数字万用表测量电阻是通过测量恒流源电流I流过被测电阻RX所产生的电压Vx实现的。通过对Vx数字化及小数点移位便可得到Rx的数字化值。原理框图如:测试时,恒流源电流I通过Hi-Lo端和测量线馈送至被测电阻Rx,电压测量端SS2通过短路线接至Hi-Lo端。数字万用表实际测量到的电阻值包括被测电阻Rx及馈线电阻RL1和RL2。当测量的电阻阻值较小时,馈线电阻产生的误差就不容忽视。如何用现有的数字万用表测量阻值很小的电阻是工程技术人员经常遇到的问题。
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拉曼光谱技术在材料科学研究中的应用拉曼光谱在材料科学中是物质结构研究的有力工具,在相组成界面、晶界等课题中可以做很多工作。包括:薄膜结构材料拉曼研究:拉曼光谱已成CVD(化学气相沉积法)制备薄膜的检测和鉴定手段。拉曼可以研究单、多、微和非晶硅结构以及硼化非晶硅、氢化非晶硅、金刚石、类金刚石等层状薄膜的结构。晶格材料研究:可通过测量晶格中的应变层的拉曼频移计算出应变层的应力,根据拉曼峰的对称性,知道晶格的完整性。
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从特性来说,PCA82C250/251在高速波特率下过冲很严重,在进行CE时通不过标准,而TJA1040/1050的电磁辐射就小的多,可以通过CE。因为世界上CAN收发器的需求量增大,TI公司、Freescale公司、美信公司、Microhip公司纷纷推出了自己的高速CAN收发器。本文对NXP的新旧两类收发器,以及SN65HVD251(TI公司生产)和MC33901(Freescale公司生产)进行对比测试。
