排序方式: 共有11条查询结果,搜索用时 343 毫秒
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研制出一种基于介质上电润湿(electrowetting-on-d ielectric,EWOD)机制的可编程数字化微流控芯片。它采用“三明治”结构:受控离散液滴被夹在两极板之间;下极板以硅为衬底,掺杂多晶硅作为芯片微电极阵列,其上涂覆有Teflon(AF1600薄膜的S iO2作为疏水性介质层;上极板是涂覆有Teflon(AF1600疏水薄膜的透明电极。通过分析数字化微流控系统的基本操作(离散液滴的传输、拆分及混合)的物理机理和模拟优化,在35 V低驱动电压下实现了约0.35μL和0.45μL去离子水离散液滴的传输和合并,并在70 V驱动电压下实现了0.8μL液滴的拆分等操作。 相似文献
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本文介绍实现AT切石英晶体振荡器微处理器温度补偿的新方法——双频温度自测法.AT切石英谐振器各泛音次数的频率温度曲线不同,利用基频与3次泛音除一阶温度系数不同外其他各阶温度系数相等的特性,基频的3倍频与3次泛音频率的差频输出与温度近似成线性关系.同时激励并测量基频和3次泛音频率,经过微处理器计算差频实现谐振器温度自测并进行晶体振荡器的微处理器温度补偿.与使用分立温度传感器相比,消除了测温元件与石英谐振器温度时间常数不同以及温度场梯度造成的测温误差,提高了测温和补偿精度. 相似文献
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A readout integrated circuit (ROIC) for a MEMS (microelectromechanical system)-array-based focal plane (MAFP) intended for imaging applications is presented. The ROIC incorporates current sources for diode detectors, scanners, timing sequence controllers, differential buffered injection-capacitive trans-impedance amplifier (DBI-CTIA) and 10-bit cyclic ADCs, and is integrated with MAFP using 3-D integration technology. A small-signal equivalent model is built to include thermal detectors into circuit simulations. The biasing current is optimized in terms of signal-to-noise ratio and power consumption. Layout design is tailored to fulfill the requirements of 3-D integration and to adapt to the size of MAFP elements, with not all but only the 2 bottom metal layers to complete nearly all the interconnections in DBI-CTIA and ADC in a 40 μm wide column. Experimental chips are designed and fabricated in a 0.35 μm CMOS mixed signal process, and verified in a code density test of which the results indicate a (0.29/-0.31) LSB differential nonlinearity (DNL) and a (0.61/-0.45) LSB integral nonlinearity (INL). Spectrum analysis shows that the effective number of bits (ENOB) is 9.09. The ROIC consumes 248 mW of power at most if not to cut off quiescent current paths when not needed. 相似文献
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为了分析超疏水表面的物理特性及应用前景,介绍了粗糙超疏水表面的两种理论模型,提出了一种基于MEMS加工技术的超疏水表面制备工艺,即利用ICP刻蚀工艺制备规则的硅方柱,并用旋转涂覆TeflonAF1600作为疏水薄膜,制备了疏水特性可控的硅表面。对接触角进行了测量,结果表明,在平整Teflon薄膜表面上,去离子水液滴的本征接触角约为117°,在边长间距比为10μm/35μm的方柱表面上的去离子水液滴显现接触角可达170°。另处,还给出了为避免Wenzel液滴出现的“安全”设计参数(方柱间距边长比小于2.5),以及一种基于润湿性梯度的微流体操控方案。 相似文献
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