The sensitivity of a micromachined acoustic sensor consisting of four hot-wire particle velocity sensors is analysed theoretically and experimentally. The device and its fabrication have been presented in part 1 of this paper (Yntema et al 2010 J. Micromech. Microeng. 20 015042). A relatively straightforward analytical model is presented that describes both the air flow around the probe and the temperature profile around the heated wires. The presence of the chip surface near the heated wires influences the fluid flow around the wires, while it also affects the temperature distribution in the probe by altering the direction of heat transport. Both effects result into a modified angular dependence of the sensor sensitivity with respect to the normal 'figure-of-eight' figure of the response. By means of finite elements software, the thermal and the acoustic flow behaviour of the sensor are also investigated numerically, both effects together and each apart, and the results are compared to the analytical model. Comparison with the experimental data is presented, showing that the model is appropriate to describe the angular dependence and the magnitude of the sensor response. It is concluded that the perturbed air flow due to the chip surface is the dominant reason for the observed angular sensitivity.
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机译:从理论和实验上分析了由四个热线粒子速度传感器组成的微机械声传感器的灵敏度。该设备及其制造已在本文的第1部分中进行了介绍(Yntema等人2010 J. Micromech。Microeng。20 015042)。提出了一个相对简单的分析模型,该模型描述了探头周围的气流和加热丝周围的温度曲线。靠近加热丝的芯片表面的存在会影响导线周围的流体流动,同时也会通过改变传热方向来影响探针中的温度分布。相对于响应的正常“八位数”图形,这两种效果都会导致传感器灵敏度的角度依赖性得到改善。通过有限元软件,还对传感器的热和声流动行为进行了数值研究,将两者的影响加在一起,并将其分开,并将结果与分析模型进行了比较。与实验数据进行了比较,表明该模型适合描述角度依赖性和传感器响应的大小。结论是,由于芯片表面而引起的扰动气流是观察到的角度灵敏度的主要原因。
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