Electrostatically variable saw delay lines - Theory and experiment

IEEE Transactions on Sonics and Ultrasonics Pub Date : 1984-11-01 DOI:10.1109/T-SU.1984.31550

A. Budreau, G. Scalzi, P. Carr, H. Bertoni

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引用次数: 6

Abstract

A theoretical and experimental investigation has been made of surface acoustic wave (SAW) timedelay change produced by the application of a dc electric field. Measurements were made on the three high-coupling cuts of lithium niobate for the electric field applied in the plane of the surface with a novel electrode configuration and normal-tothe- surface with a standard "convolver" plate. A theory has been developed for the normal field configuration, where the electric field is uniform, and for the in-plane case, where the field is nonuniform. The dominant contribution for the latterc omes from the center of the electrodes. For the 38 X-cut of lithium niobate, the normal field sensitivity (fractional timedelay change per applied electric field γ). is 141x10-12m/V, while γ for the in-plane field is 6x10-12m/V. The in-plane configuration has the advantage of having lower insertion loss and dispersion as the SAW does not have to propagate through a metal electrode. For 16.5° doubly rotated lithium niobate, a normal field device with a substrate thickness of 0.16 mm yielded a fractional timedelay change of 0.9x10-6/V. To our knowledge this is the largest time-delay change per applied voltage yet reported. The time-delay change is 10-4very linear with applied voltage; the second derivative is typically multiplied by slope. Both electrode configurations yield monolithic devices that dissipate no dc power.

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静电可变锯片延迟线。理论和实验

本文从理论和实验两方面研究了直流电场作用下表面声波的延时变化。采用新型电极结构对铌酸锂的三个高耦合切口进行了电场作用于表面平面和标准“卷积”板的法向表面的测量。一个理论已经发展为正常的场结构，其中电场是均匀的，而在平面情况下，其中的场是不均匀的。后者的主要贡献来自电极的中心。对于38 x切割的铌酸锂，正常场灵敏度(每施加电场γ的分数时间延迟变化)。为141x10-12m/V，面内场γ为6x10-12m/V。平面内结构的优点是具有较低的插入损耗和色散，因为SAW不必通过金属电极传播。对于16.5°双旋转铌酸锂，衬底厚度为0.16 mm的普通场器件产生的分数阶延迟变化为0.9x10-6/V。据我们所知，这是迄今为止报道的每个施加电压的最大延时变化。延时变化与外加电压呈10-4极线性关系;二阶导数通常是乘以斜率。两种电极配置都产生不耗散直流功率的单片器件。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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IEEE Transactions on Sonics and Ultrasonics

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