CN202795313U

CN202795313U - Touch control device and portable electronic device

Info

Publication number: CN202795313U
Application number: CN2011205738057U
Authority: CN
Inventors: 李振刚; 黄臣; 杨云
Original assignee: BYD Co Ltd
Current assignee: BYD Semiconductor Co Ltd
Priority date: 2011-07-26
Filing date: 2011-12-31
Publication date: 2013-03-13
Anticipated expiration: 2021-12-31
Also published as: CN102902429A; CN102902441B; CN102902436A; CN202548807U; CN202548806U; CN202870787U; CN102902444B; CN202795312U; CN102902427B; CN202548804U; TWM449305U; WO2013013635A1; CN102902429B; CN202795310U; CN202795314U; WO2013013625A1; WO2013013634A1; CN102902433A; CN102902444A; CN102902431A

Abstract

The utility model provides a touch control device, comprising: a substrate; a plurality of non-intersecting induction units, and a touch screen control chip. The plurality of induction units are formed on the substrate, and each induction unit is provided with a first electrode and a second electrode. An embodiment of the touch control device and the portable electronic device is advantageous in that, structure is simple, and for each induction unit, detection is performed during charging and discharging, an RC constant can be reduced, time is saved, efficiency is improved, and coordinate offset can be prevented.

Description

Contactor control device and portable electric appts

Technical field

The utility model relates to electronic device design and manufacturing technology field, particularly a kind of contactor control device and a kind of portable electric appts.

Background technology

At present the range of application of touch-screen is from the past ATM (automatic teller machine), and minority's business markets such as industrial computer expand to rapidly mobile phone, the PDA(personal digital assistant), the GPS(GPS), PMP(MP3, even the mass consumption electronic applications such as panel computer MP4 etc.).Be used for touch-screen and have that touch control operation is simple, convenient, the advantage of hommization, so touch-screen is expected to become the best interface of human-computer interaction and is widely applied in portable set rapidly.

Capacitance touch screen is divided into self-capacitance and mutual capacitance two classes usually.As shown in Figure 1, be the structural drawing of a kind of self-capacitance touch screen common in the prior art.This self-capacitance touch screen mainly contains double-deck diamond structure sensing unit 100 ' and 200 ', it detects principle is that X-axis and Y-axis are scanned respectively, exceeded preset range if detect the capacitance variations of certain point of crossing, then with the point of crossing of this row and column as touch coordinate.Although the linearity of this self-capacitance touch screen is better, often there's something fishy, and point occurs, and is difficult to realize multiple point touching.In addition, owing to adopt bilayer screen, also can cause structure and cost significantly to increase, and diamond structure the coordinate drift can occur in the very little situation of capacitance change, affected greatly by external interference.

Shown in Fig. 2 a, be the structural drawing of another kind of self-capacitance touch screen common in the prior art.This self-capacitance touch screen adopts triangular pattern screen structure.This self-capacitance touch screen comprises substrate 300 ', is arranged on a plurality of electrodes 500 ' that a plurality of triangle sensing units 400 ' on the substrate 300 ' link to each other with each triangle sensing unit 400 '.Shown in Fig. 2 b, be the detection principle of triangle self-capacitance touch screen.As shown in the figure, ellipse representation finger, S1, S2 represent to point the contact area with two triangle sensing units.The false coordinate initial point is in the lower left corner, horizontal ordinate X=S2/ (S1+S2) * P then, and wherein, P is resolution.When finger moved right, because S2 is not linear the increase, there was a deviation in the X coordinate.Can find out that from above-mentioned principle present triangle sensing unit is single-ended detection, namely only detect from a direction, then calculate the coordinate of both direction by algorithm.Although this self-capacitance touch screen structure is more simple, the capacitive sensing for screen is not optimized, and capacitance change is little, thereby causes signal to noise ratio (S/N ratio) inadequate.In addition, because this sensing unit is triangle, area is not linear the increase when the finger transverse shifting, so the linearity is relatively poor, has caused coordinate Calculation to be offset, and the linearity is good not.

In addition, this capacitive sensing unit output capacitance variable quantity is very little, reaches the flying method level, and the existence of its cable stray capacitance is had higher requirement to metering circuit.And stray capacitance can change with many factors such as temperature, position, inner electric field and outer electric field distributions, disturbs even floods the measured capacitance signal.In addition, for individual layer electric capacity, because the meeting that affects of Vcom level signal forms serious interference to inductance capacitance, wherein, the Vcom level signal is not stop the level signal of overturning in order to prevent the lcd screen liquid crystal aging.

The utility model content

The purpose of this utility model is intended to solve at least one of above-mentioned technological deficiency, particularly solves or avoid to occur the above-mentioned shortcoming in the existing self-capacitance touch screen.

The utility model embodiment first aspect has proposed a kind of contactor control device, comprising: substrate; A plurality of disjoint sensing units, described a plurality of sensing units are formed on the described substrate, and the two ends of each sensing unit have respectively the first electrode and the second electrode; The touch-screen control chip, described touch-screen control chip comprises charging device, discharge device, detection means and control and calculating device, wherein, described charging device, be used in the charging process first time, one in described a plurality of sensing units in the first electrode of a sensing unit and the second electrode applies high level signal, and with another ground connection in described the first electrode and the second electrode, carry out the charging first time with the self-capacitance that when a described sensing unit is touched, a described sensing unit is produced; In second time charging process, the first electrode and the second electrode to a described sensing unit apply high level signal, perhaps, in described the first electrode and described the second electrode one applies high level signal and with another disconnection in described the first electrode and described the second electrode, described self-capacitance is carried out the charging second time, described discharge device, be used for after described charging device charges for the first time to described self-capacitance, with the first electrode of a described sensing unit and at least one ground connection in the second electrode, described self-capacitance is carried out the discharge first time, and after described charging device charges for the second time to described self-capacitance, with the first electrode of a described sensing unit and a ground connection in the second electrode, with another disconnection in described the first electrode and described the second electrode, described self-capacitance is carried out the discharge second time, and detection means, be used for detecting to obtain the first change detected value between the described charging first time and the described first time of the discharge from described first electrode of correspondence or the second electrode, and detect to obtain the second change detected value between the described charging second time and the described second time of the discharge from described first electrode of correspondence or the second electrode, and control and calculating device, be used for described charging device, discharge device, detection means is controlled, and according to the first change detected value and the second change detected value calculate described self-capacitance to the first resistance between described the first electrode and described self-capacitance to the proportionate relationship between the second resistance between described the second electrode, and determine touch location according to the proportionate relationship between described the first resistance and described the second resistance.

Further, described detection means is capacitance detecting device CTS.

Further, described sensing unit is rectangle, and the first direction of described a plurality of sensing unit and described touch-screen is parallel to each other, and described touch location is the touch location on described first direction.

Further, a plurality of firsts and a plurality of parallel second portions, wherein, link to each other by described second portion between the adjacent described first, with the first groove and the second groove that forms a plurality of alternative arrangements, wherein, the opening direction of described a plurality of the first grooves and described a plurality of the second grooves is opposite, and described touch location is for touching the touch location of object on described first direction.

Further, described first direction is the length direction of described sensing unit, and described second direction is the direction perpendicular to described sensing unit, and described sensing unit horizontal parallel arranges or the vertical parallel setting.

Further, described a plurality of disjoint sensing unit is positioned at same layer.

Further, described sensing unit comprises: third part; Disjoint the 4th part and the 5th part, described the 4th part one end links to each other with an end of described third part, one end of described the 5th part links to each other with the other end of described third part, the described tetrameric other end has described the first electrode, and the other end of described the 5th part has described the second electrode.

Further, described sensing unit comprises: the 6th part, and an end of described the 6th part has described the first electrode; The 7th part, an end of described the 7th part links to each other with the other end of described the 6th part, and the other end of described the 7th part has described the second electrode.

The utility model embodiment second aspect has also proposed a kind of portable electric appts, comprises aforesaid contactor control device.

Sensing unit in the Touch-screen testing equipment of the utility model embodiment adopts both-end to detect, the two ends that are sensing unit all have electrode, and each electrode all links to each other with the corresponding pin of touch-screen control chip, can realize location to the touch point touching when detecting by sensing unit self.

What is more important, the utility model is realized determining of touch location by calculating the first resistance and the second resistance ratio, therefore with respect to present rhombus or triangular design, because when determining touch location, need not to calculate the size of self-capacitance, and the size of self-capacitance can not affect the precision of touch location, thereby has improved measuring accuracy, has improved the linearity.

The utility model embodiment applies level signal by the electrode to the sensing unit two ends, if this sensing unit is touched, touch object (for example finger) and then can form self-capacitance with this sensing unit, therefore the utility model can charge to this self-capacitance by the level signal that applies, and determines touch location on the touch-screen according to the proportionate relationship between the first resistance and the second resistance.And by the detection mode that self-capacitance is carried out twice charging of the utility model embodiment, offsetting some immeasurablel physical parameter or to reduce the measurement of physical quantity, thereby under the prerequisite that guarantees detection speed, effectively improve accuracy of detection.

The utility model embodiment has proposed a kind of self-capacitance detection mode of novelty, when sensing unit is touched, the touch point just can be divided into this sensing unit two resistance, thereby is carrying out considering when self-capacitance detects that these two resistance just can determine the position of touch point on this sensing unit.The utility model embodiment's is simple in structure, and for a sensing unit, detects when charge or discharge, not only can reduce the RC constant, saves time and raises the efficiency, and can guarantee that coordinate can not be offset.In addition, the property that the utility model embodiment can also the Effective Raise circuit ratio of making an uproar reduces circuit noise, improves the induction linearity.In addition, in testing process because the sensing unit that is touched is charged, therefore wherein can produce little electric current, can eliminate well the Vcom level signal to the impact of the self-capacitance of sensing unit generation in the touch-screen, therefore screenmask layer and concerned process steps can be correspondingly eliminated, thereby cost can be when having strengthened antijamming capability, further reduced.

The aspect that the utility model is additional and advantage in the following description part provide, and part will become obviously from the following description, or recognize by practice of the present utility model.

Description of drawings

Above-mentioned and/or the additional aspect of the utility model and advantage are from obviously and easily understanding becoming the description of embodiment below in conjunction with accompanying drawing, wherein:

Fig. 1 is the structural drawing of a kind of self-capacitance touch screen common in the prior art;

Fig. 2 a is the structural drawing of another kind of self-capacitance touch screen common in the prior art;

Fig. 2 b is the detection schematic diagram of another kind of self-capacitance touch screen common in the prior art;

Fig. 3 is the detection principle schematic of the utility model embodiment contactor control device;

Fig. 4 is the touch detecting method process flow diagram of the utility model embodiment;

Fig. 5 is the synoptic diagram that the rectangle sensing unit of the utility model embodiment is touched;

Fig. 6 a is the sensing unit structural drawing of an embodiment of the utility model;

Fig. 6 b is the sensing unit structural drawing of an embodiment of the utility model;

Fig. 7 a is another embodiment Touch-screen testing equipment structural drawing of the utility model;

Fig. 7 b is another embodiment touch screen detection device structural drawing of the utility model;

Fig. 8 is the synoptic diagram of the sensing unit of the utility model embodiment when being touched;

Fig. 9 a is another embodiment Touch-screen testing equipment structural drawing of the utility model;

Fig. 9 b is another embodiment touch screen detection device structural drawing of the utility model;

Figure 10 is the synoptic diagram of the sensing unit of the utility model embodiment when being touched;

Figure 11 is the contactor control device synoptic diagram of an embodiment of the utility model;

Figure 12 is the structural drawing of the utility model embodiment touch-screen control chip.

Embodiment

The below describes embodiment of the present utility model in detail, and the example of described embodiment is shown in the drawings, and wherein identical or similar label represents identical or similar element or the element with identical or similar functions from start to finish.Be exemplary below by the embodiment that is described with reference to the drawings, only be used for explaining the utility model, and can not be interpreted as restriction of the present utility model.

The utility model embodiment has proposed a kind of self-capacitance detection mode of novelty, when sensing unit is touched, the touch point can be divided into this sensing unit two resistance, is carrying out considering when self-capacitance detects that these two resistance just can determine the position of touch point on this sensing unit.As shown in Figure 3, be the detection principle schematic of the utility model embodiment contactor control device.When this sensing unit of finger touch, will be equivalent to this sensing unit is divided into two resistance, the resistance of these two resistance is relevant with the position of touch point.For example, as described in Figure, when touch point and the first electrode were nearer, then resistance R 1 was just less, and resistance R 2 is just larger; Otherwise when touch point and the second electrode were nearer, then resistance R 1 was just larger, and resistance R 2 is just less.Therefore, the utility model just can be determined the position of touch point on this sensing unit by the detection to resistance R 1 and R2.In embodiment of the present utility model, detect in several ways resistance R 1 and R2, for example can be by in the current detecting changing value, self-capacitance change detected value, level signal change detected value and the charge variation amount that detect the first electrode and the second electrode one or more, thus resistance R 1 and R2 obtained according to these change detected values.And the measurement of the utility model by the self-capacitance that is formed by the touch point being carried out charge to offset some immeasurablel physical parameter for twice or reduce physical quantity improves measuring accuracy.

Need to prove, in embodiment of the present utility model, above-mentioned the first electrode is identical with the function of the second electrode, and the two can exchange, therefore in the above-described embodiments, both can also can be from the second electrode detection from the first electrode detection, if can satisfy in charging, discharge or when detecting needs electric current is arranged through the first resistance and this requirement of the second resistance.

In embodiment of the present utility model, can apply corresponding voltage to a plurality of sensing units successively in the mode of scanning, when detecting, also can detect successively in the mode of scanning simultaneously.

As shown in Figure 4, be the touch detecting method process flow diagram of the utility model embodiment, this process flow diagram together describes in conjunction with schematic diagram shown in Figure 3.The method may further comprise the steps:

Step S401, one in described a plurality of sensing units in the first electrode of a sensing unit and the second electrode applies high level signal, and with another ground connection in described the first electrode and the second electrode, carry out the charging first time with the self-capacitance that when sensing unit is touched, sensing unit is produced.In this embodiment, in the first electrode and the second electrode applies high level signal Vcc.

If this moment, this sensing unit was pointed or other objects touches, then this sensing unit will produce self-capacitance C1(with reference to Fig. 3), therefore just can charge to self-capacitance by the high level signal Vcc that applies.At this moment, in an embodiment of the present utility model, if apply high level signal to the first electrode, the voltage that then is applied on the self-capacitance is V2=VccR2/ (R1+R2).In an embodiment of the present utility model, if apply high level signal to the second electrode, the voltage that then is applied on the self-capacitance is V1=VccR1/ (R1+R2).

In addition, in embodiment of the present utility model, by the charging to self-capacitance, can also improve the accuracy of detection of self-capacitance.

In an embodiment of the present utility model, if this sensing unit is not touched, therefore the then follow-up existence that can't detect self-capacitance can judge that it is not touched.

Step S402 is with the first electrode of a sensing unit and at least one ground connection in the second electrode.Particularly, for example with the first electrode and the equal ground connection of the second electrode of a sensing unit, perhaps with the first electrode grounding, the second electrode disconnects, and perhaps with the second electrode grounding, the first electrode disconnects, self-capacitance is carried out the discharge first time.

Step S403 detects to obtain for the first time charging and the first change detected value between the discharge for the first time from the first electrode of correspondence or the second electrode.In embodiment of the present utility model, described correspondence refers to following situation, for example, when the first electrode of a sensing unit and the equal ground connection of the second electrode are discharged, all can detect from the first electrode and the second electrode; As when the first electrode grounding, when the second electrode disconnects, then can only be from the first electrode detection; Otherwise, when the second electrode grounding, when the first electrode disconnects, then can only be from the second electrode detection.

In the present embodiment, suppose that the first change detected value is Δ Q1.Below be described as the charge variation amount as example take the first change detected value and the second change detected value, but can reaction resistance R1 and other change detected values of R2 Relations Among, also all can adopt such as level signal, electric current etc.

Wherein, if in step S401, apply high level signal to the first electrode, then Δ Q1=V2C1=VccC1R2/ (R1+R2) (1a).Wherein, V2=VccR2/ (R1+R2), the voltage of self-capacitance was V2 when charged this moment for the first time, this self-capacitance voltage can detect when charging for the first time or calculate.

Wherein, if in step S401, apply high level signal to the second electrode, then Δ Q1=V1C1=VccC1R1/ (R1+R2) (1b).Wherein, V1=VccR1/ (R1+R2), the voltage of self-capacitance was V1 when charged this moment for the first time, this self-capacitance voltage can detect when charging for the first time or calculate.Step S404, the first electrode and the second electrode to sensing unit apply high level signal, perhaps, in the first electrode and described the second electrode applies high level signal and with another disconnection in described the first electrode and the second electrode, charges self-capacitance is carried out the second time.In the utility model embodiment, can all apply high level signal to the first electrode and the second electrode; Perhaps, apply high level signal to the first electrode, and the second electrode disconnects; Perhaps, the second electrode is applied high level signal, and the first electrode disconnects.Be pointed out that in addition, because the high level signal that applies is known quantity, so the high level signal that applies for twice can be identical or not identical, all do not affect derivation.In this embodiment, to the first electrode and/or the second electrode apply with step S401 in identical high level signal Vcc.Therefore the voltage that is applied on the self-capacitance this moment is Vcc.

Step S405 is with the first electrode of a sensing unit and a ground connection in the second electrode, with another disconnection in the first electrode and described the second electrode, described self-capacitance is carried out the discharge second time.For example, can with the first electrode grounding, the second electrode be disconnected; Perhaps with the second electrode grounding, the first electrode is disconnected.

Step S406 detects to obtain for the second time charging and the second change detected value between the discharge for the second time from the first electrode of correspondence or the second electrode.In the present embodiment, suppose that the second change detected value is Δ Q2.The second change detected value need adopt the change detected value identical with the first change detected value among the step S403, namely is the charge variation amount in the utility model embodiment.Similarly, said " corresponding " also be relative concept, for example when discharging for the second time, if the second electrode disconnects, then can only detect from the first electrode.

In embodiment of the present utility model, because the voltage that is applied on the self-capacitance when charging for the second time is Vcc, and because Vcc=V1+V2, therefore, just can calculate Vcc by the second change detected value (for example charge variation value) between for the second time charging and the discharge second time this moment, obtains voltage V1+V2 thereby calculate.

Wherein, Δ Q2=VccC1=V1+V2C1(2)

Step S407, calculate the first resistance between self-capacitance to the first electrode and the proportionate relationship of the second resistance between self-capacitance to the second electrode according to the first change detected value and the second change detected value, and determine touch location according to the proportionate relationship of the first resistance and the second resistance.In an embodiment of the present utility model, the represented self-capacitance charge variation amount in through type (1) and (2) can calculate the proportionate relationship of R1 and R2, because the regular linear of figure concerns, then can calculate the position of the horizontal ordinate at place, touch point, and the position at self-capacitance C1 place.

In embodiment of the present utility model, if in step 401, apply high level signal to the first electrode, therefore R1/R2=(Δ Q2-Δ Q1)/Δ Q1 then just can obtain proportionate relationship between R1 and the R2 by the utility model embodiment.

In embodiment of the present utility model, if in step 401, apply high level signal to the second electrode, therefore R1/R2=Δ Q1/ (Δ Q2-Δ Q1) then just can obtain proportionate relationship between R1 and the R2 by the utility model embodiment.In embodiment of the present utility model, if sensing unit is door shape sensing unit or L shaped sensing unit, then just can determine touch location on touch-screen to describe in detail below with reference to concrete example by the ratio between the first resistance and the second resistance.But in other embodiment of the present utility model, if sensing unit is rectangle sensing unit or snakelike (but see on the whole be equivalent to rectangle) sensing unit, then step S407 can only calculate the touch location on the touch-screen first direction, and this first direction can be the length direction (for example horizontal direction of touch-screen) of sensing unit.

If sensing unit is rectangle sensing unit or snakelike (but see on the whole be equivalent to rectangle) sensing unit, then also need the touch location of location positioning on second direction according to sensing unit.In an embodiment of the present utility model, first direction is the length direction of sensing unit, and second direction is the direction perpendicular to sensing unit, and sensing unit is horizontally disposed with or vertically arranges.

Be pointed out that; the above-mentioned charge and discharge process first time (step S401-step S403) the and for the second time order of charge and discharge process (step S404-step S406) can intermodulation; namely carry out first step S404-step S406; carry out again step S401-step S403; do not depart from too thought of the present utility model, be included within the protection domain of the present utility model.

In embodiment of the present utility model, the self-capacitance detection means can be at present known CTS(capacitance detecting device), therefore do not repeat them here.

In an embodiment of the present utility model, if adopt two self-capacitance detection means, but then owing to two a plurality of devices of self-capacitance detection means technique, therefore can not increase the overall power of chip.

In an embodiment of the present utility model, sensing unit can take different shapes.Preferably, a plurality of disjoint sensing units are positioned at same layer, thereby in the situation that guarantees accuracy of detection, can greatly save cost.

As shown in Figure 5, the synoptic diagram that is touched for the rectangle sensing unit of the utility model embodiment.This sensing unit is rectangle, and the first direction of a plurality of sensing unit and described touch-screen is parallel to each other, so touch location is the touch location on first direction.

Shown in Fig. 6 a, be the sensing unit structural drawing of an embodiment of the utility model.This sensing unit 200 comprises a plurality of firsts 230 and a plurality of parallel second portions 240, wherein, link to each other by second portion 240 between the adjacent first 230, with the first groove 1000 and the second groove 2000 that forms a plurality of alternative arrangements, wherein, the opening direction of a plurality of the first grooves 1000 and a plurality of the second grooves 2000 is opposite, and touch location is for touching the touch location of object on first direction.Preferably, second portion 240 is arranged along first direction.In an embodiment of the present utility model, a plurality of firsts 230 can be parallel to each other, also can be not parallel.And preferably, second portion 240 is rectangle.In other embodiment of the present utility model, first 230 also can be rectangle, but first 230 also can be other various shape.In this embodiment, by the impedance of first's 230 increase resistance, thus the impedance that increases sensing unit 200, so that the first resistance and the easier detection of the second resistance improve accuracy of detection further.And in this embodiment, preferably, the interval between the second portion 240 is equal, thereby can improve equably from the impedance of sensing unit, to improve accuracy of detection.In an embodiment of the present utility model, first direction is the length direction of sensing unit 200, and second direction is the direction perpendicular to sensing unit 200, and particularly, sensing unit 200 can be horizontally disposed with or vertically arrange.

In embodiment of the present utility model, the size of sensing unit 200 length directions and the size of substrate are basically identical, so contactor control device is simple in structure, make easily, and low cost of manufacture.

In an embodiment of the present utility model, the first electrode 210 and the second electrode 220 link to each other with two firsts in a plurality of firsts 230 respectively.But in another embodiment of the present utility model, the first electrode 210 and the second electrode 220 link to each other with two second portions in a plurality of second portions 240 respectively, shown in Fig. 6 b.

And in embodiment of the present utility model, mutually vertical between second portion 240 and the first 230, the angle between the two is preferably 90 degree, certainly also can select other angles.Shown in Fig. 6 a, this sensing unit 200 joins end to end a plurality of firsts 230 by a plurality of second portions 240, and the first electrode 210 of sensing unit 200 links to each other with the first 230 at two ends respectively with the second electrode 220.On one-piece construction, this sensing unit 200 is for having the rectangle than the aspect ratio.This need to prove, although in Fig. 6 a with sensing unit 200 along the X-axis setting, it will be understood by those skilled in the art that this sensing unit 200 also can be along the Y-axis setting.Structure by this sensing unit is noise reduction effectively, improves the linearity of induction.

Shown in Fig. 7 a, be the sensing unit structural drawing of another embodiment of the utility model.In this embodiment, this sensing unit 200 can be a shape, and the length of each sensing unit 200 is different in a plurality of sensing unit 200, and is mutually nested between a plurality of sensing units 200.Wherein, each described sensing unit comprises third part 250, disjoint the 4th part 260 and the 5th part 270.Preferably, third part 250 is parallel with the first side 110 of substrate 100, the 4th part 260 is parallel with the Second Edge 120 of substrate 100 with the 5th part 270, and the 4th part 260 1 ends link to each other with an end of third part 250, and an end of the 5th part 270 links to each other with the other end of third part 250.The other end that the other end of the 4th part 260 of sensing unit 200 has the first electrode 210, the five parts 270 has the second electrode 220, and wherein, each first electrode 210 all links to each other with the corresponding pin of touch-screen control chip with the second electrode 220.

In embodiment of the present utility model, the so-called mutually nested sensing unit in the outside that refers to partly surrounds inboard sensing unit, for example shown in Fig. 7 a, can reach larger coverage rate when guaranteeing precision like this, and reduce the complexity of computing, improve the response speed of touch-screen.Certainly those skilled in the art also can adopt according to the thought of Fig. 7 a other mutually nested modes to arrange sensing unit.In an embodiment of the present utility model, the third part 250 of each sensing unit 200 is parallel with the third part 250 of other sensing units 200, the 4th part 260 of each sensing unit 200 is parallel with the 4th part 260 of other sensing units 200, and the 5th part 270 of each sensing unit 200 is parallel with the 5th part 270 of other sensing units 200.In an embodiment of the present utility model, at least one is rectangle in the third part 250 of sensing unit 200, the 4th part 260 and the 5th part 270, and preferably, third part 250, the 4th part 260 and the 5th part 270 are rectangle.In this embodiment because rectangular configuration figure rule, therefore finger laterally or when vertically moving the linearity good, in addition, the spacing between two rectangular configuration is identical, is convenient to calculate, thereby improves computing velocity.

In an embodiment of the present utility model, the 4th part 260 of each sensing unit 200 and the 5th part 270 equal in length.

In an embodiment of the present utility model, substrate 100 is rectangle, and is mutually vertical between first side 110 and the Second Edge 120, and mutually vertical between the 4th part 260 and the third part 250, mutually vertical between the 5th part 270 and the third part 250.

In an embodiment of the present utility model, spacing between the third part 250 of adjacent two sensing units 200 equates, spacing between the 4th part 260 of adjacent two sensing units 200 equates that the spacing between the 5th part 270 of adjacent two sensing units 200 equates.So just can evenly divide by first side 110 and the Second Edge 120 of 200 pairs of touch-screens of a plurality of sensing units, thereby improve arithmetic speed.Certainly in other embodiment of the present utility model, the spacing between the third part 250 of adjacent two sensing units 200 also can be unequal, and perhaps, the spacing between the 4th part 260 of adjacent two sensing units 200 also can be unequal, shown in Fig. 7 b.For example, because the user often touches the centre of touch-screen, therefore the spacing between the sensing unit at touch screen center position can be reduced, thereby improve the accuracy of detection in centre.

In an embodiment of the present utility model, a plurality of sensing units 200 are symmetrical with respect to the central shaft Y of substrate 100, and shown in Fig. 7 a, central shaft Y is perpendicular to third part 250, thereby more is conducive to improve precision.

Shown in Fig. 7 a, in this embodiment, the first electrode 210 and second electrode 220 of sensing unit 200 all are positioned on the first side 110 of substrate 100.In this embodiment, detect after the touch location on sensing unit, can obtain the touch location on touch-screen.

Need to prove, above-mentioned Fig. 7 a is the more excellent embodiment of the utility model, it can obtain larger coverage rate, but other embodiment of the present utility model can carry out the variation that some are equal to Fig. 7 a, and for example the 4th part 260 and the 5th part 270 can be uneven.

The structure of the sensing unit employing similar door shape among the utility model embodiment, not only simple in structure, to be convenient to make, institute is leaded all together on one side, and it is convenient to design, and reduces silver-colored slurry cost and making easily, and Decrease production cost is had very great help.

Synoptic diagram when being touched for the sensing unit of the utility model embodiment as shown in Figure 8.As can be seen from Figure 8, the first electrode is 210, the second electrode is 220, touch location is close to the second electrode, the length of supposing sensing unit is 10 unit lengths, and sensing unit is divided into 10 parts equably, wherein, the length of sensing unit third part 250 is 4 unit lengths, and the length of sensing unit the 4th part 260 and the 5th part 270 is 3 unit lengths.Through detecting, the ratio of knowing the first resistance and the second resistance is 4:1, and namely the first electrode 210 to the length (being embodied by the first resistance) of touch location is 80% of whole sensing unit length.In other words, the touch point is positioned at the position of 8 unit lengths in distance the first electrode 210 places, knows, the touch point is positioned at the position of 2 unit lengths in distance the second electrode 220 places.When finger was mobile, therefore the corresponding movement of touch location meeting just can judge the corresponding motion track of finger by the conversion of touch location, thereby judged user's input instruction.

Can find out that from the above example of Fig. 8 account form of the present utility model is very simple, therefore can greatly improve the reaction velocity that touch-screen detects.In embodiment of the present utility model, usually finger or other objects can touch a plurality of sensing units, can obtain first in a plurality of sensing units that this is touched the touch location of each this moment, then calculate final touch location on touch-screen by the mode that is averaging.

Shown in Fig. 9 a, be another embodiment Touch-screen testing equipment structural drawing of the utility model.In an embodiment of the present utility model, the length of a plurality of sensing units increases gradually, and each described sensing unit comprises the 6th part 280 and the 7th part 290.The end that one end of the 6th part 280 has the first electrode 210, the seven parts 290 links to each other with the other end of the 6th part 280, and the other end of the 7th part 290 has the second electrode 220.

Particularly, the 6th part 280 is parallel with the first side 110 of substrate 100, and the 7th part 290 is parallel with the Second Edge 120 of substrate 100, and first side 110 is adjacent with Second Edge 120.And each first electrode 210 all links to each other with the corresponding pin of touch-screen control chip with the second electrode 220.

In preferred embodiment of the present utility model, the 6th part 280 of each sensing unit 200 is parallel with the 6th part 280 of other sensing units 200, and the 7th part 290 of each sensing unit 200 is parallel with the 7th part 290 of other sensing units 200.Can effectively improve sensing unit to the coverage rate of touch-screen by such setting.In an embodiment of the present utility model, at least one is rectangle in the 6th part 280 of sensing unit 200, the 7th part 290, and preferably, the 6th part 280, the 7th part 290 are rectangle.In this embodiment because rectangular configuration figure rule, therefore finger laterally or when vertically moving the linearity good, in addition, the spacing between two rectangular configuration is identical, is convenient to calculate.

Sensing unit in the touch screen detection device of the utility model embodiment adopts both-end to detect, the two ends that are sensing unit all have electrode, and each electrode all links to each other with the corresponding pin of touch-screen control chip, can realize location to the touch point touching when detecting by sensing unit self.

What is more important, the utility model is realized determining of touch location by calculating the first resistance and the second resistance ratio, therefore with respect to present rhombus or triangular design, because when determining touch location, need not to calculate the size of self-capacitance, and the size of self-capacitance can not affect the precision of touch location, the dependence of self-capacitance accuracy of detection is reduced, thereby improved measuring accuracy, improved the linearity.In addition, any one all can be the rectangle of regular shape because in the 5th part 270, the 6th part 280 and the 7th part 290 of the utility model embodiment, therefore with respect to irregular shapes such as present rhombus or triangles, also can improve further the linearity.

In an embodiment of the present utility model, the 6th part 280 of each sensing unit and the 7th part 290 equal in length, thus can improve arithmetic speed.Preferably, substrate 100 is rectangle, and is mutually vertical between first side 110 and the Second Edge 120.First side 110 is mutually vertical with Second Edge 120, not only so that the sensing unit design is more regular, for example so that also mutually vertical between the 6th part 280 of sensing unit and the 7th part 290, thereby improve the coverage rate to touch-screen, and mutually vertically also can improve the linearity of detection between the 6th part 280 and the 7th part 290.

In an embodiment of the present utility model, the spacing between adjacent two sensing units 200 equates.So just can evenly divide by first side 110 and the Second Edge 120 of 200 pairs of touch-screens of a plurality of sensing units, thereby improve arithmetic speed.

Certainly in another embodiment of the present utility model, spacing between adjacent two sensing units 200 can not wait yet, shown in Fig. 9 b, for example because the user often touches the centre of touch-screen, therefore the spacing between the sensing unit at touch screen center position can be reduced, thereby improve the accuracy of detection in centre.

Shown in Fig. 9 a, in this embodiment, the first electrode 210 of sensing unit 200 is positioned on the first side 110 of substrate 100, and the second electrode 220 is positioned on the Second Edge 120 of substrate 100, and first side 110 is mutually vertical with Second Edge 120.In this embodiment, detect after the touch location on sensing unit, can obtain the touch location on touch-screen.

Synoptic diagram when being touched for the sensing unit of the utility model embodiment as shown in figure 10.As can be seen from Figure 10, the first electrode is 210, the second electrode is 220, touch location is close to the second electrode 220, the length of supposing sensing unit is 10 unit lengths, and sensing unit is divided into 10 parts equably, wherein, the length of the 6th part 280 of sensing unit is 5 unit lengths, and the length of the 7th part 290 of sensing unit is 5 unit lengths.Through detecting, the ratio of knowing the first resistance and the second resistance is 9:1, and namely the first electrode 210 to the length (being embodied by the first resistance) of touch location is 90% of whole sensing unit length.In other words, the touch point is positioned at the position of 9 unit lengths in distance the first electrode 210 places, knows, the touch point is positioned at the position of 1 unit length in distance the second electrode 220 places.

Can find out that from the above example of Figure 10 account form of the present utility model is very simple, therefore can greatly improve the reaction velocity that touch-screen detects.

In an embodiment of the present utility model, a plurality of sensing units 200 are positioned at same layer, therefore only need one deck ITO to get final product, thereby when guaranteeing precision, greatly reduce manufacturing cost.

In sum, the utility model embodiment applies level signal by the electrode to the sensing unit two ends, if this sensing unit is touched, then can form self-capacitance by this sensing unit, therefore the utility model can charge to this self-capacitance by the level signal that applies, and determines touch location on first direction according to the proportionate relationship between the first resistance and the second resistance.For example in an embodiment of the present utility model, proportionate relationship between the first resistance and the second resistance is according to described self-capacitance charge/discharge the time, from described the first electrode and/or the second electrode detects the first detected value of acquisition and the proportionate relationship between the second detected value calculates.The first detected value and the second detected value that produce during therefore from the first electrode and/or this self-capacitance charge/discharge of the second electrode detection.Like this, just can react the position that the touch point is positioned at this sensing unit by the first detected value and the second detected value, thereby determine that further the touch point is in the position of touch-screen.

For the sensing unit of Fig. 5 and Fig. 6, after having determined the touch location on the first direction, also need further the touch location of location positioning on second direction according to the sensing unit that is touched.In embodiment of the present utility model, can be with reference to shown in Fig. 5 and 6, if detect the first detected value of certain sensing unit or the second detected value greater than predetermined threshold value, illustrate that then this sensing unit is touched.Suppose that second sensing unit (its ordinate is M) is touched, then the touch location on second direction just is the coordinate M of second sensing unit.Afterwards, determine the position of touch point on touch-screen according to the touch location on the first direction and the touch location on the second direction again.

Particularly, can adopt centroid algorithm to calculate the touch location of touch point on second direction, below centroid algorithm simply be introduced.

In draw runner and touch pad application, often be necessary more than the essential spacing of concrete sensing unit, to determine the position of finger (or other capacitive object).The touch panel of finger on draw runner or touch pad is usually greater than any sensing unit.In order to adopt the position after touch is calculated at a center, this array is scanned to verify that given sensing station is effectively, be to be greater than default touch threshold for the requirement of the adjacent sensing unit signal of some.After finding the strongest signal, this signal and those greater than the closing signal of touch threshold all for computing center:

N_{Cent} = \frac{n_{i - 1} (i - 1) + n_{i} i + n_{i + 1} (i + 1)}{n_{i - 1} {+ n}_{i} + n_{i + 1}}

Wherein, locate the label of sensing unit centered by the Ncent, n is the number that detects the sensing unit that is touched, and i is the sequence number of sensing unit of being touched, and wherein i is more than or equal to 2.

For example, when finger touch at article one passage, its capacitance change is y1, the capacitance change on the second passage is that the capacitance change on y2 and the 3rd passage is when being y3.Wherein second channel y2 capacitance change is maximum.The Y coordinate just can be at last:

Y = \frac{y 1 * 1 + y 2 * 2 + y 3 * 3}{y 1 + y 2 + y 3} .

As shown in figure 11, be the contactor control device synoptic diagram of an embodiment of the utility model.This contactor control device comprises touch screen detection device, the touch-screen control chip 300 that is made of substrate 100 and a plurality of disjoint sensing unit 200.Wherein, a part of pin in the touch-screen control chip 300 links to each other with the first electrode 210 of a plurality of sensing units 200, another part pin in the touch-screen control chip 300 links to each other with the second electrode 220 of a plurality of sensing units 200, and touch-screen control chip 300 applies level signal to the first electrode 210 and/or second electrode 220 of a plurality of sensing units 200, the self-capacitance charging that this level signal produces to sensing unit 200 when sensing unit 200 is touched.

As shown in figure 12, be the structural drawing of the utility model embodiment touch-screen control chip.Touch-screen control chip 300 comprises charging device 310, discharge device 320, detection means 330 and control and calculating device 340.Charging device 310 is in first time charging process, one in a plurality of sensing units 200 in the first electrode 210 of a sensing unit 200 and the second electrode 220 applies high level signal, and with another ground connection in the first electrode 210 and the second electrode 220, carry out the charging first time with the self-capacitance that when a sensing unit 200 is touched, this sensing unit 200 is produced; In second time charging process, the first electrode 210 and the second electrode 220 to a sensing unit 200 apply high level signal, perhaps, in the first electrode 210 and the second electrode 220 one applies high level signal and with another disconnection in the first electrode 210 and the second electrode 220, self-capacitance is carried out the charging second time.Discharge device 320 is after 310 pairs of self-capacitances of charging device charge for the first time, the first electrode and at least one ground connection in the second electrode of sensing unit 200 are discharged self-capacitance is carried out the first time, and after 310 pairs of self-capacitances of charging device charge for the second time, with the first electrode of a sensing unit 200 and a ground connection in the second electrode, with another disconnection in the first electrode and the second electrode, self-capacitance is carried out the discharge second time.Detection means 330 is used for when discharging and recharging at every turn, detects to obtain for the first time charging and for the first time the first change detected value between the discharge and for the second time charging and the second change detected value between the discharge for the second time from the first electrode 210 of correspondence or the second electrode 220.Control and calculating device 340 are used for charging device 310, discharge device 320, detection means 330 are controlled, and calculate the first resistance between self-capacitance to the first electrode and self-capacitance to the proportionate relationship of the second resistance between described the second electrode according to the first change detected value and the second change detected value, and determine touch location according to the proportionate relationship of the first resistance and the second resistance.In embodiment of the present utility model, control and calculating device 340 can be controlled charging device 310 in the mode of scanning and apply corresponding voltage to a plurality of sensing units successively, when detecting, also can detect successively in the mode of scanning simultaneously, the self-capacitance that the mode controlled discharge device 320 that perhaps, also can scan produces the sensing unit that is touched in a plurality of sensing units successively discharges.

In an embodiment of the present utility model, the first change detected value, the second change detected value can be one or more in current detecting changing value, self-capacitance change detected value, level signal change detected value and the charge variation amount.

In an embodiment of the present utility model, detection means 330 is CTS(capacitance detecting device).

In an embodiment of the present utility model, control and calculating device 340 also are used for the touch location of location positioning on second direction according to the sensing unit 200 that is touched, and determine the position of described touch point on touch-screen according to the touch location on the first direction and the touch location on the second direction.Particularly, control and calculating device 340 are determined touch location on the described second direction by centroid algorithm.

In an embodiment of the present utility model, first direction is the length direction of sensing unit 200, and second direction is the direction perpendicular to sensing unit 200 length directions, and the sensing unit horizontal parallel arranges or the vertical parallel setting.

In a preferred embodiment of the present utility model, a plurality of disjoint sensing units are positioned at same layer, thereby under the prerequisite that guarantees accuracy of detection, effectively reduce manufacturing cost.

The utility model has also proposed a kind of portable electric appts, comprises aforesaid contactor control device.

The utility model embodiment applies level signal by the electrode to the sensing unit two ends, if this sensing unit is touched, then can form self-capacitance by this sensing unit, therefore the utility model can charge to this self-capacitance by the level signal that applies, and determines touch location on the touch-screen according to the proportionate relationship between the first resistance and the second resistance.And by the detection mode that self-capacitance is carried out twice charging of the utility model embodiment, offsetting some immeasurablel physical parameter or to reduce the measurement of physical quantity, thereby under the prerequisite that guarantees detection speed, effectively improve accuracy of detection.

The utility model embodiment has proposed a kind of self-capacitance detection mode of novelty, when sensing unit is touched, the touch point just can be divided into this sensing unit two resistance, thereby is carrying out considering when self-capacitance detects that these two resistance just can determine the position of touch point on this sensing unit.The utility model embodiment's is simple in structure, and for a sensing unit, can carry out charge or discharge from its first electrode and/or the second electrode, and when charge or discharge, detect, not only can reduce the RC constant, save time and raise the efficiency, and can guarantee that coordinate can not be offset.In addition, the property that the utility model embodiment can also the Effective Raise circuit ratio of making an uproar reduces circuit noise, improves the induction linearity.In addition, in testing process because the sensing unit that is touched is charged, therefore wherein can produce little electric current, can eliminate well the Vcom level signal to the impact of the self-capacitance of sensing unit generation in the touch-screen, therefore screenmask layer and concerned process steps can be correspondingly eliminated, thereby cost can be when having strengthened antijamming capability, further reduced.

In the description of this instructions, the description of reference term " embodiment ", " some embodiment ", " example ", " concrete example " or " some examples " etc. means to be contained at least one embodiment of the present utility model or the example in conjunction with specific features, structure, material or the characteristics of this embodiment or example description.In this manual, the schematic statement of above-mentioned term not necessarily referred to identical embodiment or example.And the specific features of description, structure, material or characteristics can be with suitable mode combinations in any one or more embodiment or example.

Although illustrated and described embodiment of the present utility model, for the ordinary skill in the art, be appreciated that in the situation that does not break away from principle of the present utility model and spirit and can carry out multiple variation, modification, replacement and modification to these embodiment that scope of the present utility model is by claims and be equal to and limit.

Claims

1. a contactor control device is characterized in that, comprising:

Substrate;

A plurality of disjoint sensing units, described a plurality of sensing units are formed on the described substrate, and the two ends of each sensing unit have respectively the first electrode and the second electrode;

The touch-screen control chip, described touch-screen control chip comprises charging device, discharge device, detection means and control and calculating device, wherein,

Described charging device, be used in the charging process first time, one in described a plurality of sensing units in the first electrode of a sensing unit and the second electrode applies high level signal, and with another ground connection in described the first electrode and the second electrode, carry out the charging first time with the self-capacitance that when a described sensing unit is touched, a described sensing unit is produced; In second time charging process, the first electrode and the second electrode to a described sensing unit apply high level signal, perhaps, in described the first electrode and described the second electrode one applies high level signal and with another disconnection in described the first electrode and described the second electrode, charges described self-capacitance is carried out the second time;

Described discharge device, be used for after described charging device charges for the first time to described self-capacitance, with the first electrode of a described sensing unit and at least one ground connection in the second electrode, described self-capacitance is carried out the discharge first time, and after described charging device charges for the second time to described self-capacitance, with the first electrode of a described sensing unit and a ground connection in the second electrode, with another disconnection in described the first electrode and described the second electrode, described self-capacitance is carried out the discharge second time;

Described detection means, be used for detecting to obtain the first change detected value between the described charging first time and the described first time of the discharge from described first electrode of correspondence or the second electrode, and detect to obtain the second change detected value between the described charging second time and the described second time of the discharge from described first electrode of correspondence or the second electrode;

And described control and calculating device, be used for described charging device, discharge device, detection means and control, and according to the first change detected value and the second change detected value calculate described self-capacitance to the first resistance between described the first electrode and described self-capacitance to the proportionate relationship between the second resistance between described the second electrode, and determine touch location according to the proportionate relationship between described the first resistance and described the second resistance.

2. contactor control device as claimed in claim 1 is characterized in that, described detection means is capacitance detecting device CTS.

3. contactor control device as claimed in claim 1 is characterized in that, described sensing unit is rectangle, and the first direction of described a plurality of sensing unit and described touch-screen is parallel to each other, and described touch location is the touch location on described first direction.

4. contactor control device as claimed in claim 1 is characterized in that, described sensing unit comprises:

A plurality of firsts and a plurality of parallel second portions, wherein, link to each other by described second portion between the adjacent described first, with the first groove and the second groove that forms a plurality of alternative arrangements, wherein, the opening direction of described a plurality of the first groove and described a plurality of the second grooves is opposite, and described touch location is for touching the touch location of object on first direction.

5. such as claim 3 or 4 described contactor control devices, it is characterized in that described first direction is the length direction of described sensing unit, second direction is the direction perpendicular to described sensing unit, and described sensing unit horizontal parallel arranges or the vertical parallel setting.

6. contactor control device as claimed in claim 1 is characterized in that, described a plurality of disjoint sensing units are positioned at same layer.

7. contactor control device as claimed in claim 1 is characterized in that, described sensing unit comprises:

Third part;

Disjoint the 4th part and the 5th part, described the 4th part one end links to each other with an end of described third part, one end of described the 5th part links to each other with the other end of described third part, the described tetrameric other end has described the first electrode, and the other end of described the 5th part has described the second electrode.

8. contactor control device as claimed in claim 1 is characterized in that, described sensing unit comprises:

The 6th part, an end of described the 6th part has described the first electrode;

The 7th part, an end of described the 7th part links to each other with the other end of described the 6th part, and the other end of described the 7th part has described the second electrode.

9. a portable electric appts is characterized in that, comprises each described contactor control device such as claim 1-8.