60 GHz DLHL Si IMPATT二极管的设计优化与大信号仿真

Proceedings of the 2015 Third International Conference on Computer, Communication, Control and Information Technology (C3IT) Pub Date : 2015-03-16 DOI:10.1109/C3IT.2015.7060140

Suranjana Banerjee, A. Acharyya, M. Mitra

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引用次数: 0

摘要

采用四能级优化技术设计了一种60 GHz双低-高-低(DLHL)冲击雪崩传输时间(IMPATT)二极管。最初，n-外延层和p-外延层中电荷凸起的位置、凸起的宽度以及高掺杂浓度与低掺杂浓度的比例都发生了变化，以获得器件最大的大信号DC到RF转换效率。最后在一定范围内改变偏置电流密度，得到器件直流到射频转换效率最大的偏置电流密度的最优值。重复上述四个优化步骤，直到该方法收敛以提供稳定的优化DC到RF转换效率。为此，采用了基于非正弦电压激励(NSVE)模型的大信号仿真技术。对优化后的DLHL Si IMPATT的大信号特性进行了仿真，并与已有的实验结果进行了比较。上述比较表明，与未优化的DLHL二极管相比，优化后的DLHL二极管能够提供更高的RF功率输出，在60 GHz时具有更高的直流到RF转换效率。

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Design optimization and large-signal simulation of DLHL Si IMPATT diode at 60 GHz

A four-level optimization technique has been used to design a double low-high-low (DLHL) impact avalanche transit time (IMPATT) diode based on Si for 60 GHz operation. Initially the position of the charge bumps in both n- and p-epitaxial layers followed by the widths of those and the ratio of high to low doping concentrations have been varied subject to obtain the maximum large-signal DC to RF conversation efficiency from the device. Finally the bias current density is varied within a specified range to obtain the optimum value of it for which the DC to RF conversation efficiency of the device is maximum. The above mentioned four optimization steps have been repeated until the method converges to provide a stable optimized DC to RF conversion efficiency. A large-signal simulation technique based on non-sinusoidal voltage excitation (NSVE) model developed by the authors is used for this purpose. The large-signal properties of the optimized DLHL Si IMPATT have been simulated and those are compared with the experimental results reported earlier. The said comparison shows that the optimized DLHL diode is capable of delivering significantly higher RF power output with greater DC to RF conversion efficiency at 60 GHz as compared to its un-optimized counterpart.

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Proceedings of the 2015 Third International Conference on Computer, Communication, Control and Information Technology (C3IT)

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