The utility model content
The utility model provides a kind of sensor, and this sensor adopts same antenna array identification electromagnetic signal and induced field current signal, makes the simple in structure of sensor, and cost reduces, and improves the reaction sensitivity of sensor.
Sensor of the present utility model comprises: U-shaped first direction lead; Every first direction lead be arranged in parallel with the mode interleaved of assembled arrangement successively, constitutes first direction lead group, mutually insulated between any two first direction leads; U-shaped second direction lead, every second direction lead be arranged in parallel with the mode interleaved of assembled arrangement successively, constitutes second direction lead group, mutually insulated between any two second direction leads; Arbitrary first direction lead and second direction lead all have first lead and second lead that is parallel to each other;
The combination of first lead of the arbitrary position of first direction lead of first direction lead group and second lead and adjacent last lead or back one lead and the combination of other adjacent two leads in any position do not repeat; The combination of first lead of the arbitrary position of second direction lead of second direction lead group and second lead and adjacent last lead or back one lead does not repeat with the combination of other adjacent two leads in any position;
First direction lead group and second direction lead group are intersected mutually, constitute capacitive coupling touch-control aerial array; And mutually insulated between first direction lead group and the second direction lead group; Be electrically connected with the first capacitive coupling touch-control parts at least one first direction lead in the described first direction lead group; Be electrically connected with the second capacitive coupling touch-control parts at least one second direction lead in the described second direction lead group;
The first capacitive coupling touch-control parts and the second capacitive coupling touch-control parts are staggered folded the establishing of first direction lead and the cross one another zone of second direction lead;
Described first direction lead and second direction wire openings portion have first link and second link, and wherein first link is used to connect external control component; Second link is connected in series a mode switch electronic switch, and described second link is concatenated into external control component through described mode switch electronic switch; The control termination external control component of described mode switch electronic switch; Mode switch electronic switch closes, described first direction lead and second direction lead form the electromagnetic induction loop with connecing external control component respectively separately; The mode switch electronic switch disconnects, the capacitive coupling touch-control array that described aerial array constitutes.
Aforesaid sensor, wherein, sensor also comprises an electromagnetic detecting unit, and this electromagnetic detecting unit control model is switched the control end of electronic switch, is used to detect the electromagnetic signal of aerial array induction region, and control model is switched the electronic switch action.
Aforesaid sensor wherein, is equipped with the short circuit electronic switch, the control termination external control component of this short circuit electronic switch between at least one described first direction lead and/or second direction wire openings portion first link and second link; In the disconnection of mode switch electronic switch, during the capacitive coupling touch-control array of described aerial array formation, this short circuit electronic switch closes; In the mode switch electronic switch closes, when described first direction lead and second direction lead formed the electromagnetic induction loop with connecing external control component respectively separately, this short circuit electronic switch disconnected.
Aforesaid sensor, wherein, two adjacent arbitrarily in described first direction lead group first direction wire pitch equate, and/or two adjacent arbitrarily second direction wire pitch equate in the described second direction lead group; And/or described first direction lead equates with the U-shaped peristome spacing of described second direction lead.
Aforesaid sensor, wherein, first direction lead group and second direction lead group are set to mutual square crossing.
Aforesaid sensor, wherein, the described first capacitive coupling touch-control parts are more than two, the shape of any two first capacitive coupling touch-control parts is identical; And/or the described second capacitive coupling touch-control parts are more than two, and the shape of any two second capacitive coupling touch-control parts is identical.
Aforesaid sensor, wherein, the described first capacitive coupling touch-control parts are identical with the described second capacitive coupling touch-control component shape.
Aforesaid sensor, wherein, described capacitive coupling touch-control parts are shaped as rhombus, rectangle, triangle or the shape of combination in any between them.
Aforesaid sensor, wherein, in first direction lead and the cross one another zone of second direction lead, the described first capacitive coupling touch-control parts equate with spacing between the second capacitive coupling touch-control parts.
Aforesaid sensor, wherein, the first capacitive coupling touch-control parts and first direction lead are made as one, and/or the second capacitive coupling touch-control parts and second direction lead are made as one.
Aforesaid sensor, wherein, the described first capacitive coupling touch-control parts are configured such that the equivalent electromagnetism and the overlapping or parallel distribution of first direction lead direction of first direction lead; The described second capacitive coupling touch-control parts are configured such that the equivalent electromagnetism and the overlapping or parallel distribution of second direction lead direction of second direction lead.
Aforesaid sensor, wherein, described first lead and second lead all are set to straight line, and the arbitrary first capacitive coupling touch-control parts on the first direction lead perhaps have consistent proportionate relationship in the shape symmetry of first direction lead both sides distribution;
The shape symmetry that arbitrary second capacitive coupling touch-control parts on the second direction lead distribute in second direction lead both sides perhaps has consistent proportionate relationship.
Aforesaid sensor, wherein, electromagnetic detecting unit is arranged on the Touch Zone periphery that described aerial array constitutes.
Aforesaid sensor, wherein, electromagnetic detecting unit connects logic control unit by an electromagnetic induction coil and constitutes, logic control unit output connection mode switches electronic switch controling end, be used to detect the interior electromagnetic signal of Touch Zone scope of aerial array, control model is switched electronic switch disconnection or closed; Described logic control unit independently is provided with or is integrated in the described external control component.
Aforesaid sensor, wherein, the electromagnetic induction coil ring is located at the Touch Zone that described aerial array constitutes, or is located at a side or many sides, electromagnetic induction coil and the aerial array electric insulation of described Touch Zone.
Aforesaid sensor, wherein, described Touch Zone is provided with in the zone that electromagnetic induction coil surrounds.
Above-mentioned sensor switches to capacitive coupling control mode touch mode or electromagnetic induction control mode touch mode by means of the mode switch electronic switch with the aerial array in the sensor, make aerial array at any one time or work in the capacitive coupling control mode touch mode, therefore work in the electromagnetic induction control mode touch mode, can effectively overcome in the prior art capacitance touching control pattern and the electromagnetic induction control mode touch mode problem of mutual interference mutually.Further, by first direction lead and the second direction lead that U-shaped is set, can effectively reduce the I/O interface between sensor and the external control component, and then make the peripheral circuit structure significantly simplify, be convenient to integrated, make that the processing signals data volume reduces, processing speed increases substantially.I/O interface and data volume to be processed reduce can make the processing speed of the touch-control product that utilizes this sensor improve, simple in structure, low cost of manufacture, and can satisfy the demand of two kinds of touch-controls inputs such as user's dual-purpose time writer and finger touch effectively.
The utility model also provides a kind of double mode touch module, this double mode touch module by with in the utility model arbitrarily described can switch-capacitor coupling control mode touch mode or the aerial array of electromagnetic induction control mode touch mode be arranged on the base material, has the manufacturing cost of double mode touch controllable function substrate to reduce effectively, simplify double mode touch base plate preparation technology simultaneously, can effectively promote the scope of application of this double mode touch module.
Double mode touch module of the present utility model comprises: first substrate and sensor, this sensor are aforesaid sensor, and the aerial array of described sensor is arranged on the described substrate; The first direction lead of described aerial array, the material of second direction lead are metal forming, conductive silver paste, carbon slurry or ITO conducting film, adopt the mode of printing, etching to be arranged on the substrate; Perhaps on first substrate, make with printing, etching mode.
Aforesaid double mode touch module, wherein, described electromagnetic detecting unit connects logic control unit by an electromagnetic induction coil and constitutes, electromagnetic induction coil and aerial array electric insulation, logic control unit output connects the mode switch electronic switch controling end, be used to detect the interior electromagnetic signal of Touch Zone scope of aerial array, control model is switched electronic switch and is opened and closed.
Aforesaid double mode touch module, wherein, described electromagnetic induction coil ring is established the Touch Zone that described aerial array constitutes, or is located at a side or many sides of described Touch Zone.
Aforesaid double mode touch module, wherein, described electromagnetic induction coil ring is established the Touch Zone that described aerial array constitutes, and the Touch Zone is provided with in the zone that electromagnetic induction coil surrounds.
Aforesaid double mode touch module, wherein, described electromagnetic induction coil is arranged on first substrate.
Aforesaid double mode touch module, wherein, double mode touch module also comprises one second substrate, and described electromagnetic induction coil is provided with on second substrate, second substrate covers or frame is located at first upper surface of base plate and/or lower surface, and first substrate and second substrate constitute substrate in batch.
Aforesaid double mode touch module, wherein, described first substrate and/or second substrate are glass, plastics.
Aforesaid double mode touch module, wherein, described first substrate and/or second substrate are flexible insulating material.
Aforesaid double mode touch module, wherein, described electromagnetic induction coil is enameled wire, metal forming, conductive silver paste, carbon slurry or ITO conducting film.
Above-mentioned double mode touch module can overcome the problem of the mutual interference mutually of capacitance touching control pattern and electromagnetic induction control mode touch mode in the prior art effectively, the complexity of double mode touch-control antenna array structure reduces simultaneously, make that this double mode touch module manufacturing is simple, with low cost, the integrated level height, make that the touch-control product that comprises this double mode touch module is lighter, thinner, satisfy user's demand effectively.
In addition, the utility model also provides a kind of double mode touch-control electronic device, comprise electronics, this body is provided with display screen, with any described double mode touch module in the utility model, and described double mode touch module can be arranged on the surface of electronic installation display screen, and perhaps described electromagnetic induction coil lays electronic installation display screen peripheral etc. around setting.Thus, those double mode touch-control electronic devices that include double mode touch module can be realized capacitive coupling control mode touch mode and electromagnetic induction control mode touch mode compatibility when improving reaction sensitivity, in addition, this double mode touch-control electronic device simple in structure, cost is low, and is and easy to maintenance.
Embodiment
For making the purpose of this utility model, technical scheme and advantage clearer,, the technical scheme among the utility model embodiment is clearly and completely described below in conjunction with the accompanying drawing among the utility model embodiment.Obviously, described embodiment is the utility model part embodiment, rather than whole embodiments.
Sensor in the present embodiment mainly comprises: U-shaped first direction lead; Every first direction lead be arranged in parallel with the mode interleaved of assembled arrangement successively, constitutes first direction lead group, mutually insulated between any two first direction leads;
U-shaped second direction lead, every second direction lead be arranged in parallel with the mode interleaved of assembled arrangement successively, constitutes second direction lead group, mutually insulated between any two second direction leads;
Arbitrary first direction lead and second direction lead all have first lead and second lead that is parallel to each other;
The combination of first lead of the arbitrary position of first direction lead of first direction lead group and second lead and adjacent last lead or back one lead and the combination of other adjacent two leads in any position do not repeat;
The combination of first lead of the arbitrary position of second direction lead of second direction lead group and second lead and adjacent last lead or back one lead does not repeat with the combination of other adjacent two leads in any position;
First direction lead group and second direction lead group are intersected mutually, constitute capacitive coupling touch-control aerial array; And mutually insulated between first direction lead group and the second direction lead group;
Be electrically connected with the first capacitive coupling touch-control parts at least one first direction lead in the described first direction lead group;
Be electrically connected with the second capacitive coupling touch-control parts at least one second direction lead in the described second direction lead group;
The first capacitive coupling touch-control parts and the second capacitive coupling touch-control parts are staggered folded the establishing of first direction lead and the cross one another zone of second direction lead;
Described first direction lead and second direction wire openings portion have first link and second link, and wherein first link is used to connect external control component; Second link is connected in series a mode switch electronic switch, and described second link is concatenated into external control component through described mode switch electronic switch; The control termination external control component of described mode switch electronic switch; Mode switch electronic switch closes, described first direction lead and second direction lead form the electromagnetic induction loop with connecing external control component respectively separately; The mode switch electronic switch disconnects, the capacitive coupling touch-control array that described aerial array constitutes.
Particularly, shown in Figure 1A to Fig. 1 C, Figure 1A shows the first kind of structural representation of sensor embodiment in the utility model; Figure 1B shows first structural representation of first direction lead among the utility model sensor embodiment, and Fig. 1 C shows in the utility model first of the second direction lead kind of structural representation among the sensor embodiment.In the present embodiment, the sensor construction shown in Figure 1A is specially the structure in the frame of broken lines.Wherein, first direction lead group and second direction lead group are intersected mutually, constitute capacitive coupling touch-control aerial array; And mutually insulated between first direction lead group and the second direction lead group.
First direction lead group can comprise as U-shaped first direction lead 201a, 201b, 201c among Figure 1A, mutually insulated between any two first direction leads.Wherein each the first direction lead in this first direction lead group distributes in the assembled arrangement mode in the mathematical formulae, and its combinatorial formula is C
m n, n, m get the natural number more than or equal to 4, and m<=n, and for example, n can be 5,6,8,7,9,10,19 or 32 or the like.That is to say that first lead of the arbitrary position of first direction lead of first direction lead group and second lead and adjacent last lead or the combination of back one lead and the combination of other adjacent two leads in any position do not repeat.
Correspondingly, second direction lead group can comprise as U-shaped first direction lead 101a, 101b, 101c among Figure 1A, mutually insulated between any two second direction leads.Wherein each the second direction lead in this second direction lead group distributes in the assembled arrangement mode in the mathematical formulae, and its combinatorial formula is C
m n, n, m get the natural number more than or equal to 4, and m<=n, and for example, n can be 5,6,8,10,19 or 32 or the like.That is to say that the combination of first lead of the arbitrary position of second direction lead of second direction lead group and second lead and adjacent last lead or back one lead does not repeat with the combination of other adjacent two leads in any position.
Shown in Figure 1A, 1B, the peristome of first direction lead 201a has first link 204 and second link 205 that connects external control component 100.In the present embodiment, second link 205 is serially connected with mode switch electronic switch 202, and this second link 205 can be connected to external control component 100 through mode switch electronic switch 202.(i.e. first lead and second lead) is electrically connected with a plurality of first capacitive coupling touch-control parts 203 on two limits of the U-shaped of first direction lead, and perhaps (first lead or second lead) is electrically connected with a plurality of first capacitive coupling touch-control parts 203 on arbitrary limit of the U-shaped of first direction lead.The quantity of these first capacitive coupling touch-control parts 203, size, shape are according to the requirements set of actual circuit structure.Usually, the quantity of the first capacitive coupling touch-control parts 203 is identical with the point of crossing quantity of first direction lead group and second direction lead group.Certainly, shown in Fig. 1 C, the structure of the second direction lead group shown in Fig. 1 C is analogous to the structure of first direction lead group.
The peristome of second direction lead 101a has first link 104 and second link 105 that connects external control component 100 in Fig. 1 C.In the present embodiment, second link 105 is serially connected with mode switch electronic switch 102, and this second link 105 can be connected to external control component 100 through mode switch electronic switch 102.(i.e. first lead and second lead) is electrically connected with a plurality of second capacitive coupling touch-control parts 103 on two limits of the U-shaped of second direction lead, and perhaps (first lead or second lead) is electrically connected with a plurality of second capacitive coupling touch-control parts 103 on arbitrary limit of the U-shaped of second direction lead.The quantity of these second capacitive coupling touch-control parts 103, size, shape are according to the requirements set of the circuit structure of reality.Certainly, the quantity of the second capacitive coupling touch-control parts 103 is identical with the point of crossing quantity of first direction lead group and second direction lead group.Be understandable that the second capacitive coupling touch-control parts 103 are identical with the quantity of the first capacitive coupling touch-control parts 203, and the first capacitive coupling touch-control parts in the sensor and the second capacitive coupling touch-control parts are staggered folded the establishing of first direction lead and the cross one another zone of second direction lead.
When the mode switch electronic switch 202 of first direction lead was closed, this first direction lead worked in the electromagnetic induction control mode touch mode, the electromagnetic signal of sending in order to the induced electricity magnetic pen.When all mode switch electronic switches 202 of first direction lead group are all closed, time writer is when vertically the moving up and down of first direction lead group, can measure the alternating signal of arbitrary first direction lead output by external control component, obtain relatively that lead location that the maximum alternating signal of output distributed in first direction lead group can directly be known and the accurate position of definite time writer vertical (be Y-axis to).Correspondingly, when the mode switch electronic switch 102 of second direction lead was closed, this second direction lead worked in the electromagnetic induction control mode touch mode, the electromagnetic signal of sending in order to the induced electricity magnetic pen.When all mode switch electronic switches 102 of second direction lead group are all closed, when time writer moves in the transverse horizontal of second direction lead group, can measure the alternating signal of arbitrary second direction lead output by external control component, obtain relatively that lead location that the maximum alternating signal of output distributed in second direction lead group can directly be known and the horizontal accurate position of (being X axis) of definite time writer.
Because first direction lead group and second direction lead group are intersected placements (structure as shown in the frame of broken lines of Figure 1A) mutually, so can detect the particular location that time writer is positioned at aerial array via the electromagnetic induction signal of both direction lead transmission.
What need further specify is that above-mentioned first direction lead group and second direction lead group are intersected mutually, constitute capacitive coupling touch-control aerial array simultaneously; And mutually insulated between first direction lead group and the second direction lead group.In the sensor shown in Figure 1A, all mode switch electronic switches (102 and 202) are disconnected, at this moment, first direction lead and second direction lead all work in the capacitive coupling control mode touch mode.Separately first link and outside connection control unit conducts in first direction lead and the second direction lead.After external control component receives capacitively coupled signal, the treated position of touch of knowing finger.Will be appreciated that, in the actual circuit structure that is provided with the present embodiment sensor, the mode switch electronic switch 102 and 202 in the sensor can be located at external control component 100 zones, so that the integrated control of entire circuit structure.
Sensor in the foregoing description switches to capacitive coupling control mode touch mode or electromagnetic induction control mode touch mode by the mode switch electronic switch with the aerial array in the sensor, can effectively overcome have electric capacity in the prior art simultaneously, in the double mode product of inductance touch-control, capacitive coupling control mode touch mode and electromagnetic induction control mode touch mode be the problem of mutual interference mutually.Especially, adopt the first direction lead group and the second direction lead group of the U-shaped that the assembled arrangement mode is arranged in the mathematics to intersect mutually in the foregoing description, make that the first direction lead that each is adjacent or the combination of second direction lead are unique, and then the position of the point of crossing of the last aerial array that forms is unique.
Existing capacitive coupling touch technology compares, in the foregoing description, the assembled arrangement of first lead by being arranged on U-shaped first direction lead and second direction lead and the first capacitive coupling touch-control parts 103 on second lead and the second capacitive coupling touch-control parts 203 and adjacent capacitor coupling unit, make identical first number of lead wires or second number of lead wires expand bigger touch area, can effectively reduce the I/O interface between sensor and the external control component, and then make the peripheral circuit structure significantly simplify, be convenient to integratedly, the processing signals data volume is reduced, processing speed increases substantially.I/O interface and data volume to be processed reduce can make the processing speed of the touch-control product that comprises this sensor improve, and make the simple in structure of the touch-control product comprise the utility model sensor such as mobile phone, panel computer etc., low cost of manufacture, and can satisfy the demand that two kinds of touch-controls such as user's dual-purpose time writer and finger touch are imported effectively.
Below describe the principle of the aerial array identification electromagnetic signal among the sensor embodiment of the present utility model in detail by Fig. 2 A to Fig. 2 C; Wherein, Fig. 2 A is the synoptic diagram of the Strength Changes of identification electromagnetic signal in the first direction lead, and Fig. 2 B is the synoptic diagram of the Strength Changes of identification electromagnetic signal in the first direction lead group, and Fig. 2 C is the synoptic diagram of aerial array identification electromagnetic signal.
Coil 5 is connected with exchange current among Fig. 2 A, can produce alternating magnetic field around the coil 5, and the magnetic line of force of alternating magnetic field passes first direction lead 201a, and first direction lead 201a then can the inductive electromagnetic signal and exported the alternation induced voltage.When coil 5 during the moving up and down of first direction lead 201a, the alternation induced voltage of first direction lead 201a output is different, in Fig. 2 A, when coil 5 lays respectively at the position 14, center 13 of first direction lead and position 15, when learning that by measurement coil 5 is positioned at the vertical center of first direction lead 201a, the alternation induced voltage of first direction lead 201a output is maximum.Certainly, based on the electromagnetic field principle as can be known, at sustained height, in lead 201a, when moving horizontally coil 5, the alternation induced voltage of first direction lead 201a output does not change.
In addition, shown in Fig. 2 B, the first direction lead 201a in the first direction lead group is with the equidistant from distance assembled arrangement, when verification experimental verification coil 5 is positioned at the vertical center of first direction lead 201a, and the alternation induced voltage U of first direction lead 201a output
3Maximum; And when moving to the vertical center of being partial to first direction lead 201b on the coil 5, the alternation induced voltage U of first direction lead 201b output
2Maximum; Further, when coil 5 moves to the vertical center of first direction lead 201c on again, the alternation induced voltage U of first direction lead 201c output
1Maximum.By on can in first direction lead group, obtain the positional information of coil 5 on vertical.That is to say, the first direction lead that a plurality of spacings that be arranged in parallel equate, and these a plurality of first direction leads that be arranged in parallel are distributed in the mode of assembled arrangement, and then externally pass through the relatively size of the alternation induced voltage of those first direction leads outputs in the control assembly, can obtain the accurate position of coil 5 on vertically.So, in the foregoing description the aerial array of sensor adopt as the first direction lead arranged among Fig. 2 B so that discern coil 5 preferably in vertically (Y-axis to) positional information accurately.
Same principle, in Fig. 2 C, coil 5 is positioned at the different horizontal level of second direction lead 101a, and the alternation induced voltage that its second direction lead 101a exports is different, so that obtain coil 5 positional information on (X axis) in the horizontal direction.
Shown in Fig. 2 C, aerial array comprises first direction lead group and the second direction lead group that square crossing is arranged.When the arbitrary position of coil 5,, can determine the particular location of coil 5 in aerial array by obtaining and the alternation induced voltage of first direction lead and the output of second direction lead in the aerial array relatively at aerial array.
Shown in figure 3A to Fig. 3 H, Fig. 3 A to Fig. 3 H is the principle analysis synoptic diagram of the capacitive coupling control mode touch mode among the sensor embodiment of the present utility model; Wherein, conductor 21 can be equivalent to the finger of touch-control, and conductor 23 also insulate in identical aspect independently of one another with conductor 24.When conductor 21 fitted on conductor insulated from each other 23 and the conductor 24 by insulating medium 22, the conformable region equivalence of the left side of conductor 21 and conductor 23 was a capacitor C
1, the conformable region equivalence of the right side of conductor 21 and conductor 24 is a capacitor C
2, because conductor 21 is integrative-structures, and then the capacitor C of equivalence
1And capacitor C
2For being connected in series the equivalent electrical circuit shown in Fig. 3 C.Conductor 23 and 24 of conductors can transmit alternating voltage mutually as can be known from the equivalent electrical circuit shown in the 3C.Fig. 3 C shows the equivalent circuit diagram of the point of crossing in the finger touch aerial array in the utility model, because of finger and conductor 23 and 24 AC impedance of conductor (comprising induction reactance, impedance and/or capacitive reactance etc.) to the alternating voltage of certain frequency very big, be equivalent to insulation, and the dc impedance of finger is lower, so the touch face equivalence of hand is a conductor 21, first direction lead 201a is equivalent to conductor 23, and second direction lead 101a is equivalent to conductor 24.
Shown in Fig. 3 D, (be follow-up convenient explanation, only illustrated the synoptic diagram of a first direction lead and the square crossing of a second direction lead among Fig. 3 D), when first link 104 of the 101a of second direction lead feeds alternating signals 8, finger contacts with point of crossing 1 (dash area among Fig. 3 D), so that being switched on, the loop of AC signal 8 (that is to say the capacitor C between the touch point 1 among Fig. 3 D
7And C
8Conducting), can get access to the alternating signal 9 of first link, 204 outputs of first direction lead 201a thus.When the point of crossing shown in finger touch Fig. 3 D 2,3 or 4, the C of corresponding contact point 2
1And C
2, contact point 3 C
3And C
4, or the C of contact point 4
6And C
5Be switched on, and then can detect above-mentioned alternating signal 9.From the above mentioned, the capacitive coupling touching signals of external control component in can the identification aerial array.
Because each first direction lead and second direction lead all have four intersection points, the position of its output alternating signal 9 also is identical, shown in above-mentioned Fig. 3 D possibly can't judge preferably finger be positioned at the particular location of point of crossing (being touch point) 1,2,3 or 4, so obtain unique positional information under the capacitive coupling pattern below in conjunction with 3E to Fig. 3 H detailed description external control component.
Shown in Fig. 3 E to Fig. 3 H, conductor 21 and conductor 23 among Fig. 3 E, conductor 21 and 24 binding face equate, i.e. C
1And C
2Equate that conductor 21 is unequal with the binding face of conductor 23, conductor 24 among Fig. 3 F and Fig. 3 G, and then C
1Bigger in Fig. 3 F and Fig. 3 G, because conductor 21 is certain with the applying total area of conductor 23 and 24, and C
1And C
2So series connection is according to series capacitance C=C
1* C
2/ (C
1+ C
2) as can be known, have only C
1And C
2When equating, the alternating signal of output is the strongest, each experimental data shown in Fig. 3 H, its S1>S2>S3.When replacing conductor 21 with finger, the result of its generation is consistent with the result of above-mentioned simulated experiment.
So, because actual sensor comprises 3 above U-shaped first direction leads and second direction lead at least, so in the concrete structure, each point of crossing is respectively by the first capacitive coupling touch-control parts 203 and the second capacitive coupling touch-control parts, 103 staggered folded establishing, and each point of crossing in the aerial array evenly distribute (shown in following Fig. 7 C), and then the point of crossing that can guarantee finger touch is at least two or more, so that make external control component by obtaining and the position of the alternating signal of the maximum of first link output of more adjacent all directions lead, (that is to say with the accurate location information of knowing touch point, by means of the distribution of the alternating signal of adjacent intersections output in first link output of all directions lead, the accurate touch point 1 among the component- bar chart 3D, 2,3 and 4), thus, two the adjacent at least point of crossing that comprise by touch point can unique definite capacitive coupling control mode touch mode under the positional information of touch point.
Need to prove, distance between the large part of human body and hand and the point of crossing of aerial array is much bigger with respect to the distance between finger and the point of crossing, and then induction reactance, capacitive reactance, impedance that the point of crossing of the large part of human body and hand and aerial array produces all are very large, so with respect to the capacitive reactance that finger produces in the point of crossing, can insulate in other positions of health in equivalence.
In addition, be accurately knowing of the positional information that describes capacitive coupling control mode touch mode lower sensor in detail, adopt the mode of coordinate points in the cartesian coordinate system (XY coordinate) to illustrate, can be coordinate points with each the point of crossing equivalence in the aerial array shown in Fig. 4 A, the positional information explanation of the X-axis shown in Fig. 4 B and Fig. 4 C and the coordinate points of Y-axis.Below the positional information that illustrates each touch point that moves up and down by touch point 1 among Fig. 4 A be unique.
Particularly, first direction lead group and second direction lead group are arranged in square crossing, be about to second direction lead group and be positioned over by X axis, first direction lead group be positioned over Y-axis to.Second direction lead 101a (A5, a5) with first direction lead 201a (B5, infall b5) has a touch point 1, second direction lead 101a (A5, a5) alternating voltage 8 on is coupled to first direction lead 201a (B5, b5) output alternating voltage 9 (U by touch point 1
B5), and touch point 1 also with first direction lead 201b (B8 b8) overlaps, second direction lead 101a (A5, alternating voltage 8 a5) also can be coupled to first direction lead 201b (B8, b8), output alternating voltage U
B8
If touch point 1 and first direction lead 201a (B5, b5) binding face/coincidence face greater than with first direction lead 201b (B8, b8) binding face/coincidence face, second direction lead 101a (A5 then, a5) alternating voltage 8 on is coupled to first direction lead 201a (B5, alternating voltage U b5) by touch point 1
B5Greater than being coupled to first direction lead 201b (B8, alternating voltage U b8)
B8Shown in Fig. 4 A1, as with touch point 1 progressively along moving on the Y-axis, touch point 1 and first direction lead 201a (B5, binding face b5) can gradually reduce, with first direction lead 201b (B8, b8) it is big that binding face can progressively become, (A5, a5) alternating voltage 8 on is coupled to first direction lead 201a (B5, alternating voltage U b5) by touch point 1 to second direction lead 101a so
B5Can progressively reduce, be coupled to first direction lead 201b (B8, alternating voltage U b8)
B8Can progressively increase, shown in Fig. 4 A2, when touch point 1 when Y-axis moves up and down, the alternating voltage of first direction lead group output can clocklike change, this change in voltage rule is the positional information of touch point 1 in Y-axis, can accurately determine the position of touch point 1 in Y-axis with this.
In like manner, can obtain the position of touch point on X-axis, shown in Fig. 4 A3 and Fig. 4 A4, determine the positional information of touch point 1 in X-axis.By last, can accurately determine the position of touch point 1 on X-axis, Y-axis is coordinate points.The alternating voltage data that produce according to coupling on X-axis and the Y-axis aerial array can calculate the arbitrary coordinate position of touch point 1 at the aerial array active zone accurately, and same principle can calculate the arbitrary coordinate position of touch point 2,3,4 at the aerial array active zone accurately.
The position coordinates point that moves on the touch point 1 as Fig. 4 B and Fig. 4 C parsing, W1W2W3W4 among Fig. 4 A is a capacitive coupling induction active zone, Y-axis is provided with the Y11-Y0 position, each position is provided with aerial array B4b4 respectively, B1b1, B5b5, B2b2, B6b6, B3b3, B7b7, B4b4, B8b8, B5b5, B9b9, B6b6, as respectively with alphabetical A, B, C, D, E, F, G, H, I, J, K, L represents first direction lead B1b1---B9b9, the permutation table of the first direction lead correspondence position of Y-axis is DAEBFCGDHEIF so, each letter of permutation table does not repeat with the combination of adjacent letters, combination in permutation table has DAE as A, EAD, DEAB etc., other position in permutation table does not have the same with it combination and occurs, E has two positions at permutation table, the combination of last position has EB, AEB, EBF, BFEA etc., the combination of one position, back has HE, HEI, EIF, IFEH etc., other position in permutation table does not have the same with it combination yet and occurs, the setting of the first direction lead of each position also is not repeat to arrange into principle with adjacent combination on the Y-axis, this not repeated arrangement combination of each direction lead of X-axis and Y-axis, can guarantee accurately judgement and the identification of touch point on the point of crossing in the aerial array, also can allow sensor under the capacitive coupling control mode touch mode, realize the multi-point touch operation with aerial array.
On the basis of the foregoing description, preferred sensor also comprises an electromagnetic detecting unit, this electromagnetic detecting unit is used for the control end that control model is switched electronic switch 202 or 102, so that detect the electromagnetic signal of aerial array induction region, the action that the electromagnetic detecting unit in the present embodiment is mainly used in mode switch electronic switch 202 in control the foregoing description or 102 promptly disconnects or is closed.Usually electromagnetic detecting unit can be located in the external control component, and then control model is switched electronic switch 202 or 102 preferably.
Further, electromagnetic detecting unit can be arranged on the Touch Zone periphery that described aerial array constitutes.
Preferably, electromagnetic detecting unit is made of electromagnetic induction coil connection amplification, shaping unit and logic control unit.Usually logic control unit can be exported the control end that connection mode switches electronic switch 202 or 102, so that detect the interior electromagnetic signal of Touch Zone scope of aerial array, and then control model is switched electronic switch disconnection or closed preferably; Described amplification, shaping unit and logic control unit independently are provided with or are integrated in the described external control component.For example, amplification, shaping unit and logic control unit can be the electromagnetical analogies switching treatmenting unit that is positioned at CPU inside, it can connect electromagnetic induction coil by amplification, shaping unit, so that obtain the electromagnetic signal of electromagnetic induction coil, make CPU that the capacitive coupling control mode touch mode is switched to the electromagnetic induction coupled mode.
Shown in Fig. 5 A or Fig. 5 B, Fig. 5 A and Fig. 5 B show second kind and the third structural representation of the sensor embodiment in the utility model respectively, based on the sensor of foregoing description, electromagnetic induction coil 111 rings shown in Fig. 5 A are located at the Touch Zone that described aerial array constitutes.That is to say that the Touch Zone of sensor is provided with in the zone that electromagnetic induction coil surrounds.Need to prove, the aerial array that Fig. 5 A shows is under the capacitive coupling control mode touch mode, what aerial array was exported is alternating signal 9, under the aerial array electromagnetic induction control mode touch mode, what aerial array was exported is signal 10 and 11, the electromagnetic signal 12 of an induction of electromagnetic induction coil 111 outputs this moment, so that, this electromagnetic signal 12 inputs to logic control unit, and then can effectively the capacitive coupling control mode touch mode in the Touch Zone scope of switched antenna array switched to the electromagnetic induction control mode touch mode by amplification, shaping.
Electromagnetic induction coil 111 shown in Fig. 5 B is located at many sides of described Touch Zone, electromagnetic induction coil and aerial array electric insulation.Certainly, electromagnetic induction coil also can be located at a side of described Touch Zone, and it guarantees electromagnetic induction coil and aerial array electric insulation, makes electromagnetic induction coil can respond to the electromagnetic signal of Touch Zone preferably.
Further, the Touch Zone of the sensor described in the foregoing description not only can be provided with in the zone that electromagnetic induction coil surrounds, can also be arranged at electromagnetic induction coil above or below, it guarantees that electromagnetic induction coil and aerial array electric insulation get final product.But the edge that it should be noted that the Touch Zone of sensor can be less than or equal to the edge of electromagnetic induction coil, makes in the Touch Zone that the signal of time writer all can be responded to by electromagnetic induction coil or be discerned arbitrarily.
In addition, with reference to shown in Figure 6, Fig. 6 shows second kind of structural representation among the sensor embodiment in the utility model, sensor in the present embodiment mainly is to increase short circuit electronic switch 110 or 210 on the basis of a last embodiment, so that during the capacitive coupling touch-control array that aerial array constitutes, this short circuit electronic switch closes; Can reduce the transfer impedance of aerial array thus, improve the linearity of sensor under the capacitive coupling control mode touch mode in the present embodiment alternating voltage.
Especially, the aerial array that is provided with the short circuit electronic switch shown in this Fig. 6 can increase substantially the linearity of capacitive coupling control mode touch mode, especially at the touch screen of the large-size that uses this sensor, above-mentioned short circuit electronic switch can shorten signal transmission distance significantly, reduced the impedance of signal transmission in the aerial array, made that the processing speed of external control component of those sensors further improves, the linearity promotes.
In antenna array structure shown in Figure 1A, be equipped with short circuit electronic switch (as the short circuit electronic switch 110 or 210 among Fig. 6) between at least one first direction lead 201a and/or second direction lead 101a peristome first link (as first link 104,204 among Figure 1B and Fig. 1 C) and second link (as first link 105,205 among Figure 1B and Fig. 1 C).
Usually the control end of this short circuit electronic switch 110 or 210 can be connected external control component; Disconnect at the mode switch electronic switch, and aerial array constitute capacitive coupling touch-control array the time, this short circuit electronic switch closes (closure at this place can be that the part of short circuit electronic switch 110 or 210 is closed or all closed); All closed at the mode switch electronic switch, when first direction lead 201a and second direction lead 101a formed the electromagnetic induction loop with connecing external control component 100 respectively separately, this short circuit electronic switch 110 and 210 all disconnected.
Shown in Fig. 7 A to Fig. 7 D, Fig. 7 A is the wiring synoptic diagram of the first direction lead group of sensor embodiment in the utility model, Fig. 7 B is the wiring synoptic diagram of the second direction lead group of sensor embodiment in the utility model, Fig. 7 C is Fig. 7 A and the folded wire structures synoptic diagram of establishing of the mutual cross-interleaved of Fig. 7 B lead group in the utility model, and Fig. 7 D is the structural representation of the first direction lead of sensor embodiment in the utility model.
Wherein, shown in Fig. 7 A, first direction lead in the first direction lead group distributes in the assembled arrangement mode, and two arbitrarily adjacent first direction wire pitch equate in this first direction lead group, and the U-shaped peristome spacing that each first direction lead preferably is set equates.First direction lead top shown in Fig. 7 A is electrically connected with a plurality of capacitive coupling touch-control parts, and the shape of any two first capacitive coupling touch-control parts is identical.Usually, described capacitive coupling touch-control parts are shaped as rhombus, rectangle, triangle or the shape of combination in any between them, only are the example explanation among Fig. 7 A.Especially, the first capacitive coupling touch-control parts and first direction lead can be made as one.
Shown in Fig. 7 B, second direction lead in the second direction lead group distributes in the assembled arrangement mode, and two arbitrarily adjacent second direction wire pitch equate in this second direction lead group, and the U-shaped peristome spacing that each second direction lead preferably is set equates.Be electrically connected with a plurality of capacitive coupling touch-control parts on the second direction lead shown in Fig. 7 B, the shape of any two second capacitive coupling touch-control parts is identical.Usually, described capacitive coupling touch-control parts are shaped as rhombus, rectangle, triangle or the shape of combination in any between them, only are the example explanation among Fig. 7 B.Especially, the second capacitive coupling touch-control parts and second direction lead can be made as one.
The sensor construction of the reality shown in Fig. 7 C, its first direction lead group and second direction lead group are set to mutual square crossing, arbitrarily adjacent two first direction leads and arbitrarily the spacing of two adjacent second direction leads equate that all and the first direction lead equates with the U-shaped peristome spacing of second direction lead.Especially, any two first capacitive coupling touch-control parts are identical with the shape of the second capacitive coupling touch-control parts.In the sensor construction shown in Fig. 7 C, in first direction lead and the cross one another zone of second direction lead, the described first capacitive coupling touch-control parts equate with spacing between the second capacitive coupling touch-control parts, so that make the touch point of any finger can comprise the two or more first capacitive coupling touch-control parts and/or the second capacitive coupling touch-control parts, and then make minimum plural capacitive coupling parts in the lead group of each direction comprise the alternation information of touch point, this combination can discern preferably alternation information the position of corresponding touch point.
Preferably, shown in Fig. 7 D, on the basis of the foregoing description, the first capacitive coupling touch-control parts also can be configured such that the equivalent electromagnetism and the overlapping or parallel distribution of first direction lead direction of first direction lead; And second capacitive coupling touch-control parts also can be configured such that the equivalent electromagnetism and the overlapping or parallel distribution of second direction lead direction of second direction lead.Only show the synoptic diagram of first direction lead among Fig. 7 D, do not limit at this.
Usually, in the sensor construction of reality, first lead and second lead all are set to straight line, and the arbitrary first capacitive coupling touch-control parts on the first direction lead perhaps have consistent proportionate relationship in the shape symmetry of first direction lead both sides distribution; And, the shape symmetry that arbitrary second capacitive coupling touch-control parts on the second direction lead distribute in the second direction lead both sides symmetry up and down of first lead/second lead (promptly along), perhaps has consistent proportionate relationship, so that among this embodiment the equivalent electromagnetism of first direction lead with the overlapping or parallel distribution of first direction lead direction, the equivalent electromagnetism of second direction lead with the overlapping or parallel distribution of second direction lead direction.Aerial array in this sensor can make first direction lead group consistent with the signal equivalence of the aerial array output shown in above-mentioned Fig. 7 C with the signal of second direction lead group output, so that can accurately know the positional information of the touch point under electromagnetic induction control mode touch mode or the capacitive coupling control mode touch mode, and make the internal arithmetic of the external control component that connects aerial array simple.For instance, the shape that may exist the first capacitive coupling touch-control parts to distribute in first direction lead both sides is asymmetric, but the equivalent electromagnetism that obtains is not point-blank, it easily causes the signal of external control component identification mixed and disorderly, and then the external control component complexity of calculation is improved, and may there be the particular location that accurately to locate touch point, so preferably first lead and second lead all are set to straight line in the present embodiment so that first direction lead and second direction lead separately first lead and the equivalent electromagnetism on second lead in a straight line.
According on the other hand of the present utility model, the utility model also provides a kind of double mode touch module, it comprises first substrate and sensor, and it still is the described sensor of any embodiment in the utility model that the sensor at this place can be, and the aerial array of described sensor is arranged on the described substrate.
As shown in Figure 8, Fig. 8 shows the structural representation of double mode touch module embodiment in the utility model.Wherein, the concrete structure introduction of sensor is located at sensor on the substrate 300 with reference to the description of Figure 1A, reduces so that realize the complexity of double mode touch-control antenna array structure, makes that this double mode touch module manufacturing is simple, with low cost, the integrated level height.Certainly, double mode touch module can overcome the problem of the mutual interference mutually of capacitance touching control pattern and electromagnetic induction control mode touch mode in the prior art effectively.Just schematically show the structure of double mode touch module among Fig. 8, certainly, the structure of this double mode touch module is not defined as the structure among the figure.The position relation of its substrate and sensor is set according to actual product demand.
Preferably, the material of the first direction lead of aerial array (as the 201a among Fig. 8), second direction lead (as the 101a among Fig. 8) is metal forming, conductive silver paste, carbon slurry, ITO conducting film or other conductor in the sensor.Wherein first direction lead and second direction lead can adopt the mode of printing, etching to be arranged on the substrate; Perhaps on first substrate, make with etching, mode of printing.
Certainly, description based on the sensor embodiment, the electromagnetic detecting unit of this double mode touch module also can connect amplification, shaping and logic control unit by an electromagnetic induction coil and constitute, wherein, electromagnetic induction coil and aerial array electric insulation, logic control unit output connects the mode switch electronic switch controling end, is used to detect the interior electromagnetic signal of Touch Zone scope of aerial array, and control model is switched electronic switch and opened and closed.
Electromagnetic induction coil in the present embodiment also can encircle establishes the Touch Zone that aerial array constitutes, or is located at a side or many sides of described Touch Zone.Concrete setting can be with reference to the location diagram shown in above-mentioned Fig. 5 A and Fig. 5 B.
Preferably, the electromagnetic induction coil ring is established the Touch Zone that described aerial array constitutes, and the Touch Zone is provided with in the zone that electromagnetic induction coil surrounds.In a preferred embodiment, electromagnetic induction coil also can be arranged on first substrate, shown in above-mentioned Fig. 5 A, electromagnetic induction coil and the aerial array mode by etching is arranged on first substrate.Certainly should locate the particular location of electromagnetic induction coil sets according to the product demand of reality.
Need to prove, the double mode touch module of in the utility model this also can comprise one second substrate, described electromagnetic induction coil is provided with on second substrate, and second substrate covers or frame is located at first upper surface of base plate and/or lower surface, and first substrate and second substrate constitute substrate in batch.That is to say that the Touch Zone of aerial array is that active zone not only can be provided with in the zone that electromagnetic induction coil surrounds, can also be arranged at electromagnetic induction coil above or below.
As shown in Figure 9, Fig. 9 shows the another kind of structural representation of double mode touch module embodiment in the utility model.Wherein, sensor can be arranged among Fig. 9 in first substrate 302, and the sensor construction at this place is with reference to the arbitrary description among the sensor embodiment.In the present embodiment, electromagnetic induction coil 303 is located on second substrate 301, and second substrate at this place is positioned at the below of first substrate 302, can on second substrate 301, electromagnetic induction coil 303 be set all, also the position of the Touch Zone correspondence of aerial array in the sensor can be provided with electromagnetic induction coil 303.Present embodiment is not to its qualification.Especially, the electromagnetic induction coil described in the above-mentioned any embodiment can adopt enameled wire, perhaps is above-mentioned described electric conductor by etching, printing, for example metal forming, conductive silver paste, carbon slurry or ITO conducting film etc.
In addition, first substrate described in the above-mentioned any embodiment and/or second substrate all can be the substrate of glass substrate, plastic base or the preparation of other hard insulation, and certain first substrate and/or second substrate also can be flexible insulating material.
Further, the utility model also provides a kind of double mode touch-control electronic device, comprises electronics, and this body is provided with display screen, and also comprises any described double mode touch module in the utility model.In practical structure, double mode touch module can be arranged on the surface of electronic installation display screen.Further, when this double mode touch module was arranged on electronic installation display screen surperficial, described electromagnetic induction coil can lay the electronic installation display screen peripheral around setting.
For instance, above-mentioned double mode touch-control electronic device can be panel computer, touch-control mobile phone etc., and it adopts the double mode touch-control electronic device of above-mentioned double mode touch module lighter, thinner.
It should be noted that at last: above embodiment only in order to the explanation the technical solution of the utility model, is not intended to limit; Although the utility model is had been described in detail with reference to previous embodiment, those of ordinary skill in the art is to be understood that: it still can be made amendment to the technical scheme that aforementioned each embodiment put down in writing, and perhaps part technical characterictic wherein is equal to replacement; And these modifications or replacement do not make the essence of appropriate technical solution break away from the spirit and scope of each embodiment technical scheme of the utility model.