Abstract
We present a stabilized theory to address the breakdown or inaccuracy issue for low-frequency (LF) characteristic mode analysis (CMA). At LFs, to properly preserve the governing quasi-static circuit physics, the eigenvalue decomposition technique is leveraged to formulate a stabilized eigenvalue problem regarding low-order CMs, which dominate the scattering, radiation, and energy storage properties of arbitrarily shaped conducting bodies. Several efficient schemes are introduced for the computation of the low-order CMs in the LF regime, including the augmented electric-field integral equation, the potential ( $\mathbf {A}$ - $\Phi$ )-based integral equation, and the Calderon multiplicative preconditioner. The LF stabilized CMA enables one to understand and interpret the behaviors of complicated conducting objects with a reduced “modal” representation at LFs, which offers an insightful tool for reduced order modeling in circuit design and analysis.
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