Analytic formulation of the response of a two-wire transmission line excited by a plane wave

Ari, N.; Blumer, W.

doi:10.1109/15.8757

Cited by 36 publications

(8 citation statements)

References 6 publications

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“…Using (126) we can re-write Laplace-domain circuit equations in (106) as (127) Pre-multiplying both sides of (127) by and using the relation , we have (128) Hence the transfer-function of the reduced system can be written as (129) Comparing the original transfer-function represented by (108) with the transfer-function of the reduced system represented by (129), we can draw the following conclusions. The eigenvalues of are given by the…”

Section: Circuit Reduction Using Arnoldi Algorithmmentioning

confidence: 99%

Recent Advances in Modeling and Simulation of High-Speed Interconnects

Nakhla

Achar

2005

Computational Methods in Large Scale Simulation

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The rapid increase in operating speeds, density and complexity of modern integrated circuits has made interconnect analysis a requirement for all state-of-the-art circuit simulators. Interconnect effects such as ringing, signal delay, distortion and crosstalk can severely degrade signal integrity. Interconnections can be from various levels of design hierarch. As the frequency of operations increases, the interconnect lengths become a significant fraction of the operating wavelength, and conventional lumped models become inadequate in describing the interconnect performance and transmission line models become necessary. This chapter describes some of the recent advances in transmission line simulation techniques. Application of mode-order-reduction algorithms to high-speed interconnect analysis is also presented.

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Section: Circuit Reduction Using Arnoldi Algorithmmentioning

confidence: 99%

Recent Advances in Modeling and Simulation of High-Speed Interconnects

Nakhla

Achar

2005

Computational Methods in Large Scale Simulation

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“…Both ends of the microstrip line are loaded with the loads Z 1 and Z 2 respectively, whose impedances are ohmic. The transmission line equations (telegrapher's equations) have been derived electrogynamically for the transmission line of two parallel homogeneous conductors separated by a dielectric layer and excited by an electromagnetic field [12][13][14][15]. We assume that w a, h l, h a, then the microstrip line considered can be equivalent to the transmission line.…”

Section: Transducer Designmentioning

confidence: 99%

Uwb-Sp Standard Transducer Based on Microstrip Line

Wei¹,

Yan²,

Shoulong³

et al. 2018

PIER M

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In this paper, an ultra-wideband standard transducer based on microstrip line is developed for the accurate measurement and metrology of UWB-SP. The transducer consists of a section of microstrip line and a section of coaxial line connected to the microstrip line via an SMA connector. The initial part of the transducer is chosen to receive the excitation signal, in order to expand the effective time window. Simulated results show that the waveform recovered by the transducer is almost coincident with the waveform of the excited electric field within the effective time window, and the upper frequency of the bandwidth is up to 3.5 GHz. Measured results show that the transducer can recover the waveform of the incident electric field very well. Additionally, the sensitivity and time window can be calibrated readily and accurately by the vector network analyzer as well as the UWB TEM cell. The experimental results are in good agreement with the theoretical and simulated ones.

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“…Let the corresponding residues at different ports be . The original Gilbert's realization will yield Define Next, the realization represented by (131) can be obtained as Unified Transient Simulation: Once a matrix-transfer function describing the multiport interconnect network is obtained, a time-domain realization in the form of state-space equations can be obtained as (132) where and are the vector of terminal currents and voltages of the linear subnetwork [described by (56)]. The differential equations represented by the macromodel (132) can be combined with (55) using the relation as…”

Section: Rementioning

confidence: 99%

Simulation of high-speed interconnects

2001

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With the rapid developments in very large-scale integration (VLSI) technology, design and computer-aided design (CAD) techniques, at both the chip and package level, the operating frequencies are fast reaching the vicinity of gigahertz and switching times are getting to the subnanosecond levels. The ever increasing quest for high-speed applications is placing higher demands on interconnect performance and highlighted the previously negligible effects of interconnects, such as ringing, signal delay, distortion, reflections, and crosstalk. In this review paper, various high-speed interconnect effects are briefly discussed. In addition, recent advances in transmission line macromodeling techniques are presented. Also, simulation of high-speed interconnects using model-reduction-based algorithms is discussed in detail.

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Analytic formulation of the response of a two-wire transmission line excited by a plane wave

Cited by 36 publications

References 6 publications

Recent Advances in Modeling and Simulation of High-Speed Interconnects

Recent Advances in Modeling and Simulation of High-Speed Interconnects

Uwb-Sp Standard Transducer Based on Microstrip Line

Simulation of high-speed interconnects

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