CN111538408A - Vibration-based indication method, touch control assembly, terminal and readable storage medium - Google Patents

Abstract

The invention discloses an indicating method based on vibration, which is applied to touch equipment, wherein the touch equipment comprises a touch screen and a vibration motor, and the method comprises the following steps: the method comprises the steps of obtaining a first target area on a touch screen, setting a first non-target area according to the first target area, and setting a first interval area between the first target area and the first non-target area; acquiring a current touch position of a user on a touch screen; if the current touch position is located in the first non-target area, driving the vibration motor to vibrate according to the non-target vibration parameters corresponding to the first non-target area; if the current touch position is located in the first target area, driving the vibration motor to vibrate according to a first target vibration parameter corresponding to the first target area; and if the current touch position is located in the first interval area, driving the vibration motor to vibrate according to the first prompt vibration parameter corresponding to the first interval area. The invention can effectively improve the convenience of the user. The invention also provides a touch control assembly, a terminal and a readable storage medium.

Description

Vibration-based indication method, touch control assembly, terminal and readable storage medium

Technical Field

The invention relates to the technical field of tactile feedback, in particular to a vibration-based indication method, a touch control assembly, a terminal and a readable storage medium.

Background

With the development of science and technology, touch terminals are widely used in daily life. At present, a user wants to know which position the user touches by the finger of the user is mainly realized through vision, and under certain conditions, for example, the user is in a state that the user cannot watch the screen of the touch terminal by distraction such as driving, or the user cannot see the screen of the touch terminal for a blind person, at this time, when the touch terminal is used, the user cannot know which position the user touches by the finger of the user, and the use is very inconvenient.

Disclosure of Invention

In view of this, it is necessary to propose a vibration-based pointing method, a touch module, a terminal, and a readable storage medium in view of the above problems.

A vibration-based indication method is applied to a touch device, the touch device comprises a touch screen and a vibration motor, and the vibration-based indication method comprises the following steps: acquiring a first target area on the touch screen, setting a first non-target area according to the first target area, and setting a first interval area between the first target area and the first non-target area; acquiring the current touch position of a user on the touch screen; if the current touch position is located in the first non-target area, driving the vibration motor to vibrate according to non-target vibration parameters corresponding to the first non-target area; if the current touch position is located in the first target area, driving the vibration motor to vibrate according to a first target vibration parameter corresponding to the first target area; and if the current touch position is located in the first interval area, driving the vibration motor to vibrate according to a first prompt vibration parameter corresponding to the first interval area.

A touch control assembly is applied to touch control equipment, the touch control equipment comprises a touch control screen and a vibration motor, the vibration motor is used for driving the touch control screen to vibrate, and the vibration-based indication method comprises the following steps: the area module is used for acquiring a first target area on the touch screen, setting a first non-target area according to the first target area, and setting a first interval area between the first target area and the first non-target area; the position module is used for acquiring the current touch position of a user on the touch screen; the vibration module is used for driving the vibration motor to vibrate according to the non-target vibration parameters corresponding to the first non-target area if the current touch position is located in the first non-target area; if the current touch position is located in the first target area, driving the vibration motor to vibrate according to a first target vibration parameter corresponding to the first target area; and if the current touch position is located in the first interval area, driving the vibration motor to vibrate according to a first prompt vibration parameter corresponding to the first interval area.

A touch terminal, comprising: a processor, a memory and a communication circuit, the processor being coupled to the memory and the communication circuit, the memory having stored therein a computer program, the processor executing the computer program to implement the method as described above.

A readable storage medium storing a computer program executable by a processor to implement the method as described above.

The embodiment of the invention has the following beneficial effects:

by acquiring the first target area, setting the first non-target area and the first interval area between the first target area and the first non-target area according to the first target area, and driving the vibration motor to move according to different vibration parameters when the current touch position of the user is located in the first interval area and the first non-target area, the user can acquire different vibration sensations, and therefore the user can know that the area corresponding to the current touch position can effectively improve the use convenience of the user without visual assistance.

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.

Wherein:

FIG. 1 is a schematic flow chart diagram of a first embodiment of a vibration-based interaction method provided by the present invention;

FIG. 2 is a distribution diagram illustrating a distribution of area locations of a touch screen in the vibration-based interaction method according to the first embodiment of the present invention;

FIG. 3 is a distribution diagram of a second embodiment of the area location distribution of the touch screen in the vibration-based interaction method provided by the present invention;

FIG. 4 is a distribution diagram of a distribution of area locations of a touch screen in the vibration-based interaction method according to a third embodiment of the present invention;

FIG. 5 is a schematic flow chart diagram of a second embodiment of a vibration-based interaction method provided by the present invention;

FIG. 6 is a distribution diagram illustrating a distribution of area locations of a touch screen in the vibration-based interaction method according to a fourth embodiment of the present invention;

FIG. 7 is a schematic flow chart diagram of a third embodiment of a vibration-based interaction method provided by the present invention;

FIG. 8 is a schematic structural diagram of a touch device according to an embodiment of the present invention;

fig. 9 is a schematic structural diagram of a touch terminal according to an embodiment of the present invention;

FIG. 10 is a schematic structural diagram of an embodiment of a readable storage medium provided by the present invention.

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, fig. 1 is a flowchart illustrating a vibration-based interaction method according to a first embodiment of the present invention. The vibration-based interaction method provided by the invention comprises the following steps:

s101: the method comprises the steps of obtaining a first target area on a touch screen, setting a first non-target area according to the first target area, and setting a first interval area between the first target area and the first non-target area.

In this implementation scenario, the method is applied to a touch terminal, and the touch terminal includes a touch screen and a vibration motor. In this embodiment, the user may set the first target area, and the other area of the touch screen may be used as the first non-target area, and a spacing area is set between the first target area and the first non-target area. The user may set parameters such as the width of the spacing region. Or the first target area and the first non-target area are preset, and the first target area and the first non-target area are divided according to an instruction input by a user to set an interval area. Further, the spacer region may also be a user setting. The user may also set a parameter of the spacing region, for example, the width of the spacing region.

In this implementation scenario, the first target area may be located at an edge or a middle of the touch screen, and the shape of the first target area may be a square, a circle, an irregular figure, or the like. When the first target area is located at the edge of the touch screen, a spacing area is arranged at the edge of the first target area adjacent to the first non-target area. When the first target area is located in the middle of the touch screen, spacing areas are arranged around the first target area.

Specifically, referring to fig. 2 and fig. 3 in combination, fig. 2 is a distribution diagram illustrating a distribution of area positions of a touch screen in the vibration-based interaction method according to the first embodiment of the present invention. Fig. 3 is a distribution diagram of a distribution of area positions of a touch screen in the vibration-based interaction method according to a second embodiment of the present invention. As shown in fig. 2, the touch screen 10 includes a first target area 11, a first non-target area 12, and a first spacing area 13. After the first target area 11 and the first non-target area 12 are determined, a first spacing area 13 in a stripe shape is provided between the first target area 11 and the first non-target area 12. As shown in fig. 3, the touch screen 20 includes a first target area 21, a first non-target area 22, and a first spacing area 23. When the first target region 21 and the first non-target region 22 are determined and the first target region 11 is circular, a first spaced region 23 having a ring shape is provided between the first target region 21 and the first non-target region 22.

S102: and acquiring the current touch position of the user on the touch screen.

In this implementation scenario, a current touch position of a user on the touch screen is obtained, and specifically, a touch sensing layer is disposed in the touch screen and is used for obtaining the current touch position of the user on the touch screen according to parameters such as capacitance, resistance, inductance, infrared, pressure, and the like.

S103: and if the current touch position is located in the first non-target area, driving the vibration motor to vibrate according to the non-target vibration parameters corresponding to the first non-target area.

In this implementation scenario, whether the current touch position is located in the first non-target area is determined according to the obtained current touch position, for example, the coordinates of the current touch position and the coordinate ranges of the first target area, the first non-target area and the first spacing area may be obtained, and whether the coordinates of the current touch position belong to the coordinate range of the first non-target area is determined. For example, if the coordinates of the current touch position are (21, 34) and the coordinate range of the first non-target area is (x is 0-30, and y is 0-60), the current touch position is located in the first non-target area.

And when the current touch position is located in the first non-target area, acquiring non-target vibration parameters corresponding to the first non-target area, and driving the vibration motor to vibrate according to the non-target vibration parameters, wherein the non-target vibration parameters comprise vibration frequency, vibration amplitude and the like. The non-target vibration parameters can be preset according to instructions input by a user, and can also be obtained by obtaining current use conditions and calculating according to preset vibration rules.

In this implementation scenario, the non-target vibration parameter is related to a first distance between the current touch position and the first target area, for example, the shorter the first distance, the higher the vibration frequency and/or the larger the vibration amplitude in the non-target vibration parameter, and the larger the first distance, the lower the vibration frequency and/or the smaller the vibration amplitude in the non-target vibration parameter. Therefore, a user can acquire a plurality of different vibration sensations by touching different points for a plurality of times, and the change of the distance between the current touch position and the first target area can be acquired according to the acquired vibration sensations. Or the finger of the user can slide on the touch screen, and whether the sliding direction is towards the first target area can be acquired according to the change of the vibration sense sensed in the sliding process.

Specifically, referring to fig. 2, in the present embodiment, it is defined that the shorter the first distance is, the higher the vibration frequency in the non-target vibration parameter is, and the variation range of the vibration frequency is 80 hz to 200 hz. Two points AB in fig. 2 are located in the first non-target area 12, and it can be seen that point a is closer to the first target area 11, so when the user's finger slides from point a to point B, the user can feel that the vibration frequency of the touch screen 10 becomes lower, meaning that the currently touched point is farther from the first target area 11, and the user can immediately select the reverse direction, slide from point B to point a, and approach to the first target area 11.

In this embodiment scenario, the shortest distance between the current touch position and the first target area is defined as the first distance, and in other embodiment scenarios, the distance between the current touch position and the center of the first target area may be defined as the first distance. The first distance may also be the farthest distance of the current touch position from the first target area.

In other implementation scenarios, a plurality of current touch positions may also occur, for example, when the user touches the touch screen with a plurality of fingers, the shortest distance from the first target area among the plurality of current touch positions is taken as the first distance.

In other implementation scenarios, a plurality of first target areas may also appear, please refer to fig. 4 in combination, and fig. 4 is a distribution diagram of a third embodiment of the area position distribution of the touch screen in the vibration-based interaction method provided by the present invention. The touch screen 30 includes first target areas 31 and 32, a first non-target area 33, and first spaced areas 34 and 35. Distances between the current touch position and the two first target areas 31 and 32 are calculated, respectively, and the shortest one of the two is selected as the first distance.

S104: and if the current touch position is located in the first interval area, driving the vibration motor to vibrate according to the first prompt vibration parameter corresponding to the first interval area.

In the implementation scenario, whether the current touch position is located in the first interval area is determined according to the acquired current touch position. For example, it may be determined whether the coordinates of the current touch position belong to the coordinate range of the first spaced area. Specifically, the method is similar to the above method for determining whether the current touch position is located in the first non-target area, and details are not repeated.

When the current touch position is located in the first interval area, a first prompt vibration parameter corresponding to the first interval area is obtained, and the vibration motor is driven to vibrate according to the first prompt vibration parameter. The first prompt vibration parameter is different from the first non-target vibration parameter, and thus the vibration sensation experienced by the user is also different. In this implementation scenario, the first prompt vibration parameter includes a first vibration duration, and the first vibration duration is shorter, so that the vibration motor will generate a short-signal vibration. When the current touch position is located in the first interval area, the user can know that the current finger touch position is located in the first interval area at the edge of the first target area according to the experienced vibration sense.

S105: and if the current touch position is located in the first target area, driving the vibration motor to vibrate according to the first target vibration parameters corresponding to the first target area.

In the implementation scenario, whether the current touch position is located in the first target area is determined according to the acquired current touch position. For example, it may be determined whether the coordinates of the current touch position belong to the coordinate range of the first target area. Specifically, the method is similar to the above method for determining whether the current touch position is located in the first non-target area, and details are not repeated.

When the current touch position is located in the first target area, a first target vibration parameter corresponding to the first target area is obtained, and the vibration motor is driven to vibrate according to the first target vibration parameter. The first target vibration parameter is different from the first non-target vibration parameter and different from the first prompt vibration parameter, so that the vibration sensations experienced by the user are different. In the present implementation scenario, the first target vibration parameter is 0, i.e., the vibration motor is controlled not to vibrate. When the current touch position is located in the first target area, the user can know that the current finger touch position is located in the first target area according to the experienced vibration sense.

In one particular implementation scenario, reference is made to FIG. 2. Assuming that the point where the user touches the touch screen 10 for the first time is a, and then slides from a to B, in the present implementation scenario, the farther the first distance is, the lower the vibration frequency in the first non-target vibration parameter is, when the user's finger slides from a point a to B, the lower the sensed vibration frequency becomes, the user can know that the current touch position is farther from the first target region 11, and then the user can immediately select the reverse direction, slide from B to a point a, and approach to the first target region 11. When the user's finger continues to slide to point C in the first spaced area 13, the vibration sensation different from that in the first non-target area 12 is felt, and it can be known that the current touch position is in the first spaced area 13, and the user's finger can continue to slide forward until the first target area 11 is reached, at which time the vibration motor does not vibrate, and the user does not feel the vibration sensation, so that it can be determined that the current touch position is in the first target area 11.

In fig. 2, a point E in the first non-target area is located in the vertical direction of the point a, and assuming that a point where the user touches the touch screen 10 for the first time is a, and then slides from a to E, since a first distance from the point E to the first target area 11 is the same as a first distance from the point a to the first target area 11, the vibration frequency in the first non-target vibration parameter is not changed, the vibration sensation felt by the user is not changed, and the user can know that the user is not approaching the first target area 11 at present, and thus the sliding direction is changed.

In another specific implementation scenario, reference is still made to FIG. 2. Assuming that the point where the user touches the touch screen 10 for the first time is C, the user may feel a vibration, and if the user slides from C to a, the user may feel a new vibration different from the first contact, and may feel that the vibration frequency of the new vibration is lower, so that the user may change the sliding direction, slide from a to C, and continue to slide until there is no vibration after C, and the user may know that the current touch position is located in the first target region 11.

In yet another specific implementation scenario, which is still described in conjunction with FIG. 2. Assuming that the point where the user touches the touch screen 10 for the first time is the point D located in the first target area 11, the user will not feel the vibration, and thus the user can know that the current touch position is located in the first target area 11.

As can be seen from the above description, in this embodiment, by acquiring the first target area, setting the first non-target area and the first spacing area between the first target area and the first non-target area according to the first target area, and when the current touch position of the user is located in the first target area, the first spacing area and the first non-target area, driving the vibration motor to move according to different vibration parameters, so that the user can acquire different vibration sensations, thereby obtaining an area corresponding to the current touch position, where the first non-target vibration parameter is related to the first distance between the current touch position and the first target area, and the user can determine whether to adjust the moving direction of the current touch position according to the vibration sensation acquired in the first non-target area, so as to effectively improve convenience of use for the user.

Referring to fig. 5, fig. 5 is a flowchart illustrating a vibration-based interaction method according to a second embodiment of the present invention. The vibration-based interaction method provided by the invention comprises the following steps:

s201: the method comprises the steps of obtaining a first target area on a touch screen, setting a first non-target area according to the first target area, and setting a first interval area between the first target area and the first non-target area.

S202: and acquiring the current touch position of the user on the touch screen.

In a specific implementation scenario, steps S201 to S202 are substantially the same as steps S101 to S102 in the first embodiment of the vibration-based interaction method provided by the present invention, and are not described herein again.

S203: and if the current touch position is located in the first target area, judging whether the current touch position is located in the second target area. If not, go to step S204, and if so, go to step S205.

In this implementation scenario, please refer to fig. 6 in combination, where fig. 6 is a distribution diagram illustrating a distribution of area positions of a touch screen in the vibration-based interaction method according to a fourth embodiment of the present invention. The touch screen 40 has a larger area, and the user may want to touch the second target area 41 at a longer position, so that a first target area 42 can be set to include the second target area 41, the user can touch the first target area 42 according to the sensed vibration, and then touch the second target area 41 according to the sensed vibration after the user reaches the first target area 42. The step of indicating the user to touch the first target area 42 by vibration sense in this implementation scenario is substantially the same as the first embodiment of the vibration-based interaction method provided by the present invention, and is not repeated here.

In this implementation scenario, a final touch area that the user finally wants to touch may be obtained, a current touch position where the user touches the touch screen for the first time is obtained, a third distance between the current touch position and the final touch area is calculated, for example, a shortest distance between the current touch position and the final touch area may be used as the third distance, if the third distance is greater than a preset threshold, the final touch area is used as a second target area, a first target area with a larger range including the second target area is set, and then a first non-target area and a second separation area are set according to the first target area. If the final touch area is set as the second target area, the first target area is set according to the thickness of the touch point of the user, the moving speed of the current touch point of the user, the use habit of the user and the like. If the third distance is smaller than the preset threshold, the final touch area may be used as a first target area, and a first non-target area and a first spacing area are set according to the first target area.

In the implementation scenario, the current touch position is obtained, and whether the current touch position is located in the second target area is judged. For example, it may be determined whether the coordinates of the current touch position belong to the coordinate range of the second target area. Specifically, the method is similar to the above method for determining whether the current touch position is located in the first non-target area, and details are not repeated here.

S204: and acquiring a second distance between the current touch position and the second target area, and acquiring a first target vibration parameter according to the second distance.

In this implementation scenario, the current touch location is not located in the second target area. A second distance between the current touch position and the second target area is obtained, and a method for determining the second distance is substantially the same as the method for determining the first distance described above, and is not repeated here.

In this implementation scenario, the calculation method of the first target vibration parameter is similar to the calculation method of the first non-target vibration parameter in the above, and it is defined that the shorter the second distance, the greater the vibration frequency and/or amplitude in the non-target vibration parameter, and the longer the second distance, the smaller the vibration frequency and/or amplitude in the non-target vibration parameter. In order to allow the user to distinguish the first non-target region from the first target region by the vibration sensation, the difference between the maximum value of the first non-target vibration parameter and the minimum value of the first target vibration is greater than a preset threshold, for example 50 hz.

S205: and driving the vibration motor to vibrate according to a second target vibration parameter corresponding to a second target area.

In the implementation scenario, if the current touch position is located in the second target area, a second target vibration parameter corresponding to the second target area is obtained, and the vibration motor is driven to vibrate according to the second target vibration parameter. The second target vibration parameter is different from the first target vibration parameter, the first non-target vibration parameter and the first prompt vibration parameter. In this implementation scenario, the first target vibration parameter is 0, that is, the vibration motor is controlled not to vibrate, or the first target vibration parameter may be intermittent vibration, and when the current touch position is located in the first target area, the user may know that the current finger touch position is located in the first target area according to the experienced vibration sensation.

It is understood that in other embodiments, a third target area may be provided in the second target area in order to improve the direction of the movement of the touch point of the client. More target areas may also be set by analogy.

As can be seen from the above description, in this embodiment, a first target area is set first, the first target area includes a second target area, a first non-target area and a first spacing area are set according to the first target area, a user touches the first target area according to different vibration sensations provided by the first target area, the first non-target area and the first spacing area, and then obtains a first target vibration parameter according to a second distance between a current touch position and the second target area, where the second target vibration parameter changes according to the length of the second distance, so that the user can determine a moving direction of the current touch position according to a change of the vibration sensation felt in the first target area, and efficiency and reliability of the user reaching the second target area can be effectively improved.

Referring to fig. 7, fig. 7 is a flowchart illustrating a vibration-based interaction method according to a third embodiment of the present invention. The vibration-based interaction method provided by the invention comprises the following steps:

s301: the method comprises the steps of obtaining a first target area on a touch screen, setting a first non-target area according to the first target area, and setting a first interval area between the first target area and the first non-target area.

In a specific implementation scenario, step S301 is substantially the same as step S101 in the first embodiment of the vibration-based interaction method provided by the present invention, and details thereof are not repeated here.

S302: and acquiring a second target area in the first target area, setting a second non-target area according to the second target area, and setting a second interval area between the second target area and the second non-target area.

In this implementation scenario, the second target area may be set by the user, and according to the second target area, the remaining area in the first target area is set as a second non-target area, and a second gap area is set in the second non-target area and the second target area.

S303: and acquiring the current touch position of the user on the touch screen.

In this implementation scenario, step S303 is substantially the same as step S102 in the first embodiment of the vibration-based interaction method provided by the present invention, and details are not repeated here.

S304: and if the current touch position is located in the first target area, judging whether the current touch position is located in the second target area. If so, step S306 is executed, otherwise, step S305 or S307 is executed.

S305: and acquiring a second distance between the current touch position and the second target area, and acquiring a first target vibration parameter according to the second distance.

S306: and driving the vibration motor to vibrate according to a second target vibration parameter corresponding to a second target area.

In this implementation scenario, steps S304 to S306 are substantially the same as steps S203 to S205 in the second embodiment of the vibration-based interaction method provided by the present invention, and are not repeated here.

S307: and if the current touch position is located in the second interval area, driving the vibration motor to vibrate according to a second prompt vibration parameter corresponding to the second interval area.

In this implementation scenario, if the current touch position is located in the second interval region, the vibration motor is driven to vibrate according to the second prompt vibration parameter corresponding to the second interval region, where the second prompt vibration parameter includes the second vibration time, that is, the vibration motor is driven to vibrate at the second vibration time, so that the user can distinguish the vibration sense from other vibration senses. In this implementation scenario, the second prompt vibration parameter is different from the second prompt vibration parameter.

As can be seen from the above description, in this embodiment, a second non-target area and a second prompt area are set in the first target area according to the second target area, and when the current touch position is located in the second interval area, the vibration motor is driven to vibrate according to the second prompt vibration parameter corresponding to the second interval area, so that the current touch position can be better prompted to a user, and the user is helped to more accurately touch the second target area.

Referring to fig. 8, fig. 8 is a schematic structural diagram of a touch device according to an embodiment of the present invention. The touch assembly 50 includes: an area module 51, a position module 52 and a vibration module 53. The area module 51 is configured to obtain a first target area on the touch screen, set a first non-target area according to the first target area, and set a first interval area between the first target area and the first non-target area. The position module 52 is used to obtain the current touch position of the user on the touch screen. The vibration module 53 is configured to drive the vibration motor to vibrate according to the non-target vibration parameter corresponding to the first non-target area if the current touch position is located in the first non-target area; if the current touch position is located in the first target area, driving the vibration motor to vibrate according to a first target vibration parameter corresponding to the first target area; and if the current touch position is located in the first interval area, driving the vibration motor to vibrate according to the first prompt vibration parameter corresponding to the first interval area.

The vibration module 53 is further configured to obtain a first distance between the current touch position and the first target area, and obtain a non-target vibration parameter according to the first distance.

Wherein the non-target vibration parameters include a non-target vibration frequency: the shorter the first distance, the higher the non-target vibration frequency.

The vibration module 53 is further configured to control the vibration motor to stop vibrating if the current touch position is located in the first target area.

The vibration module 53 is further configured to drive the vibration motor to vibrate within a first prompt duration if the current touch position is located in the first interval area.

Wherein the first target area comprises a second target area.

The vibration module 53 is further configured to determine whether the current touch position is located in the second target area; if the current touch position is not located in the second target area, acquiring a second distance between the current touch position and the second target area; and acquiring a first target vibration parameter according to the second distance.

The vibration module 53 is further configured to drive the vibration motor to vibrate according to the second target vibration parameter if the current touch position is located in the second target area.

The area module 51 is further configured to set a second non-target area according to the second target area, and set a second spacing area between the second target area and the second non-target area.

The vibration module 53 is further configured to drive the vibration motor to vibrate according to the second prompt vibration parameter corresponding to the second interval region if the current touch position is located in the second interval region.

The first prompt vibration parameter comprises a first vibration duration; and/or the second prompt vibration parameter comprises a second vibration duration.

As can be seen from the above description, in the touch control assembly in this embodiment, the first target area is obtained, the first non-target area and the first spacing area are set according to the first target area, when the current touch position of the user is located in the first target area, the first spacing area and the first non-target area, the vibration motor is driven to move according to different vibration parameters, so that the user can obtain different vibration sensations, thereby obtaining an area corresponding to the current touch position, the first non-target vibration parameter is related to the first distance between the current touch position and the first target area, and the user can determine whether to adjust the moving direction of the current touch position according to the vibration sensation obtained in the first non-target area, so that convenience in use of the user can be effectively improved.

Referring to fig. 9, fig. 9 is a schematic structural diagram of a touch terminal according to an embodiment of the present invention. The touch terminal 60 includes a processor 61 and a memory 62. The processor 61 is coupled to the memory 62. The memory 62 stores a computer program which is executed by the processor 61 when it is operated to implement the method as shown in fig. 1, 5 and 7. The detailed methods can be referred to above and are not described herein.

As can be seen from the above description, in the touch terminal in this embodiment, the first non-target area and the first spacing area are set according to the first target area, when the current touch position of the user is located in the first target area, the first spacing area and the first non-target area, the vibration motor is driven to move according to different vibration parameters, so that the user can obtain different vibration sensations, thereby obtaining an area corresponding to the current touch position, the first non-target vibration parameter is related to a first distance between the current touch position and the first target area, and the user can determine whether to adjust the moving direction of the current touch position according to the vibration sensation obtained in the first non-target area, so that convenience in use of the user can be effectively improved.

Referring to fig. 10, fig. 10 is a schematic structural diagram of an embodiment of a readable storage medium provided in the present invention. The readable storage medium 70 stores at least one computer program 71, and the computer program 71 is used for being executed by the processor to implement the methods shown in fig. 1, fig. 5, and fig. 7, and the detailed methods can be referred to above and are not described herein again. In one embodiment, the readable storage medium 70 may be a memory chip in a terminal, a hard disk, or other readable and writable storage tool such as a mobile hard disk or a flash drive, an optical disk, or the like, and may also be a server or the like.

As can be seen from the above description, the computer program in the readable storage medium in this embodiment may be configured to set the first non-target area and the first separation area according to the first target area, and when the current touch position of the user is located in the first target area, the first separation area, and the first non-target area, the vibration motor is driven to move according to different vibration parameters, so that the user may obtain different vibration sensations, thereby obtaining an area corresponding to the current touch position, where the first non-target vibration parameter is related to a first distance between the current touch position and the first target area, and the user may determine whether to adjust a moving direction of the current touch position according to the vibration sensation obtained in the first non-target area, so as to effectively improve convenience of the user.

Different from the prior art, the method and the device provided by the invention prompt the moving direction of the current touch position of the user by providing different vibration senses for the user, so that the user can determine whether the current moving direction is correct without visual assistance, and the convenience of use of the user can be improved.

The above disclosure is only for the purpose of illustrating the preferred embodiments of the present invention, and it is therefore to be understood that the invention is not limited by the scope of the appended claims.

Claims (11)

1. A vibration-based indication method is applied to a touch device, the touch device comprises a touch screen and a vibration motor, and the vibration-based indication method comprises the following steps:

acquiring a first target area on the touch screen, setting a first non-target area according to the first target area, and setting a first interval area between the first target area and the first non-target area;

acquiring the current touch position of a user on the touch screen;

if the current touch position is located in the first non-target area, driving the vibration motor to vibrate according to non-target vibration parameters corresponding to the first non-target area;

if the current touch position is located in the first target area, driving the vibration motor to vibrate according to a first target vibration parameter corresponding to the first target area;

and if the current touch position is located in the first interval area, driving the vibration motor to vibrate according to a first prompt vibration parameter corresponding to the first interval area.

2. The vibration-based indication method of claim 1, wherein the step of driving the vibration motor to vibrate according to the non-target vibration parameters corresponding to the first non-target area is preceded by the step of:

and acquiring a first distance between the current touch position and the first target area, and acquiring the non-target vibration parameter according to the first distance.

3. The vibration-based indication method of claim 2, wherein the non-target vibration parameters include a non-target vibration frequency:

the shorter the first distance, the higher the non-target vibration frequency.

4. The vibration-based indication method of claim 1, wherein if the current touch position is located in the first target area, the step of driving the vibration motor to vibrate according to a first target vibration parameter corresponding to the first target area comprises:

and if the current touch position is located in the first target area, controlling the vibration motor to stop vibrating.

5. The vibration-based indication method according to claim 1, wherein the step of driving the vibration motor to vibrate according to a first prompting vibration parameter corresponding to the first interval region if the current touch position is located in the first interval region comprises:

and if the current touch position is located in the first interval area, driving the vibration motor to vibrate within a first prompt duration.

6. The vibration-based indication method of claim 1, wherein the first target area comprises a second target area;

before the step of driving the vibration motor to vibrate according to the first target vibration parameter corresponding to the first target area, the method comprises the following steps of:

judging whether the current touch position is located in the second target area;

if the current touch position is not located in the second target area, acquiring a second distance between the current touch position and the second target area;

and acquiring the first target vibration parameter according to the second distance.

7. The vibration-based pointing method according to claim 6, wherein the step of determining whether the current touch position is located in the second target area includes:

and if the current touch position is located in the second target area, driving the vibration motor to vibrate according to a second target vibration parameter.

8. The vibration-based pointing method according to claim 6, wherein said step of acquiring a first target area on the touch screen is followed by:

setting a second non-target area according to the second target area, and setting a second interval area between the second target area and the second non-target area;

before the step of driving the vibration motor to vibrate according to the first target vibration parameter corresponding to the first target area, the method comprises the following steps of:

and if the current touch position is located in the second interval area, driving the vibration motor to vibrate according to a second prompt vibration parameter corresponding to the second interval area.

9. A touch control assembly is applied to a touch control device, the touch control device comprises a touch control screen and a vibration motor, the vibration motor is used for driving the touch control screen to vibrate, and the vibration-based indication method comprises the following steps:

the area module is used for acquiring a first target area on the touch screen, setting a first non-target area according to the first target area, and setting a first interval area between the first target area and the first non-target area;

the position module is used for acquiring the current touch position of a user on the touch screen;

the vibration module is used for driving the vibration motor to vibrate according to the non-target vibration parameters corresponding to the first non-target area if the current touch position is located in the first non-target area; if the current touch position is located in the first target area, driving the vibration motor to vibrate according to a first target vibration parameter corresponding to the first target area; and if the current touch position is located in the first interval area, driving the vibration motor to vibrate according to a first prompt vibration parameter corresponding to the first interval area.

10. A touch terminal, comprising: a processor, a memory and a communication circuit, the processor coupled to the memory and the communication circuit, the memory having stored therein a computer program, the processor executing the computer program to implement the method of any of claims 1-8.

11. A readable storage medium, in which a computer program is stored which is executable by a processor to implement the method according to any one of claims 1-8.

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