摘要本设计是基于555定时器,连接构成多谐振荡器以及单稳态触发器而测量电容的。单稳态触发器中所涉及的电容,即是被测量的电容xC。其脉冲输入信号是555定时器构成的多谐振荡器所产生。信号的频率可以根据所选的电阻,电容的参数而调节。这样便可以定量的确定被测电容的容值范围。因为单稳态触发器的输出脉宽是根据电容xC值的不同而不同的,所以脉宽即是对应的电容值,其精度可以达到0.1%。然后在电路中加入一个由LM741以及一个电容和一个电阻构成的阻容平滑滤波器,将单稳态触发器输出的信号滤波,使最终输出电压ov与被测量的电容值呈线性关系。最后是输出电压的数字化,将ov输入到7448译码器中翻译成BCD码,输入到LED数码管中显示出来关键词:电容,555定时器,滤波器,线性,译码器,LED数码管1目录一、测量系统的方案设计··············································31.1、测量部分的系统方案设计·····································31.1.1、恒亚充电法测量···················································31.1.2、恒流充电法测量···················································31.1.3、脉冲计数法测量···················································31.2、测量信号数字化系统方案选择································31.2.1、利用单片机进行编程翻译··········································41.2.2、利用译码器进行翻译··············································4二、单元电路的设计及原理·············································42.1、电容值测量电路及原理·······································42.1.1、多谐振荡器电路图及工作原理·······································62.1.2、单稳态触发器电路图及工作原理·····································72.1.3、滤波器工作电路图及原理··········································82.2、模拟信号的处理以及数字化显示·····························9三、系统参数设定······················································10四、结论及谢词························································114.1、结论·····························································114.2、谢词····························································11参考文献··································································12附表:元器件明细表······················································132一系统方案设计1.1测量部分的系统方案设计1.1.1:恒压充电法测量。用一个电阻和电容串联,用恒压源对电容进行充电,然后根据电容充电的曲线超过某个固定电压所需要的时间,利用曲线拟合的方法测量。测量所使用的原始公式是:。可见电容的值和电压以及时间呈微分关系。用这种方法测量,时间和容值是非线性的。因此测量难度高,精度低,并且难以实现数字...
