CN104881190A - Method and electronic apparatus for handling interference - Google Patents

Abstract

The embodiment of the invention discloses a method and an electronic apparatus for handling interference. The method herein includes: detecting a first reference of a touch control unit of the electronic apparatus; the first reference representing the deformation degree of the touch control unit; determining a first touch control area of the touch control unit based on the first reference, and regulating a second reference of the first touch control area based on the first reference; the second reference representing a drive reference of the touch control unit; controlling the first touch control area of the touch control unit to output the second reference.

Description

A kind of interference disposal route and electronic equipment

Technical field

The present invention relates to data processing technique, be specifically related to a kind of interference disposal route and electronic equipment.

Background technology

Along with the development of touch technology, large-sized touch screen is applied in the electronic device, as all-in-one.Capacitance type touch control screen comprises glassy layer and film coating.When the touching display screen of electronic equipment keeps flat, being subject to the impact of touching display screen own wt, can there is sinking deformation in the outermost face glass of touching display screen; The size of touching display screen is larger, and the deformation that face glass sinks is more serious.Usually; the image element circuit of the display panel of electronic equipment is arranged on the inner side of touch screen; when touch screen generation sinking deformation; clearance between touch screen and display panel is thinning; the image element circuit of display panel can affect the inductance capacitance of capacitance type touch control screen, and distance is nearer, larger to the interference of inductance capacitance; thus the touch control operation of impact to touch screen, cause touch control operation exception or the problem without response.

Summary of the invention

For solving the technical matters of existing existence, the embodiment of the present invention provides a kind of interference disposal route and electronic equipment, can solve touch control operation that the deformation due to touch control unit causes abnormal or without the problem of response.

For achieving the above object, the technical scheme of the embodiment of the present invention is achieved in that

Embodiments provide a kind of interference disposal route, described method comprises:

First parameter of the touch control unit of detected electrons equipment; The deformation degree of touch control unit described in described first parameter characterization;

The first touch area of described touch control unit is determined based on described first parameter, and based on the second parameter of the first touch area described in described first parameter adjustment; The driving parameter of touch control unit described in described second parameter characterization;

Described first touch area controlling described touch control unit exports described second parameter.

In such scheme, described second parameter after adjustment and described first parameter positive correlation.

In such scheme, described the first touch area determining described touch control unit based on described first parameter, comprising:

Determine the central point of described first touch area based on described first parameter, determine the first touch-control subregion and the second touch-control subregion by described central point; Described first touch area comprises the first touch-control subregion and described second touch-control subregion;

Wherein, the point coincides of described first touch-control subregion and described second touch-control subregion, and the area of described first touch-control subregion is not equal to the area of described second touch-control subregion.

In such scheme, the described central point determining described first touch area based on described first parameter, determine the first touch-control subregion and the second touch-control subregion by described central point, comprising:

Determine that the maximum position of described first parameter is the central point of described first touch-control subregion and described second touch-control subregion;

The first touch-control subregion is determined by the first radius based on described central point;

The second touch-control subregion is determined by the second radius based on described central point;

Wherein, described first radius is not equal to described second radius; The size of described first radius and described touch area has the first proportionate relationship; The size of described second radius and described touch area has the second proportionate relationship; Described first proportionate relationship and described second proportionate relationship all with described first parameter positive correlation.

In such scheme, when the area of described second touch-control subregion is greater than the area of described first touch-control subregion, described the second parameter based on the first touch area described in described first parameter adjustment, comprising:

The second parameter adjusting described first touch-control subregion is M1;

To adjust in described second touch-control subregion and the second parameter of touch area outside described first touch-control subregion is M2;

Wherein, M1 is not equal to M2; M1 and M2 all with described first parameter positive correlation.

The embodiment of the present invention additionally provides a kind of electronic equipment, and described electronic equipment comprises: touch control unit, detecting unit, analysis and processing unit and control module; Wherein,

Described detecting unit, for detecting the first parameter of touch control unit; The deformation degree of touch control unit described in described first parameter characterization;

Described analysis and processing unit, described first parameter for detecting based on described detecting unit determines the first touch area of described touch control unit, and based on the second parameter of the first touch area described in described first parameter adjustment; The driving parameter of touch control unit described in described second parameter characterization;

Described control module, exports described second parameter for described first touch area controlling described touch control unit.

In such scheme, described second parameter after adjustment and described first parameter positive correlation.

In such scheme, described analysis and processing unit, for determining the central point of described first touch area based on described first parameter, determines the first touch-control subregion and the second touch-control subregion by described central point; Described first touch area comprises the first touch-control subregion and described second touch-control subregion; Wherein, the point coincides of described first touch-control subregion and described second touch-control subregion, and the area of described first touch-control subregion is not equal to the area of described second touch-control subregion.

In such scheme, described analysis and processing unit, for determining that the maximum position of described first parameter is the central point of described first touch-control subregion and described second touch-control subregion; The first touch-control subregion is determined by the first radius based on described central point; The second touch-control subregion is determined by the second radius based on described central point; Wherein, described first radius is not equal to described second radius; The size of described first radius and described touch area has the first proportionate relationship; The size of described second radius and described touch area has the second proportionate relationship; Described first proportionate relationship and described second proportionate relationship all with described first parameter positive correlation.

In such scheme, described analysis and processing unit, for when the area of described second touch-control subregion is greater than the area of described first touch-control subregion, the second parameter adjusting described first touch-control subregion is M1; To adjust in described second touch-control subregion and the second parameter of touch area outside described first touch-control subregion is M2; Wherein, M1 is not equal to M2; M1 and M2 all with described first parameter positive correlation.

The interference disposal route that the embodiment of the present invention provides and electronic equipment, the first parameter of the touch control unit of detected electrons equipment; The deformation degree of touch control unit described in described first parameter characterization; The first touch area of described touch control unit is determined based on described first parameter, and based on the second parameter of the first touch area described in described first parameter adjustment; The driving parameter of touch control unit described in described second parameter characterization; Described first touch area controlling described touch control unit exports described second parameter.So; adopt the technical scheme of the embodiment of the present invention; by the detection of the first parameter to touch control unit; thus adjust the second parameter of described touch control unit; make when the deformation degree of described touch control unit is excessive; increase the driving parameter of described touch control unit, avoid touch control operation that the deformation due to touch control unit causes abnormal or without the problem of response, improve the operating experience of user.

Accompanying drawing explanation

Fig. 1 is the schematic flow sheet of the interference disposal route of the embodiment of the present invention one;

Fig. 2 is the schematic flow sheet of the interference disposal route of the embodiment of the present invention two;

Fig. 3 is the schematic flow sheet of the interference disposal route of the embodiment of the present invention three;

Fig. 4 is the scene schematic diagram of the first touch area in the embodiment of the present invention three;

Fig. 5 is the composition structural representation of the electronic equipment of the embodiment of the present invention.

Embodiment

Below in conjunction with drawings and the specific embodiments, the present invention is further detailed explanation.

Embodiment one

Embodiments provide a kind of interference disposal route.Fig. 1 is the schematic flow sheet of the interference disposal route of the embodiment of the present invention one; As shown in Figure 1, described method comprises:

Step 101: the first parameter of the touch control unit of detected electrons equipment; The deformation degree of touch control unit described in described first parameter characterization.

Interference disposal route described in the present embodiment is applied in electronic equipment, and described electronic equipment has touch control unit, and described touch control unit can be capacitive touch control unit; Concrete, described electronic equipment can be the mobile phone, panel computer, all-in-one, desktop computer etc. with touch controllable function.Then in this step, the first parameter of the touch control unit of described detected electrons equipment, comprising: described electronic equipment detects the first parameter of the touch control unit of self.

Concrete, the outermost layer of described touch control unit (as capacitive touch control unit) is glassy layer, scribbles conductive coating (ITO), then form conductive glass layer in glassy layer; Four electrodes are drawn at four angles of conductive glass layer, and electro-conductive glass forms uniform electric field under described four electrodes provide voltage; Conductive glass layer is arranged with the inductance capacitance of array type; Because human body is energized conductor, when user's finger contacts is to touch control unit surface, points and siphon away portion of electrical current from contact point, thus change the capacitance size of inductance capacitance corresponding to described contact point; Controller determines the position coordinates of contact point based on the change of the capacitance size of inductance capacitance.Surface area due to glassy layer is comparatively large and its thickness is thinner, when described touch control unit (being specially glassy layer) is in non-vertical laying state (as keeping flat), what glassy layer can receive self gravitation affects generation deformation, based on this, detect the first parameter of described touch control unit in this step, also namely detect the first parameter of described glassy layer.

Wherein, described touch control unit is arranged on the top of the display panels circuit of described electronic equipment, between described touch control unit and described display panels circuit, there is one deck air layer, namely between described touch control unit and described display panels circuit, there is certain distance; Described air layer is specifically as follows 1.4 millimeters (mm).In the present embodiment, the deformation degree of touch control unit described in described first parameter characterization, described first parameter can be characterized by the distance between described touch control unit and described display panels circuit.Concrete, as a kind of embodiment, described first parameter detects by range sensor and obtains; As touch control unit as described in detecting and as described in the difference of distance between display panels circuit and gauged distance determine as described in the first parameter.As another kind of embodiment, can based on the own wt of described touch control unit (being specially glassy layer), the angle in conjunction with described touch control unit and vertical direction determines described first parameter; Such as, when the angle of described touch control unit and vertical direction is reverse 90 degree, described reverse 90 degree can be understood as and are rotated counterclockwise 90 degree, and namely the touch control unit of described electronic equipment is upper, display panels circuit under; Accordingly, forward 90 degree is rotated ninety degrees clockwise, namely described electronic equipment touch control unit under, display panels circuit is upper.Then when the angle of described touch control unit and vertical direction is reverse 90 degree, because touch control unit is generally the rectangle (as rectangle) of rule, then focus point is the mid point of described rectangle, and also namely the deformation degree of described focus point is maximum; Based on the weight of the glassy layer of described touch control unit, thickness and own material type, determine the first parameter of described touch control unit by preset formula model; Here, the rule of described first parameter is: the first parameter of the focus point of described touch control unit is maximum, and first parameter on four summits of described touch control unit is minimum, and from described focus point to described four summits, described first parameter linearly reduces trend.

Step 102: the first touch area determining described touch control unit based on described first parameter, and based on the second parameter of the first touch area described in described first parameter adjustment; The driving parameter of touch control unit described in described second parameter characterization.

Here, described touch control unit has touch area, and described touch area is generally equal to the viewing area of described electronic equipment, and certainly, described touch area also can be unequal with described viewing area.Then in this step, described first touch area is less than or equal to described touch area.Four electrodes are drawn at four angles of the conductive glass layer of described touch control unit, thus make described electro-conductive glass form uniform electric field at described four electrodes applying driving voltage, then in this step, described second parameter is the driving parameter of described touch control unit, and described driving parameter is specifically as follows driving voltage.

In this step, described the first touch area determining described touch control unit based on described first parameter, comprising: the numerical values recited based on described first parameter determines the first touch area of described touch control unit.Concrete, determine that the touch area of described first parameter in the first preset threshold range is described first touch area; Such as, when described first parameter is more than or equal to when a is less than or equal to b, (a and b is positive integer and a is less than b), determines that touch area corresponding to described first parameter is described first touch area.Certainly, the quantity of described first touch area is at least one, such as, when described first parameter be more than or equal to a be less than or equal to b time, determine that touch area corresponding to described first parameter is the first touch-control subregion; When described first parameter be more than or equal to c be less than b time, determine that touch area corresponding to described first parameter is the second touch-control subregion; Wherein, a, b, c are positive integer.

Wherein, owing to being subject to the impact of touch control unit deformation, the air layer between described touch control unit and display panels circuit changes, and the distance also namely between described touch control unit and described display panels circuit changes; When described touch control unit deformation makes the distance between described touch control unit and display panels circuit diminish, be subject to the disturbing effect of described display panels circuit, when described touch control unit exports according to the driving parameter of acquiescence, possibility None-identified goes out the operating point of operating body.Based on this, described the second parameter based on the first touch area described in described first parameter adjustment, comprise: when described first parameter reaches preset threshold range, improve described second parameter to the corresponding numerical value of described preset threshold range, and described second parameter after adjustment and described first parameter positive correlation.Such as: the corresponding numerical value M1 of pre-configured first preset threshold range, the second preset threshold range corresponding numerical value M2, M1 and M2 are all greater than acquiescence and drive parameter, and M1 is greater than M2; Then when described first parameter is in described first preset threshold range, adjust described second parameter to M1; When described second parameter is in described second preset threshold range, adjust described second parameter to M2.

Step 103: described first touch area controlling described touch control unit exports described second parameter.

Adopt the technical scheme of the embodiment of the present invention; by the detection of the first parameter to touch control unit; thus adjust the second parameter of described touch control unit; make when the deformation degree of described touch control unit is excessive; increase the driving parameter of described touch control unit; avoid touch control operation that the deformation due to touch control unit causes abnormal or without the problem of response, improve the operating experience of user.

Embodiment two

Embodiments provide a kind of interference disposal route.Fig. 2 is the schematic flow sheet of the interference disposal route of the embodiment of the present invention two; As shown in Figure 2, described method comprises:

Step 201: the first parameter of the touch control unit of detected electrons equipment; The deformation degree of touch control unit described in described first parameter characterization.

Interference disposal route described in the present embodiment is applied in electronic equipment, and described electronic equipment has touch control unit, and described touch control unit can be capacitive touch control unit; Concrete, described electronic equipment can be the mobile phone, panel computer, all-in-one, desktop computer etc. with touch controllable function.Then in this step, the first parameter of the touch control unit of described detected electrons equipment, comprising: described electronic equipment detects the first parameter of the touch control unit of self.

Concrete, the outermost layer of described touch control unit (as capacitive touch control unit) is glassy layer, scribbles conductive coating (ITO), then form conductive glass layer in glassy layer; Four electrodes are drawn at four angles of conductive glass layer, and electro-conductive glass forms uniform electric field under described four electrodes provide voltage; Conductive glass layer is arranged with the inductance capacitance of array type; Because human body is energized conductor, when user's finger contacts is to touch control unit surface, points and siphon away portion of electrical current from contact point, thus change the capacitance size of inductance capacitance corresponding to described contact point; Controller determines the position coordinates of contact point based on the change of the capacitance size of inductance capacitance.Surface area due to glassy layer is comparatively large and its thickness is thinner, when described touch control unit (being specially glassy layer) is in non-vertical laying state (as keeping flat), what glassy layer can receive self gravitation affects generation deformation, based on this, detect the first parameter of described touch control unit in this step, also namely detect the first parameter of described glassy layer.

Wherein, described touch control unit is arranged on the top of the display panels circuit of described electronic equipment, between described touch control unit and described display panels circuit, there is one deck air layer, namely between described touch control unit and described display panels circuit, there is certain distance; Described air layer is specifically as follows 1.4 millimeters (mm).In the present embodiment, the deformation degree of touch control unit described in described first parameter characterization, described first parameter can be characterized by the distance between described touch control unit and described display panels circuit.Concrete, as a kind of embodiment, described first parameter detects by range sensor and obtains; As touch control unit as described in detecting and as described in the difference of distance between display panels circuit and gauged distance determine as described in the first parameter.As another kind of embodiment, can based on the own wt of described touch control unit (being specially glassy layer), the angle in conjunction with described touch control unit and vertical direction determines described first parameter; Such as, when the angle of described touch control unit and vertical direction is reverse 90 degree, described reverse 90 degree can be understood as and are rotated counterclockwise 90 degree, and namely the touch control unit of described electronic equipment is upper, display panels circuit under; Accordingly, forward 90 degree is rotated ninety degrees clockwise, namely described electronic equipment touch control unit under, display panels circuit is upper.Then when the angle of described touch control unit and vertical direction is reverse 90 degree, because touch control unit is generally the rectangle (as rectangle) of rule, then focus point is the mid point of described rectangle, and also namely the deformation degree of described focus point is maximum; Based on the weight of the glassy layer of described touch control unit, thickness and own material type, determine the first parameter of described touch control unit by preset formula model; Here, the rule of described first parameter is: the first parameter of the focus point of described touch control unit is maximum, and first parameter on four summits of described touch control unit is minimum, and from described focus point to described four summits, described first parameter linearly reduces trend.

Step 202: the central point determining described first touch area based on described first parameter, determines the first touch-control subregion and the second touch-control subregion by described central point; Described first touch area comprises the first touch-control subregion and described second touch-control subregion; Wherein, the point coincides of described first touch-control subregion and described second touch-control subregion, and the area of described first touch-control subregion is not equal to the area of described second touch-control subregion.

Here, described touch control unit has touch area, and described touch area is generally equal to the viewing area of described electronic equipment, and certainly, described touch area also can be unequal with described viewing area.Then in this step, described first touch area is less than or equal to described touch area.Four electrodes are drawn at four angles of the conductive glass layer of described touch control unit, thus make described electro-conductive glass form uniform electric field at described four electrodes applying driving voltage, then in this step, described second parameter is the driving parameter of described touch control unit, and described driving parameter is specifically as follows driving voltage.

In the present embodiment, the described central point determining described first touch area based on described first parameter, the first touch-control subregion and the second touch-control subregion is determined by described central point, comprise: determine the central point of the maximum touch point of described first parameter as described first touch area, namely, using the central point of touch point maximum for the deformation degree of described touch control unit as described first touch area, divide the first touch-control subregion and the second touch-control subregion based on described central point; Due to the impact by the quality of glassy layer of described touch control unit, thickness and material, described first parameter linearly changes to four summits from described central point, and namely described first touch-control subregion and described second touch-control subregion are the region of continuous distribution; Then in this step, be initial point based on described central point, determine described first touch-control subregion by the first radius; Be initial point based on described central point, determine described second touch-control subregion by the second radius; Wherein, described first radius is not equal to described second radius; The size of described first radius and described touch area has the first proportionate relationship; The size of described second radius and described touch area has the second proportionate relationship; Described first proportionate relationship and described second proportionate relationship all with described first parameter positive correlation.Wherein, the maximum touch point of described first parameter can be at least one, and namely the central point of described first touch area is at least one; When the central point of described first touch area is one, described first touch-control subregion is the border circular areas determined by the first radius, and described second touch-control subregion is the border circular areas determined by described second radius; When the central point of described first touch area is at least two, described first touch-control subregion is the elliptical region determined by the first radius; Described second touch-control subregion is the elliptical region determined by the second radius.Wherein, described first radius and described second radius and described first parameter positive correlation, also namely with the deformation degree positive correlation of described touch control unit.Wherein, the area of described first touch-control subregion is not equal to the area of described second touch-control subregion, then the area of described first touch-control subregion is greater than the area of described second touch-control subregion, or the area of described first touch-control subregion is less than the area of described second touch-control subregion.

Step 203: the second parameter adjusting described first touch-control subregion is M1; To adjust in described second touch-control subregion and the second parameter of touch area outside described first touch-control subregion is M2; Wherein, M1 is not equal to M2; M1 and M2 all with described first parameter positive correlation; The driving parameter of touch control unit described in described second parameter characterization.Wherein, the area of described second touch-control subregion is greater than the area of described first touch-control subregion.

In the present embodiment, the area of described second touch-control subregion is greater than for the area of described first touch-control subregion, then the acquiescence of the second parameter of described first touch-control subregion to be the second parameter that M1 is greater than described second touch-control subregion be M2 is greater than described touch control unit drives parameter, can be understood as, the deformation degree of described touch control unit is larger, corresponding driving parameter adjustment larger.

Step 204: the described first touch-control subregion controlling described touch control unit exports described second parameter by M1; To control in described second touch-control subregion and touch area outside described first touch-control subregion exports described second parameter by M2.

Adopt the technical scheme of the embodiment of the present invention; by the detection of the first parameter to touch control unit; thus adjust the second parameter of described touch control unit; make when the deformation degree of described touch control unit is excessive; increase the driving parameter of described touch control unit; avoid touch control operation that the deformation due to touch control unit causes abnormal or without the problem of response, improve the operating experience of user.

Embodiment three

The embodiment of the present invention additionally provides a kind of interference disposal route.The present embodiment is described in detail to the interference disposal route of the embodiment of the present invention to have particular application as example.In the present embodiment, the touch area of the touch control unit of described electronic equipment is equal with the viewing area of display unit and be rectangle, described electronic equipment is in horizontal positioned state, namely described touch control unit and described display unit be in horizontal direction and described touch control unit above described display unit.Fig. 3 is the schematic flow sheet of the interference disposal route of the embodiment of the present invention three; As shown in Figure 3, described method comprises:

Step 301: the first parameter of the touch control unit of detected electrons equipment; The deformation degree of touch control unit described in described first parameter characterization.

Interference disposal route described in the present embodiment is applied in electronic equipment, and described electronic equipment has touch control unit, and described touch control unit can be capacitive touch control unit; Concrete, described electronic equipment can be the mobile phone, panel computer, all-in-one, desktop computer etc. with touch controllable function.Then in this step, the first parameter of the touch control unit of described detected electrons equipment, comprising: described electronic equipment detects the first parameter of the touch control unit of self.

Concrete, the outermost layer of described touch control unit (as capacitive touch control unit) is glassy layer, scribbles conductive coating (ITO), then form conductive glass layer in glassy layer; Four electrodes are drawn at four angles of conductive glass layer, and electro-conductive glass forms uniform electric field under described four electrodes provide voltage; Conductive glass layer is arranged with the inductance capacitance of array type; Because human body is energized conductor, when user's finger contacts is to touch control unit surface, points and siphon away portion of electrical current from contact point, thus change the capacitance size of inductance capacitance corresponding to described contact point; Controller determines the position coordinates of contact point based on the change of the capacitance size of inductance capacitance.Surface area due to glassy layer is comparatively large and its thickness is thinner, when described touch control unit (being specially glassy layer) is in non-vertical laying state (as keeping flat), what glassy layer can receive self gravitation affects generation deformation, based on this, detect the first parameter of described touch control unit in this step, also namely detect the first parameter of described glassy layer.

Wherein, described touch control unit is arranged on the top of the display panels circuit of described electronic equipment, between described touch control unit and described display panels circuit, there is one deck air layer, namely between described touch control unit and described display panels circuit, there is certain distance; Described air layer is specifically as follows 1.4 millimeters (mm).In the present embodiment, the deformation degree of touch control unit described in described first parameter characterization, described first parameter can be characterized by the distance between described touch control unit and described display panels circuit.Concrete, as a kind of embodiment, described first parameter detects by range sensor and obtains; As touch control unit as described in detecting and as described in the difference of distance between display panels circuit and gauged distance determine as described in the first parameter.As another kind of embodiment, can based on the own wt of described touch control unit (being specially glassy layer), the angle in conjunction with described touch control unit and vertical direction determines described first parameter; Such as, when the angle of described touch control unit and vertical direction is reverse 90 degree, described reverse 90 degree can be understood as and are rotated counterclockwise 90 degree, and namely the touch control unit of described electronic equipment is upper, display panels circuit under; Accordingly, forward 90 degree is rotated ninety degrees clockwise, namely described electronic equipment touch control unit under, display panels circuit is upper.Then when the angle of described touch control unit and vertical direction is reverse 90 degree, because touch control unit is generally the rectangle (as rectangle) of rule, then focus point is the mid point of described rectangle, and also namely the deformation degree of described focus point is maximum; Based on the weight of the glassy layer of described touch control unit, thickness and own material type, determine the first parameter of described touch control unit by preset formula model; Here, the rule of described first parameter is: the first parameter of the focus point of described touch control unit is maximum, and first parameter on four summits of described touch control unit is minimum, and from described focus point to described four summits, described first parameter linearly reduces trend.

Step 302: based on described first parameter determination central point O.

Here, in this step, determine the central point of the maximum touch point of described first parameter as described first touch area.Touch control unit due to electronic equipment described in the present embodiment is rectangle, and the outermost glassy layer thickness of described touch control unit is even, and the touch point that therefore described first parameter is maximum is the segment centerline point parallel with the long limit of described touch control unit.Based on this, Fig. 4 is the scene schematic diagram of the first touch area in the embodiment of the present invention three, as shown in Figure 4, with the top left co-ordinate of described touch control unit for (0,0), lower right corner coordinate is (x, y) be example, then determine that the coordinate of described central point O is for (x/2, y/2).

Step 302: centered by O point, X1 is major radius, Y1 is that short radius determines the first touch-control subregion; X2 is major radius, Y2 is that short radius determines the second touch-control subregion; Wherein, X1 is less than X2; Y1 is less than Y2.

In the present embodiment, because described touch control unit is rectangle, then described first touch-control subregion and described second touch-control subregion are elliptic region, be namely major radius with X1, Y1 determines the first elliptic region for short radius, take X2 as major radius, Y2 determines the second elliptic region for short radius.Concrete, X1=N1X, Y1=N1Y; X2=N2X, Y1=N2Y; Wherein, N1 is less than N2.

Concrete, the numerical values recited of N1 and N2 and the numerical values recited positive correlation of described first parameter, namely described first parameter is larger, and the numerical value of N1 and N2 is larger.Such as, N1=0.05 or 0.06; N2=0.10 or 0.15.

Step 303: the second parameter adjusting described first touch-control subregion is M1; To adjust in described second touch-control subregion and the second parameter of touch area outside described first touch-control subregion is M2; Wherein, M1 is greater than M2; M1 and M2 all with described first parameter positive correlation; Wherein, the driving parameter of touch control unit described in described second parameter characterization.Wherein, the area of described second touch-control subregion is greater than the area of described first touch-control subregion.

Here, the driving parameter of touch control unit described in described second parameter characterization, described driving parameter is specifically as follows driving voltage.Wherein, M1 is greater than M2 and is greater than M; M is that the acquiescence of described touch control unit drives parameter.

Step 304: the described first touch-control subregion controlling described touch control unit exports described second parameter by M1; To control in described second touch-control subregion and touch area outside described first touch-control subregion exports described second parameter by M2.

Adopt the technical scheme of the embodiment of the present invention; by the detection of the first parameter to touch control unit; thus adjust the second parameter of described touch control unit; make when the deformation degree of described touch control unit is excessive; increase the driving parameter of described touch control unit; avoid touch control operation that the deformation due to touch control unit causes abnormal or without the problem of response, improve the operating experience of user.

Embodiment four

The embodiment of the present invention additionally provides a kind of electronic equipment.Fig. 5 is the composition structural representation of the electronic equipment of the embodiment of the present invention; As shown in Figure 5, described electronic equipment comprises: touch control unit 50, detecting unit 51, analysis and processing unit 52 and control module 53; Wherein,

Described detecting unit 51, for detecting the first parameter of touch control unit 50; The deformation degree of touch control unit 50 described in described first parameter characterization;

Described analysis and processing unit 52, described first parameter for detecting based on described detecting unit 51 determines the first touch area of described touch control unit 50, and based on the second parameter of the first touch area described in described first parameter adjustment; The driving parameter of touch control unit 50 described in described second parameter characterization;

Described control module 53, exports described second parameter for described first touch area controlling described touch control unit 50.

Wherein, described second parameter after adjustment and described first parameter positive correlation.

Those skilled in the art are to be understood that, the function of each processing unit in the electronic equipment of the embodiment of the present invention, can refer to the associated description of aforementioned interference disposal route and understand, each processing unit in the electronic equipment of the embodiment of the present invention, realizing by realizing the mimic channel of the function described in the embodiment of the present invention, also can be realized by the operation of the software of the function of execution described in the embodiment of the present invention on intelligent terminal.

Embodiment five

The embodiment of the present invention additionally provides a kind of electronic equipment, and as shown in Figure 5, described electronic equipment comprises: touch control unit 50, detecting unit 51, analysis and processing unit 52 and control module 53; Wherein,

Described detecting unit 51, for detecting the first parameter of touch control unit 50; The deformation degree of touch control unit 50 described in described first parameter characterization;

Described analysis and processing unit 52, for determining the central point of described first touch area based on described first parameter, determines the first touch-control subregion and the second touch-control subregion by described central point; Described first touch area comprises the first touch-control subregion and described second touch-control subregion; Wherein, the point coincides of described first touch-control subregion and described second touch-control subregion, and the area of described first touch-control subregion is not equal to the area of described second touch-control subregion; Also for when the area of described second touch-control subregion is greater than the area of described first touch-control subregion, the second parameter adjusting described first touch-control subregion is M1; To adjust in described second touch-control subregion and the second parameter of touch area outside described first touch-control subregion is M2; Wherein, M1 is not equal to M2; M1 and M2 all with described first parameter positive correlation; The driving parameter of touch control unit 50 described in described second parameter characterization;

Described control module 53, exports described second parameter for described first touch area controlling described touch control unit 50.

Wherein, described second parameter after adjustment and described first parameter positive correlation.

Concrete, described analysis and processing unit 52, for determining that the maximum position of described first parameter is the central point of described first touch-control subregion and described second touch-control subregion; The first touch-control subregion is determined by the first radius based on described central point; The second touch-control subregion is determined by the second radius based on described central point; Wherein, described first radius is not equal to described second radius; The size of described first radius and described touch area has the first proportionate relationship; The size of described second radius and described touch area has the second proportionate relationship; Described first proportionate relationship and described second proportionate relationship all with described first parameter positive correlation.

Those skilled in the art are to be understood that, the function of each processing unit in the electronic equipment of the embodiment of the present invention, can refer to the associated description of aforementioned interference disposal route and understand, each processing unit in the electronic equipment of the embodiment of the present invention, realizing by realizing the mimic channel of the function described in the embodiment of the present invention, also can be realized by the operation of the software of the function of execution described in the embodiment of the present invention on intelligent terminal.

In the embodiment of the present invention four and embodiment five, analysis and processing unit 52 in described electronic equipment and control module 53, in actual applications all can by the central processing unit (CPU in described electronic equipment, CentralProcessing Unit), digital signal processor (DSP, Digital Signal Processor) or programmable gate array (FPGA, Field-Programmable Gate Array) realization; Touch control unit 50 in described electronic equipment, can be realized by the capacitance type touch control screen in described electronic equipment in actual applications; Detecting unit 51 in described electronic equipment, can be realized by the sensor (as range sensor) in described electronic equipment in actual applications.

Those skilled in the art should understand, embodiments of the invention can be provided as method, system or computer program.Therefore, the present invention can adopt the form of hardware embodiment, software implementation or the embodiment in conjunction with software and hardware aspect.And the present invention can adopt in one or more form wherein including the upper computer program implemented of computer-usable storage medium (including but not limited to magnetic disk memory and optical memory etc.) of computer usable program code.

The present invention describes with reference to according to the process flow diagram of the method for the embodiment of the present invention, equipment (system) and computer program and/or block scheme.Should understand can by the combination of the flow process in each flow process in computer program instructions realization flow figure and/or block scheme and/or square frame and process flow diagram and/or block scheme and/or square frame.These computer program instructions can being provided to the processor of multi-purpose computer, special purpose computer, Embedded Processor or other programmable data processing device to produce a machine, making the instruction performed by the processor of computing machine or other programmable data processing device produce device for realizing the function of specifying in process flow diagram flow process or multiple flow process and/or block scheme square frame or multiple square frame.

These computer program instructions also can be stored in can in the computer-readable memory that works in a specific way of vectoring computer or other programmable data processing device, the instruction making to be stored in this computer-readable memory produces the manufacture comprising command device, and this command device realizes the function of specifying in process flow diagram flow process or multiple flow process and/or block scheme square frame or multiple square frame.

These computer program instructions also can be loaded in computing machine or other programmable data processing device, make on computing machine or other programmable devices, to perform sequence of operations step to produce computer implemented process, thus the instruction performed on computing machine or other programmable devices is provided for the step realizing the function of specifying in process flow diagram flow process or multiple flow process and/or block scheme square frame or multiple square frame.

The above, be only preferred embodiment of the present invention, be not intended to limit protection scope of the present invention.

Claims (10)

1. disturb a disposal route, described method comprises:

First parameter of the touch control unit of detected electrons equipment; The deformation degree of touch control unit described in described first parameter characterization;

The first touch area of described touch control unit is determined based on described first parameter, and based on the second parameter of the first touch area described in described first parameter adjustment; The driving parameter of touch control unit described in described second parameter characterization;

Described first touch area controlling described touch control unit exports described second parameter.

2. method according to claim 1, is characterized in that, described second parameter after adjustment and described first parameter positive correlation.

3. method according to claim 1, is characterized in that, described the first touch area determining described touch control unit based on described first parameter, comprising:

Determine the central point of described first touch area based on described first parameter, determine the first touch-control subregion and the second touch-control subregion by described central point; Described first touch area comprises the first touch-control subregion and described second touch-control subregion;

Wherein, the point coincides of described first touch-control subregion and described second touch-control subregion, and the area of described first touch-control subregion is not equal to the area of described second touch-control subregion.

4. method according to claim 3, is characterized in that, the described central point determining described first touch area based on described first parameter, determines the first touch-control subregion and the second touch-control subregion, comprising by described central point:

Determine that the maximum position of described first parameter is the central point of described first touch-control subregion and described second touch-control subregion;

The first touch-control subregion is determined by the first radius based on described central point;

The second touch-control subregion is determined by the second radius based on described central point;

Wherein, described first radius is not equal to described second radius; The size of described first radius and described touch area has the first proportionate relationship; The size of described second radius and described touch area has the second proportionate relationship; Described first proportionate relationship and described second proportionate relationship all with described first parameter positive correlation.

5. method according to claim 3, is characterized in that, when the area of described second touch-control subregion is greater than the area of described first touch-control subregion, described the second parameter based on the first touch area described in described first parameter adjustment, comprising:

The second parameter adjusting described first touch-control subregion is M1;

To adjust in described second touch-control subregion and the second parameter of touch area outside described first touch-control subregion is M2;

Wherein, M1 is not equal to M2; M1 and M2 all with described first parameter positive correlation.

6. an electronic equipment, described electronic equipment comprises: touch control unit, detecting unit, analysis and processing unit and control module; Wherein,

Described detecting unit, for detecting the first parameter of touch control unit; The deformation degree of touch control unit described in described first parameter characterization;

Described analysis and processing unit, described first parameter for detecting based on described detecting unit determines the first touch area of described touch control unit, and based on the second parameter of the first touch area described in described first parameter adjustment; The driving parameter of touch control unit described in described second parameter characterization;

Described control module, exports described second parameter for described first touch area controlling described touch control unit.

7. electronic equipment according to claim 6, is characterized in that, described second parameter after adjustment and described first parameter positive correlation.

8. electronic equipment according to claim 6, is characterized in that, described analysis and processing unit, for determining the central point of described first touch area based on described first parameter, determines the first touch-control subregion and the second touch-control subregion by described central point; Described first touch area comprises the first touch-control subregion and described second touch-control subregion; Wherein, the point coincides of described first touch-control subregion and described second touch-control subregion, and the area of described first touch-control subregion is not equal to the area of described second touch-control subregion.

9. electronic equipment according to claim 8, is characterized in that, described analysis and processing unit, for determining that the maximum position of described first parameter is the central point of described first touch-control subregion and described second touch-control subregion; The first touch-control subregion is determined by the first radius based on described central point; The second touch-control subregion is determined by the second radius based on described central point; Wherein, described first radius is not equal to described second radius; The size of described first radius and described touch area has the first proportionate relationship; The size of described second radius and described touch area has the second proportionate relationship; Described first proportionate relationship and described second proportionate relationship all with described first parameter positive correlation.

10. electronic equipment according to claim 8, is characterized in that, described analysis and processing unit, and for when the area of described second touch-control subregion is greater than the area of described first touch-control subregion, the second parameter adjusting described first touch-control subregion is M1; To adjust in described second touch-control subregion and the second parameter of touch area outside described first touch-control subregion is M2; Wherein, M1 is not equal to M2; M1 and M2 all with described first parameter positive correlation.