基于神经网络的片上螺旋电感器建模与设计

A. Ilumoka, Y. Park
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引用次数: 2

摘要

提出了一种基于神经网络的高q级片上螺旋电感的建模和再设计方法。该方法包括建立神经网络模型,将三维多级螺旋电感器的几何和材料特性映射到SPICE等效电路参数。神经网络取代了计算昂贵的基于fem的提取和现场解决方案。该方法特别具有吸引力,因为它能够准确有效地预测重要的电感特性,如自感、q因子、自谐振频率和寄生电阻和电容。与现场解决方案相比,它还提供了大量的计算节省——神经模型评估平均需要现场解决方案所需cpu时间的2%。该方法不仅可以作为快速提取螺旋电感电路的基础,还可以从优化后的电感电路级参数中快速优化螺旋布局设计。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Neural network-based modeling and design of on-chip spiral inductors
A neural network approach is presented for the modeling and re-design of high-Q on-chip spiral inductors. The approach involves the creation of neural network models to map 3D multi-level spiral inductor geometric and material characteristics to SPICE equivalent circuit parameters. The neural network replaces computationally expensive FEM-based extraction and field solution. The approach is especially attractive because it is capable of accurately and efficiently predicting important inductor characteristics such as self-inductance, Q-factor, self-resonant frequency and parasitic resistance and capacitance. It also offers substantial computational savings over field solution-evaluation of neural model required on average 2% of the cpu time required for field solution. The neural approach served not only as a basis for fast spiral inductor circuit extraction but also permits fast spiral layout design refinement from post-optimization inductor circuit-level parameters.
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