CN105573538B - Sliding broken line compensation method and electronic equipment - Google Patents

Abstract

The invention discloses a sliding disconnection compensation method and electronic equipment, wherein the method comprises the following steps: detecting the nth sliding speed of the nth sliding track end at the first moment; when the nth sliding speed is larger than a first speed threshold, detecting the nth sliding direction corresponding to the nth sliding speed, the (n + 1) th sliding speed at the starting end of the (n + 1) th sliding track and the (n + 1) th sliding direction; when the difference value between the nth sliding speed and the (n + 1) th sliding speed is smaller than a second speed threshold value, and the angle formed by the nth sliding direction and the (n + 1) th sliding direction is smaller than an angle threshold value, connecting the nth sliding track and the (n + 1) th sliding track to form a new sliding track; responding to the sliding operation of the user according to the new sliding track; the nth sliding track and the (n + 1) th sliding track are formed by identifying sliding operation of a user by the electronic equipment; and n is an integer not less than 1.

Description

Sliding broken line compensation method and electronic equipment

Technical Field

The present invention relates to information processing in the field of electronic devices, and in particular, to a sliding disconnection compensation method and an electronic device.

Background

Along with the development of the electronic information industry, the application of electronic equipment is more and more extensive, and the interactive screen is deeply favored by users because the interactive screen can provide a good graphical interactive interface; however, in the use process of the world, the problem of sliding disconnection can occur when the user slides to shake and water and other substances appear on the interactive screen, so that misjudgment and misoperation of the electronic equipment are caused.

The sliding disconnection is one sliding of the user, and the electronic equipment recognizes two or more sliding with power failure.

Disclosure of Invention

In view of this, embodiments of the present invention are directed to a method for compensating a sliding breakpoint and an electronic device, so as to implement compensation of the sliding breakpoint and reduce a misjudgment rate of the electronic device.

In order to achieve the purpose, the technical scheme of the invention is realized as follows:

the first aspect of the embodiments of the present invention provides a sliding disconnection compensation method, including:

detecting the nth sliding speed of the nth sliding track end at the first moment;

when the nth sliding speed is larger than a first speed threshold, detecting the nth sliding direction corresponding to the nth sliding speed, the (n + 1) th sliding speed at the starting end of the (n + 1) th sliding track and the (n + 1) th sliding direction;

when the difference value between the nth sliding speed and the (n + 1) th sliding speed is smaller than a second speed threshold value, and the angle formed by the nth sliding direction and the (n + 1) th sliding direction is smaller than an angle threshold value, connecting the nth sliding track and the (n + 1) th sliding track to form a new sliding track;

responding to the sliding operation of the user according to the new sliding track;

the nth sliding track and the (n + 1) th sliding track are formed by identifying sliding operation of a user by the electronic equipment;

and n is an integer not less than 1.

Preferably, the first and second electrodes are formed of a metal,

the method further comprises the following steps:

recording the sliding speed of the designated position of the sliding track formed by the sliding operation of the user before the first moment to form a history record;

determining the first rate threshold according to the history.

Preferably, the first and second electrodes are formed of a metal,

the method further comprises the following steps:

detecting the acceleration of the end of the nth sliding track;

and determining the second speed threshold according to the acceleration and the distance between the end of the nth sliding track and the start of the (n + 1) th sliding track.

Preferably, the first and second electrodes are formed of a metal,

the method further comprises the following steps:

detecting the distance between the end of the nth sliding track and the start of the (n + 1) th sliding track;

the detecting the nth sliding speed of the nth sliding track end at the first moment comprises the following steps:

detecting an nth sliding speed at the end of the nth sliding track when the distance between the nth sliding track and the (n + 1) th sliding track is smaller than a distance threshold.

Preferably, the first and second electrodes are formed of a metal,

the method is applied to the sliding breakpoint compensation mode of the electronic equipment;

prior to the first time, the method further comprises:

receiving a user input;

entering a sliding breakpoint compensation mode in response to the user input.

The second aspect of the embodiments of the present invention further provides an electronic device, where the electronic device includes an interactive screen that receives a sliding operation;

the interactive screen is used for detecting the nth sliding speed at the tail end of the nth sliding track at the first moment;

the interactive screen is further used for detecting an nth sliding direction corresponding to the nth sliding speed, an nth +1 sliding speed at the start end of an nth +1 sliding track and an nth +1 sliding direction when the nth sliding speed is greater than a first speed threshold;

the electronic device further includes:

a forming unit, configured to connect the nth sliding track and the n +1 th sliding track to form a new sliding track when a difference between the nth sliding speed and the n +1 th sliding speed is smaller than a second speed threshold and an angle formed by the nth sliding direction and the n +1 th sliding direction is smaller than an angle threshold;

the response unit is used for responding to the sliding operation of the user according to the new sliding track;

the nth sliding track and the (n + 1) th sliding track are formed by identifying sliding operation of a user by the electronic equipment;

and n is an integer not less than 1.

Preferably, the first and second electrodes are formed of a metal,

the electronic device further includes:

the recording unit is used for recording the sliding speed of the specified position of the sliding track formed by the sliding operation of the user before the first moment to form a history record;

a first determining unit, configured to determine the first rate threshold according to the history.

Preferably, the first and second electrodes are formed of a metal,

the interactive screen is further used for detecting the acceleration of the tail end of the nth sliding track;

the electronic device further includes:

a second determining unit, configured to determine the second rate threshold according to the acceleration and a distance between the end of the nth sliding track and the start of the (n + 1) th sliding track.

Preferably, the first and second electrodes are formed of a metal,

the interactive screen is further used for detecting the distance between the tail end of the nth sliding track and the start end of the (n + 1) th sliding track;

the interactive screen is specifically configured to detect an nth sliding rate at the end of an nth sliding track when the distance between the nth sliding track and the (n + 1) th sliding track is smaller than a distance threshold.

Preferably, the first and second electrodes are formed of a metal,

the method is applied to the sliding breakpoint compensation mode of the electronic equipment;

the electronic device further includes:

a receiving unit for receiving a user input before the first time;

the response unit is further used for responding to the user input to enter a sliding breakpoint compensation mode.

According to the sliding breakpoint compensation method and the electronic device, when the nth sliding speed at the nth sliding tail end, the nth +1 sliding speed at the n +1 th sliding track start end and the n +1 th sliding direction meet the preset conditions, the two sliding tracks are considered to be from one sliding of a user, the electronic device possibly caused by sliding jitter and other factors is identified as two sliding, the nth sliding track and the n +1 th sliding track are connected and corrected into a new sliding track, and response is carried out according to the new sliding track, so that the misjudgment rate of the electronic device can be reduced, the identification accuracy of the electronic device on the sliding of the user is improved, and the using satisfaction degree of the user is improved.

Drawings

Fig. 1 is a schematic flow chart of a first sliding disconnection compensation method according to an embodiment of the present invention;

FIG. 2 is a schematic diagram illustrating the effect of the sliding wire breakage according to the embodiment of the present invention;

fig. 3 is a schematic flow chart of a second sliding disconnection compensation method according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a first electronic device according to an embodiment of the invention;

fig. 5 is a schematic structural diagram of a second electronic device according to an embodiment of the invention.

Detailed Description

The technical solution of the present invention is further described in detail with reference to the drawings and the specific embodiments of the specification.

The first embodiment is as follows:

as shown in fig. 1, the present embodiment provides a sliding disconnection compensation method, which includes:

step S110: detecting the nth sliding speed of the nth sliding track end at the first moment;

step S120: when the nth sliding speed is larger than a first speed threshold, detecting the nth sliding direction corresponding to the nth sliding speed, the (n + 1) th sliding speed at the starting end of the (n + 1) th sliding track and the (n + 1) th sliding direction;

step S130: when the difference value between the nth sliding speed and the (n + 1) th sliding speed is smaller than a second speed threshold value, and the angle formed by the nth sliding direction and the (n + 1) th sliding direction is smaller than an angle threshold value, connecting the nth sliding track and the (n + 1) th sliding track to form a new sliding track;

step S140: responding to the sliding operation of the user according to the new sliding track;

the nth sliding track and the (n + 1) th sliding track are formed by identifying sliding operation of a user by the electronic equipment;

and n is an integer not less than 1.

The method of the embodiment is applied to electronic equipment with an interactive screen, wherein the interactive screen can be a contact touch screen or a suspension touch screen. The touch screen detects a user operation by a user's finger touching the screen. The floating touch screen can detect user operation within a certain distance from the screen for a user.

When the finger of the user floats away from the contact touch screen at the middle position of one sliding because of the too fast sliding, or the friction resistance is too large because of the dry weather, so that the finger shakes to form the middle position of one sliding and floats away from the contact touch screen, or the magazine such as water appears on the contact touch screen, so that the finger of the user does not directly contact the screen at the middle position of one sliding, or the user slides, the suspension touch screen is shielded by the middle position of one sliding because of the water, sundries and the like, so that the suspension touch screen is identified as a scene of two sliding, the method can be used for performing sliding disconnection compensation to correct the identification of the electronic equipment and avoid misoperation.

The end of the nth sliding track and the beginning of the (n + 1) th sliding track recognized by the electronic device should be two ends of the two sliding tracks which are close to each other. The starting end of the sliding track corresponds to the starting end of the sliding track set by the electronic equipment; the tail end of the sliding track corresponds to the middle point end of the sliding track identified by the electronic equipment.

In fig. 2, a solid arrow Id1 represents an nth sliding track recognized by the electronic device, and a solid arrow Id2 represents an n +1 th sliding track recognized by the electronic device; the arrow position of the solid arrow is the end of the slide track, the start position of the solid arrow is the start of the slide track, and it is obvious that the end of the nth slide track and the start of the (n + 1) th slide track are close to each other.

The Id1 and the Id2 are identification information of a sliding track marked on the electronic device, specifically, identification serial numbers and the like, and if the Id1 and the Id2 are identification serial numbers, a difference value between the Id1 and the Id2 is 1.

A sliding speed at the end of the nth sliding track indicated by a broken-line arrow V1, an nth sliding speed indicated by the length of the broken-line arrow, and an nth sliding direction indicated by the direction in which the broken-line arrow points in fig. 2; the sliding speed at the start of the (n + 1) th sliding locus indicated by a broken-line arrow V2, the (n + 1) th sliding speed indicated by the length of the broken-line arrow, and the (n + 1) th sliding direction indicated by the direction of the broken-line arrow.

The first moment is the current moment when the user operates the electronic equipment, the user slides once in the middle position of the electronic equipment, the sliding speed reaches a certain speed after accelerating from the starting point, and the speed is usually high relative to the starting end and the tail end of the sliding; it is first determined whether the sliding speed at the end of the nth sliding track is greater than the first speed threshold in step S110. And the difference between the sliding speed and the sliding direction at two adjacent positions of the first sliding will not be too large, so it will be further determined in step S130 whether the difference between the nth sliding speed and the (n + 1) th sliding speed is small enough, for example, smaller than the second speed threshold; and whether the angle formed by the two sliding directions is small enough, if the angle is smaller than the angle threshold value; if both of these requirements are met, there is a high probability that the electronic device has a false judgment, and a single sliding operation of the user is recognized as a double sliding operation, so in step S130 of this embodiment, the end of the nth sliding track is connected to the beginning of the (n + 1) th sliding track to form a completely new sliding track, and the user sliding is responded according to this sliding track in step S140, so that the false judgment and false operation probability of the electronic device can be reduced, and the recognition and response accuracy and the user using satisfaction can be improved.

The n sliding track and the n +1 sliding track are two continuous sliding tracks identified by the electronic equipment; usually, the nth sliding track is recognized first, and only the (n + 1) th sliding track is recognized next.

When the breakpoint between the nth sliding track and the (n + 1) th sliding track is compensated to form a new sliding track in the step S130, the sliding speed and the sliding direction at the breakpoint can be predicted according to the characteristics that the user cannot slide suddenly and according to the nth sliding speed and the nth sliding direction, so as to form a smooth new sliding track to be closer to the real sliding track formed by the user sliding operation.

In a specific implementation process, while referring to the nth sliding direction and the nth sliding speed, the nth +1 sliding direction and the nth +1 sliding speed can be simultaneously referred to jointly predict the sliding direction and the sliding speed at each position of the breakpoint position, so as to form a real sliding track which is closer to the sliding operation of the user.

Preferably, the first and second electrodes are formed of a metal,

as shown in fig. 3, the method further comprises:

step S101: recording the sliding speed of the designated position of the sliding track formed by the sliding operation of the user before the first moment to form a history record;

step S102: determining the first rate threshold according to the history.

Due to different operation habits of different users, specifically different sliding speeds, in a specific implementation, the first rate threshold may be an empirical value statistically determined by a manufacturer according to big data of the sliding speeds of most users, and the empirical value is directly stored in the electronic device as the first rate threshold; in the embodiment, the first rate threshold value suitable for the user is determined according to the operation habits of different users, so as to further improve the accuracy rate.

The specified position is preferably an intermediate position of multiple sliding of the user; typically the intermediate position may be a position between the first a% and b% of a single sliding trajectory.

A is less than b, and a and b are both positive numbers less than 100;

specifically, the value range of a is 5 to 15, specifically 10, the value range of b is 75 to 95, specifically 90.

In the case where the history is formed of the sliding speed at the designated position of the sliding track of M sliding operations before the first time, or the sliding speed at the designated position of the sliding track of all sliding operations in a period of time before the first time, the specific implementation method is many, and the description is not repeated here.

As shown in fig. 3, the method further comprises:

step S103: detecting the acceleration of the end of the nth sliding track;

step S104: and determining the second speed threshold according to the acceleration and the distance between the end of the nth sliding track and the start of the (n + 1) th sliding track.

Obviously, the second speed threshold may also be an empirical value statistically formed by a manufacturer according to data of a plurality of users, but in the process of a break point occurring in each specific sliding, the second speed threshold is related to the current sliding speed of the user and the distance between the break points, so in this embodiment, in order to further improve the accuracy, the second speed threshold is dynamically determined according to the distance between the two sliding tracks and the acceleration at the end of the nth sliding track.

In a specific implementation process, in order to further improve the accuracy, the step S103 may specifically further include determining the second rate threshold value by using an acceleration at the end of the nth sliding track, an acceleration at the start of the (n + 1) th sliding track, and a distance between the nth sliding track and the (n + 1) th sliding track. Specifically, the second rate threshold is determined according to the average value of the acceleration at the end of the nth sliding track and the acceleration at the start of the (n + 1) th sliding track and the distance.

The method further comprises the following steps:

detecting the distance between the end of the nth sliding track and the start of the (n + 1) th sliding track;

the detecting the nth sliding speed of the nth sliding track end at the first moment comprises the following steps:

detecting an nth sliding speed at the end of the nth sliding track when the distance between the nth sliding track and the (n + 1) th sliding track is smaller than a distance threshold.

Further combining the above technical solutions, when the two sliding distances are large, it may be that the user performs two sliding operations quickly, and at this time, the distance between the end of the nth sliding track and the start of the (n + 1) th sliding track may be large, and obviously, this situation may exclude the erroneous determination of the electronic device caused by one sliding operation, so in this embodiment, in order to reduce the erroneous operation of the electronic device sliding breakpoint compensation and the meaningless operation of the electronic device, before detecting the nth sliding rate, the line performs the distance detection and determination.

The distance threshold may be determined according to parameters such as the size of the electronic device and the user sliding operation record, and will not be described in detail herein.

In addition, the method is applied to the sliding breakpoint compensation mode of the electronic equipment;

prior to the first time, the method further comprises:

receiving a user input;

entering a sliding breakpoint compensation mode in response to the user input.

The user can control whether the electronic equipment is in the sliding breakpoint compensation mode or not according to the current use environment of the electronic equipment to control whether the electronic equipment executes the sliding breakpoint compensation or not, and the control degree of the user is increased.

In summary, the present embodiment provides a method for compensating a sliding breakpoint, which can effectively reduce the probability that the electronic device is erroneously determined to slide for multiple times by the sliding operation of the user under various conditions, and improve the recognition accuracy, response accuracy and user usage satisfaction of the electronic device for the sliding operation of the user.

Example two:

as shown in fig. 4, the present embodiment provides an electronic device including an interactive screen 110 that receives a slide operation;

the interactive screen 110 is configured to detect an nth sliding rate at an end of an nth sliding track at a first time;

the interactive screen 110 is further configured to detect an nth sliding direction corresponding to the nth sliding speed, an nth +1 sliding speed at the start of the nth +1 sliding track, and an nth +1 sliding direction when the nth sliding speed is greater than a first speed threshold;

the electronic device further includes:

a forming unit 120, configured to connect the nth sliding track and the n +1 th sliding track to form a new sliding track when a difference between the nth sliding speed and the n +1 th sliding speed is smaller than a second speed threshold and an angle formed by the nth sliding direction and the n +1 th sliding direction is smaller than an angle threshold;

a response unit 130, configured to respond to a user sliding operation according to the new sliding trajectory;

the nth sliding track and the (n + 1) th sliding track are formed by identifying sliding operation of a user by the electronic equipment;

and n is an integer not less than 1.

The interactive screen may be a touch screen or a floating touch screen as described in the first embodiment; the interactive screen comprises a sensor for detecting a user operation gesture and a display for displaying; the display can be a display structure such as a liquid crystal display, an Organic Light Emitting Diode (OLED) display or an electronic ink display; the sensor can be a sensor such as a capacitance detection matrix or a camera and the like which is used for collecting user operation gestures.

The specific structures of the forming unit 120 and the responding unit 130 may each include a processor and a storage medium; the storage medium is connected with the processor through an internal communication structure of the electronic equipment such as a bus. The storage medium has stored thereon executable instructions, and the processor performs the functions of the forming unit 120 and/or the responding unit 130 by reading the executable instructions on the storage medium.

The processor can be an application processor AP, a central processing unit CPU, a microprocessor MCU, a digital signal processor DSP or a programmable array PLC of electronic equipment and other electronic components with processing functions.

In a specific implementation, the response unit is different according to different operations executed by the electronic device instructed by the user sliding operation, and specifically, when the user sliding operation is used to move a position of an icon displayed on the interactive screen, the response unit further includes the interactive screen; if the user sliding operation is used for controlling the electronic device to play audio, the response unit further includes an audio player, a specific speaker and other specific structures.

As shown in fig. 5, preferably, the electronic device further includes:

a recording unit 140, configured to record, before the first time, a sliding rate of a specified position of a sliding track formed by a sliding operation of a user, so as to form a history record;

a first determining unit 150, configured to determine the first rate threshold according to the history.

The specific structure of the recording unit 140 at least includes a storage medium, specifically, a storage medium such as a RAM, a ROM, or a Flash.

The specific structure of the first determination unit may also be a processor and a storage medium; the first determining unit 150, the forming unit 120 and the responding unit 140 are integrated with the same processor or respectively correspond to different processors. The structure of the processor can be referred to the corresponding parts of the embodiment, and is not described in detail here.

Further, the interactive screen 110 is configured to detect an acceleration at the end of the nth sliding track;

the electronic device further includes:

a second determining unit, configured to determine the second rate threshold according to the acceleration and a distance between the end of the nth sliding track and the start of the (n + 1) th sliding track.

The specific structure of the second determination unit may include a calculator or a processor having a calculation function; the calculator or the processor with the calculation function can calculate the acceleration and the distance according to a preset algorithm, and further calculate to obtain the second speed threshold. In a specific implementation, the second determining unit may also include a storage medium and a processor having a query function, where the storage medium stores a list of second speed thresholds indexed by the acceleration and the distance, and the second determining unit may specifically determine the second speed threshold by querying the query.

The interactive screen 110 is configured to detect a distance between an end of the nth sliding track and a start of the (n + 1) th sliding track; the interactive screen is specifically configured to detect an nth sliding rate at the end of an nth sliding track when the distance between the nth sliding track and the (n + 1) th sliding track is smaller than a distance threshold.

When the interactive screen 110 is a contact interactive screen, the interactive screen may be a capacitive screen or a resistive screen, and the detection of the touch points is performed on the sliding through a capacitive matrix or a resistive screen, at this time, the interactive screen 110 may detect the touch timing and the touch coordinates of the touch points (the touch points are the touched touch points), calculate the distance according to detection signals such as the touch coordinates between two adjacent touch points, and further detect the nth sliding speed through judgment; in a specific implementation, the interactive screen may also detect the distance and the nth sliding rate synchronously to improve a response speed, but in this embodiment, it is preferable to detect the distance first and then detect the nth sliding rate, so that a processing amount of the electronic device can be reduced; and the processing speed of the existing electronic equipment is quite high, and the influence degree on the corresponding speed is small.

Further, the method is applied to the sliding breakpoint compensation mode of the electronic equipment;

the electronic device further includes:

a receiving unit for receiving a user input before the first time;

the response unit is further used for responding to the user input to enter a sliding breakpoint compensation mode.

The specific structure of the receiving unit may include a human-computer interaction interface, such as a key on the electronic device. The receiving unit may also be the interactive screen.

The specific structure of the response unit can be referred to the above corresponding parts of this embodiment, and is not described herein again.

In summary, this embodiment provides an electronic device, which can be used to implement any of the technical solutions in the first embodiment of the method to provide implementation hardware, and can be used to implement any of the technical solutions in the first embodiment, and the method and the device can also improve the accuracy of the electronic device on user sliding and the user using satisfaction. The electronic device can be an electronic device such as a smart phone, a personal computer, a tablet computer or an electronic book.

One specific example is provided below in connection with embodiment one: the example is applied to an electronic device comprising a touch screen, and specifically comprises the following steps:

the first step is as follows: the touch screen is electrified and initialized to enter a normal working mode;

the second step is that: and when the touch lifting action is found, judging the current speed value of the touch, and if the speed value is smaller than a critical value, not starting the disconnection compensation. If the velocity of v1 is greater than the empirical value of 60cm/s in fig. 2, it is considered that the first judgment condition is satisfied and the process proceeds to the third step. If the v1 speed is less than the empirical value of 60cm/s, the user is considered to be sliding normally slowly, and the process returns to no processing. Wherein the current speed value corresponds to the nth slip rate;

the third step: and when the touch pressing action is found again, comparing the current Id value of the current touch with the Id value of the last touch, and if the current Id value is not more than 1 difference value of the previous Id value, not starting disconnection compensation. If the current Id value is not the difference value of 1 compared with the previous Id value, the second judgment condition is considered to be met, and the step five is carried out; otherwise, no processing is performed. In fig. 2, if Id2-Id1 is 1, the fourth step is entered.

The fourth step: and when the touch pressing action is found, comparing the speed vectors of the two disconnected lines at the breakpoint, and if the difference between the two speed vectors is greater than a critical value, not starting the line breakage compensation. In the attached figure 2, if v2-v1 is less than 10cm/s and the angle difference theta is less than 10 degrees, the third judgment condition is considered to be met, the fifth step is carried out, and otherwise, the processing is not carried out. The breakpoint is located between the start of the current sliding touch and the end of the previous sliding touch.

The fifth step: and compensating the breakpoint, increasing the breakpoint report point, and connecting the two disconnected sliding tracks into a new sliding track.

And a sixth step: and capturing a complete sliding report event by the application software, and responding to the sliding operation of the user according to the new sliding track, specifically executing the processing such as screen switching or icon moving and the like.

In the several embodiments provided in the present application, it should be understood that the disclosed apparatus and method may be implemented in other ways. The above-described device embodiments are merely illustrative, for example, the division of the unit is only a logical functional division, and there may be other division ways in actual implementation, such as: multiple units or components may be combined, or may be integrated into another system, or some features may be omitted, or not implemented. In addition, the coupling, direct coupling or communication connection between the components shown or discussed may be through some interfaces, and the indirect coupling or communication connection between the devices or units may be electrical, mechanical or other forms.

The units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, that is, may be located in one place, or may be distributed on a plurality of network units; some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

In addition, all the functional units in the embodiments of the present invention may be integrated into one processing module, or each unit may be separately used as one unit, or two or more units may be integrated into one unit; the integrated unit can be realized in a form of hardware, or in a form of hardware plus a software functional unit.

Those of ordinary skill in the art will understand that: all or part of the steps for implementing the method embodiments may be implemented by hardware related to program instructions, and the program may be stored in a computer readable storage medium, and when executed, the program performs the steps including the method embodiments; and the aforementioned storage medium includes: a mobile storage device, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk or an optical disk, and other various media capable of storing program codes.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.

Claims (10)

1. A sliding broken line compensation method is characterized in that,

the method comprises the following steps:

detecting the nth sliding speed of the nth sliding track end at the first moment;

when the nth sliding speed is larger than a first speed threshold, detecting the nth sliding direction corresponding to the nth sliding speed, the (n + 1) th sliding speed at the starting end of the (n + 1) th sliding track and the (n + 1) th sliding direction;

when the difference value between the nth sliding speed and the (n + 1) th sliding speed is smaller than a second speed threshold value, and the angle formed by the nth sliding direction and the (n + 1) th sliding direction is smaller than an angle threshold value, connecting the nth sliding track and the (n + 1) th sliding track to form a new sliding track;

responding to the sliding operation of the user according to the new sliding track;

the nth sliding track and the (n + 1) th sliding track are formed by identifying sliding operation of a user by the electronic equipment;

and n is an integer not less than 1.

2. The method of claim 1,

the method further comprises the following steps:

recording the sliding speed of the designated position of the sliding track formed by the sliding operation of the user before the first moment to form a history record;

determining the first rate threshold according to the history.

3. The method of claim 1,

the method further comprises the following steps:

detecting the acceleration of the end of the nth sliding track;

and determining the second speed threshold according to the acceleration and the distance between the end of the nth sliding track and the start of the (n + 1) th sliding track.

4. The method of claim 1, 2 or 3,

the method further comprises the following steps:

detecting the distance between the end of the nth sliding track and the start of the (n + 1) th sliding track;

the detecting the nth sliding speed of the nth sliding track end at the first moment comprises the following steps:

detecting an nth sliding speed at the end of the nth sliding track when the distance between the nth sliding track and the (n + 1) th sliding track is smaller than a distance threshold.

5. The method of claim 1, 2 or 3,

the method is applied to the sliding breakpoint compensation mode of the electronic equipment;

prior to the first time, the method further comprises:

receiving a user input;

entering a sliding breakpoint compensation mode in response to the user input.

6. An electronic device, characterized in that the electronic device comprises an interactive screen receiving a sliding operation;

the interactive screen is used for detecting the nth sliding speed at the tail end of the nth sliding track at the first moment;

the interactive screen is further used for detecting an nth sliding direction corresponding to the nth sliding speed, an nth +1 sliding speed at the start end of an nth +1 sliding track and an nth +1 sliding direction when the nth sliding speed is greater than a first speed threshold;

the electronic device further includes:

a forming unit, configured to connect the nth sliding track and the n +1 th sliding track to form a new sliding track when a difference between the nth sliding speed and the n +1 th sliding speed is smaller than a second speed threshold and an angle formed by the nth sliding direction and the n +1 th sliding direction is smaller than an angle threshold;

the response unit is used for responding to the sliding operation of the user according to the new sliding track;

the nth sliding track and the (n + 1) th sliding track are formed by identifying sliding operation of a user by the electronic equipment;

and n is an integer not less than 1.

7. The electronic device of claim 6,

the electronic device further includes:

the recording unit is used for recording the sliding speed of the specified position of the sliding track formed by the sliding operation of the user before the first moment to form a history record;

a first determining unit, configured to determine the first rate threshold according to the history.

8. The electronic device of claim 6,

the interactive screen is further used for detecting the acceleration of the tail end of the nth sliding track;

the electronic device further includes:

a second determining unit, configured to determine the second rate threshold according to the acceleration and a distance between the end of the nth sliding track and the start of the (n + 1) th sliding track.

9. The electronic device of claim 6, 7 or 8,

the interactive screen is further used for detecting the distance between the tail end of the nth sliding track and the start end of the (n + 1) th sliding track;

the interactive screen is specifically configured to detect an nth sliding rate at the end of an nth sliding track when the distance between the nth sliding track and the (n + 1) th sliding track is smaller than a distance threshold.

10. The electronic device of claim 6, 7 or 8,

the electronic equipment is applied to the sliding breakpoint compensation mode of the electronic equipment;

the electronic device further includes:

a receiving unit for receiving a user input before the first time;

the response unit is further used for responding to the user input to enter a sliding breakpoint compensation mode.

Images