CN102902440A - Touch detection method and touch device - Google Patents

Touch detection method and touch device Download PDF

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Publication number
CN102902440A
CN102902440A CN2011104594861A CN201110459486A CN102902440A CN 102902440 A CN102902440 A CN 102902440A CN 2011104594861 A CN2011104594861 A CN 2011104594861A CN 201110459486 A CN201110459486 A CN 201110459486A CN 102902440 A CN102902440 A CN 102902440A
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electrode
touch
portion
sensing unit
plurality
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CN2011104594861A
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Chinese (zh)
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CN102902440B (en
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李振刚
黄臣
杨云
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比亚迪股份有限公司
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Priority to CN201110210959 priority
Priority to CN201110211018.2 priority
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Priority to CN201110459486.1A priority patent/CN102902440B/en
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    • GPHYSICS
    • G06COMPUTING; CALCULATING; COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F3/00Input arrangements for transferring data to be processed into a form capable of being handled by the computer; Output arrangements for transferring data from processing unit to output unit, e.g. interface arrangements
    • G06F3/01Input arrangements or combined input and output arrangements for interaction between user and computer
    • G06F3/03Arrangements for converting the position or the displacement of a member into a coded form
    • G06F3/041Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means
    • G06F3/044Digitisers, e.g. for touch screens or touch pads, characterised by the transducing means by capacitive means

Abstract

The invention provides a touch detection method and a touch device. The method comprises the following steps of: applying a high level signal to one of a first electrode and a second electrode in one of a plurality of sensing units, and grounding the other one of the first electrode and the second electrode to carry out first charging; applying high level signals to the first electrode and the second electrode to carry out second charging; grounding the first electrode and the second electrode of the sensing unit or grounding one of the first electrode and the second electrode and disconnecting the other one of the first electrode and the second electrode to carry out first discharging on self capacitors; detecting the corresponding first electrode or second electrode to obtain a second detection variation value between second charging and first discharging; and computing the touch position according to a first detection variation value and the second detection variation value.

Description

触摸检测方法及触控装置 The touch detection apparatus and a touch

技术领域 FIELD

[0001] 本发明涉及电子设备设计及制造技术领域,特别涉及一种触摸检测方法及触控装置。 [0001] The present invention relates to the design and manufacturing technology of electronic devices, and particularly to a method for detecting a touch and a touch device.

背景技术 Background technique

[0002]目前触摸屏的应用范围从以往的银行自动柜员机,工控计算机等小众商用市场,迅速扩展到手机,PDA (个人数字助理),GPS (全球定位系统),PMP (MP3,MP4等),甚至平板电脑等大众消费电子领域。 [0002] Currently the scope of application of the touch screen of automatic teller machines from the previous bank, industrial computer and other niche commercial market, the rapid expansion of the mobile phone, PDA (personal digital assistant), GPS (Global Positioning System), PMP (MP3, MP4, etc.), even tablet PCs and other mass consumer electronics. 用于触摸屏具有触控操作简单、便捷、人性化的优点,因此触摸屏有望成为人机互动的最佳界面而迅速在便携式设备中得到了广泛应用。 A touch screen for touch operation is simple, convenient and user-friendly advantages, so the touch screen interface is expected to become the best human-computer interaction and rapid has been widely used in portable devices.

[0003] 电容触摸屏通常被分为自电容和互电容两类。 [0003] The capacitive touch screen are generally divided into two types of self capacitance and mutual capacitance. 如图I所示,为现有技术中常见的一种自电容触摸屏的结构图。 As shown in FIG. I, the prior art is a common configuration diagram of a self-capacitance touch screen. 该自电容触摸屏主要有双层的菱形结构感应单元100'和200',其检测原理是对X轴和Y轴分别扫描,如果检测到某个交叉点的电容变化超出了预设范围,则将该行和列的交叉点做为触摸坐标。 The capacitance touch screen rhombus structure mainly bilayer sensing unit 100 'and 200', which is the principle of detecting X and Y axes, respectively, scanning, if it detects a change in capacitance of the intersection outside the predetermined range, then the intersections of rows and columns as the touch coordinates. 虽然该自电容触摸屏的线性度较好,但是经常有鬼点出现,难以实现多点触摸。 Although self-linearity of the capacitive touch screen is better, but often point ghosts appear, it is difficult to achieve multi-point touch. 此外,由于采用双层屏,也会导致结构及成本大幅增加,并且菱形结构在电容变化量很小的情况下会出现坐标飘移,受外界干扰影响大。 In addition, the use of the double screen, and can lead to a substantial increase in construction costs, and the diamond structure in a small amount of capacitance change happens coordinate drifted outside interference big impact.

[0004] 如图2a所示,为现有技术中常见的另一种自电容触摸屏的结构图。 As shown in [0004] Figure 2a, the prior art is another configuration diagram of a self-capacitance touch screen common. 该自电容触摸屏采用三角形图形屏结构。 The capacitance touch screen panel structure triangular pattern. 该自电容触摸屏包括基板300'、设置在基板300'之上的多个三角形感应单元400'、和每个三角形感应单元400'相连的多个电极500'。 A plurality of triangular sensing units of the self-capacitance touch screen includes a substrate 300 ', disposed in the substrate 300' on 400 ', the sensing unit 400 and each triangle' connected to the plurality of electrodes 500 '. 如图2b所示,为三角形自电容触摸屏的检测原理。 2b, the detection principle of a triangular self-capacitance touch screen. 如图所示,椭圆表示手指,S1、S2表示手指与两个三角形感应单元的接触面积。 As shown, a finger is elliptic, S1, S2 represents the contact area of ​​the finger with two triangular sensing unit. 假设坐标原点在左下角,则横坐标X = S2/(S1+S2)*P,其中,P为分辨率。 Assumed that the coordinate origin at the lower left, the abscissa X = S2 / (S1 + S2) * P, wherein, P is the resolution. 当手指向右移动时,由于S2不是线性增大,所以X坐标存在一个偏差。 When the finger is moved rightward, since the increase in S2 it is not linear, there is a deviation of the X coordinate. 从上述原理可以看出,目前的三角形感应单元是单端检测,即只从一个方向检测,然后通过算法算出两个方向的坐标。 As can be seen from the above principle, the triangular sensing current detecting unit is a single-ended, i.e., detects only from one direction, then the coordinates of two directions is calculated by the algorithm. 虽然该自电容触摸屏结构更为简单,但并没有针对屏幕的电容感应进行优化,电容变化量小,从而导致信噪比不够。 Although the self-capacitance touch screen structure is more simple, but not optimized for capacitive sensing screen, a small amount of capacitance variation, leading to noise ratio is not enough. 此外,由于该感应单元为三角形,当手指横向移动时面积不是线性增大,因此线性度较差,导致了坐标计算发生偏移,线性度不够好。 Further, since the sensing means is a triangle, when the lateral movement of the finger area is not linearly increased, thus the linearity is poor, resulting in the shifted coordinate calculation, linearity good enough.

[0005] 此外,该电容感应单元输出电容变化量很小,达到飞法级,其电缆杂散电容的存在,对测量电路提出了更高的要求。 [0005] In addition, the capacitive sensing cell output capacitance variation is small, to fly stage method, the presence of stray capacitance of the cable which, for a higher measuring circuit requirements. 而且,杂散电容会随温度、位置、内外电场分布等诸多因素影响而变化,干扰甚至淹没被测电容信号。 Furthermore, stray capacitance varies with many factors can affect the temperature, position, and outside the electric field distribution, the interference signal measured capacitance even submerged. 此外,对于单层电容来说,由于Vcom电平信号的影响会对感应电容形成严重的干扰,其中,Vcom电平信号是为了防止LCD屏幕液晶老化而不停翻转的电平信号。 Further, for a single layer capacitor, because the influence of the level of the signal Vcom be a serious disturbance sensing capacitor, wherein, the level of signal Vcom to prevent the LCD screen of the liquid crystal aging kept inverted level signal.

发明内容 SUMMARY

[0006] 本发明的目的旨在至少解决上述技术缺陷之一,特别是解决或避免出现现有自电容触摸屏中的上述缺点。 Objective [0006] The present invention is intended to solve at least one of the above technical defects, in particular, to solve the above-described disadvantages of the prior or avoid the self-capacitance touch screen.

[0007] 本发明实施例第一方面提出了一种触摸屏的触摸检测方法,所述触摸屏包括多个不相交的感应单元,每个感应单元的两端分别具有第一电极和第二电极,所述方法包括以下步骤:向所述多个感应单元中一个感应单元的第一电极和第二电极中的一个施加高电平信号,并将所述第一电极和第二电极中的另一个接地,以在所述一个感应单元被触摸时对所述一个感应单元产生的自电容进行第一次充电;向所述多个感应单元中的一个感应单元的第一电极和第二电极施加高电平信号,或者,向所述第一电极和所述第二电极中的一个施加高电平信号并将所述第一电极和所述第二电极中的另一个断开,以对所述自电容进行第二次充电;从对应的所述第一电极或第二电极进行检测以获得所述第一次充电和所述第二次充电之间的第一检测变化值;将所述一个感应单 Embodiment of the first aspect [0007] The present invention proposes a method of detecting a touch of a touch screen, the touch screen comprises a plurality of disjoint sensing unit, both ends of each sensing cell having first and second electrodes, the said method comprising the steps of: a first electrode unit and a high-level signal is applied to the second sensing electrode to the plurality of sensing units, and the other of the first ground electrode and the second electrode , when the self-capacitance sensing unit is a touch sensing unit to the one generated by the first charge; applying a high electrically to the first electrode of said plurality of sensing means sensing units and the second electrode level signal or a high level signal is applied to said first electrode and said second electrode and said one other of the first electrode and the second electrode is disconnected, to the self- charging a second capacitor; detecting from the corresponding first or second electrode to obtain a first charge and the first charge detecting a change between a second value; and said sensing a single 元的第一电极和第二电极接地,或者,将所述第一电极和所述第二电极中的一个接地并将所述第一电极和所述第二电极中的另一个断开,以对所述自电容进行第一次放电;从对应的所述第一电极或第二电极进行检测以获得所述第二次充电和所述第一次放电之间的第二检测变化值;根据所述第一检测变化值和第二检测变化值计算所述自电容至所述第一电极之间的第一电阻和所述自电容至所述第二电极之间的第二电阻的比例关系;以及根据所述第一电阻和所述第二电阻之间的比例关系确定触摸位置。 A first electrode and a second electrode grounded element, or the other one of said first ground electrode and the second electrode and the first electrode and the second electrode is disconnected to the discharge from the first capacitor; detecting from the corresponding first or second electrode to obtain a second detection of the second change value between the first charge and discharge; the detecting a change in said first value and the second change in the detection value calculating a first proportional relationship between the resistance from the first electrode of the capacitor to and from the capacitor to the second resistor between the second electrode ; and a touch position is determined according to the proportional relationship between the first resistor and the second resistor.

[0008] 本发明实施例第二方面还提出了一种触控装置,包括:基板;多个不相交的感应单元,所述多个感应单元形成在所述基板之上,且每个感应单元的两端分别具有第一电极和第二电极;触摸屏控制芯片,所述触摸屏控制芯片包括充电模块、放电模块和检测模块,其中,所述充电模块,用于在第一次充电过程中,向所述多个感应单元中一个感应单元的第一电极和第二电极中的一个施加高电平信号,并将所述第一电极和第二电极中的另一个接地,以在所述一个感应单元被触摸时对所述一个感应单元产生的自电容进行第一次充电;在第二次充电过程中,向所述多个感应单元中的一个感应单元的第一电极和第二电极施加高电平信号,或者,向所述第一电极和第二电极中的一个施加高电平信号并将所述第一电极和第二电极中的另一个断开,以对所述自电容 Embodiment [0008] A second aspect of the present invention further provides a touch device, comprising: a substrate; a plurality of disjoint sensing unit, a plurality of sensing cells formed on said substrate, each sensing unit and the both ends having a first electrode and a second electrode; touch screen control chip, the touch screen control module includes a charging chip, discharge module and a detection module, wherein the charging module for charging in the first process, the a plurality of said first and second electrodes in a sensing unit sensing unit applying a high level signal, and the first electrode and the second electrode is the other ground, to a sensor in the unit from a capacitance of the sensing unit generated by the first charging is touched; in the second charging process, a high applied to the first electrode and the second electrode of one of said plurality of sensing means sensing units level signal or a high level signal is applied to the other and disconnect the first electrode and the second electrode to the first electrode and a second electrode, the self-capacitance 进行第二次充电;所述放电模块,用于在所述充电模块对所述自电容第二次充电之后,将所述一个感应单元的第一电极和第二电极接地,或者,将所述第一电极和所述第二电极中的一个接地并将所述第一电极和所述第二电极中的另一个断开以对所述自电容进行第一次放电,和所述检测模块,用于从对应的所述第一电极或第二电极进行检测以获得所述第一次充电和所述第二次充电之间的第一检测变化值,及从对应的所述第一电极或第二电极进行检测以获得所述第二次充电和所述第一次放电之间的第二检测变化值,和控制及计算模块,用于对所述充电模块、放电模块、第一检测模块和第二检测模块进行控制,并根据第一检测变化值和第二检测变化值计算所述自电容至所述第一电极之间的第一电阻和所述自电容至所述第二电极之间的第二电阻之间的比例 A second charge; the discharge module, a charging module for the second time since the charging capacitor, a first electrode of the sensing cell and the second electrode is grounded, or, in the a ground electrode and the second electrode of the other of the first and the second electrode and the first electrode and turned off to perform the self-capacitance of the first discharge, and the detection module, detecting a change between a first value for a second charge detected from the corresponding first or second electrode to achieve the first and the charge, and from the corresponding first electrode or the second electrode to obtain a second detected value between the detected change in the said second charge and first discharge, and calculation and control means for the charging module, a discharge module, a first detection module and second detection control module, and calculating from the capacitor to a first resistance between said first electrode and said second electrode from the capacitor to the detection of a first change value and the second change value detection the ratio between the second resistance between 系,并根据所述第一电阻和所述第二电阻之间的比例关系确定触摸位置。 System, and the touch position is determined according to the proportional relationship between the first resistor and the second resistor.

[0009] 本发明实施例第三方面还提出了一种便携式电子设备,包括如上所述的触控装置。 [0009] The embodiment of the third aspect of the present invention further provides an embodiment of a portable electronic device comprising a touch device as described above.

[0010] 本发明实施例的触摸屏检测设备中的感应单元采用双端检测,即感应单元的两端均具有电极,且每个电极均与触摸屏控制芯片的对应管脚相连,在进行触摸检测时通过感应单元自身即可实现对触摸点的定位。 When the [0010] touch screen detection apparatus of the embodiment of the present invention uses the double end detection sensor unit, i.e. the unit has induced across the electrodes, and each electrode is connected with a corresponding pin of the touch screen control chip, the touch detection is performed itself can be realized through the touch point locating sensing unit.

[0011] 更为重要的是,本发明通过计算第一电阻和第二电阻之间比例实现触摸位置的确定,因此相对于目前的菱形或三角形设计来说,由于在确定触摸位置时,无需计算自电容的大小,且自电容的大小不会影响触摸位置的精度,从而提高了测量精度,改善了线性度。 [0011] More importantly, the present invention is calculated by determining the ratio between the first and second resistors to achieve touch position, and therefore with respect to the current design of diamond or triangular, because when the touch position is determined, need not be calculated from the size of the capacitor, and from the magnitude of the capacitance does not affect the accuracy of the touch position, thus improve the measurement accuracy, improved linearity. [0012] 本发明实施例通过对感应单元两端的电极施加电平信号,如果该感应单元被触碰,触摸物体(例如手指)则会与该感应单元形成自电容,因此本发明通过施加的电平信号可对该自电容进行充电,并根据第一电阻和第二电阻之间的比例关系确定触摸屏上的触摸位置。 [0012] The embodiments of the present invention the electrical level signal is applied through the electrodes to the ends of the sensing unit, if the sensing unit is touched, touch object (e.g., a finger) will form a self-capacitance of the sensing unit, so the present invention is applied by the level of the signal from the capacitor can be charged, and determining a touch location on the touch screen in accordance with a proportional relationship between the first and second resistors. 且通过本发明实施例的对自电容进行两次充电的检测方式,以抵消某些不可测量的物理参数或者减少物理量的测量,从而在保证检测速度的前提下,有效地提高检测精度。 And the self-capacitance of the embodiments of the invention by way of detecting the charging twice to counteract certain non-physical parameter measured or decrease the measurement of physical quantities, thereby ensuring detection speed premise effectively improve the detection accuracy.

[0013] 本发明实施例提出了一种新颖的自电容检测方式,在感应单元被触摸时,触摸点就可将该感应单元分为两个电阻,从而在进行自电容检测的同时考虑这两个电阻就可以确定触摸点在该感应单元上的位置。 [0013] Example A novel self-capacitance detection method of the present invention, when the sensing unit is touched, the touch point sensing unit can be divided into two resistors, thereby making the self-capacitance detected considering both resistors can determine the position of the sensing unit on the touch point. 本发明实施例的结构简单,并且对于一个感应单元来说,在充电或放电时进行检测,不仅能够降低RC常数,节省时间提高效率,并且还能够保证坐标不会偏移。 Simple structure of the embodiment of the present invention, and for a sensing unit, the detecting during charging or discharging, not only reduces the RC constant, to save time and improve efficiency, and also to ensure that coordinates do not. 此外,本发明实施例还可以有效提高电路的性噪比,降低电路噪声,提高感应线性度。 Further, embodiments of the present invention can further improve the signal to noise ratio of the circuit, the noise reduction circuit, enhance the response linearity. 另外,在检测过程中由于对被触摸的感应单元进行充电,因此其中会产生小电流,能够很好地消除Vcom电平信号对触摸屏中感应单元产生的自电容的影响,因此可以相应地消除屏幕屏蔽层及相关工序,从而可以在增强了抗干扰能力的同时进一步降低成本。 Further, in the detection process due to the touch sensing unit is charged, and therefore which produces a small current, perfectly eliminate self-capacitance impact Vcom level signal touchscreen induced generation unit, it is possible to correspondingly eliminate screen shield and related processes, the cost can be further reduced while the interferences.

[0014] 本发明附加的方面和优点将在下面的描述中部分给出,部分将从下面的描述中变·得明显,或通过本发明的实践了解到。 [0014] This additional aspects and advantages of the invention will be set forth in part in the description which follows, from the following description, distinct sections changers, or learned by practice of the present invention.

附图说明 BRIEF DESCRIPTION

[0015] 本发明上述的和/或附加的方面和优点从下面结合附图对实施例的描述中将变得明显和容易理解,其中: [0015] The present invention described above and / or additional aspects and advantages from the following description of embodiments in conjunction with the accompanying drawings of the embodiments will become apparent and more readily appreciated, wherein:

[0016] 图I为现有技术中常见的一种自电容触摸屏的结构图; [0016] Figure I is a common form of prior art self-capacitance touch screen configuration diagram;

[0017] 图2a为现有技术中常见的另一种自电容触摸屏的结构图; [0017] Figure 2a is a prior art common structural view of another self-capacitance touch screen;

[0018] 图2b为现有技术中常见的另一种自电容触摸屏的检测原理图; [0018] Figure 2b is common in the prior art schematic of another self-test capacitive touch screen;

[0019] 图3为本发明实施例触控装置的检测原理示意图; [0019] FIG. 3 is a schematic embodiment of a touch detection principle embodiment of the invention apparatus;

[0020] 图4为本发明一个实施例的触摸检测方法流程图; [0020] FIG. 4 touch detecting method for a flowchart of an embodiment of the present invention;

[0021] 图5为本发明实施例的矩形感应单元被触摸的示意图; [0021] FIG. 5 is a schematic view of a rectangular embodiment the sensing unit is touched embodiment of the invention;

[0022] 图6a为本发明一个实施例的感应单元结构图; [0022] FIG 6a block diagram of a sensing unit according to an embodiment of the present invention;

[0023] 图6b为本发明一个实施例的感应单元结构图; A sensing unit configuration diagram of an embodiment [0023] FIG. 6b of the present invention;

[0024] 图7a为本发明另一个实施例触摸屏检测设备结构图; [0024] Another embodiment of FIG. 7a configuration diagram of a touch screen detecting apparatus embodiment of the present invention;

[0025] 图7b为本发明另一个实施例触摸屏检测装置结构图; [0025] Another embodiment of a touch screen detecting means configuration diagram in FIG. 7b embodiment of the present invention;

[0026] 图8为本发明实施例的感应单元被触摸时的示意图; [0026] FIG. 8 is a schematic view of the sensing unit is touched embodiment embodiment of the invention;

[0027] 图9a为本发明再一个实施例触摸屏检测设备结构图; [0027] FIG. 9a still another embodiment, the touch screen detecting apparatus configuration diagram of embodiment of the invention;

[0028] 图9b为本发明再一个实施例触摸屏检测装置结构图; A further embodiment of a touch panel detection device configuration diagram of Embodiment [0028] FIG. 9b of the present invention;

[0029] 图10为本发明实施例的感应单元被触摸时的示意图; [0029] FIG. 10 is a schematic embodiment of the sensor element has been touched embodiment of the invention;

[0030] 图11为本发明一个实施例的触控装置示意图; [0030] FIG 11 a schematic view of a touch device according to an embodiment of the present invention;

[0031]图12为本发明实施例触摸屏控制芯片的结构图。 [0031] FIG 12 a structural diagram of a touch screen control chip embodiment of the present invention.

具体实施方式 Detailed ways

[0032] 下面详细描述本发明的实施例,所述实施例的示例在附图中示出,其中自始至终相同或类似的标号表示相同或类似的元件或具有相同或类似功能的元件。 [0032] Example embodiments of the present invention is described in detail below, exemplary embodiments of the embodiment shown in the accompanying drawings, wherein same or similar reference numerals designate the same or similar elements or elements having the same or similar functions. 下面通过参考附图描述的实施例是示例性的,仅用于解释本发明,而不能解释为对本发明的限制。 By following with reference to the embodiments described are exemplary only for explaining the present invention and should not be construed as limiting the present invention.

[0033] 本发明实施例提出了一种新颖的自电容检测方式,在感应单元被触摸时,触摸点可以将该感应单元分为两个电阻,在进行自电容检测的同时考虑这两个电阻就可以确定触摸点在该感应单元上的位置。 [0033] Example A novel self-capacitance detection method of the present invention, when the sensing unit is touched, the sensing unit may be a touch point is divided into two resistors, capacitance detection is performed from taking two resistors you can determine the position of the sensing unit on the touch point. 如图3所示,为本发明实施例触控装置的检测原理示意图。 3, a schematic view of the principle of the detection device of embodiments of the present invention the touch. 当手指触摸该感应单元时,将相当于将该感应单元分割为两个电阻,这两个电阻的阻值与触摸点的位置相关。 When a finger touches the sensing means, the sensing means corresponding to the division of two resistors, the resistance associated with the position of a touch point of these two resistors. 例如,如图所述,当触摸点与第一电极较近时,则电阻Rl就较小,而电阻R2就较大;反之,当触摸点与第二电极较近时,则电阻Rl就较大,而电阻R2就较小。 For example, as described, when the touch point is close to the first electrode, the resistance Rl on the small and the large and resistor R2; the other hand, when the touch point closer to the second electrode, the resistance Rl on the more large, and the resistance R2 is small. 因此,本发明通过对电阻Rl和R2的检测就可以确定触摸点在该感应单元上的位置。 Accordingly, the present invention is by detecting resistors Rl and R2 can determine the position of the touch on the sensing unit. 在本发明的实施例中,通过多种方式检测电阻Rl和R2,例如可通过检测第一电极和第二电极的电流检测变化值、自电容检测变化值、电平信号检测变化值和电荷变化量中的一种或多种,从而根据这些检测变化值获得电阻Rl和R2。 In an embodiment of the present invention, by various means detecting resistor Rl and R2, for example, detecting a change in current value detected by the first electrode and the second electrode, a capacitance detecting a change from the value of the level signal and detecting a change in value of the charge change amount of one or more so as to obtain resistors Rl and R2 changes in accordance with these detection values. 并且本发明通过对由触摸点形成的自电容进行两次充电以抵消某些不可测量的物理参数或者减少物理量的测量,提高测量精度。 And the present invention is to offset the charge by two physical parameter measurement or some non-reducing physical measurement, improve the measurement accuracy of the self-capacitance is formed by the touch point.

[0034] 需要说明的是,在本发明的实施例中,上述第一电极和第二电极的功能相同,且二者可以互换,因此在上述实施例中,既可以从第一电极检测也可以从第二电极检测,只要能满足在充电、放电或检测时需要有电流经过第一电阻和第二电阻这一要求即可。 [0034] Incidentally, in the embodiment of the present invention, the first electrode and the second electrode of the same functions, and both are interchangeable, so in the above embodiment, may be also detected from the first electrode can be detected from the second electrode, as long as satisfying the charge or discharge current is detected when needed through the first and second resistors to this requirement.

[0035] 在本发明的实施例中,可以以扫描的方式依次向多个感应单元施加相应的电压,同时在检测时也可以以扫描的方式依次进行检测。 [0035] In an embodiment of the present invention may be applied sequentially in a scanning manner corresponding to the plurality of voltage sensing unit can also sequentially detects a scanning manner upon detection.

[0036] 如图4所示,为本发明实施例的触摸检测方法流程图,该流程图结合图3所示的原理图一同进行说明。 [0036] As shown in FIG 4, the touch detecting method of the present invention, an embodiment of a flow chart, showing the principle in conjunction with the flowchart shown in FIG. 3 will be described together. 该方法包括以下步骤: The method comprises the steps of:

[0037] 步骤S401,向所述多个感应单元中一个感应单元的第一电极和第二电极中的一个施加高电平信号,并将所述第一电极和第二电极中的另一个接地,以在感应单元被触摸时对感应单兀产生的自电容进行第一次充电。 [0037] step S401, the high level signal is applied to the first electrode of the plurality of sensing units in a sensing unit and a second electrode, and the other of said first ground electrode and the second electrode , when the self-capacitance touch sensing unit for sensing a single Wu is generated by the first charge. 在该实施例中,向第一电极和第二电极中的一个施加高电平信号Vcc。 In this embodiment, a high level signal Vcc is applied to the first electrode and the second electrode a.

[0038] 如果此时该感应单元被手指或其他物体触摸,则该感应单元将会产生自电容Cl (参照图3),因此通过施加的高电平信号Vcc就可对自电容进行充电。 [0038] At this time, if the sensing unit is touched with a finger or other object, the sensing unit will generate a self-capacitance CI (see FIG. 3), and therefore can be charged by the self-capacitance of the high level signal is applied to Vcc. 此时,在本发明的一个实施例中,如果向第一电极施加高电平信号,则施加在自电容上的电压为V2 = VccR2/(R1+R2)。 At this time, a voltage, in one embodiment of the present invention, if the high level signal is applied to the first electrode, is applied on the self-capacitance of V2 = VccR2 / (R1 + R2). 在本发明的一个实施例中,如果向第二电极施加高电平信号,则施加在自电容上的电压为Vl = VccRl/(R1+R2)。 In one embodiment of the present invention, if the high-level signal is applied to the second electrode, is applied from the voltage on the capacitor is Vl = VccRl / (R1 + R2).

[0039] 此外,在本发明的实施例中,通过对自电容的充电,还可以提高自电容的检测精度。 [0039] Further, in the embodiment of the present invention, the capacitor is charged by the self, but also can improve the detection accuracy of self-capacitance.

[0040] 在本发明的一个实施例中,如果该感应单元没有被触摸,则后续将无法检测到自电容的存在,因此可判断其未被触摸。 [0040] In one embodiment of the present invention, if the sensing unit is not touched, then the following will not detect the presence of self-capacitance, and therefore it can be judged not touched.

[0041] 步骤S402,向一个感应单元的第一电极和第二电极施加高电平信号,或者,向第一电极和第二电极中的一个施加高电平信号并将第一电极和第二电极中的另一个断开,以对自电容进行第二次充电。 [0041] step S402, is applied to the first electrode and the second electrode of a high-level signal sensing unit, or a high level signal is applied to the first electrode and the first electrode and the second electrode and a second the other electrodes disconnected from the capacitor to a second of the charge.

[0042] 在本发明实施例中,可向第一电极和第二电极均施加高电平信号;或者,向第一电极施加高电平信号,而将第二电极断开;或者,向第二电极施加高电平信号,而将第一电极断开。 [0042] In an embodiment of the present invention may be applied to both the first and second electrodes to the high level signal; Alternatively, a high level signal is applied to the first electrode and the second electrode is disconnected; or to the second a high level signal is applied to two electrodes, the first electrode is disconnected. 另外需指出的是,由于施加的高电平信号为已知量,故两次所施加的高电平信号可以相同或者不相同,均不影响推导过程。 Further to be noted that, due to the high-level signal of a high level signal is applied to a known quantity, it may be applied twice a same or different, do not affect the derivation process. 在该实施例中,向第一电极和/或第二电极施加与步骤S401中相同的高电平信号Vcc。 In this embodiment, the same high level signal is applied to Vcc and step S401 to the first electrode and / or the second electrode. 此时施加在自电容上的电压为Vcc。 At this time, since the voltage applied to the capacitor is Vcc.

[0043] 步骤S403,从对应的第一电极或第二电极进行检测以获得第一次充电和第二次充电之间的第一检测变化值。 [0043] step S403, the inspection on the corresponding first electrode or the second electrode to obtain a first detected value changes between the first charge and the second charge. 在本发明的实施例中,所述的对应是指以下情况,例如,当一个感应单元的第一电极和第二电极均接高电平信号进行充电时,从第一电极和第二电极均可进行检测;如当第一电极接高电平信号,第二电极断开时,则只能从第一电极检测;反之,当第二电极接高电平信号,第一电极断开时,则只能从第二电极检测。 In an embodiment of the present invention, the following means corresponds, for example, when the first and second electrodes are connected to a sensing unit for charging a high level signal from both the first and second electrodes can be detected; such as when a high level signal of the first electrode, the second electrode is disconnected from the first electrode can only be detected; the other hand, when a high level signal of the second electrode, the first electrode is disconnected, It can only be detected from the second electrode.

[0044] 在本发明的实施例中,只要第二次充电的方式与第一次充电的方式不同,就可引起自电容中电荷量的变化。 [0044] In an embodiment of the present invention, as long as the second charge in the first charge and the manner in different ways, can cause changes in amount of charge from the capacitor. 此外,在检测完后需对自电容进行放电以便进行下一次充放电过程。 Further, after detecting the need to charge a capacitor from a discharge for the discharge process.

[0045] 在本实施例中,假设第一检测变化值为AQ1。 [0045] In the present embodiment, it is assumed a first detectable change is AQ1. 以下以第一检测变化值和第二检测变化值为电荷变化量为例进行描述,但是能够反应电阻Rl和R2之间关系的其他检测变化值,例如电平信号、电流等也均可采用。 The following changes to the first detection value and the second variation amount detecting a change of charge is described as an example, but can detect a change in the reaction of other relationship between the resistance value Rl and R2, for example, level signal, current, etc. can be employed. [0046] 其中,如果在步骤401中,向第一电极施加高电平信号,则AQl = VlCl =VccClRl/(R1+R2) (Ia),其中,Vl = VccRl/(R1+R2)。 [0046] wherein, if in step 401, a high level signal is applied to the first electrode, the AQl = VlCl = VccClRl / (R1 + R2) (Ia), wherein, Vl = VccRl / (R1 + R2). 此时第一次充电时自电容的电压为V2,该自电容电压可在第一次充电时检测或计算得到。 Since the capacitor voltage at this time is V2 when the first charge, the self-capacitance can be detected or calculated voltage at the first charge.

[0047] 其中,如果在步骤401中,向第二电极施加高电平信号,则AQl = V2C1 =VccClR2/ (R1+R2) (Ib),其中,V2 = VccR2/ (R1+R2)。 [0047] wherein, if in step 401, a high level signal is applied to the second electrode, the AQl = V2C1 = VccClR2 / (R1 + R2) (Ib), where, V2 = VccR2 / (R1 + R2). 此时第一次充电时自电容的电压为Vl,该自电容电压可在第一次充电时检测或计算得到。 Since the voltage of the capacitor to the first charge Vl At this time, since the capacitor voltage can be detected or calculated at the first charge.

[0048] 步骤S404,将一个感应单元的第一电极和第二电极接地,或者,将第一电极和第二电极中的一个接地并将第一电极和第二电极中的另一个断开,以对自电容进行第一次放电。 [0048] step S404, the one of the first electrode and the second electrode unit sensing ground, or another one of the first ground electrode and the second electrode and the first electrode and the second electrode is disconnected, in self-capacitance of the first discharge.

[0049] 具体地,可将一个感应单元的第一电极和第二电极均接地,或者,将第一电极接地,而第二电极断开,或者,将第二电极接地,而将第一电极断开,以对自电容进行第一次放电。 [0049] Specifically, a first electrode and a second electrode of the sensing cell are grounded, or the first ground electrode and the second electrode is disconnected, or the second electrode is grounded, and the first electrode turned off to self-capacitance of the first discharge.

[0050] 步骤S405,从对应的第一电极或第二电极进行检测以获得第二次充电和第一次放电之间的第二检测变化值。 [0050] step S405, the inspection on the corresponding first electrode or the second electrode to obtain a second detected value changes between the first and second charge and discharge.

[0051] 在本实施例中,假设第二检测变化值为AQ2。 [0051] In the present embodiment, change detection is assumed that the second AQ2. 第二检测变化值需采用与步骤S403中的第一检测变化值相同的检测变化值,即在本发明实施例中均为电荷变化量。 Detecting a change requires the use of a second value to the first change value detection step S403 detects a change of the same value, i.e., both the charge variation amount in the embodiment of the present invention. 同样地,在此所述“对应的”也是相对的概念,例如在第一次放电时,如果第二电极断开,则只能从第一电极进行检测。 Similarly, the herein "corresponding to" is a relative concept, for example, when the first discharge, if the second electrode is disconnected, the only detected from the first electrode.

[0052]其中,Λ Q2 = VccCl (2) [0052] wherein, Λ Q2 = VccCl (2)

[0053] 步骤S406,根据第一检测变化值和第二检测变化值计算自电容至第一电极之间的第一电阻和自电容至第二电极之间的第二电阻的比例关系,并根据第一电阻和第二电阻的比例关系确定触摸位置。 [0053] step S406, based on the first detection value and the second variation detecting a change of the first value calculated from the proportional relationship between the resistance and the capacitor to the first electrode from the second electrode to the capacitance between the second resistor, and in accordance with the ratio between the first and second resistors determine the touch location. 在本发明的一个实施例中,通过式(Ia)(或Ib)和(2)所表示的自电容电荷变化量可以计算出Rl与R2的比例关系,由于图形的规则线性关系,则可以计算出触摸点所在的横坐标的位置,及自电容Cl所在的位置。 In one embodiment of the present invention, by the formula (Ia) (or Ib) can be calculated and the capacitive charge variation amount from (2) represented by the Rl and R2 proportional relationship, since rules linear patterns can be calculated the abscissa where the position of the touch point, and the position where the self-capacitance Cl.

[0054] 在本发明的实施例中,如果在步骤401中,向第一电极施加高电平信号,则R1/R2=Λ Ql/ ( Λ Q2- Δ Ql),因此通过本发明实施例就可获得Rl和R2之间的比例关系。 [0054] In an embodiment of the present invention, if in step 401, a high level signal is applied to the first electrode, then R1 / R2 = Λ Ql / (Λ Q2- Δ Ql), and therefore the embodiments of the present invention to obtained proportional relationship between Rl and R2.

[0055] 在本发明的实施例中,如果在步骤401中,向第二电极施加高电平信号,则R1/R2=(Λ Q2- Λ Ql) / Λ Ql,因此通过本发明实施例就可获得Rl和R2之间的比例关系。 [0055] In an embodiment of the present invention, if in step 401, a high level signal is applied to the second electrode, the R1 / R2 = (Λ Q2- Λ Ql) / Λ Ql, embodiments of the present invention is therefore to obtained proportional relationship between Rl and R2.

[0056] 在本发明的实施例中,如果感应单元为门形感应单元或L形感应单元,则通过第一电阻和第二电阻之间的比值就可确定在触摸屏上的触摸位置,以下将结合具体的例子进行详述。 [0056] In an embodiment of the present invention, can determine the touch location on the touch screen if the sensing unit is a gate-shaped or L-shaped sensing unit sensing means, the ratio between the first and second resistors through, will be with reference to specific examples described in detail. 但在本发明的其他实施例中,如果感应单元为矩形感应单元或蛇形(但整体上看相当于矩形)感应单元,则步骤S406只能计算出在触摸屏第一方向上的触摸位置,该第一方向可以是感应单元的长度方向(例如触摸屏的水平方向)。 However, in other embodiments of the present invention, if the sensing unit sensing unit or serpentine rectangular (rectangle, but on the whole the equivalent of) the sensing unit, then step S406 is calculated only in a first direction of the touch position of the touch screen, the the first direction may be a longitudinal direction (e.g. horizontal direction of the touch screen) of the sensing unit.

[0057] 如果感应单元为矩形感应单元或蛇形(但整体上看相当于矩形)感应单元,则还需要根据感应单元的位置确定在第二方向上的触摸位置。 [0057] If the sensing unit sensing unit or serpentine rectangular (rectangle, but on the whole the equivalent of) the sensing unit, it is also necessary to determine the touch position in the second direction according to the position sensing unit. 在本发明的一个实施例中,第一方向为感应单元的长度方向,第二方向为垂直于感应单元的方向,感应单元水平设置或垂直设置。 In one embodiment of the present invention, the first direction is a longitudinal direction of the sensing unit, the direction sensing unit, the sensing unit disposed horizontally or vertically arranged perpendicular to the second direction.

[0058] 在本发明的实施例中,自电容检测模块可为目前已知的自电容检测模块,因此在此不再赘述。 [0058] In an embodiment of the present invention, the detection module may be a self-capacitance of known self capacitance detection module, and therefore not repeated here. · ·

[0059] 在本发明的一个实施例中,如果采用两个自电容检测模块的话,则由于两个自电容检测模块可共用多个器件,因此不会增大芯片的整体功耗。 [0059] In one embodiment of the present invention, if two self-capacitance detection module, then since the two self-capacitance detection module may share a plurality of devices, and therefore does not increase the overall power consumption of the chip.

[0060] 在本发明的一个实施例中,感应单元可采用不同的形状。 [0060] embodiment, the sensing unit may take different shapes in one embodiment of the present invention. 优选地,多个不相交的感应单元位于同一层,从而在保证检测精度的情况下,能够极大地节省成本。 Preferably, a plurality of disjoint sensing unit in the same layer, so that in a case where the detection accuracy is guaranteed, can greatly save costs.

[0061] 在本发明的上述实施例中,虽然以第一次充电、第二次充电和第一次放电为例进行描述,但是本发明中只要有三个不同的状态即可,通过测量任意两个不同状态之间的状态差(即检测变化值)就可获得Rl和R2之间的比例关系。 [0061] In the above embodiment of the present invention, although the first charge, a second charge and first discharge described as an example, but the present invention as long as there can be three different states, by measuring any two state difference between the different states (i.e. detecting a change in value) can be obtained proportional relationship between Rl and R2. 在该实施例中,三个不同的状态为第一次充电后的状态,第二次充电后的状态和放电后的状态。 In this embodiment, three different states of the first state of charge, charge state and the second state after discharge.

[0062] 如图5所示,为本发明实施例的矩形感应单元被触摸的示意图。 As shown in [0062] FIG. 5, a schematic view of a rectangular embodiment of the sensing unit is touched embodiment of the present invention. 该感应单元为矩形,且多个感应单元与所述触摸屏的第一方向相互平行,因此触摸位置为在第一方向上的触摸位置。 The sensing means is rectangular, and a plurality of sensing units with the touch screen in a first direction parallel to each other, the touch position as a touch position in the first direction.

[0063] 如图6a所示,为本发明一个实施例的感应单元结构图。 As shown in [0063] FIG. 6a, a block diagram of the sensing unit according to an embodiment of the present invention. 该感应单元200包括多个第一部分230和多个平行第二部分240,其中,相邻的第一部分230之间通过第二部分240相连,以形成多个交替排列的第一凹槽1000和第二凹槽2000,其中,多个第一凹槽1000和多个第二凹槽2000的开口方向相反。 The sensing unit 200 includes a plurality of the first portion 230 and a plurality of second parallel portion 240, wherein first portion 230 between the adjacent second portions 240 are connected to form a plurality of alternately arranged first groove 1000 and the second two recesses 2000, wherein a plurality of first grooves 1000 and the opening 2000 in the direction opposite to the plurality of second grooves. 优选地,第二部分240沿第一方向排列。 Preferably, the second portion 240 are arranged in the first direction. 在本发明的一个实施例中,多个第一部分230可以相互平行,也可以不平行。 In one embodiment of the present invention, the plurality of the first portion 230 may be parallel to each other and to be non-parallel. 且,优选地,第二部分240为矩形。 And, preferably, the second portion 240 is rectangular. 在本发明的其他实施例中,第一部分230也可为矩形,但第一部分230还可为其它多种形状。 In other embodiments of the present invention, the first portion 230 may be rectangular, but the first portion 230 may also be other various shapes. 在该实施例中,通过第一部分230增加电阻的阻抗,从而增大感应单元200的阻抗,使得第一电阻和第二电阻更易检测,进一步地提高检测精度。 In this embodiment, by increasing the resistance of the resistor of the first portion 230, thereby increasing the impedance of the induction unit 200 so that the first and second resistors easier detection, the detection accuracy is further improved. 且在该实施例中,优选地,第二部分240之间的间隔相等,从而能够从感应单元的阻抗进行均匀地提高,以改善检测精度。 And in this embodiment, preferably, the spacing between the second portion 240 are equal, it is possible to uniformly increase the impedance from the sensing unit to improve the detection accuracy. 在本发明的一个实施例中,第一方向为感应单兀200的长度方向,第二方向为垂直于感应单元200的方向,具体地,感应单元200可水平设置或垂直设置。 In one embodiment of the present invention, the first direction is a longitudinal direction Wu single sensor 200, and the second direction is a direction perpendicular to the sensing unit 200 is, specifically, the sensing unit 200 may be arranged horizontally or vertically disposed.

[0064] 在本发明的实施例中,感应单元200长度方向的尺寸与基板的尺寸基本一致,因此触控装置结构简单,容易制造,且制造成本低。 [0064] In an embodiment of the present invention, the size and the size of the substrate in the longitudinal direction sensing unit 200 are basically the same, so the touch device structure is simple, easy to manufacture, low manufacturing cost.

[0065] 在本发明的一个实施例中,第一电极210和第二电极220分别与多个第一部分230中的两个第一部分相连。 [0065] In one embodiment of the present invention, the first electrode 210 and second electrode 220 are respectively connected to the two first portions 230 of the plurality of first portions. 但是在本发明的另一个实施例中,第一电极210和第二电极220分别与多个第二部分240中的两个第二部分相连,如图6b所示。 However embodiment, the first electrode 210 and second electrode 220 is connected to the second portion of the plurality of two second portions 240, respectively, in another embodiment of the present invention, shown in Figure 6b. [0066] 并且,在本发明的实施例中,第二部分240和第一部分230之间相互垂直,二者之间的角度优选为90度,当然也可选择其他角度。 [0066] Further, in the embodiment of the present invention, perpendicular to each other between a first portion 240 and second portion 230, the angle between them is preferably 90 degrees, of course, choose a different angle. 如图6a所示,该感应单元200通过多个第二部分240将多个第一部分230首尾相连,感应单元200的第一电极210和第二电极220分别与两端的第一部分230相连。 As shown in FIG 6a, the sensing unit 200, a plurality of second portions 240 of the first electrode a first plurality of end to end portions 230, 210 of the sensing unit 200 and the second electrode 220 are connected through the first portion 230 at both ends. 从整体结构上看,该感应单元200为具有较大长宽比的矩形。 The whole structure, the sensing unit 200 is a rectangle having a large aspect ratio. 该需要说明的是,虽然在图6a中将感应单元200沿X轴设置,但是本领域技术人员应该理解的是,该感应单元200也可沿Y轴设置。 It should be noted that, although FIG. 6a provided in the sensing unit 200 along the X axis, those skilled in the art will appreciate that the sensing unit 200 may be provided along the Y axis. 通过该感应单元的结构可以有效地减少噪声,提高感应的线性度。 Noise can be effectively reduced by the configuration of the sensing unit, improve the linearity of the sensor.

[0067] 如图7a所示,为本发明另一个实施例的感应单元结构图。 [0067] FIG. 7a, the sensing unit oriented configuration diagram of another embodiment of the invention. 在该实施例中,该感应单元200可为门形,且多个感应单元200中每个感应单元200的长度不同,多个感应单元200之间相互嵌套。 In this embodiment, the sensing unit 200 may be a gate-shaped, and the length of each of the various sensing units 200 of the plurality of sensing units 200, a plurality of sensing cells 200 nest with each other. 其中,每个所述感应单元包括第三部分250、不相交的第四部分260和第五部分270。 Wherein each of the sensing unit 250 comprises a third portion, fourth portion 260 does not intersect and the fifth portion 270. 优选地,第三部分250与基板100的第一边110平行,第四部分260和第五部分270与基板100的第二边120平行,且第四部分260 —端与第三部分250的一端相连, 第五部分270的一端与第三部分250的另一端相连。 Preferably, the third portion 250 of the substrate 110 parallel to the first side 100, second side 120 parallel to the fifth portion 260 and fourth portion 270 of the substrate 100, and a fourth portion 260. - One end of the third end portion 250 It is connected to one end of the fifth portion 270 is connected to the other end of the third portion 250. 感应单元200的第四部分260的另一端具有第一电极210,第五部分270的另一端具有第二电极220,其中,每个第一电极210和第二电极220均与触摸屏控制芯片的对应的管脚相连。 The other end of the sensing unit 260 of the fourth portion 200 having a first electrode 210, the other end of the fifth portion 270 having a second electrode 220, wherein each of the first electrode 210 and second electrode 220 corresponds to the touch panel control chip connected to pins.

[0068] 在本发明的实施例中,所谓相互嵌套是指外侧的感应单元部分地包围内侧的感应单元,例如如图7a所示,这样能够在保证精度的同时达到较大的覆盖率,并且降低运算的复杂度,提高触摸屏的响应速度。 [0068] In an embodiment of the present invention, the term nested refers to the outside part surrounding the sensing unit inside the sensing unit, for example, as shown, so that to achieve greater coverage at the same time ensure the accuracy 7a, and reduce the computational complexity, improve the response speed of the touch screen. 当然本领域技术人员还可根据图7a的思想采用其他相互嵌套的方式排列感应单元。 Of course, those skilled in the art may use other are arranged nested into each other according to the sensing unit of FIG. 7a thought. 在本发明的一个实施例中,每个感应单元200的第三部分250与其他感应单元200的第三部分250平行,每个感应单元200的第四部分260与其他感应单元200的第四部分260平行,每个感应单元200的第五部分270与其他感应单元200的第五部分270平行。 In one embodiment of the present invention, each of the third portion 200 of the sensing unit 250 250 in parallel with the other portion of the third sensor unit 200, and the other portion 260 to a fourth sensing unit 200 sensing units each of the fourth portion 200 260 in parallel, each of the fifth portion 200 of the sensing unit 270 and the other sensing unit 200 of the fifth portion 270 in parallel. 在本发明的一个实施例中,感应单元200的第三部分250、第四部分260和第五部分270中至少一个为矩形,优选地,第三部分250、第四部分260和第五部分270均为矩形。 In one embodiment of the present invention, 250, the fourth 260 and the fifth portion 270 third portion 200 of the sensing unit in at least one of a rectangular shape, preferably, the third portion 250 and fourth portion 260 and a fifth portion 270 They are rectangular. 在该实施例中,由于矩形结构图形规则,因此在手指横向或纵向移动时线性度好,此外,两个矩形结构之间的间距相同,便于计算,从而提高计算速度。 In this embodiment, since the pattern rule a rectangular structure, and therefore a good horizontal or vertical movement of the finger when the linearity, in addition, the distance between two identical rectangular configuration to facilitate the calculation, thereby increasing calculation speed.

[0069] 在本发明的一个实施例中,每个感应单元200的第四部分260与第五部分270长度相等。 [0069] In one embodiment of the present invention, each of the sensing unit is equal to the fourth part and the fifth part 200 260 270 length.

[0070] 在本发明的一个实施例中,基板100为矩形,第一边110和第二边120之间相互垂直,且第四部分260和第三部分250之间相互垂直,第五部分270和第三部分250之间相互垂直。 [0070] In one embodiment of the present invention, the substrate 100 is a rectangular, perpendicular to each other between a first side 110 and second side 120, and a fourth vertical portion 260 with each other and a third portion 250, fifth portion 270 and a third portion 250 between the mutually perpendicular.

[0071] 在本发明的一个实施例中,相邻两个感应单元200的第三部分250之间的间距相等,相邻两个感应单元200的第四部分260之间的间距相等,相邻两个感应单元200的第五部分270之间的间距相等。 [0071] In one embodiment of the present invention, 250 is equal to the spacing between two adjacent third portion 200 of the sensing unit 260 is equal to the spacing between two adjacent fourth portion 200 of sensing means adjacent equal to the spacing between the fifth portion 200 of the two sensing units 270. 这样就可以通过多个感应单元200对触摸屏的第一边110和第二边120均匀划分,从而提高运算速度。 This allows a plurality of side by the second sensing unit 200 to the touch screen 110 and the second side 120 evenly divided, thereby increasing processing speed. 当然在本发明的其他实施例中,相邻两个感应单元200的第三部分250之间的间距也可不相等,或者,相邻两个感应单元200的第四部分260之间的间距也可不相等,如图7b所示。 Of course, in other embodiments of the present invention, the distance between two adjacent sensing units 250 may not be equal to the third portion 200, or the spacing between adjacent fourth portion 260 of the two sensing units 200 may not be are equal, as shown in Figure 7b. 例如,由于用户往往触摸触摸屏的中心部位,因此可以将触摸屏中心部位的感应单元之间的间距减小,从而提高中心部位的检测精度。 For example, since the user often touches the center portion of the touch screen, so the pitch can be between the central portion of the touch screen sensing unit is reduced, thereby improving the detection accuracy of the center portion.

[0072] 在本发明的一个实施例中,多个感应单元200相对于基板100的中心轴Y对称,如图7a所示,中心轴Y垂直于第三部分250,从而更有利于提高精度。 [0072] In one embodiment of the present invention, the plurality of sensing units 200 symmetrically with respect to the central axis Y of the substrate 100, shown in Figure 7a, the central axis Y perpendicular to the third portion 250, which is more conducive to improve the accuracy. [0073] 如图7a所示,在该实施例中,感应单元200的第一电极210和第二电极220均位于基板100的第一边110上。 As shown in [0073] FIG. 7a, in this embodiment, the first electrode 200 of the sensing unit 210 and the second electrode 220 are located on the first side 110 of the substrate 100. 在该实施例中,检测到在感应单元上的触摸位置之后,即可获得在触摸屏之上的触摸位置。 In this embodiment, after detecting the touch position on the sensing unit, the touch position can be obtained on the touch screen.

[0074] 需要说明的是,上述图7a为本发明较优的实施例,其能够获得较大的覆盖率,但是本发明的其他实施例可对图7a进行一些等同的变化,例如第四部分260和第五部分270可以是不平行的。 [0074] Incidentally, the above-described embodiment of FIG. 7a superior embodiment of the present invention, it is possible to obtain a larger coverage, but other embodiments of the present invention may be equivalent to some variations of FIG. 7a, the fourth part e.g. 260 and fifth portion 270 may not be parallel.

[0075] 本发明实施例中的感应单元采用类似门形的结构,不仅结构简单,便于制作,所有引线都在同一边,设计方便,减少银浆成本并且制作容易,对减少生产成本有很大帮助。 [0075] The embodiments of the present invention the sensing unit similar gate-shaped configuration, not only simple structure, ease of fabrication, all of the terminals are on the same side, to facilitate the design, reduce cost and easy to manufacture silver paste, greatly reducing the cost of production help.

[0076] 如图8所示,为本发明实施例的感应单元被触摸时的示意图。 [0076] As shown in FIG 8, a schematic view of the touch sensing unit according to the embodiment of the invention is. 从图8可知,第一电极为210,第二电极为220,触摸位置接近于第二电极,假设感应单元的长度为10个单位长度,且将感应单元均匀地分为10份,其中,感应单元第三部分250的长度为4个单位长度,感应单元第四部分260和第五部分270的长度为3个单位长度。 Seen from FIG. 8, a first electrode 210, second electrode 220, the touch position close to the second electrode, the length is assumed that the sensing unit 10 per unit length, and the sensing unit 10 is uniformly divided into parts, wherein the sensor unit length of the third portion 250 is four units of length, the length of the fifth portion 260 and fourth portion 270 of the sensing unit 3 per unit length. 经过检测,获知第一电阻和第二电阻之比为4 : 1,即第一电极210至触摸位置的长度(由第一电阻体现)为全部感应单元长度的80%。 After testing, the known ratio of the first resistor and the second resistor has a 4: 1, i.e., the length of the first electrode 210 to a touch position (embodied by a first resistor) is 80% of the total length of the sensing unit. 换句话说,触摸点位于距离第一电极210处8个单位长度的位置,获知,触摸点位于距离第二电极220处2个单位长度的位置。 In other words, the touch point located at a distance of 2,108 units of length of the first electrode, known, position of the touch point is located at a distance of 2,202 units of length of the second electrode. 当手指移动时,触摸位置会相应移动,因此通过触摸位置的变换就可判断手指相应的移动轨迹,从而判断用户的输入指令。 When the finger is moved, the touch position moves accordingly, and therefore can determine the appropriate finger movement trajectory of the touch position by the conversion, to determine the user input instructions.

[0077] 从图8的以上例子可以看出,本发明的计算方式非常简单,因此能够极大地提高触摸屏检测的反应速度。 [0077] As can be seen from the above example of FIG. 8, calculated the present invention is very simple, it is possible to greatly improve the response speed of the touch screen detection. 在本发明的实施例中,通常手指或其他物体会触摸多个感应单元,此时可以先获得在这被触摸的多个感应单元中每个的触摸位置,然后通过求平均的方式计算最终在触摸屏上的触摸位置。 In an embodiment of the present invention, generally finger or other object will touch sensing units, the first case can be obtained in which a plurality of sensing units each of the touched position of the touch, and is calculated by means of averaging of the final touch position on the touch screen.

[0078] 如图9a所示,为本发明再一个实施例触摸屏检测设备结构图。 As shown in [0078] FIG. 9a, a further embodiment of a touch screen configuration diagram of detecting apparatus of the present embodiment of the invention. 在本发明的一个实施例中,多个感应单元的长度逐渐增加,且每个所述感应单元包括第六部分280和第七部分290。 In one embodiment of the present invention, the length of the plurality of sensing units is gradually increased, and each of the sensing unit 280 includes a sixth portion 290 and Part VII. 第六部分280的一端具有第一电极210,第七部分290的一端与第六部分280的另一端相连,且第七部分290的另一端具有第二电极220。 One end of the sixth portion 280 having a first electrode 210, a seventh portion 290 is connected to one end to the other end of the sixth portion 280, and the other end portion having a second electrode 290 VII 220.

[0079] 具体地,第六部分280与基板100的第一边110平行,第七部分290与基板100的第二边120平行,且第一边110和第二边120相邻。 [0079] Specifically, the sixth portion 280 is parallel to the first side 110 of the substrate 100, a second edge portion of the seventh 120 and 290 parallel to the substrate 100, and the first side 110 and second side 120 adjacent. 且每个第一电极210和第二电极220均与触摸屏控制芯片的对应管脚相连。 And each of the first electrode 210 and second electrode 220 are connected to pins corresponding to the touch screen control chip.

[0080] 在本发明的优选实施例中,每个感应单元200的第六部分280与其他感应单元200的第六部分280平行,每个感应单元200的第七部分290与其他感应单元200的第七部分290平行。 [0080] embodiment, each of the sixth portion 200 of the sensing unit 280 sensing unit 280 and the other parallel portion 200 of the sixth preferred embodiment of the present invention, each of the seventh portion 200 of the sensing unit 290 sensing unit 200 with the other part VII 290 parallel. 通过这样的设置能够有效地提高感应单元对触摸屏的覆盖率。 By such an arrangement can improve the coverage of the sensing unit of the touch screen. 在本发明的一个实施例中,感应单元200的第六部分280、第七部分290中至少一个为矩形,优选地,第六部分280、第七部分290均为矩形。 In one embodiment of the present invention, 280, 290 Part VII sixth portion 200 of the sensing unit in at least one of a rectangular shape, preferably, a sixth portion 280, a seventh portion 290 are rectangular. 在该实施例中,由于矩形结构图形规则,因此在手指横向或纵向移动时线性度好,此外,两个矩形结构之间的间距相同,便于计算。 In this embodiment, since the pattern rule a rectangular structure, and therefore a good horizontal or vertical movement of the finger when the linearity, in addition, the distance between two identical rectangular structure, easy to calculate.

[0081 ] 本发明实施例的触摸屏检测装置中的感应单元采用双端检测,即感应单元的两端均具有电极,且每个电极均与触摸屏控制芯片的对应管脚相连,在进行触摸检测时通过感应单元自身即可实现对触摸点的定位。 When the [0081] touch screen detection apparatus of the embodiment of the present invention uses the double end detection sensor unit, i.e., both ends of the sensing unit has the electrodes, and each electrode is connected with a corresponding pin of the touch screen control chip, the touch detection is performed itself can be realized through the touch point locating sensing unit.

[0082] 更为重要的是,本发明通过计算第一电阻和第二电阻之间比例实现触摸位置的确定,因此相对于目前的菱形或三角形设计来说,由于在确定触摸位置时,无需计算自电容的大小,且自电容的大小不会影响触摸位置的精度,对自电容检测精度的依赖降低,从而提高了测量精度,改善了线性度。 [0082] More importantly, the present invention is calculated by determining the ratio between the first and second resistors to achieve touch position, and therefore with respect to the current design of diamond or triangular, because when the touch position is determined, need not be calculated from the size of the capacitor, and from the magnitude of the capacitance does not affect the accuracy of the touch position, to reduce reliance on self-capacitance detection accuracy, thereby improving the measurement accuracy, improved linearity. 此外,由于本发明实施例的第五部分270、第六部分280和第七部分290中任意一个均可为形状规则的矩形,因此相对于目前的菱形或三角形等不规则的形状来说,也可以进一步地提高线性度。 Further, since the embodiment of the present invention, the fifth portion 270 cases, 280 and the seventh portion 290 may be any one sixth part of a regular rectangular shape, and therefore an irregular shape with respect to the current rhombus or a triangle, it is also linearity can be further improved.

[0083] 在本发明的一个实施例中,每个感应单元的第六部分280与第七部分290长度相等,从而能够提高运算速度。 [0083] In one embodiment of the present invention, each of the sixth portion 280 is equal to 290 and the seventh part of the length of the sensing unit, the operation speed can be improved. 优选地,基板100为矩形,第一边110和第二边120之间相互垂直。 Preferably, the substrate 100 is a rectangular, perpendicular to each other between a first side 110 and second side 120. 第一边110和第二边120相互垂直,不仅使得感应单元设计更加规则,例如使得感应单元的第六部分280和第七部分290之间也相互垂直,从而提高对触摸屏的覆盖率,而且第六部分280和第七部分290之间相互垂直也可以提高检测的线性度。 First side 110 and second side 120 perpendicular to each other, so that not only the sensing unit is more design rules, for example, be perpendicular to each other such that between the sixth portion 280 of the sensing unit 290 and the seventh part, thereby improving the coverage of the touch screen, and the first between the seventh portion 280 and six parts 290 may be perpendicular to each other to improve the linearity of detection.

[0084] 在本发明的一个实施例中,相邻两个感应单元200之间的间距相等。 [0084] In one embodiment of the present invention, it is equal between two adjacent sensing unit 200 pitch. 这样就可以通过多个感应单元200对触摸屏的第一边110和第二边120均匀划分,从而提高运算速度。 This allows a plurality of side by the second sensing unit 200 to the touch screen 110 and the second side 120 evenly divided, thereby increasing processing speed.

[0085] 当然在本发明的另一个实施例中,相邻两个感应单元200之间的间距也可以不等,如图9b所示,例如由于用户往往触摸触摸屏的中心部位,因此可以将触摸屏中心部位的感应单元之间的间距减小,从而提高中心部位的检测精度。 [0085] Of course, in another embodiment of the present invention, between two adjacent sensing unit 200 may be unequal spacing, as shown in FIG. 9b, for example because the user often touches the center portion of the touch screen, the touch screen can be the spacing between the central portion of the sensing unit is reduced, thereby improving the detection accuracy of the center portion.

[0086] 如图9a所示,在该实施例中,感应单元200的第一电极210位于基板100的第一边110上,第二电极220位于基板100的第二边120上,且第一边110和第二边120相互垂直。 As shown in [0086] FIG. 9a, in this embodiment, the first electrode 210 of the sensing unit 200 positioned on the first side 110 of the substrate 100, a second electrode 220 disposed on the second side 120 of the substrate 100, and the first a second side edge 110 and 120 perpendicular to each other. 在该实施例中,检测到在感应单元上的触摸位置之后,即可获得在触摸屏之上的触摸位置。 In this embodiment, after detecting the touch position on the sensing unit, the touch position can be obtained on the touch screen.

[0087] 如图10所示,为本发明实施例的感应单元被触摸时的示意图。 [0087] As shown in FIG. 10, a schematic view of the touch sensing unit according to the embodiment of the invention is. 从图10可知,第一电极为210,第二电极为220,触摸位置接近于第二电极220,假设感应单元的长度为10个单位长度,且将感应单元均匀地分为10份,其中,感应单元的第六部分280的长度为5个单位长度,感应单元的第七部分290的长度为5个单位长度。 Seen from FIG. 10, a first electrode 210, second electrode 220, the touch position close to the second electrode 220, assuming the length of the sensing unit 10 per unit length, and the sensing unit 10 is uniformly divided into parts, wherein the length of the sixth portion 280 of the sensing unit 5 is a unit length, the length of the sensing unit 290 is part of a seventh length of 5 units. 经过检测,获知第一电阻和第二电阻之比为9 : 1,即第一电极210至触摸位置的长度(由第一电阻体现)为全部感应单元长度的90%。 After testing, the known ratio of the first and second resistors of 9: 1, i.e., the length of the first electrode 210 to a touch position (embodied by a first resistor) is 90% of the total length of the sensing unit. 换句话说,触摸点位于距离第一电极210处9个单位长度的位置,获知,触摸点位于距离第二电极220处I个单位长度的位置。 In other words, the touch point located at a distance of 2,109 units of length of the first electrode, known, position of the touch point is located at a distance of 220 I unit length of the second electrode.

[0088] 从图10的以上例子可以看出,本发明的计算方式非常简单,因此能够极大地提高触摸屏检测的反应速度。 [0088] As can be seen from the above example of FIG. 10, calculated according to the present invention is very simple, it is possible to greatly improve the response speed of the touch screen detection.

[0089] 在本发明的一个实施例中,多个感应单元200位于同一层,因此只需要一层ITO即可,从而在保证精度的同时,极大地降低制造成本。 [0089] In one embodiment of the present invention, the plurality of sensing units 200 at the same level, it is only necessary to ITO layer, thus ensuring the accuracy, while greatly reducing the manufacturing cost.

[0090] 本发明实施例的触摸屏检测装置中的感应单元采用双端检测,即感应单元的两端均具有电极,且每个电极均与触摸屏控制芯片的对应管脚相连,在进行触摸检测时通过感应单元自身即可实现对触摸点的定位。 When the [0090] touch screen detection apparatus of the embodiment of the present invention uses the double end detection sensor unit, i.e., both ends of the sensing unit has the electrodes, and each electrode is connected with a corresponding pin of the touch screen control chip, the touch detection is performed itself can be realized through the touch point locating sensing unit.

[0091] 更为重要的是,本发明通过计算第一电阻和第二电阻之间比例实现触摸位置的确定,因此相对于目前的菱形或三角形设计来说,由于在确定触摸位置时,无需计算自电容的大小,且自电容的大小不会影响触摸位置的精度,对自电容检测精度的依赖降低,从而提高了测量精度,改善了线性度。 [0091] More importantly, the present invention is calculated by determining the ratio between the first and second resistors to achieve touch position, and therefore with respect to the current design of diamond or triangular, because when the touch position is determined, need not be calculated from the size of the capacitor, and from the magnitude of the capacitance does not affect the accuracy of the touch position, to reduce reliance on self-capacitance detection accuracy, thereby improving the measurement accuracy, improved linearity. 此外,由于本发明实施例的第五部分270、第六部分280和第七部分290中任意一个均可为形状规则的矩形,因此相对于目前的菱形或三角形等不规则的形状来说,也可以进一步地提高线性度。 Further, since the embodiment of the present invention, the fifth portion 270 cases, 280 and the seventh portion 290 may be any one sixth part of a regular rectangular shape, and therefore an irregular shape with respect to the current rhombus or a triangle, it is also linearity can be further improved.

[0092] 综上所述,本发明实施例通过对感应单元两端的电极施加电平信号,如果该感应单元被触碰,则会该感应单元会形成自电容,因此本发明通过施加的电平信号可对该自电容进行充电,并根据第一电阻和第二电阻之间的比例关系确定在第一方向上的触摸位置。 [0092] In summary, embodiments of the present invention by applying a level signal induced across the electrodes of the unit, if the sensing unit is touched, the sensing unit will be formed from the capacitance, thus the present invention is applied by the level signal from the capacitor can be charged, and determining a touch position in the first direction based on the proportional relationship between the first and second resistors. 例如在本发明的一个实施例中,第一电阻和第二电阻之间的比例关系根据在对所述自电容充电/放电时,从所述第一电极和/或第二电极进行检测获得的第一检测值和第二检测值之间的比例关系计算得到。 In one example embodiment of the present invention, the ratio between the first and second resistors in accordance with the self-capacitance when charging / discharging, is detected from the first electrode and / or the second electrode obtained a first proportional relationship between the detected value and the second detection value is calculated. 因此从第一电极和/或第二电极检测该自电容充电/放电时产生的第一检测值和第二检测值。 Thus from the first electrode and / or self-generated when the capacitor charging / discharging of the second electrode and the first detection value of the second detection value. 这样,通过第一检测值和第二检测值就能够反应触摸点位于该感应单元的位置,从而进一步确定触摸点在触摸屏的位置。 Thus, by detecting a first value and the second value can be detected at a position of the touch point reaction sensing unit, thereby further determining a position of a touch point in the touch screen.

[0093] 对于图5和图6的感应单元来说,在确定了第一方向上的触摸位置之后,还需要进一步根据被触摸的感应单元的位置确定在第二方向上的触摸位置。 [0093] For the sensing unit of FIG. 5 and FIG. 6 is, after determining the touch position in the first direction, still needed to determine the touch position in the second direction according to the position of the touch sensing unit. 在本发明的实施例中,可参照图5和6所示,如果检测到某个感应单元的第一检测值或第二检测值大于预设阈值,则说明该感应单元被触摸。 In an embodiment of the present invention, reference may be shown in FIG. 5 and 6, if the detected value of a sensing unit detecting a first or second detection value is greater than the predetermined threshold value, then the sensing unit is touched. 假设第二个感应单元(其纵坐标为M)被触摸,则在第二方向上的触摸位置就为第二个感应单元的坐标M。 If the second sensing unit (which is the ordinate M) is touched, the touch position in the second direction on the second coordinate sensing unit M. 之后,再根据第一方向上的触摸位置和第二方向上的触摸位置确定触摸点在触摸屏上的位置。 After again determining the position of the touch on the touch screen according to the touch position on the touch position on the first and second directions.

[0094] 具体地,可采用质心算法计算触摸点在第二方向上的触摸位置,以下对质心算法进行简单介绍。 [0094] Specifically, the centroid algorithm employed touched touch position in the second direction, the centroid algorithm will be briefly described. · ·

[0095] 在滑条和触摸板应用中,经常有必要在具体感应单元的本质间距以上确定出手指(或其他电容性物体)的位置。 [0095] In the slider and a touch panel applications it is often necessary to determine the position of the finger (or other capacitive object) in the nature of a pitch than the specific sensing unit. 手指在滑条或触摸板上的接触面板通常大于任何个感应单元。 Finger on the touch panel or a touchpad slider is often larger than any induction units. 为了采用一个中心来计算触摸后的位置,对这个阵列进行扫描以验证所给定的传感器位置是有效的,对于一定数量的相邻感应单元信号的要求是要大于预设触摸阈值。 In order to calculate using a center position of a touch on the array is scanned to verify that a given sensor location is effective, the requirements for the adjacent signal sensing unit is greater than a number of preset touch threshold. 在找到最为强烈的信号后,此信号和那些大于触摸阈值的临近信号均用于计算中心: After finding the strongest signal, this signal and those near the touch signal is greater than the threshold value are used to calculate the center:

[0096] Nr t = Wl(/~1)+Wl"+Wl+l(/+1) [0096] Nr t = Wl (/ ~ 1) + Wl "+ Wl + l (/ + 1)

Cent ni-\+ni+ni+\ Cent ni - \ + ni + ni + \

[0097] 其中,Ncent为中心处感应单元的标号,n为检测到被触摸的感应单元的个数,i为被触摸感应单元的序号,其中i大于等于2。 [0097] wherein, Ncent designated sensing unit at the center, n is the number of the detected touch sensing unit, i is the number of the touch sensing unit, where i is greater than or equal to 2.

[0098] 例如,当手指触摸在第一条通道,其电容变化量为yl,第二条通道上的电容变化量为y2和第三条通道上的电容变化量为y3时。 [0098] For example, when the finger touches the first channel, the capacitance variation is YL, the amount of change in capacitance on the second channel is a capacitance variation in the third channel is y2 and y3 time. 其中第二通道y2电容变化量最大。 Wherein the second channel y2 maximum capacitance variation. Y坐标就可以算是: Y coordinates can be:

vl * I + v2 * 2 + v3 * 3 vl * I + v2 * 2 + v3 * 3

[0099] Y= Z——7^—~^——o [0099] Y = Z - 7 ^ - ~ ^ - o

y\ + y2 + y3 y \ + y2 + y3

[0100] 如图11所示,为本发明一个实施例的触控装置示意图。 [0100] 11, a diagram of a touch device according to the present embodiment of the invention. 该触控装置包括由基板100和多个不相交的感应单元200所构成的触摸屏检测装置、触摸屏控制芯片300。 The touch device comprises a touch screen substrate 100 and the detecting means a plurality of disjoint sensing unit 200 is constituted, touch screen control chip 300. 其中,触摸屏控制芯片300中的一部分管脚与多个感应单元200的第一电极210相连,触摸屏控制芯片300中的另一部分管脚与多个感应单元200的第二电极220相连,且触摸屏控制芯片300向多个感应单元200的第一电极210和/或第二电极220施加电平信号,该电平信号在感应单元200被触摸时向感应单元200产生的自电容充电。 Wherein the first electrode of the touch screen control chip 300 and a portion of the plurality of pins 210 coupled to the sensing unit 200, the second electrode is connected to another portion of the touch screen controller chip pins 300 and 200 of the plurality of sensing units 220, and the touch screen control chip 300 to the plurality of sensing units 210 of the first electrode 200 and / or the second electrode 220 is applied to the signal level, the level of the signal charge from the capacitance sensing unit 200 is touched to generate the sensing unit 200.

[0101] 如图12所示,为本发明实施例触摸屏控制芯片的结构图。 [0101] FIG. 12 is a schematic structural view of a touch screen control chip embodiment of the invention. 触摸屏控制芯片300包括充电模块310、放电模块320、检测模块330和控制及计算模块340。 Touch screen control chip 300 includes a charging module 310, a discharge module 320, a detection module 330 and a calculation and control module 340. 充电模块310在第一次充电过程中,向多个感应单元中的一个感应单元200的第一电极210和第二电极220中的一个施加高电平信号,并将第一电极210和第二电极220中的另一个接地,以在一个感应单元200被触摸时对一个感应单元200产生的自电容进行第一次充电;在第二次充电过程中,向多个感应单元中的一个感应单元200的第一电极210和第二电极220施加高电平信号,或者,向第一电极210和第二电极220中的一个施加高电平信号并将第一电极210和第二电极220中的另一个断开,以对自电容进行第二次充电。 In the first charging process, the second electrodes 210 and 220 in a charging module 310 is applied to the plurality of sensing units in a sensing unit of the first electrode 200 a high level signal, and the first electrode 210 and the second another ground electrode 220, when a self-capacitance sensing unit 200 is a touch sensing unit 200 for performing a first charge generated; in the second charging process, to the plurality of sensing units in a sensing unit 220 is applied to the first electrode 210 and second electrode 200 of the high level signal or a high level signal 220 is applied to the first electrode and the second electrode 210 and the electrodes 220 to 210 and the second electrode in a first another disconnect, self-capacitance to the second charge. 放电模块320用于在充电模块310对自电容第二次充电之后,将一个感应单元200的第一电极210和第二电极220接地,或者,将第一电极210和第二电极220中的一个接地并将第一电极210和所述第二电极220中的另一个断开以对自电容进行第一次放电。 Discharge module 320 is used at 310 after the self-capacitance of the second charge, the first electrode 200, a sensing unit 210 and the second electrode 220 is grounded, or the first electrode 210 and second electrode 220 is a charging module and the other is grounded and the second electrode 220 is disconnected from the discharge to a first electrode of the capacitor 210. 检测模块330用于在每次充放电时,从对应的第一电极210或第二电极220进行检测以获得第一次充电和第二次充电之间的第一检测变化值,及从对应的第一电极210或第二电极进行检测以获得第二次充电和第一次放电之间的第二检测变化值。 Detection module 330 for each time charging and discharging, from the corresponding first electrode 210 or second electrode 220 to obtain a first detected value detected change in charge between the first and second charge, and from the corresponding the first electrode 210 or the second electrode to obtain a second detected value detected change in charge between the second and the first discharge. 控制及计算模块340用于对充电模块310、放电模块320、第一检测模块330和第二检测模块340进行控制,并根据第一检测变化值和第二检测变化值计算自电容至第一电极之间的第一电阻和自电容至所述第二电极之间的第二电阻的比例关系,并根据第一电阻和第二电阻的比例关系确定触摸位置。 And a control module 340 for calculating the charging module 310, the discharge module 320, a first detecting module 330 and the second detecting module 340 controls and calculated from the first capacitor to the first electrode according to the change in the detection value and the second change value detection and a first resistance between the proportional relation from the capacitor to the second resistor between the second electrode and the touch position is determined by the ratio of the first and second resistors. 在本发明的实施例中,控制及计算模块340可以以扫描的方式控制充电模块310依次向多个感应单元施加相应的电压,同时在检测时也可以以扫描的方式依次进行检测,或者,也可以扫描的方式控制放电模块320依次对多个感应单元中被触摸的感应单元所产生的自电容进行放电。 In an embodiment of the present invention, the control and calculation module 340 may scan module 310 controls the charging voltage is sequentially applied to a plurality of respective sensing means, but may also be performed sequentially in a scanning manner while detecting the detection. Alternatively, can scan module 320 is controlled sequentially discharged from the plurality of capacitive touch sensing unit sensing unit are generated by discharge.

[0102] 在本发明的上述实施例中,虽然以第一次充电、第二次充电和第一次放电为例进行描述,但是本发明中只要有三个不同的状态即可,通过测量任意两个不同状态之间的状态差(即检测变化值)就可获得Rl和R2之间的比例关系。 [0102] In the above embodiment of the present invention, although the first charge, a second charge and first discharge described as an example, but the present invention as long as there can be three different states, by measuring any two state difference between the different states (i.e. detecting a change in value) can be obtained proportional relationship between Rl and R2. 在该实施例中,三个不同的状态为第一次充电后的状态,第二次充电后的状态和放电后的状态。 In this embodiment, three different states of the first state of charge, charge state and the second state after discharge.

[0103] 在本发明的一个实施例中,第一检测变化值、第二检测变化值可为电流检测变化值、自电容检测变化值、电平信号检测变化值和电荷变化量中的一种或多种。 [0103] In one embodiment of the present invention, a first detection value changes, the change value may vary the second detection current value detecting a change in capacitance detection value from the electrical signal and detecting a change in value of the level variation amount of charge or more.

[0104] 在本发明的一个实施例中,检测模块330为CTS (电容检测模块)。 [0104] In one embodiment of the present invention, the detection module 330 is CTS (capacitance detection module).

[0105] 在本发明的一个实施例中,控制及计算模块340还用于根据被触摸的感应单元200的位置确定在第二方向上的触摸位置,并根据第一方向上的触摸位置和第二方向上的触摸位置确定所述触摸点在触摸屏上的位置。 [0105] In one embodiment of the present invention, the control module 340 is further configured to calculate and determine a touch location in the second direction according to the position of the sensing unit 200 is touched and the touch position in the first direction and the touch position on the second direction is determined position on the touch screen of the touch. 具体地,控制及计算模块340通过质心算法确定所述第二方向上的触摸位置。 Specifically, the control module 340 calculates and determines the touch position on the second direction by a centroid algorithm.

[0106] 在本发明的一个实施例中,第一方向为感应单元200的长度方向,第二方向为垂直于感应单元200长度方向的方向,感应单元水平平行设置或垂直平行设置。 [0106] In one embodiment of the present invention, the first direction is a longitudinal direction of the induction unit 200, the second direction is a direction perpendicular to the longitudinal direction of the sensing unit 200, the sensing unit disposed in parallel horizontal or vertical parallel.

[0107] 在本发明的一个优选实施例中,多个不相交的感应单元位于同一层,从而在保证检测精度的前提下,有效地降低制造成本。 [0107] In a preferred embodiment of the present invention, a plurality of disjoint sensing unit in the same layer, thereby ensuring the detection accuracy of the premise, effectively reduces the manufacturing cost.

[0108] 本发明还提出了一种便携式电子设备,包括如上所述的触控装置。 [0108] The present invention also provides a portable electronic device comprising a touch device as described above.

[0109] 本发明实施例通过对感应单元两端的电极施加电平信号,如果该感应单元被触碰,则会该感应单元会形成自电容,因此本发明通过施加的电平信号可对该自电容进行充电,并根据第一电阻和第二电阻之间的比例关系确定触摸屏上的触摸位置。 [0109] Example embodiments of the present invention by applying a level of a signal induced across the electrodes of the unit, if the sensing unit is touched, the sensing unit will be formed from the capacitance, thus the present invention may be applied to the signal level from the charge the capacitor, and determine the touch location on the touch screen in accordance with a proportional relationship between the first and second resistors. 且通过本发明实施例的对自电容进行两次充电的检测方式,以抵消某些不可测量的物理参数或者减少物理量的测量,从而在保证检测速度的前提下,有效地提高检测精度。 And the self-capacitance of the embodiments of the invention by way of detecting the charging twice to counteract certain non-physical parameter measured or decrease the measurement of physical quantities, thereby ensuring detection speed premise effectively improve the detection accuracy.

[0110] 本发明实施例提出了一种新颖的自电容检测方式,在感应单元被触摸时,触摸点就可将该感应单元分为两个电阻,从而在进行自电容检测的同时考虑这两个电阻就可以确定触摸点在该感应单元上的位置。 [0110] Example A novel self-capacitance detection method of the present invention, when the sensing unit is touched, the touch point sensing unit can be divided into two resistors, thereby making the self-capacitance detected considering both resistors can determine the position of the sensing unit on the touch point. 本发明实施例的结构简单,并且对于一个感应单元来说,可从其的第一电极和/或第二电极进行充电或放电,并在充电或放电时进行检测,不仅能够降低RC常数,节省时间提高效率,并且还能够保证坐标不会偏移。 Simple structure of the embodiment of the present invention, and for a sensing unit, the first electrode and / or the second electrode may be charged or discharged therefrom, and detected during charging or discharging, not only reduces the RC constant, save time and improve efficiency, and also to ensure that coordinates do not. 此外,本发明实施例还可以有效提高电路的性噪比,降低电路噪声,提高感应线性度。 Further, embodiments of the present invention can further improve the signal to noise ratio of the circuit, the noise reduction circuit, enhance the response linearity. 另外,在检测过程中由于对被触摸的感应单元进行充电,因此其中会产生小电流,能够很好地消除Vcom电平信号对触摸屏中感应单元产生的自电容的影响,因此可以相应地消除屏幕屏蔽层及相关工序,从而可以在增强了抗干扰能力的同时进一步降低成本。 Further, in the detection process due to the touch sensing unit is charged, and therefore which produces a small current, perfectly eliminate self-capacitance impact Vcom level signal touchscreen induced generation unit, it is possible to correspondingly eliminate screen shield and related processes, the cost can be further reduced while the interferences.

[0111] 在本说明书的描述中,参考术语“一个实施例”、“一些实施例”、“示例”、“具体示例”、或“一些示例”等的描述意指结合该实施例或示例描述的具体特征、结构、材料或者特点包含于本发明的至少一个实施例或示例中。 [0111] In the description of the present specification, reference to the term "one embodiment," "some embodiments", "an example", "a specific example", or "some examples" means that a description of the exemplary embodiment or embodiments described a particular feature, structure, material, or characteristic is included in at least one embodiment of the present invention, embodiments or examples. 在本说明书中,对上述术语的示意性表述不一定指的是相同的实施例或示例。 In the present specification, a schematic representation of the above terms necessarily referring to the same embodiment or example. 而且,描述的具体特征、结构、材料或者特点可以在任何的一个或多个实施例或示例中以合适的方式结合。 Furthermore, the particular features, structures, materials, or characteristics described embodiments or examples may be at any one or more in a proper manner.

[0112] 尽管已经示出和描述了本发明的实施例,对于本领域的普通技术人员而言,可以理解在不脱离本发明的原理和精神的情况下可以对这些实施例进行多种变化、修改、替换和变型,本发明的范围由所附权利要求及其等同限定。 [0112] While there has been illustrated and described embodiments of the present invention, those of ordinary skill in the art, to be understood that various changes may be made to these embodiments without departing from the principles and spirit of the present invention, modifications, substitutions and modifications, the scope of the invention being indicated by the appended claims and their equivalents.

Claims (21)

1. 一种触摸屏的触摸检测方法,其特征在于,所述触摸屏包括多个不相交的感应单元,每个感应单元的两端分别具有第一电极和第二电极,所述方法包括以下步骤: 向所述多个感应单元中一个感应单元的第一电极和第二电极中的一个施加高电平信号,并将所述第一电极和第二电极中的另一个接地,以在所述一个感应单元被触摸时对所述一个感应单元产生的自电容进行第一次充电; 向所述多个感应单元中的一个感应单元的第一电极和第二电极施加高电平信号,或者,向所述第一电极和所述第二电极中的一个施加高电平信号并将所述第一电极和所述第二电极中的另一个断开,以对所述自电容进行第二次充电; 从对应的所述第一电极或第二电极进行检测以获得所述第一次充电和所述第二次充电之间的第一检测变化值; 将所述一个感应单元的第一电极和 A touch detecting method for a touch panel, wherein the touch screen comprises a plurality of disjoint sensing units, each sensing unit ends respectively having first and second electrodes, said method comprising the steps of: a high level signal is applied to the first electrode of the plurality of sensing units in a sensing unit and a second electrode, and the other of said first ground electrode and the second electrode to the one capacitance of the sensing unit from a sensing unit is touched generated by the first charge; high-level signal is applied to one of said plurality of sensing means sensing a first electrode and a second electrode unit, or to the the first electrode and the other a high-level signal is applied to the first electrode and the second electrode and the second electrode is disconnected to perform a second charge from the capacitor ; detected from the corresponding first or second electrode to obtain a first detected value changes between the first charge and the second charge; a first electrode of the sensing unit and 第二电极接地,或者,将所述第一电极和所述第二电极中的一个接地并将所述第一电极和所述第二电极中的另一个断开,以对所述自电容进行第一次放电; 从对应的所述第一电极或第二电极进行检测以获得所述第二次充电和所述第一次放电之间的第二检测变化值; 根据所述第一检测变化值和第二检测变化值计算所述自电容至所述第一电极之间的第一电阻和所述自电容至所述第二电极之间的第二电阻的比例关系;以及根据所述第一电阻和所述第二电阻之间的比例关系确定触摸位置。 The second electrode is grounded, or another one of said first ground electrode and the second electrode and the first electrode and the second electrode is disconnected, for the self-capacitance first discharge; detecting from the corresponding first or second electrode to obtain a second detection of the second change value between the first charge and discharge; detecting a change based on the first detecting a change in value and the second value is calculated from the capacitor to a first electrical resistance between the first electrode from the capacitor to the second resistor between the second electrode and the relationship between the ratio; and based on the first a proportional relationship between the resistor and the second resistor to determine the touch location.
2.如权利要求I所述的触摸屏的触摸检测方法,其特征在于,所述第一检测变化值和第二检测变化值为电流检测变化值、自电容检测变化值、电平信号检测变化值和电荷变化量中的一种或多种。 2. The touch detection method of the touch panel I as claimed in claim, characterized in that the first detection value and the second variation detecting a change in the current value detecting a change in value, detecting a change from the capacitance value of the level signal detected variation value and charge variation amount of one or more.
3.如权利要求I所述的触摸屏的触摸检测方法,其特征在于,所述感应单元为矩形,且所述多个感应单元与所述触摸屏的第一方向相互平行,所述触摸位置为触摸物体在所述第一方向上的触摸位置。 The touch detection method of the touch panel I as claimed in claim, wherein the sensing means is rectangular, and the plurality of sensing units with a first direction parallel to each of the touch screen, a touch position of the touch a touch position of the object in the first direction.
4.如权利要求I所述的触摸屏的触摸检测方法,其特征在于,所述感应单元包括: 多个第一部分和多个平行的第二部分,其中,相邻的所述第一部分之间通过所述第二部分相连,以形成多个交替排列的第一凹槽和第二凹槽,其中,所述多个第一凹槽和所述多个第二凹槽的开口方向相反。 The touch detection method of the touch panel I as claimed in claim, wherein the sensing unit comprises: a first portion and a second portion of the plurality of plurality of parallel, wherein between the first portion through the adjacent said second portion connected to the first and second grooves form a plurality of alternately arranged, wherein the plurality of openings opposite direction of the first groove and the second plurality of grooves.
5.如权利要求3或4所述的触摸屏的触摸检测方法,其特征在于,还包括: 根据所述被触摸的感应单元的位置确定在第二方向上的触摸位置;以及根据所述第一方向上的触摸位置和第二方向上的触摸位置确定所述触摸点在触摸屏上的位置。 The touch detecting method of claim 3 or 4, the touch screen according to claim, characterized in that, further comprising: determining a touch position in the second direction according to a touched position of said sensing unit; and based on the first touch position on the touch position on the direction and a second direction to determine the position of points on a touch screen of the touch.
6.如权利要求5所述的触摸屏的触摸检测方法,其特征在于,所述第二方向上的触摸位置通过质心算法确定。 The method of detecting a touch of the touch screen as claimed in claim 5, characterized in that the touch position on the direction determined by the second centroid algorithm.
7.如权利要求3-6任一项所述的触摸检测方法,其特征在于,所述第一方向为所述感应单元的长度方向,所述第二方向为垂直于所述感应单元的方向,所述感应单元水平平行设置或垂直平行设置。 The touch detection method as claimed in any one of claims 3-6 in the direction of the induction means, characterized in that said first direction is a longitudinal direction of the sensing unit, the second direction is perpendicular to the , the sensing unit disposed parallel to the horizontal or vertical parallel.
8.如权利要求I所述的触摸屏的触摸检测方法,其特征在于,所述感应单元包括: 第三部分,所述第三部分的一端具有所述第一电极;第四部分,所述第四部分的一端与所述第三部分的另一端相连,所述第四部分的另一端具有所述第二电极。 8. The touch detecting method of the touch panel I as claimed in claim, wherein the sensing unit comprises: a third portion, said third portion having an end of said first electrode; a fourth portion, said first four end to the other end portion of the third portion, the other end of the fourth portion having the second electrode.
9.如权利要求I所述的触摸屏的触摸检测方法,其特征在于,所述感应单元包括: 第五部分; 不相交的第六部分和第七部分,所述第六部分一端与所述第五部分的一端相连,所述第七部分的一端与所述第五部分的另一端相连,所述第六部分的另一端具有所述第一电极,且所述第七部分的另一端具有所述第二电极。 I as claimed in claim 9. The touch detection method for a touch panel, wherein the sensing unit comprises: a fifth portion; part VI and VII disjoint, and the first end portion of the sixth One end of the five-part connected to the one end portion to the other end of the fifth portion is connected to the seventh, sixth and the other end portion having the first electrode, and the other end portion of the seventh having said second electrode.
10. 一种触控装置,其特征在于,包括: 基板; 多个不相交的感应单元,所述多个感应单元形成在所述基板之上,且每个感应单元的两端分别具有第一电极和第二电极; 触摸屏控制芯片,所述触摸屏控制芯片包括充电模块、放电模块、检测模块和控制及计算模块,其中, 所述充电模块,用于在第一次充电过程中,向所述多个感应单元中一个感应单元的第一电极和第二电极中的一个施加高电平信号,并将所述第一电极和第二电极中的另一个接地,以在所述一个感应单元被触摸时对所述一个感应单元产生的自电容进行第一次充电;在第二次充电过程中,向所述多个感应单元中的一个感应单元的第一电极和第二电极施加高电平信号,或者,向所述第一电极和第二电极中的一个施加高电平信号并将所述第一电极和第二电极中的另一个断开,以对所述自电 A touch device, comprising: a substrate; a plurality of disjoint sensing unit, a plurality of sensing cells formed on said substrate, and both ends of each having a first sensing unit, respectively and a second electrode; touch screen control chip, the touch screen control module includes a charging chip, discharge module, a detection module and a control and calculation module, wherein said charging means for charging the first, to the a high level signal is applied to the first and second electrodes, a plurality of sensing cells in the sensing unit and the first ground electrode and the other second electrode, a sensing unit to be in the since the capacitance of a sensing unit generated by first charging the touch; in the second charging process, a high level is applied to one of said plurality of sensing means sensing a first electrode and a second electrode unit signal, or a high level signal is applied to the other and disconnect the first electrode and the second electrode to the first electrode and a second electrode to electrically from the 进行第二次充电, 所述放电模块,用于在所述充电模块对所述自电容第二次充电之后将所述一个感应单元的第一电极和第二电极接地,或者,将所述第一电极和所述第二电极中的一个接地并将所述第一电极和所述第二电极中的另一个断开以对所述自电容进行第一次放电, 所述检测模块,用于从对应的所述第一电极或第二电极进行检测以获得所述第一次充电和所述第二次充电之间的第一检测变化值,及从对应的所述第一电极或第二电极进行检测以获得所述第二次充电和所述第一次放电之间的第二检测变化值;和控制及计算模块,用于对所述充电模块、放电模块、第一检测模块和第二检测模块进行控制,并根据第一检测变化值和第二检测变化值计算所述自电容至所述第一电极之间的第一电阻和所述自电容至所述第二电极之间的第二电阻之间的比例关 A second charge, a discharge module, a charging module for the first capacitor is charged since the second electrode of the first sensing unit and a second ground electrode, or, in a ground electrode and the second electrode of the other of said first electrode a second electrode and to the on and off for the first time the self-discharge capacitor, the detection module, for detecting from said corresponding first or second electrode to obtain a first detected value changes between the first charge and the second charge, and from the corresponding first or second electrode detecting said electrodes to obtain a second detected second change value between the first charge and discharge; and a control and calculation means for the charging module, a discharge module, and a first detecting module two detection control module, and calculating the first resistance to the self-capacitance between the first electrode and the self-capacitance between the second electrode to detect changes in value according to a first and a second change in the detection value a second proportional relationship between the resistance ,并根据所述第一电阻和所述第二电阻之间的比例关系确定触摸位置。 And determining a touch location based on the proportional relationship between the first resistor and the second resistor.
11.如权利要求10所述的触控装置,其特征在于,所述第一检测变化值和第二检测变化值为电流检测变化值、自电容检测变化值、电平信号检测变化值和电荷变化量中的一种或多种。 11. The touch device according to claim 10, characterized in that the first detection value and the second variation detecting a change in the current value detecting a change in value, detecting a change from the capacitance value, detecting a change in the level signal and the charge value one or more of the amount of change.
12.如权利要求11所述的触控装置,其特征在于,所述检测模块为电容检测模块CTS。 12. The touch device according to claim 11, wherein the detection module is a module capacitance detection CTS.
13.如权利要求10所述的触控装置,其特征在于,所述感应单元为矩形,且所述多个感应单元与所述触摸屏的第一方向相互平行,所述触摸位置为在所述第一方向上的触摸位置。 13. The touch device according to claim 10, wherein the sensing means is rectangular, and the plurality of sensing units with a first direction parallel to each of the touch screen, the touch location is in the a touch position in the first direction.
14.如权利要求10所述的触控装置,其特征在于,所述感应单元包括: 多个第一部分和多个平行的第二部分,其中,相邻的所述第一部分之间通过所述第二部分相连,以形成多个交替排列的第一凹槽和第二凹槽,其中,所述多个第一凹槽和所述多个第二凹槽的开口方向相反。 14. The touch device according to claim 10, wherein the sensing unit comprises: a first portion and a second portion of the plurality of plurality of parallel, wherein between said adjacent ones of the first portion by a second portion connected to the first and second grooves form a plurality of alternately arranged, wherein the plurality of openings opposite direction of the first groove and the second plurality of grooves.
15.如权利要求13或14所述的触控装置,其特征在于, 所述控制及计算模块,还用于根据所述被触摸的感应单元的位置确定在第二方向上的触摸位置,并根据所述第一方向上的触摸位置和第二方向上的触摸位置确定所述触摸点在触摸屏上的位置。 15. The touch device of claim 13 or claim 14, wherein said calculation and control module is further for determining a touch position in the second direction according to the touched position sensing means, and determining a point position on the touch screen according to the touch position of the touch on the touch position on the first and second directions.
16.如权利要求15所述的触控装置,其特征在于,所述控制及计算模块通过质心算法确定所述第二方向上的触摸位置。 16. The touch device according to claim 15, characterized in that the control and calculation module centroid algorithm to determine the touch position on the second direction.
17.如权利要求15所述的触控装置,其特征在于,所述第一方向为所述感应单元的长度方向,所述第二方向为垂直于所述感应单元的方向,所述感应单元水平平行设置或垂直平行设置。 17. The touch device according to claim 15, wherein said first direction is a longitudinal direction of the sensing unit, the second direction is perpendicular to said direction sensing means, the sensing unit horizontally or vertically arranged in parallel are arranged in parallel.
18.如权利要求10所述的触控装置,其特征在于,所述多个不相交的感应单元位于同一层。 18. The touch device according to claim 10, wherein said plurality of disjoint sensing unit in the same layer.
19.如权利要求10所述的触控装置,其特征在于,所述感应单元包括: 第三部分,所述第三部分的一端具有所述第一电极; 第四部分,所述第四部分的一端与所述第三部分的另一端相连,所述第四部分的另一端具有所述第二电极。 The fourth portion of the fourth portion,; a third portion, said third portion having an end of the first electrode: 19. The touch device according to claim 10, wherein said sensing means comprises the end and the other end of the third portion, the other end of the fourth portion having the second electrode.
20.如权利要求10所述的触控装置,其特征在于,所述感应单元包括: 第五部分; 不相交的第六部分和第七部分,所述第六部分一端与所述第五部分的一端相连,所述第七部分的一端与所述第五部分的另一端相连,所述第六部分的另一端具有所述第一电极,且所述第七部分的另一端具有所述第二电极。 20. The touch device according to claim 10, wherein the sensing unit comprises: a fifth portion; part VI and VII do not intersect the portion of one end of the fifth portion VI is connected to one end portion connected to one end of the other end of the fifth and the seventh portion, the other end of the sixth portion having the first electrode, and the other end of said first portion having VII two electrodes.
21. 一种便携式电子设备,其特征在于,包括如权利要求10-20任一项所述的触控装置。 21. A portable electronic device, characterized by comprising touch device as claimed in any one of claims 10-20.
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CN 201120573629 CN202600660U (en) 2011-07-26 2011-12-31 Touch control device and portable electronic equipment
CN201110459293.6A CN102902429B (en) 2011-07-26 2011-12-31 The touch detection apparatus and a touch
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CN 201220134097 CN202795314U (en) 2011-07-26 2012-04-01 Touch control device and touch detecting assembly thereof and portable electronic device
CN 201220134544 CN202615359U (en) 2011-07-26 2012-04-01 Touch detection module and touch control device and portable electronic equipment
CN201210093658.2A CN102902442B (en) 2011-07-26 2012-04-01 The touch detection component, the touch device and a portable electronic device
CN 201220134109 CN202870787U (en) 2011-07-26 2012-04-01 Touch detection component, touch control device and portable electronic equipment
CN 201220134531 CN202795315U (en) 2011-07-26 2012-04-01 Touching detection assembly and touching control device and portable type electronic device
CN201210094078.5A CN102902444B (en) 2011-07-26 2012-04-01 The touch detection component, a touch device and a portable electronic device
CN201210093649.3A CN102902441B (en) 2011-07-26 2012-04-01 The touch detection component, the touch device and a portable electronic device
CN 201220134083 CN202649960U (en) 2011-07-26 2012-04-01 Portable electric equipment, touch detection assembly and touch control device
CN201210093687.9A CN102902399B (en) 2011-07-26 2012-04-01 The touch detection component, the touch device and a portable electronic device
CN201210093646.XA CN102902398B (en) 2011-07-26 2012-04-01 The portable electronic device, the touch device and the touch detection component
CN 201220134087 CN202649961U (en) 2011-07-26 2012-04-01 Touch detection assembly, touch control device and portable electric equipment
CN201210093681.1A CN102902443B (en) 2011-07-26 2012-04-01 A touch detection component, the touch device and a portable electronic device

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CN 201120573465 CN202548805U (en) 2011-07-26 2011-12-31 Touch screen detection equipment, touch device and portable electronic equipment
CN201110459295.5A CN102902430B (en) 2011-07-26 2011-12-31 The touch detection apparatus and a touch
CN 201120573769 CN202548807U (en) 2011-07-26 2011-12-31 Touch control device and portable electronic equipment
CN201110459473.4A CN102902438B (en) 2011-07-26 2011-12-31 The method of detecting a touch, a touch screen and a touch detection device means
CN201110459408.1A CN102902435B (en) 2011-07-26 2011-12-31 The touch detection apparatus and a touch
CN 201120573217 CN202548804U (en) 2011-07-26 2011-12-31 Touch device and portable electronic device
CN201110459333.7A CN102902433B (en) 2011-07-26 2011-12-31 The touch detection apparatus and a touch
CN 201120573797 CN202600661U (en) 2011-07-26 2011-12-31 Touch screen detection equipment, touch control device and portable electronic equipment
CN 201120573859 CN202795285U (en) 2011-07-26 2011-12-31 Touch device and a portable electronic device
CN 201120573379 CN202795310U (en) 2011-07-26 2011-12-31 Touch device and a portable electronic device
CN 201120573805 CN202795313U (en) 2011-07-26 2011-12-31 Touch device and a portable electronic device
CN201110459115.3A CN102902427B (en) 2011-07-26 2011-12-31 The touch detection apparatus and a touch
CN201110459367.6A CN102902434B (en) 2011-07-26 2011-12-31 The touch detection apparatus and a touch
CN201110459482.3A CN102902439B (en) 2011-07-26 2011-12-31 The touch detection apparatus and a touch
CN 201120573691 CN202548806U (en) 2011-07-26 2011-12-31 Touch control apparatus and portable electronic equipment
CN 201120573486 CN202649983U (en) 2011-07-26 2011-12-31 Touch device and a portable electronic device
CN 201120573791 CN202649984U (en) 2011-07-26 2011-12-31 Touch screen detection device, touch control device, and portable electronic device
CN 201120573222 CN202795309U (en) 2011-07-26 2011-12-31 Touch device and a portable electronic device
CN201110459449.0A CN102902436B (en) 2011-07-26 2011-12-31 The touch screen and the touch device detecting apparatus
CN201110459292.1A CN102902428B (en) 2011-07-26 2011-12-31 The touch detection apparatus and a touch
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CN201110459466.4A CN102902437B (en) 2011-07-26 2011-12-31 The touch screen and the touch device detecting apparatus
CN201110459316.3A CN102902432B (en) 2011-07-26 2011-12-31 The touch detection apparatus and a touch
CN 201120573468 CN202795312U (en) 2011-07-26 2011-12-31 Touch device and a portable electronic device
CN 201120573629 CN202600660U (en) 2011-07-26 2011-12-31 Touch control device and portable electronic equipment
CN201110459293.6A CN102902429B (en) 2011-07-26 2011-12-31 The touch detection apparatus and a touch
CN 201120573430 CN202795311U (en) 2011-07-26 2011-12-31 Touch device and a portable electronic device
CN 201220134097 CN202795314U (en) 2011-07-26 2012-04-01 Touch control device and touch detecting assembly thereof and portable electronic device
CN 201220134544 CN202615359U (en) 2011-07-26 2012-04-01 Touch detection module and touch control device and portable electronic equipment
CN201210093658.2A CN102902442B (en) 2011-07-26 2012-04-01 The touch detection component, the touch device and a portable electronic device
CN 201220134109 CN202870787U (en) 2011-07-26 2012-04-01 Touch detection component, touch control device and portable electronic equipment
CN 201220134531 CN202795315U (en) 2011-07-26 2012-04-01 Touching detection assembly and touching control device and portable type electronic device
CN201210094078.5A CN102902444B (en) 2011-07-26 2012-04-01 The touch detection component, a touch device and a portable electronic device
CN201210093649.3A CN102902441B (en) 2011-07-26 2012-04-01 The touch detection component, the touch device and a portable electronic device
CN 201220134083 CN202649960U (en) 2011-07-26 2012-04-01 Portable electric equipment, touch detection assembly and touch control device
CN201210093687.9A CN102902399B (en) 2011-07-26 2012-04-01 The touch detection component, the touch device and a portable electronic device
CN201210093646.XA CN102902398B (en) 2011-07-26 2012-04-01 The portable electronic device, the touch device and the touch detection component
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