Mohamed F Hagag, Thomas R Jones, Karim Seddik, Dimitrios Peroulis
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The study starts with a simple lumped model cell to facilitate understanding of the phenomena. Following this, transmission lines are introduced, and the effects of incorporating loss are examined. To accomplish this, three models are investigated: a lossless L-C TL lumped model loaded with a shunt lossless TMC and a TL loaded with a shunt lossless and lossy TMC. Dispersion diagrams are plotted and momentum bandgaps are identified at a modulation frequency double the signal frequency. Within the momentum bandgap, only imaginary frequencies are found and correlated to momentum bandgap width and signal growth level. 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Dispersion diagrams are plotted and momentum bandgaps are identified at a modulation frequency double the signal frequency. Within the momentum bandgap, only imaginary frequencies are found and correlated to momentum bandgap width and signal growth level. 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引用次数: 0
摘要
我们首次对具有纯时间调制特性阻抗 Z o(无限超光度)的传输线(TL)中的信号增长进行了全面研究。这项研究开创性地探讨了改变电池电气长度的影响,以及损耗对动量带隙和放大水平的影响。它还深入研究了静态负载对时间调制传输线的截断如何影响放大增益对输入信号和调制之间相对相位的敏感性,并将这些发现与参数放大的情况进行了比较。通过在 TL 上加载正弦时间调制电容器 (TMC) 来改变 Z o。研究从一个简单的块状模型单元开始,以便于理解相关现象。随后,引入传输线,并研究加入损耗的影响。为此,研究了三种模型:装有并联无损耗 TMC 的无损耗 L-C TL 块状模型,以及装有并联无损耗和有损耗 TMC 的 TL。绘制了频散图,并确定了调制频率为信号频率两倍时的动量带隙。在动量带隙内,只发现了虚频,并与动量带隙宽度和信号增长水平相关。利用谐波平衡和瞬态模拟确认了信号增长,结果与频散图结果一致。
Signal growth in a pure time-modulated transmission line and the loss effect.
We present the first comprehensive study for signal growth in transmission lines (TL) with purely time-modulated characteristic impedance (infinite superluminality). This study pioneers the investigation into the effects of varying the cell's electrical length and the impact of loss on momentum bandgaps and amplification levels. It also thoroughly examines how time-modulated transmission line truncation by a static load influences the sensitivity of amplification gain to the relative phase between the incoming signal and modulation, comparing these findings with the case of parametric amplification. Varying is accomplished by loading TLs with a sinusoidally time-modulated capacitor (TMC). The study starts with a simple lumped model cell to facilitate understanding of the phenomena. Following this, transmission lines are introduced, and the effects of incorporating loss are examined. To accomplish this, three models are investigated: a lossless L-C TL lumped model loaded with a shunt lossless TMC and a TL loaded with a shunt lossless and lossy TMC. Dispersion diagrams are plotted and momentum bandgaps are identified at a modulation frequency double the signal frequency. Within the momentum bandgap, only imaginary frequencies are found and correlated to momentum bandgap width and signal growth level. Signal growth is confirmed using harmonic balance and transient simulations, and the results are consistent with the dispersion diagram outcomes.
期刊介绍:
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