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引用次数: 13
摘要
本文描述了在蓝宝石衬底上使用铌酸锂和氮化镓来定义直接序列扩频调制的SAW相关器。制作了最大长度序列周期为7和15的无源相关器,并在128°y形切割的大块铌酸锂上进行了测试。输入换能器在470-930 MHz的载波频率上调制,芯片持续时间为100 n / s。在输出端,测得最大峰旁瓣比为15db。然后在蓝宝石上用GaN制造相同的设计,以便使用设计以确保低片密度的AlGaN势垒结合声电增益部分。我们考虑一个基本单元由抽头和增益部分组成,以支持长相关器结构。这代表了减轻单片GaN SAW相关器中声学传播损失的第一步。
This paper describes the use of Lithium Niobate and GaN on sapphire substrates to define SAW correlators for direct sequence spread spectrum modulation. Passive correlators with maximal length sequence periods of 7 and 15 are fabricated and tested on 128° Y-cut bulk Lithium Niobate. The input transducer is modulated at carrier frequencies of 470-930 MHz with a chip duration of 100 n $s$. At the output, a maximum peak-to-sidelobe ratio of 15 dB is measured. The same design is then fabricated in GaN on sapphire in order to incorporate acoustoelectric gain sections using an AlGaN barrier engineered to ensure low sheet density. We consider a basic cell consisting of a tap followed by a gain section to support long correlator structures. This represents a first step towards mitigating acoustic propagation losses in monolithic GaN SAW correlators.
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