CN110187796B - Electronic equipment and data processing method - Google Patents

Abstract

The invention discloses an electronic device and a data processing method, wherein the electronic device comprises: the first sensor is used for acquiring distance sensing parameters; the second sensor is used for acquiring touch sensing parameters; the touch sensing area of the second sensor covers a specific area of the first surface of the electronic equipment; the first sensor can acquire distance sensing parameters in a space above the touch sensing area. Therefore, in the application, the distance sensor is arranged to sense the distance parameter of the space above the touch sensing area, so that the electronic equipment can realize input through the distance sensor besides touch input, input modes of the electronic equipment are enriched, and user experience is improved.

Description

Electronic equipment and data processing method

Technical Field

The invention relates to the technical field of terminals, in particular to electronic equipment and a data processing method.

Background

At present, a touch area is usually arranged in notebook equipment, but a user can only realize touch operation by touch input such as keyboard knocking or clicking or sliding in the touch area, so that the input mode is single, and the use experience of the user is poor.

Disclosure of Invention

In view of the foregoing, the present invention provides an electronic device and a data processing method.

The application provides an electronic device, including:

the first sensor is used for acquiring distance sensing parameters;

the second sensor is used for acquiring touch sensing parameters;

the touch sensing area of the second sensor covers a specific area of the first surface of the electronic equipment; the first sensor can acquire distance sensing parameters in a space above the touch sensing area.

In the electronic device, preferably, the first sensor is disposed at a position where a window is opened on a circuit board of the second sensor, and the first sensor collects distance sensing parameters of a space above the touch sensing area through the window.

In the electronic device, preferably, the window is disposed at a middle position of the first edge on the circuit board.

The electronic device preferably further includes:

the protection structure is laid on the surface of the second sensor and covers the first sensor;

wherein the first sensor is capable of acquiring the distance sensing parameter through the protective structure.

The electronic device preferably further includes:

and the processor is used for generating an operation instruction based on the distance sensing parameter and the touch sensing parameter, and responding to the operation instruction so as to execute a corresponding function.

Preferably, in the electronic device, the processor generates an operation instruction based on the distance sensing parameter and the touch sensing parameter, and specifically includes:

recognizing the gesture type of the operation body based on the distance sensing parameters;

if the gesture type is a first type, generating an operation instruction corresponding to the first type;

and if the gesture type is a second type, processing the touch sensing parameter by using the distance sensing parameter, and generating an operation instruction based on the processed touch sensing parameter.

The application also provides a data processing method, which comprises the following steps:

responding to the distance sensing parameters acquired by the first sensor, and acquiring touch sensing parameters acquired by the second sensor;

the touch sensing area of the second sensor covers a specific area of the first surface of the electronic equipment; the first sensor can acquire distance sensing parameters in a space above the touch sensing area;

generating an operation instruction based on the distance sensing parameter and the touch sensing parameter;

and responding to the operation instruction to execute a corresponding function.

In the method, preferably, the first sensor is disposed at an opening position of a circuit board of the second sensor;

generating an operation instruction based on the distance sensing parameter and the touch sensing parameter, wherein the operation instruction comprises:

recognizing the gesture type of the operation body based on the distance sensing parameters;

if the gesture type is a first type, generating an operation instruction corresponding to the first type;

and if the gesture type is the second type, processing the touch sensing parameters, and generating an operation instruction based on the processed touch sensing parameters.

Preferably, the method for processing the touch sensing parameter includes:

and setting parameters corresponding to the windowing position in the touch sensing parameters as target parameters.

In the method, preferably, the target parameter is related to a parameter corresponding to a position adjacent to the windowing in the touch sensing parameter.

According to the technical scheme, the electronic equipment and the data processing method disclosed by the application have the advantages that the first sensor capable of collecting the distance sensing parameters is arranged on the electronic equipment, so that the first sensor can collect the distance sensing parameters in the space above the touch sensing area of the second sensor. Therefore, in the application, the distance sensor is arranged to sense the distance parameter of the space above the touch sensing area, so that the electronic equipment can realize input through the distance sensor besides touch input, input modes of the electronic equipment are enriched, and user experience is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of an electronic device according to an embodiment of the present disclosure;

FIGS. 2-3 are diagrams illustrating examples of applications of embodiments of the present application;

fig. 4-7 are schematic structural diagrams of other embodiments of the present application, respectively;

fig. 8 is a flowchart illustrating an implementation of a data processing method according to a second embodiment of the present application;

fig. 9-11 are other exemplary diagrams of practical applications of the embodiments of the present application, respectively.

Detailed Description

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 only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, a schematic structural diagram of an electronic device according to an embodiment of the present disclosure is shown, where the electronic device may be a notebook or a computer with a touch function.

Specifically, the electronic device in this embodiment may include the following structure:

the first sensor 101 is used for collecting distance sensing parameters.

The first sensor 101 is a distance sensor, and can collect distance sensing parameters for an object in a specific space, and the distance sensing parameters can be used for detecting state parameters such as a distance, a position, and an attitude of the object.

And the second sensor 102 is used for acquiring touch sensing parameters.

The second sensor 102 is a touch sensor, and can collect touch sensing parameters on a touch sensing area, and the touch sensing parameters can be used for detecting parameters such as a position and a track of a touch operation.

In this embodiment, the touch sensing area of the second sensor 102 may cover a specific area on the first surface of the electronic device, and the specific area may be an area convenient for a user to perform a touch operation, for example, an area below the notebook keyboard in fig. 2 is the touch sensing area, and the user may perform a touch action on the touch sensing area to implement a touch input.

Based on this, the first sensor 101 in this embodiment is disposed at a position on the electronic device corresponding to the second sensor 102, so that the first sensor 101 can collect distance sensing parameters in a space above a touch sensing area, as shown in fig. 3, the touch sensing area of the second sensor 102 is a specific area below a keyboard of a notebook computer, and the first sensor 101 can collect distance sensing parameters of an object appearing on the space above the specific area.

According to the technical scheme, the electronic equipment provided by the embodiment of the application has the advantages that the first sensor capable of collecting the distance sensing parameters is arranged on the electronic equipment, so that the first sensor can collect the distance sensing parameters in the space above the touch sensing area of the second sensor. Therefore, in the embodiment, the distance sensor is arranged to sense the distance parameter of the space above the touch sensing area, so that the electronic equipment can realize input through the distance sensor in addition to touch input, input modes of the electronic equipment are enriched, and user experience is improved.

In one implementation, the first sensor 101 may be disposed at a position of the window 121 of the circuit board of the second sensor 102, as shown in fig. 4, the window is opened at a specific position in the circuit board of the second sensor 102, and the first sensor 101 is disposed at the position of the window 121, so that the first sensor 101 can collect distance sensing parameters of a space above the touch sensing area of the second sensor 102 through the window 121, and a situation that parameter collection cannot be achieved due to shielding of a housing or other structures of the electronic device is avoided.

Specifically, the position of the window 121 may be a middle position of the first edge on the circuit board of the second sensor 102, as shown in fig. 5.

The size, such as the length and the width, of the window 121 may be determined based on the actual size of the first sensor 101, so that the first sensor 101 can acquire the distance sensing parameters of the space above the touch sensing area of the second sensor 102 through the window 121.

In addition, in order to protect the first sensor 101 and the second sensor 102, in the embodiment, a protection structure 103 may be laid on the surface of the second sensor 102, as shown in fig. 6, the protection structure 103 covers the first sensor 101, and the material of the protection structure 103 can allow the first sensor 101 to be used for acquiring the penetration of the signal wave acquisition parameter of the distance sensing parameter, so that the first sensor 101 can acquire the distance sensing parameter of any object appearing in the space above the touch sensing area of the second sensor 102 through the protection structure 101.

Specifically, the protection structure 103 may be made of glass or mylar, which allows signal waves to be transmitted and received. Furthermore, a layer of ink layer can be laid on the protection structure 103, the ink layer does not affect the emission and the reception of signal waves, the color of the ink layer can be consistent with the color of the surface of the electronic device where the second sensor 102 is located on the electronic device, and the attractiveness of the electronic device is not affected.

In one implementation, the electronic device in this embodiment may further include the following structure, as shown in fig. 7:

after the distance sensing parameters are collected by the first sensor 101 and the touch sensing parameters are collected by the second sensor 102, the processor 104, such as a central Processing unit (cpu), may generate an operation instruction based on the distance sensing parameters and the touch sensing parameters, and respond to the operation instruction to execute a corresponding function.

That is to say, after the user performs an input operation through the first sensor 101 and the second sensor 102, the processor 104 may generate a corresponding operation instruction based on the distance sensing parameter and the touch sensing parameter, and provide a corresponding function for the user after responding to the operation instruction, for example, selecting a movie playing function or a shutdown function.

Specifically, in this embodiment, when the processor 104 generates the operation instruction based on the distance sensor and the touch sensing parameter, the following method may be specifically implemented:

firstly, recognizing a gesture type of the operation body based on the distance sensing parameter, for example, the processor 104 analyzes the distance sensing parameter through a recognition algorithm to recognize the gesture of the operation body, and further determines the gesture type of the operation body, such as a gesture of a single finger sliding of a user, a gesture of palm shaking, or a gesture of finger pressing;

if the gesture type of the operation body is a first type, generating an operation instruction corresponding to the first type, wherein the first type can be a preset functional gesture type, such as a gesture of sliding a single finger of a finger, a gesture of shaking a palm and the like;

and if the gesture type of the operation body is the second type, processing the touch sensing parameters by using the distance sensing parameters, and generating an operation instruction based on the processed touch sensing parameters. The second type may be other gesture types besides the functional gesture type, for example, a gesture in which the distance value of the operation body is lower than a certain threshold, or a gesture in which a finger is pressed down and the distance between the finger and the operation body is lower than a certain threshold, or a gesture in which a palm is pressed down, and the like.

Specifically, in this embodiment, the processor 104 processes the touch sensing parameter by using the distance sensing parameter, which means that a parameter corresponding to the position of the window where the first sensor is located in the touch sensing parameter is processed. That is, in the touch sensing parameters, there is a case where the touch sensing parameters are absent or suddenly changed at the window opening position due to the setting of the first sensor at the window opening, in this case, the processor 104 in this embodiment may correct the parameter of the position where the touch sensing parameter is missing or abrupt in the touch sensing area by using the distance sensing parameter, for example, setting a parameter corresponding to the position of the window in the touch sensing parameters as a target parameter, wherein the target parameter can be a preset parameter value or a parameter related to the corresponding position of the window in the touch sensing parameters, if the parameter at the position of the first sensor in the touch sensing parameters is set to be consistent with the parameter at the peripheral position of the first sensor, and then the processed touch sensing parameters are obtained, so that the accuracy of the touch sensing parameters is improved, and the higher touch input accuracy is realized.

It should be noted that, in this embodiment, when the processor 104 processes the touch sensing parameter with the distance sensing parameter, it may first perform a false touch prevention process on the touch input based on the distance sensing parameter, for example, determine whether the current operation body input is the touch input based on the parameters of the distance of the operation body, the area of the operation body, and the like in the distance sensing parameter, and only when the current operation body input belongs to the touch input, modify the touch sensing parameter based on the scheme in the foregoing, and generate a corresponding operation instruction based on the modified touch sensing parameter, so as to implement a corresponding function.

For example, if the distance of the operation body in the distance sensing parameters is smaller than a certain threshold and the area is larger than a corresponding threshold, the operation body is located in a touch sensing area and the area of the area exceeds a certain value, for example, a palm gesture is identified based on the distance sensing parameters, the palm distance is smaller than the certain threshold and the area is larger than the corresponding threshold, the touch is considered to be a non-input touch at this time, the touch sensing parameters are set to be 0 or null at this time, the touch input is considered not to be received (a subsequently generated operation instruction is a null instruction), and then the processed touch sensing parameters are obtained, so that the false touch processing is realized, and thus the higher accuracy of the touch input is realized.

Referring to fig. 8, an implementation flowchart of a data processing method provided in the second embodiment of the present application is shown, where the method may be applied to an electronic device having a distance sensor and a touch sensor, such as a notebook or a computer, and is mainly used for implementing multiple inputs of the electronic device.

Specifically, the method in this embodiment may include the following steps:

step 801: and responding to the distance sensing parameters acquired by the first sensor, and acquiring touch sensing parameters acquired by the second sensor.

The first sensor is a distance sensor, can acquire distance sensing parameters of an object in a specific space, and the distance sensing parameters can be used for detecting state parameters of the object such as distance, position and posture. The second sensor is a touch sensor and can acquire touch sensing parameters on a touch sensing area, and the touch sensing parameters can be used for detecting parameters such as positions, tracks and the like of touch operation.

In this embodiment, the touch sensing area of the second sensor covers a specific area of the first surface of the electronic device, such as a C-surface of a notebook computer, where the specific area may be an area convenient for a user to perform touch operation, and the first sensor is disposed at a position on the electronic device corresponding to the second sensor, so that the first sensor can collect distance sensing parameters in a space above the touch sensing area.

Step 802: and generating an operation instruction based on the distance sensing parameter and the touch sensing parameter.

Step 803: and responding to the operation instruction to execute the corresponding function.

That is to say, after the user performs an input operation through the first sensor and the second sensor, in this embodiment, a corresponding operation instruction may be generated based on the distance sensing parameter and the touch sensing parameter, and after responding to the operation instruction, a corresponding function, for example, a function of selecting a movie to play or turning off, is provided for the user.

According to the data processing method, the first sensor capable of collecting the distance sensing parameters is arranged on the electronic device, so that the first sensor can collect the distance sensing parameters in the space above the touch sensing area of the second sensor, and further, the operation instruction can be generated based on the distance sensing parameters and the touch sensing parameters, and the corresponding function can be realized. Therefore, in the embodiment, the distance sensor is arranged to sense the distance parameter of the space above the touch sensing area, so that the electronic equipment can realize input through the distance sensor in addition to touch input, input modes of the electronic equipment are enriched, and user experience is improved.

In an implementation manner, the first sensor may be disposed at a position where a window is opened on a circuit board of the second sensor, and referring to the structure in fig. 4, correspondingly, in this embodiment, when the step 802 generates the operation instruction based on the distance sensing parameter and the touch sensing parameter, the following manner may be specifically implemented:

firstly, recognizing the gesture type of an operation body based on distance sensing parameters, for example, analyzing the distance sensing parameters through a recognition algorithm to recognize the gesture of the operation body, and further determining the gesture type of the operation body, such as a gesture of sliding of a single finger of a user, a gesture of shaking a palm or a gesture of pressing down the finger;

if the gesture type of the operation body is a first type, generating an operation instruction corresponding to the first type, wherein the first type can be a preset functional gesture type, such as a gesture of sliding a single finger of a finger, a gesture of shaking a palm and the like;

and if the gesture type of the operation body is the second type, processing the touch sensing parameters by using the distance sensing parameters, and generating an operation instruction based on the processed touch sensing parameters. The second type may be other gesture types besides the functional gesture type, for example, a gesture in which the distance value of the operation body is lower than a certain threshold, or a gesture in which a finger is pressed down and the distance between the finger and the operation body is lower than a certain threshold, or a gesture in which a palm is pressed down, and the like.

Specifically, in this embodiment, the processing of the touch sensing parameter by the distance sensing parameter refers to processing a parameter corresponding to the position of the window where the first sensor is located in the touch sensing parameter. That is, in the touch sensing parameters, there is a case where the touch sensing parameters are absent or suddenly changed at the window opening position due to the setting of the first sensor at the window opening, in this case, in the embodiment, the distance sensing parameter may be used to correct the parameter of the position where the touch sensing parameter is missing or suddenly changed in the touch sensing area, for example, setting a parameter corresponding to the position of the window in the touch sensing parameters as a target parameter, wherein the target parameter can be a preset parameter value or a parameter related to the corresponding position of the window in the touch sensing parameters, if the parameter at the position of the first sensor in the touch sensing parameters is set to be consistent with the parameter at the peripheral position of the first sensor, and then the processed touch sensing parameters are obtained, so that the accuracy of the touch sensing parameters is improved, and the higher touch input accuracy is realized.

It should be noted that, in the embodiment, when the touch sensing parameter is processed by using the distance sensing parameter, the touch input may be first processed based on the distance sensing parameter to prevent false touch, for example, whether the current operation body input is the touch input is determined based on the parameters of the distance of the operation body, the area of the operation body, and the like in the distance sensing parameter, only when the current operation body input belongs to the touch input, the touch sensing parameter is corrected based on the scheme in the foregoing, and a corresponding operation instruction is generated based on the corrected touch sensing parameter to implement a corresponding function, and if the current operation body input does not belong to the touch input, then the response to the touch sensing parameter is not needed, the operation instruction is not generated, or the operation instruction is null, and the operation of the operation body is not responded.

For example, if the distance of the operation body in the distance sensing parameters is smaller than a certain threshold and the area is larger than a corresponding threshold, the operation body is located in a touch sensing area and the area of the area exceeds a certain value, if a palm gesture is identified based on the distance sensing parameters, the palm distance is smaller than the certain threshold and the area is larger than the corresponding threshold, the touch is considered to be a non-input touch, the touch sensing parameters are set to be 0 or null, the touch input is not received (a subsequently generated operation instruction is a null instruction), and then the processed touch sensing parameters are obtained, so that the anti-false touch processing is realized, and thus the higher accuracy of the touch input is realized.

The following takes a notebook with a touch area as an example to illustrate the technical solution in this embodiment:

in order to implement touch input and non-contact gesture input simultaneously on the notebook with the C-side keyboard, in this embodiment, a windowing area is provided on the Circuit board pcb (printed Circuit board) of the touch pad on the C-side, and the distance sensor is integrated with the windowing area, as shown in fig. 9.

The distance sensor can directly transmit and receive signals through the glass or mylar material in the touchable windowing area. In order to ensure consistency, as shown in fig. 9, the windowed area may be coated with ink of the same color as that of the C-plane, so that the structure of the touchpad has a laminated structure, wherein the ink material is selected to be a material that can transmit the signal wave emitting light in the same frequency band.

Based on above scheme, because touchpad windowing breaks empty the back, touchpad can have the detection dead zone problem, in order to solve this problem, can get rid of touchpad because the dead zone problem that the PCB windowing exists through following mode of handling touch-sensitive parameter in this embodiment, specifically as follows:

in combination with the data flow diagram in the hardware architecture of the notebook computer in fig. 10, in this embodiment, a signal of the distance sensor may be used as a touchpad correction signal, when a finger of a user touches the distance sensor and it is determined that the user is not performing gesture input at this time, the distance sensor transmits the signal to the touchpad, and the touchpad may compensate missing data in touch sensing parameters acquired by a capacitance sensor in the touchpad by using data of X, Y, Z in sensing parameters of the distance sensor, so that a signal of a whole touchpad detection area is completed and a response is performed after the signal is transmitted to the CPU, and there is no dead zone, where a specific flow is shown in fig. 11:

after starting, firstly judging whether a finger touches the touchpad, if so, continuously detecting whether a dead zone exists, and judging whether the parameters of the distance sensor are in an activated state when the dead zone exists, if so, obtaining data Xp, Yp and Zp in the distance sensing parameters, and correcting the data on the dead zone X, Y, Z in the data of the touchpad to obtain the output parameters of the touchpad: x ', Y ', Z '.

Therefore, a new way of integrating the distance sensor can be provided in the embodiment, and the parameter integrity of the intelligent touchpad can be maintained.

Specifically, through the notebook in this embodiment, the user can not only be suitable for the original touchpad function, but also can realize functions such as non-contact operation and intelligent monitoring, and improve user experience. Secondly, the detection position of the distance sensor is more in line with the user scene, so that the recognition efficiency can be improved, and the user experience can be improved. Further, in the embodiment, the dead zone problem after the touchpad is windowed is solved by modifying the touch sensing parameter.

The embodiments in the present description are described in a progressive manner, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other. The device disclosed by the embodiment corresponds to the method disclosed by the embodiment, so that the description is simple, and the relevant points can be referred to the method part for description.

Those of skill would further appreciate that the various illustrative elements and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware, computer software, or combinations of both, and that the various illustrative components and steps have been described above generally in terms of their functionality in order to clearly illustrate this interchangeability of hardware and software. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the implementation. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present invention.

The steps of a method or algorithm described in connection with the embodiments disclosed herein may be embodied directly in hardware, in a software module executed by a processor, or in a combination of the two. A software module may reside in Random Access Memory (RAM), memory, Read Only Memory (ROM), electrically programmable ROM, electrically erasable programmable ROM, registers, hard disk, a removable disk, a CD-ROM, or any other form of storage medium known in the art.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (2)

1. An electronic device, the electronic device being a notebook with a touch function, the electronic device comprising:

the first sensor is used for acquiring distance sensing parameters;

the second sensor is used for acquiring touch sensing parameters;

the touch sensing area of the second sensor covers a specific area of the first surface of the electronic equipment; the first sensor can acquire distance sensing parameters in a space above the touch sensing area; the touch sensing area of the second sensor is a specific area below the notebook keyboard;

the first sensor is arranged at the position of a window of a circuit board of the second sensor, the window is arranged at the middle position of a first edge on the circuit board, and the first sensor collects distance sensing parameters of a space above the touch sensing area through the window;

the processor is used for generating an operation instruction based on the distance sensing parameter and the touch sensing parameter, and responding to the operation instruction so as to execute a corresponding function;

the processor generates an operation instruction based on the distance sensing parameter and the touch sensing parameter, and specifically comprises the following steps:

recognizing gesture types of the operation body based on the distance sensing parameters, wherein the gesture types comprise a first type and a second type;

if the gesture type is a first type, indicating that the operation body is performing gesture input through the first sensor, and generating an operation instruction corresponding to the first type;

if the gesture type is a second type, the gesture type indicates that the operating body performs touch input operation through the second sensor, the touch sensing parameters are processed according to the distance sensing parameters, an operation instruction is generated based on the processed touch sensing parameters, and the processing of the touch sensing parameters includes: setting parameters corresponding to the windowing positions in the touch sensing parameters as target parameters, wherein the target parameters are related to parameters corresponding to the windowing adjacent positions in the touch sensing parameters;

the electronic device further includes: the protection structure is laid on the surface of the second sensor and covers the first sensor;

the ink layer is laid on the surface of the protection structure, so that the color of the ink layer is consistent with that of the surface of the electronic equipment where the second sensor is located;

wherein the first sensor is capable of acquiring the distance sensing parameter through the protective structure and the ink layer.

2. A data processing method is applied to electronic equipment, the electronic equipment is a notebook with a touch function, and the data processing method comprises the following steps:

responding to the distance sensing parameters acquired by the first sensor, and acquiring touch sensing parameters acquired by the second sensor;

the touch sensing area of the second sensor covers a specific area of the first surface of the electronic equipment; the first sensor can acquire distance sensing parameters in a space above the touch sensing area; the touch sensing area of the second sensor is a specific area below the notebook keyboard;

generating an operation instruction based on the distance sensing parameter and the touch sensing parameter;

responding to the operation instruction to execute a corresponding function;

the first sensor is arranged at the position of the opening window of the circuit board of the second sensor;

generating an operation instruction based on the distance sensing parameter and the touch sensing parameter, wherein the operation instruction comprises:

recognizing gesture types of the operation body based on the distance sensing parameters, wherein the gesture types comprise a first type and a second type;

if the gesture type is a first type, indicating that the operation body is performing gesture input through the first sensor, and generating an operation instruction corresponding to the first type;

if the gesture type is a second type, the gesture type indicates that the operating body performs touch input operation through the second sensor, the touch sensing parameters are processed, an operation instruction is generated based on the processed touch sensing parameters, and the processing of the touch sensing parameters includes: setting parameters corresponding to the windowing positions in the touch sensing parameters as target parameters, wherein the target parameters are related to parameters corresponding to the windowing adjacent positions in the touch sensing parameters;

the electronic device further includes: the protection structure is laid on the surface of the second sensor and covers the first sensor;

the ink layer is laid on the surface of the protection structure, so that the color of the ink layer is consistent with that of the surface of the electronic equipment where the second sensor is located;

wherein the first sensor is capable of acquiring the distance sensing parameter through the protective structure and the ink layer.

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