Wideband passive multiport model order reduction and realization of RLCM circuits
This paper presents a novel compact passive modeling technique for high-performance RF passive and interconnect circuits modeled as high-order resistor–inductor– capacitor–mutual inductance circuits. The new method is based on a recently pr...
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| Main Authors: | , , , , |
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| Other Authors: | |
| Format: | Article |
| Language: | English |
| Published: |
2010
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| Subjects: | |
| Online Access: | https://hdl.handle.net/10356/92089 http://hdl.handle.net/10220/6329 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | This paper presents a novel compact passive
modeling technique for high-performance RF passive and
interconnect circuits modeled as high-order resistor–inductor–
capacitor–mutual inductance circuits. The new method is based
on a recently proposed general s-domain hierarchical modeling
and analysis method and vector potential equivalent circuit model
for self and mutual inductances. Theoretically, this paper shows
that s-domain hierarchical reduction is equivalent to implicit
moment matching at around s = 0 and that the existing hierarchical
reduction method by one-point expansion is numerically
stable for general tree-structured circuits. It is also shown that
hierarchical reduction preserves the reciprocity of passive circuit
matrices. Practically, a hierarchical multipoint reduction scheme
to obtain accurate-order reduced admittance matrices of general
passive circuits is proposed. A novel explicit waveform-matching
algorithm is proposed for searching dominant poles and residues
from different expansion points based on the unique hierarchical
reduction framework. To enforce passivity, state-space-based
optimization is applied to the model order reduced admittance
matrix. Then, a general multiport network realization method
to realize the passivity-enforced reduced admittance based on
the relaxed one-port network synthesis technique using Foster’s
canonical form is proposed. The resulting modeling algorithm can
generate the multiport passive SPICE-compatible model for any
linear passive network with easily controlled model accuracy and
complexity. Experimental results on an RF spiral inductor and
a number of high-speed transmission line circuits are presented.
In comparison with other approaches, the proposed reduction is
as accurate as passive reduced-order interconnect macromodeling
algorithm in the high-frequency domain due to the enhanced
multipoint expansion, but leads to smaller realized circuit models.
In addition, under the same reduction ratio, realized models by
the new method have less error compared with reduced circuits by
time-constant-based reduction techniques in time domain. |
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