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,Click to edit Master text styles,Second level,Third level,Fourth level,Fifth level,*,Click to edit Master title style,Click to edit Master text styles,Second level,Third level,Fourth level,Fifth level,Click to edit Master title style,*,Click to edit Master text styles,Second level,Third level,Fourth level,Fifth level,Click to edit Master title style,Logo,*,Click to edit Master text styles,Second level,Third level,Fourth level,Fifth level,Click to edit Master title style,Logo,*,Click to edit Master text styles,Second level,Third level,Fourth level,Fifth level,Click to edit Master title style,Logo,*,Click to edit Master text styles,Second level,Third level,Fourth level,Fifth level,Click to edit Master title style,Logo,*,Click to edit Master text styles,Second level,Third level,Fourth level,Fifth level,Click to edit Master title style,Logo,*,Click to edit Master text styles,Second level,Third level,Fourth level,Fifth level,Click to edit Master title style,Logo,*,Click to edit Master text styles,Second level,Third level,Fourth level,Fifth level,Click to edit Master title style,Logo,*,Click to edit Master text styles,Second level,Third level,Fourth level,Fifth level,Click to edit Master title style,Logo,*,Click to edit Master text styles,Second level,Third level,Fourth level,Fifth level,Click to edit Master title style,Logo,*,Click to edit Master text styles,Second level,Third level,Fourth level,Fifth level,Click to edit Master title style,Logo,*,Click to edit Master text styles,Second level,Third level,Fourth level,Fifth level,Click to edit Master title style,Logo,*,Click to edit Master text styles,Second level,Third level,Fourth level,Fifth level,Click to edit Master title style,Logo,*,讲述内容,一,、,触摸按键的原理和实现,二,、,电阻屏简介,三,、,电容屏简介,1,、原理,2,、影响触摸灵敏度的因素,3,、软件识别方法,4,、如何适应不同硬件,抛砖引玉,1,、原理,2,、四线、五线、七线、八线之分,1,、原理,2、,多点触控之,反射式电容屏,触摸按键的原理与实现,原理:,R,C,0,C,0,C,R,VCC,VCC,无触摸时的电路模型,有触摸时的电路模型,1,、基准电容:,板材、板厚、电极面积、杂散电容(走线电容),2,、形状(规则形状,不规则形状),3,、布局(触摸焊盘和走线方式),4,、外部干扰,5,、上拉电阻大小,6,、采样时钟的频率,触摸按键的原理与实现,影响触摸灵敏度的因素(提高电容增量):,触摸盘的面积尽,可能与手指触摸面积,一样大,无关手指触,摸的部分的寄生电容,尽量小。,触摸按键的原理与实现,软件识别方法:,1,、初始化定时器,捕获模式,上升沿捕获,计数器寄存器置零;,2,、初始化,IO,为推挽输出,置,IO,输出,0,,给电容放电;,3,、延时;,4,、初始化,IO,为浮空输入,如果需要(不同,MCU,),设置复用模式为定时器输入通道;,5,、开启定时器上升沿捕获中断,启动定时器计时;,6,、等待定时器上升沿中断;,7,、在中断中,关闭中断源,读取捕获值;,8,、主循环中与原始值比较,判断是否被触摸了。,9,、重复,29,。,如何适应不同的硬件,抛砖引玉:,触摸按键的原理与实现,1,、不同材质、极板面积、极板距离的触摸按键:,设置电容值增量因子;,2,、相同性质的触摸按键,数量不同:,构造触摸按键结构体,修改数组大小适应不同数量的触摸按键。,电阻屏简介,原理:,以四线电阻屏为例,:,电阻屏简介,原理:,距离之比,=,电阻之比,=,电压之比,1,、通常(,RX1+RX2,)和(,RY1+RY2,)值是已知的。,2,、,X,方向和,Y,方向的分压比,=,距离之比,可以算出,RX1,、,RX2,、,RY1,、,RY2,四个电阻值。,3,、,RZ,是触点电阻,按压力越大,,RZ,越小。,4,、根据测量值,Z1,、,Z2,的电压比值和,RX1,、,RY2,阻值,可算出,RZ,,即,Z,坐标。,电阻屏简介,四线,五线,六线之分:,1,、五线电阻屏测量原理和四线电阻屏一样;,2,、不同点在于,五线电阻屏的,X,、,Y,电极位于同一个,ITO,导电层,,分时加载,X,电场和,Y,电场。另一个,ITO,导电层仅作为导体用。,3,、五线电阻屏没有,Z,坐标。,五线电阻屏(四千万)要比四线电阻屏(一百万)耐用,经常按压,的,ITO,导电层不参与电阻分压测量,不必考虑导电层的厚薄是否均匀,此,外,即使导电层受按压破裂,也影响不大,只要有电气连接即可。,六线电阻屏,比五线电阻屏多了接地层,用于屏蔽电磁干扰。,还有七线、八线电阻屏,用得较少,原理同四线电阻屏,仅仅是,提高精度,减少线上电阻的影响。,电容屏简介,原理:,表面式触摸屏,投射式触摸屏,在,ITO,导电层施加电场,当有,手指触碰屏表面时,屏表面和手指,之间形成电容,电流就从导电层的,四个角的导线流向手指。测量四个,角的电流大小,根据比例可算出手,指的触摸位置。,该电场为高频交变电场。,两个导电层,每个导电层相互垂直,镂空,形成点阵形式的电容,通过扫描,行列电容的变化,感知触摸位置。,定位精度取决于点阵电容的数量,,以及屏的大小。,电容屏简介,多点触控之反射式电容屏:,表面电容式触摸屏只有单点触控。,投射电容式触摸屏有多点触控的概念。,但是,投射式电容屏在多点触控时,会出现“鬼点”,需要特殊处理。,猜一下,哪几个是“鬼点”?,Thank you,还有什么疑问,请提出,联系本人:,也可以以发送邮件到,
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