Technical field

The present invention relates to the field of electronic technologies, and in particular, to a touch response method and apparatus.

Background technique

At present, with the development of flexible display technology, the touch screen can not only achieve a small curvature of a fixed arc, but also achieve any bending or even winding of a large arc. Such a touch screen has the characteristics of being thin, bendable, non-fragile, portable, etc. More and more terminal devices (such as smartphones, tablets, smart wearable devices, etc.) are beginning to configure such touch screens. However, when the deformation amplitude at a certain position of the touch screen is large, the touchable area at the deformation position is small, and when the end user wants to perform the touch operation at the deformation position, the touch screen is difficult to sense the touch of the end user. The control operation causes the touch response capability of the touch screen at the deformation position to be greatly reduced, and the touch response efficiency of the touch screen is also reduced.

Summary of the invention

The embodiment of the invention discloses a touch response method and device, which can effectively improve the touch response capability of the touch screen deformation position and improve the touch response efficiency of the touch screen.

A first aspect of the embodiments of the present invention discloses a touch response method, including:

Obtaining a deformation position of the touch screen and a first deformation width at the deformation position;

Obtaining a first touch response parameter corresponding to the first deformation magnitude;

Setting the touch response parameter at the deformation position to the first touch response parameter;

Responding to the touch operation on the touch screen according to the first touch response parameter.

The second aspect of the embodiment of the present invention discloses a touch response device, including:

An acquiring module, configured to acquire a deformation position of the touch screen and a first deformation width at the deformation position;

The acquiring module is further configured to acquire a first touch response parameter corresponding to the first deformation magnitude;

a setting module, configured to set a touch response parameter at the deformation position as the first touch response parameter;

a response module, configured to perform a touch operation on the touch screen according to the first touch response parameter Line response.

A third aspect of the embodiments of the present invention discloses a computer readable storage medium, wherein the computer readable storage medium stores instructions for causing a computer to perform the touch described in the first aspect when the instruction is run on a computer Control response method.

A fourth aspect of the embodiments of the present invention discloses a computer program product comprising instructions for causing a computer to perform the touch response method of the first aspect described above when the instructions are run on a computer.

In the embodiment of the present invention, the first deformation range at the deformation position and the deformation position of the touch screen is first obtained, and then the first touch response parameter corresponding to the first deformation amplitude is obtained, and the touch response parameter at the deformation position is set to be the first A touch response parameter finally responds to the touch operation on the touch screen according to the first touch response parameter, that is, the touch response parameter at the touch screen deformation position can be adjusted, thereby effectively improving the touch response capability at the touch screen deformation position. Improve the touch response efficiency of the touch screen.

DRAWINGS

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings to be used in the embodiments will be briefly described below. It is obvious that the drawings in the following description are only some embodiments of the present invention. Those skilled in the art can also obtain other drawings based on these drawings without paying for creative labor.

1 is a schematic flow chart of a touch response method according to an embodiment of the present invention;

2 is a schematic flow chart of another touch response method according to an embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a touch response device according to an embodiment of the present invention.

Detailed ways

The technical solutions in the embodiments of the present invention will be clearly and completely described in the following with reference to the accompanying drawings.

The embodiment of the invention discloses a touch response method and device for improving the touch response capability at the deformation position of the touch screen, so as to improve the touch response efficiency of the touch screen, which are respectively described in detail below.

The touch response method provided by the embodiment of the present invention may be implemented by a smart phone (such as an Android mobile phone, an iOS mobile phone, a Windows Phone mobile phone, etc.), a tablet computer, a mobile Internet device (MID), a smart wearable device, or the like. Configuring a terminal that can be deformed by a touch screen to fulfill. The touch screen that can be deformed can be a flexible touch screen, such as an Organic Light-Emitting Diode (OLED) flexible touch screen, which can be freely stretched and retracted to achieve changes in size, shape, and the like.

The deformation amplitude described in the embodiment of the present invention specifically refers to the bending amplitude of the touch screen at the deformation position.

FIG. 1 is a schematic flowchart diagram of a touch response method according to an embodiment of the present invention. The touch response method described in this embodiment includes:

S101. The terminal acquires a deformation position of the touch screen and a first deformation width at the deformation position.

In a specific implementation, the terminal may acquire the deformation position of the touch screen and the deformation amplitude (referred to as the first deformation width) of the touch screen through a sensor integrated with the touch screen for detecting the deformation amplitude. The deformation position of the touch screen may specifically be a touch area of the touch screen, and may be determined according to the position coordinates of the sensor. For each sensor, the position coordinates of the touch screen may be defined, and the detected deformation amplitude exceeds the preset deformation amplitude threshold. The position coordinates can be used as the deformation position.

It should be noted that the preset deformation amplitude threshold may be 0, that is, as long as the sensor detects that deformation has occurred (the deformation amplitude is greater than 0), the position coordinate of the sensor may be used as the deformation position; or the preset deformation amplitude threshold may also be used. For a value greater than 0, denoted as C, that is, when the sensor detects that the generated deformation reaches a certain extent (deformation amplitude is greater than C), the position coordinate of the sensor is taken as the deformation position.

S102. The terminal acquires a first touch response parameter corresponding to the first deformation magnitude.

In the embodiment of the present invention, the touch response parameter may include at least one of a touch sensing sensitivity, a touch data read frequency, and a touch response sensitivity, that is, a touch sensing sensitivity and a touch data according to the deformation amplitude. The suitability adjustment is performed by any one or more of the read frequency and the touch response sensitivity. The sensitivity of the touch sensing is sensitive to the touch area, that is, the touch screen can sense the threshold of the touch area of the touch operation, and the lower the threshold of the touch area, the easier the touch screen senses the input touch operation. That is, the sensitivity of the touch sensing is higher. In order to ensure the effectiveness of the touch sensing sensitivity when sensing the touch operation, the minimum sensing threshold of the touch sensing sensitivity of the touch screen should be greater than the minimum sensing area of the touch screen capable of sensing the touch operation. The reading frequency of the touch data refers to the number of times the processor reads the touch data per unit time (for example, every second). The sensitivity of the touch response is the degree of adjustment of the corresponding parameter of the controlled object according to the unit touch distance. The greater the degree of adjustment, the higher the sensitivity of the touch response.

In a specific implementation, the terminal may pre-set N deformation amplitude threshold intervals, N is a positive integer, and the correspondence between the N deformation amplitude threshold intervals and the touch response parameters, and the terminal firstly adopts a preset N deformation range. In the threshold interval, querying the first deformation amplitude threshold interval to which the first deformation amplitude belongs, and then acquiring the threshold corresponding to the first deformation amplitude threshold interval according to the correspondence between the preset deformation amplitude threshold interval and the touch response parameter The first touch response parameter.

For example, the terminal is pre-configured with three ranges of deformation amplitude threshold intervals [a1, a2), [a2, a3), [a3, a4), where a4>a3>a2>a1, and each deformation amplitude threshold interval Corresponding to at least one of pre-set touch sensing sensitivity (denoted as S), touch data read frequency (denoted as T), and touch response sensitivity (denoted as R). For example, the deformation amplitude threshold interval [a1, a2) corresponds to at least one of S1, T1 and R1, [a2, a3) corresponds to at least one of S2, T2 and R2, [a3, a4) and S3, T3 and R3. At least one of the corresponding ones, and the larger the magnitude of the deformation amplitude represented by each deformation amplitude threshold interval, the corresponding touch response parameter (ie, S, or T, or R, or S and T, or S and R, or T And R, or S, T and R) are larger, that is, S3>S2>S1, T3>T2>T1, and R3>R2>R1. The larger the touch sensing sensitivity S is, the smaller the threshold of the corresponding touch area is. When the touch response sensitivity R is larger, the corresponding adjusted amount is larger. After obtaining the first deformation amplitude at the deformation position of the touch screen, if it is found that the first deformation amplitude threshold interval to which the first deformation amplitude belongs is [a1, a2), the threshold range and touch according to the preset deformation amplitude may be Corresponding relationship between the control response parameters queries the first touch response parameter corresponding to the first deformation magnitude as at least one of S1, T1 and R1.

S103. The terminal sets a touch response parameter at the deformation position as the first touch response parameter.

In a specific implementation, after acquiring the first touch response parameter, the terminal adjusts the touch response parameter at the deformation position from the current (or default) touch response parameter to the first touch response parameter.

For example, when the touch screen is not deformed, the default touch sensing sensitivity at the flat position of the touch screen, that is, the threshold of the touch area defaults to 0.3*0.3 cm ² . Normally, to prevent false touches, this threshold may be slightly larger than the minimum touch area value (eg, 0.1*0.1 cm ² ) that the touch screen can actually sense. When the deformation amplitude at the deformation position of the touch screen, that is, the larger the first deformation amplitude, the smaller the touchable area at the deformation position is, so that the touch operation at the deformation position of the touch screen can be sensed in time and accurately. The touch sensing sensitivity corresponding to the first deformation magnitude is larger, that is, the threshold of the touch area at the deformation position is smaller (for example, 0.2*0.2 cm ² , 0.1*0.1 cm ² ), and the deformation position is The touch sensing sensitivity at the location is set to the touch sensing sensitivity corresponding to the first deformation amplitude by the default touch sensing sensitivity, that is, the threshold of the touch area is set to 0.2*0.2cm ² or 0.1* from 0.3*0.3cm ² . 0.1cm ² . In the above manner, even if the deformation range of the touch screen is large, the touchable area at the deformation position becomes small, and the touch screen can still sense the touch operation of the user on the touch screen, that is, the touch screen can be based on a smaller touch area threshold. To determine the trigger event.

In some feasible implementation manners, the greater the reading frequency of the touch data, the more the number of touch parameters that the user obtains for the touch screen in the same time, and the easier the processor is to parse the user's gesture, thereby more accurately Analyze the user's operational intent. When the first deformation amplitude at the touch screen deformation position is larger, the gesture of the user's touch operation at the touch screen deformation position is less standard and more difficult to recognize. In this case, in order to more accurately recognize the user's gesture and reduce the probability of misoperation, the read frequency of the touch data corresponding to the first deformation range is higher, and the touch data at the deformation position is read. The frequency is set to the read frequency of the touch data corresponding to the first deformation magnitude. In the above manner, the touch data at the deformation position acquired in the same time can be more, the efficiency of parsing the user gesture can be improved, the user operation intention is more accurate, and the user operation can be responded efficiently and accurately.

In some feasible implementation manners, when the first deformation amplitude at the deformation position of the touch screen is larger, in order to improve the touch response capability at the deformation position of the touch screen, the acquired touch response sensitivity corresponding to the first deformation amplitude is The higher the touch response sensitivity at the deformation position is the touch response sensitivity corresponding to the first deformation magnitude. In the above manner, the unit sliding distance can be made to correspond to a larger adjustment amount. For example, for the brightness, volume and other parameters of the terminal, the same sliding distance on the touch screen of the terminal, the adjustment amount of the brightness, the volume, and the like in the flat state of the touch screen is larger than that in the flat state of the touch screen, thereby improving the position of the touch screen at the deformation position. Touch response efficiency.

S104. The terminal responds to the touch operation on the touch screen according to the first touch response parameter.

In a specific implementation, the terminal responds to the touch operation on the touch screen according to the obtained first touch response parameter to determine whether to respond to the touch operation. For example, the first touch response parameter may include touch sensing. Sensitivity and sensitivity of the touch response, the terminal first obtains the touch parameter of the touch operation of the touch screen, and matches the touch parameter with the touch sensitivity. The touch parameter may be the touch area, and the terminal will The touch area of the touch operation is compared with the touch area threshold corresponding to the touch sensitivity. If the touch area reaches the touch area threshold, the touch parameter is determined to match the touch sensitivity, and then The touch response sensitivity responds to the touch operation.

In the embodiment of the present invention, the terminal first acquires the first deformation range of the deformation position and the deformation position of the touch screen, and then acquires the first touch response parameter corresponding to the first deformation range, and sets the touch response parameter at the deformation position. The first touch response parameter finally responds to the touch operation on the touch screen according to the first touch response parameter, that is, the touch response parameter at the deformation position of the touch screen can be adjusted according to the deformation amplitude, thereby effectively improving the touch screen deformation. The touch response capability at the location improves the touch response efficiency of the touch screen.

FIG. 2 is a schematic flowchart diagram of another touch response method according to an embodiment of the present invention. The touch response method described in this embodiment includes:

S201. The terminal acquires a deformation position of the touch screen and a first deformation width at the deformation position.

For the specific implementation of the step S201, reference may be made to the related description of the step S101 in the foregoing method embodiment, and details are not described herein again.

S202. The terminal acquires a second touch response parameter corresponding to the second deformation magnitude when detecting that the deformation magnitude at the deformation position is changed from the first deformation magnitude to the second deformation magnitude.

The terminal is pre-set with N deformation amplitude threshold intervals, N is a positive integer, and the correspondence between the N deformation amplitude threshold intervals and the touch response parameters.

In a specific implementation, when it is detected that the deformation amplitude at the deformation position of the touch screen changes, the deformation amplitude at the deformation position is changed from the first deformation amplitude (denoted as a5) to the second deformation amplitude (denoted as a6), and the terminal firstly In the preset N deformation amplitude threshold intervals, the second deformation amplitude threshold interval to which the second deformation amplitude belongs is queried, and then according to the correspondence between the preset deformation amplitude threshold interval and the touch response parameter, The second touch response parameter corresponding to the threshold range of the second deformation range.

It is assumed that a6 and a5 belong to different deformation amplitude threshold intervals. If a6 is greater than a5, the deformation amplitude at the deformation position of the touch screen becomes larger, and the touchable area at the deformation position becomes smaller, and the user is sensed. The touch operation is more difficult, and the acquired second touch response parameter is greater than the first touch response parameter to improve the touch response capability at the deformed position. If a6 is smaller than a5, that is, the deformation amplitude at the deformation position of the touch screen becomes smaller, the touchable area at the deformation position becomes larger at this time, and the touch operation of the user is easier to be sensed, and the acquired second touch is easier. The response parameter is smaller than the first touch response parameter to reduce the probability of misoperation.

S203. The terminal sets a touch response parameter at the deformation position as the second touch response parameter.

In a specific implementation, if the terminal inquires that the second deformation amplitude and the first deformation amplitude belong to different deformation amplitude threshold intervals, after acquiring the second touch response parameter, the touch response parameter at the touch screen deformation position is obtained. The current touch response parameter (ie, the first touch response parameter) is adjusted to the second touch response parameter. Of course, if it is found that the second deformation amplitude and the first deformation amplitude belong to the same deformation amplitude threshold interval, the touch response parameter at the deformation position is not adjusted.

S204. The terminal responds to the touch operation on the touch screen according to the second touch response parameter.

The second touch response parameter may include at least one of a touch sensing sensitivity, a read frequency of the touch data, and a touch response sensitivity.

In a specific implementation, the terminal responds to the touch operation on the touch screen according to the second touch response parameter corresponding to the latest deformation range (ie, the second deformation amplitude) to determine whether to respond to the touch operation.

In some possible implementation manners, the second touch response parameter may only include the touch sensing sensitivity, and the terminal first reads the touch data according to the default touch data read frequency or the first touch response parameter. The frequency is obtained by the touch parameter of the touch operation on the touch screen, and the touch parameter is matched with the touch sensitivity. The touch parameter may be the touch area, and the touch area of the touch operation and the touch Comparing the touch area thresholds corresponding to the sensing sensitivity, if the touch area reaches the touch area threshold, determining that the touch parameter matches the touch sensing sensitivity, and then according to the default touch response sensitivity or the first touch The touch response sensitivity included in the response parameter is responsive to the touch operation.

In some implementations, the second touch response parameter may only include the read frequency of the touch data, and the terminal first acquires the touch parameter of the touch operation on the touch screen according to the read frequency of the touch data, The touch parameter is matched with the default touch sensing sensitivity or the touch sensing sensitivity included in the first touch response parameter. The touch parameter may be the touch area, and the touch area of the touch operation is compared with the default. The touch sensing sensitivity or the touch area sensitivity corresponding to the touch sensing sensitivity of the first touch response parameter is compared. If the touch area reaches the touch area threshold, the touch parameter and the default touch sensing sensitivity are determined. Or the touch sensing sensitivity of the first touch response parameter is matched, and then responding to the touch operation according to a default touch response sensitivity or a touch response sensitivity included in the first touch response parameter.

In some feasible implementation manners, the second touch response parameter may only include touch response sensitivity The terminal first obtains the touch parameter of the touch operation on the touch screen according to the reading frequency of the default touch data or the reading frequency of the touch data included in the first touch response parameter, and the touch parameter and the default The touch sensing sensitivity or the touch sensing sensitivity included in the first touch response parameter is matched, and the touch parameter may be a touch area, and the touch area of the touch operation and the default touch sensing sensitivity or the first Comparing the touch area threshold corresponding to the touch sensing sensitivity of the touch response parameter, if the touch area reaches the touch area threshold, determining the touch parameter and the default touch sensing sensitivity or the first touch response The parameter includes a touch sensing sensitivity matching, and then responds to the touch operation according to the touch response sensitivity.

In some possible implementation manners, the second touch response parameter may include the touch sensing sensitivity and the read frequency of the touch data, and the terminal first acquires the touch operation on the touch screen according to the read frequency of the touch data. The touch parameter matches the touch sensitivity with the touch sensitivity. The touch parameter may be a touch area, and the touch area of the touch operation corresponds to the touch area threshold. For comparison, if the touch area reaches the touch area threshold, it is determined that the touch parameter matches the touch sensing sensitivity, and then according to the default touch response sensitivity or the touch response sensitivity included in the first touch response parameter. The touch operation is responsive.

In some possible implementation manners, the second touch response parameter may include the touch sensing sensitivity and the touch response sensitivity, and the terminal first selects the touch according to the default touch data read frequency or the first touch response parameter. Controlling the reading frequency of the data to obtain the touch parameter of the touch operation on the touch screen, and matching the touch parameter with the touch sensing sensitivity, wherein the touch parameter may be a touch area, and the terminal touches the touch operation The control area is compared with the touch area threshold corresponding to the touch sensitivity. If the touch area reaches the touch area threshold, the touch parameter is determined to match the touch sensitivity, and then the touch response sensitivity is determined. The touch operation is responsive.

In some possible implementation manners, the second touch response parameter may include the read frequency of the touch data and the touch response sensitivity, and the terminal first acquires the touch operation on the touch screen according to the read frequency of the touch data. The touch parameter matches the default touch sensing sensitivity or the touch sensing sensitivity included in the first touch response parameter, and the touch parameter may be a touch area, and the terminal touches the touch operation. The control area is compared with the default touch sensing sensitivity or the touch area threshold corresponding to the touch sensing sensitivity of the first touch response parameter. If the touch area reaches the touch area threshold, the touch parameter and the default are determined. The touch sensing sensitivity or the touch sensing sensitivity included in the first touch response parameter is matched, and then the touch operation is performed according to the touch response sensitivity. Line response.

In some possible implementation manners, the second touch response parameter may include the touch sensing sensitivity, the read frequency of the touch data, and the touch response sensitivity, and the terminal first acquires the touch screen according to the read frequency of the touch data. The touch parameter of the touch operation matches the touch parameter with the touch sensitivity. The touch parameter can be the touch area, and the touch area of the touch operation corresponds to the touch sensitivity. The touch area threshold is compared. If the touch area reaches the touch area threshold, the touch parameter is determined to match the touch sensing sensitivity, and the touch response is responded to according to the touch response sensitivity.

In some possible implementation manners, the terminal obtains the pressing force of the touch operation when detecting the touch operation at the touch screen deformation position of the user, and the pressing force is generally greater, and the touch area of the touch operation on the touch screen is The larger the touch screen is, the easier it is to sense the touch operation. Therefore, the touch response parameter at the deformation position of the touch screen can be adjusted according to the pressing force.

Specifically, when the terminal detects that the pressing force of the touch operation is large, after the second touch response parameter is obtained, the value of the second touch response parameter is appropriately reduced to obtain the third touch response parameter. Then, the touch response parameter at the deformation position of the touch screen is set as the third touch response parameter.

Similarly, when the terminal detects that the pressing force of the touch operation is small, after obtaining the second touch response parameter, the value of the second touch response parameter is appropriately increased to obtain the fourth touch response parameter. Then, the touch response parameter at the deformation position of the touch screen is set as the fourth touch response parameter.

In some feasible implementation manners, when the terminal detects that the pressing force of the touch operation is large, after determining that the second deformation amplitude belongs to the second deformation amplitude threshold interval, first determining that the second deformation range threshold interval is slightly smaller The third deformation range threshold interval (for example, the deformation amplitude is one step smaller), and then the fifth touch response parameter corresponding to the third deformation amplitude threshold interval is obtained, and finally the touch response parameter at the touch screen deformation position is set as the fifth touch Control response parameters.

Similarly, when the terminal detects that the pressing force of the touch operation is small, after determining that the second deformation amplitude belongs to the second deformation amplitude threshold interval, it may first determine that the threshold interval is slightly larger than the second deformation amplitude threshold (for example, the deformation amplitude is one greater. The fourth deformation range threshold interval of the stage, and then the sixth touch response parameter corresponding to the fourth deformation amplitude threshold interval is obtained, and finally the touch response parameter at the touch screen deformation position is set as the sixth touch response parameter.

For example, suppose the terminal is pre-configured with three ranges of deformation amplitude threshold intervals [a1, a2), [a2, a3), [a3, a4), where a4>a3>a2>a1 and the deformation amplitude threshold interval [ A1, a2) and S1, T1 and R1 At least one corresponding, [a2, a3) corresponding to at least one of S2, T2 and R2, [a3, a4) corresponding to at least one of S3, T3 and R3, S3>S2>S1, T3>T2>T1, R3>R2>R1. When the terminal detects that the pressing force of the touch operation is large, after determining that the second deformation amplitude belongs to the interval [a2, a3), first determining the third deformation amplitude smaller than the deformation amplitude of the interval [a2, a3]. Threshold interval [a1, a2), and then acquiring a fifth touch response parameter corresponding to the interval [a1, a2) (including at least one of S1, T1, and R1), and finally setting the touch response parameter at the touch screen deformation position. The fifth touch response parameter.

Similarly, when the terminal detects that the pressing force of the touch operation is small, after determining that the second deformation amplitude belongs to the interval [a2, a3), first determining the fourth deformation level larger than the interval [a2, a3). The deformation amplitude threshold interval [a3, a4), and then obtain the sixth touch response parameter corresponding to the interval [a3, a4) (including at least one of S3, T3, and R3), and finally the touch response at the touch screen deformation position The parameter is set to the sixth touch response parameter. In the above manner, the touch response parameter at the deformation position of the touch screen can be adjusted according to the touch intensity of the user, which can prevent misoperations to a certain extent, and can improve the touch response efficiency to a certain extent.

Wherein, determining whether the pressing force of the touch operation is larger or smaller may be: the terminal is pre-set with a plurality of pressing force intervals, for example, three pressing force intervals, [f1, f2), [f2, f3), [f3, F4), where f4>f3>f2>f1. When the terminal obtains the pressing force f of the touch operation, the pressing force interval to which the f belongs is queried. If the pressing force interval to which f belongs is [f2, f3), it is determined that f belongs to the normal pressing force; if the pressing force interval to which f belongs For [f1, f2), it is determined that f belongs to a small pressing force; if f is a pressing force interval of [f3, f4), it is determined that f belongs to a large pressing force.

In some feasible implementation manners, when the deformation amplitude of the touch screen is changed from the first deformation amplitude to the second deformation amplitude, and the deformation amplitude threshold interval to which the second deformation amplitude belongs is detected to be greater than the deformation amplitude threshold interval to which the first deformation amplitude belongs However, at this time, the user's pressing force value for the touch operation of the touch screen is large, and the touch response parameter at the deformation position of the touch screen may not be changed.

Similarly, when the deformation amplitude of the touch screen is changed from the first deformation amplitude to the second deformation amplitude, and the deformation amplitude threshold interval to which the second deformation amplitude belongs is detected is smaller than the deformation amplitude threshold interval to which the first deformation amplitude belongs, but at this time, the user If the pressing force value of the touch operation of the touch screen is small, the touch response parameter at the deformation position of the touch screen may not be changed.

In some feasible implementation manners, the terminal presets a function of manually adjusting the touch response parameter, and the user may experience the touch response parameters corresponding to the preset N deformation amplitude threshold intervals according to the actual effect during the touch operation process. Make personal adjustments. Users can also adjust according to their own touch habits Touch response parameters of various areas of the touch screen, for example, the terminal acquires a target area selected by the user, and displays a default touch response parameter of the target area, and then receives a target touch response parameter set by the user for the target area, and defaults the target area. The touch response parameter is adjusted to the target touch response parameter, thereby allowing the user to participate in the setting of the touch response parameter, so as to ensure that the touch response parameter conforms to the user's usage habit as much as possible, and the touch response efficiency of the touch screen can be further improved.

In the embodiment of the present invention, the terminal first acquires the first deformation range of the deformation position and the deformation position of the touch screen, and then acquires and the second deformation when detecting that the deformation amplitude at the deformation position is changed from the first deformation range to the second deformation range. a second touch response parameter corresponding to the deformation amplitude, and the touch response parameter at the deformation position is set as a second touch response parameter, and finally responding to the touch operation on the touch screen according to the second touch response parameter, that is, according to The deformation amplitude can adjust the touch response parameter at the deformation position of the touch screen, thereby effectively improving the touch response capability at the deformation position of the touch screen, and improving the touch response efficiency of the touch screen.

FIG. 3 is a schematic structural diagram of a touch response device according to an embodiment of the present invention. The touch response device described in this embodiment includes:

The obtaining module 301 is configured to acquire a deformation position of the touch screen and a first deformation width at the deformation position.

The acquiring module 301 is further configured to acquire a first touch response parameter corresponding to the first deformation magnitude.

The setting module 302 is configured to set the touch response parameter at the deformation position to the first touch response parameter.

The response module 303 is configured to respond to the touch operation on the touch screen according to the first touch response parameter.

In some possible implementations, the first touch response parameter includes at least one of a touch sensing sensitivity, a read frequency of touch data, and a touch response sensitivity.

In some possible implementations, the acquiring module 301 is further configured to: when the deformation magnitude at the deformation position is changed from the first deformation magnitude to the second deformation magnitude, acquire the second deformation The second touch response parameter corresponding to the amplitude.

The setting module 302 is further configured to adjust the touch response parameter at the deformation position from the first touch response parameter to the second touch response parameter.

The response module 303 is further configured to respond to the touch operation on the touch screen according to the second touch response parameter.

In some embodiments, the first touch response parameter includes the touch sensing sensitivity and the touch response sensitivity, and the response module 303 includes:

The obtaining unit 3031 is configured to acquire a touch parameter of the touch operation on the touch screen.

The executing unit 3032 is configured to respond to the touch operation according to the touch response sensitivity when the touch parameter matches the touch sensing sensitivity.

In some possible implementations, the touch parameter includes a touch area.

In some possible implementation manners, the specific manner in which the acquiring module 301 acquires the first touch response parameter corresponding to the first deformation magnitude is:

The first deformation magnitude threshold interval to which the first deformation magnitude belongs is queried from the preset N deformation amplitude threshold intervals, and the N is a positive integer.

Obtaining a first touch response parameter corresponding to the first deformation magnitude threshold interval according to a correspondence between a preset deformation magnitude threshold interval and a touch response parameter.

In some possible implementations, the touch screen is a flexible touch screen.

In some implementations, the first touch response parameter includes the touch sensing sensitivity and the read frequency of the touch data, and the response module 303 includes:

The acquiring unit 3031 is configured to acquire a touch parameter of the touch operation on the touch screen according to the read frequency of the touch data.

The executing unit 3032 is configured to respond to the touch operation according to the preset touch response sensitivity when the touch parameter is matched with the touch sensing sensitivity.

In some implementations, the first touch response parameter includes a read frequency of the touch data and the touch response sensitivity, and the response module 303 includes:

The acquiring unit 3031 is configured to acquire a touch parameter of the touch operation on the touch screen according to the read frequency of the touch data.

The executing unit 3032 is configured to respond to the touch operation according to the touch response sensitivity when the touch parameter matches the preset touch sensing sensitivity.

In some embodiments, the first touch response parameter includes the touch sensing sensitivity, the read frequency of the touch data, and the touch response sensitivity, and the response module 303, the package include:

The acquiring unit 3031 is configured to acquire a touch parameter of the touch operation on the touch screen according to the read frequency of the touch data.

The executing unit 3032 is configured to respond to the touch operation according to the touch response sensitivity when the touch parameter matches the touch sensing sensitivity.

In the embodiment of the invention, the touch sensing sensitivity is a sensing sensitivity level to the touch area, and the minimum sensing threshold of the touch sensing sensitivity is greater than the minimum sensing area of the touch screen. The touch response sensitivity is a degree of adjustment of a corresponding parameter of the controlled object according to the unit touch distance.

It is to be understood that the functions of the functional modules and units of the touch response device of the present embodiment may be specifically implemented according to the method in the foregoing method embodiments. For the specific implementation process, reference may be made to the related description of the foregoing method embodiments, where Let me repeat.

In the embodiment of the present invention, the acquiring module 301 first acquires the first deformation range of the deformation position and the deformation position of the touch screen, and then acquires the first touch response parameter corresponding to the first deformation amplitude, and the setting module 302 touches the deformation position. The control response parameter is set as the first touch response parameter, and finally the response module 303 responds to the touch operation on the touch screen according to the first touch response parameter, that is, the touch response parameter at the touch screen deformation position can be adjusted, thereby effectively improving The touch response capability of the touch screen deformation position improves the touch response efficiency of the touch screen.

The present invention also provides a computer readable storage medium having instructions stored therein that, when executed on a computer, cause the computer to perform the touch response method described in the above method embodiments.

The present invention also provides a computer program product comprising instructions which, when run on a computer, cause the computer to perform the touch response method described in the above method embodiments.

It should be noted that, for the foregoing various method embodiments, for the sake of simple description, they are all expressed as a series of action combinations, but those skilled in the art should understand that the present invention is not limited by the described action sequence. Because certain steps may be performed in other sequences or concurrently in accordance with the present invention. In the following, those skilled in the art should also understand that the embodiments described in the specification are all preferred embodiments, and the actions and modules involved are not necessarily required by the present invention.

The steps in the method of the embodiment of the present invention may be sequentially adjusted, merged, and deleted according to actual needs. The modules and units in the device of the embodiment of the present invention may be combined, divided, and deleted according to actual needs.

A person skilled in the art can understand that all or part of the steps of the foregoing embodiments can be completed by a program to instruct related hardware. The program can be stored in a computer readable storage medium, and the storage medium can include: Flash disk, Read-Only Memory (ROM), Random Access Memory (RAM), disk or optical disk.

The above disclosure is only a preferred embodiment of the present invention, and of course, the scope of the present invention is not limited thereto, and those skilled in the art can understand all or part of the process of implementing the above embodiments, and according to the present invention. The equivalent changes required are still within the scope of the invention.

Claims (19)

1. A touch response method, comprising:

   Obtaining a deformation position of the touch screen and a first deformation width at the deformation position;

   Obtaining a first touch response parameter corresponding to the first deformation magnitude;

   Setting the touch response parameter at the deformation position to the first touch response parameter;

   Responding to the touch operation on the touch screen according to the first touch response parameter.
2. The method of claim 1 , wherein the first touch response parameter comprises at least one of a touch sensing sensitivity, a read frequency of touch data, and a touch response sensitivity.
3. The method according to claim 1 or 2, wherein the method further comprises:

   Obtaining a second touch response parameter corresponding to the second deformation magnitude when detecting that the deformation magnitude at the deformation position is changed from the first deformation magnitude to the second deformation magnitude;

   Adjusting the touch response parameter at the deformation position from the first touch response parameter to the second touch response parameter;

   Responding to the touch operation on the touch screen according to the second touch response parameter.
4. The method according to claim 2, wherein the first touch response parameter comprises the touch sensing sensitivity and the touch response sensitivity, and the Respond to touch operations on the touch screen, including:

   Obtaining a touch parameter of the touch operation on the touch screen;

   When the touch parameter matches the touch sensing sensitivity, the touch response is responded to according to the touch response sensitivity.
5. The method according to claim 4, wherein the touch parameter comprises a touch area.
6. The method according to claim 1, wherein the acquiring the first touch response parameter corresponding to the first deformation magnitude comprises:

   Querying, from the preset N deformation amplitude threshold intervals, a first deformation magnitude threshold interval to which the first deformation magnitude belongs, where N is a positive integer;

   Obtaining a first touch response parameter corresponding to the first deformation magnitude threshold interval according to a correspondence between a preset deformation magnitude threshold interval and a touch response parameter.
7. The method according to any one of claims 1 to 6, wherein the touch screen is a flexible touch screen.
8. The method according to any one of claims 1 to 6, wherein the touch sensing sensitivity is a sensitivity level to the touch area.
9. The method according to claim 8, wherein the minimum sensing threshold of the touch sensing sensitivity is greater than the minimum sensing area of the touch screen.
10. The method according to any one of claims 1 to 6, wherein the touch response sensitivity is a degree of adjustment of a corresponding parameter of the controlled object according to the unit touch distance.
11. A touch response device, comprising:

    An acquiring module, configured to acquire a deformation position of the touch screen and a first deformation width at the deformation position;

    The acquiring module is further configured to acquire a first touch response parameter corresponding to the first deformation magnitude;

    a setting module, configured to set a touch response parameter at the deformation position as the first touch response parameter;

    The response module is configured to respond to the touch operation on the touch screen according to the first touch response parameter.
12. The device according to claim 11, wherein the first touch response parameter comprises at least one of a touch sensing sensitivity, a read frequency of touch data, and a touch response sensitivity.
13. Device according to claim 11 or 12, characterized in that

    The acquiring module is further configured to: when detecting the deformation amplitude at the deformation position, by the first shape Obtaining a second touch response parameter corresponding to the second deformation magnitude when the variable amplitude becomes the second deformation amplitude;

    The setting module is further configured to adjust the touch response parameter at the deformation position from the first touch response parameter to the second touch response parameter;

    The response module is further configured to respond to the touch operation on the touch screen according to the second touch response parameter.
14. The device according to claim 12, wherein the first touch response parameter comprises the touch sensing sensitivity and the touch response sensitivity, and the response module comprises:

    An acquiring unit, configured to acquire a touch parameter of the touch operation on the touch screen;

    The execution unit is configured to respond to the touch operation according to the touch response sensitivity when the touch parameter matches the touch sensing sensitivity.
15. The device according to claim 14, wherein the touch parameter comprises a touch area.
16. The device according to claim 11, wherein the specific manner in which the acquiring module acquires the first touch response parameter corresponding to the first deformation magnitude is:

    Querying, from the preset N deformation amplitude threshold intervals, a first deformation magnitude threshold interval to which the first deformation magnitude belongs, where N is a positive integer;

    Obtaining a first touch response parameter corresponding to the first deformation magnitude threshold interval according to a correspondence between a preset deformation magnitude threshold interval and a touch response parameter.
17. The device according to any one of claims 11 to 16, wherein the touch screen is a flexible touch screen.
18. A computer readable storage medium having stored therein instructions for causing a computer to perform the touch response method of any one of claims 1 to 10 when the instructions are run on a computer.
19. A computer program product comprising instructions for causing a computer to perform the touch response method of any one of claims 1 to 10 when the instructions are run on a computer.

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