Numerical Solution of Ordinary and Partial Differential Equations by Means of Equivalent Circuits

Kron, Gabriel

doi:10.1063/1.1707568

Cited by 69 publications

(26 citation statements)

References 6 publications

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“…A transport lattice provides an approximate, alternative approach to traditional analytical and finite element methods. This approach is consistent with earlier use of electrical analog computers to solve partial differential equations by using relatively small circuits (38). A transport lattice also allows both field-dependent transport (e.g., ionic conduction in aqueous electrolytes) and transmembrane voltage-dependent transport (e.g., voltage-gated channels and electroporation) to be easily incorporated into a system model.…”

Section: Resultssupporting

confidence: 55%

An approach to electrical modeling of single and multiple cells

Gowrishankar

Weaver

2003

Proc. Natl. Acad. Sci. U.S.A.

186

124

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Previous theoretical approaches to understanding effects of electric fields on cells have used partial differential equations such as Laplace's equation and cell models with simple shapes. Here we describe a transport lattice method illustrated by a didactic multicellular system model with irregular shapes. Each elementary membrane region includes local models for passive membrane resistance and capacitance, nonlinear active sources of the resting potential, and a hysteretic model of electroporation. Field amplification through current or voltage concentration changes with frequency, exhibiting significant spatial heterogeneity until the microwave range is reached, where cellular structure becomes almost ''electrically invisible.'' In the time domain, membrane electroporation exhibits significant heterogeneity but occurs mostly at invaginations and cell layers with tight junctions. Such results involve emergent behavior and emphasize the importance of using multicellular models for understanding tissue-level electric field effects in higher organisms. E lectric field effects in biological systems are of long-standing scientific interest. Endogenous fields are important in development (1) and wound healing (2). Small external fields from dc to ϾϷ1 GHz are of interest with respect to sensory systems, medical applications, and possible human health hazards (3-12). Larger pulsed fields are involved in stimulation of excitable cells (13,14) and electroporation and heating of tissue in vivo (15)(16)(17)(18)(19) and cells in vitro (20)(21)(22)(23) or ex vivo (24).Biological cells contain highly conductive aqueous electrolytes separated by thin, low-conductivity membranes populated with electrically active macromolecules. As a result, multicellular systems are extremely heterogeneous with respect to their passive electrical properties (local resistance and capacitance) and both passive and active interaction mechanisms (ion pumps, voltage-gated channels, and electroporatable membrane regions). This heterogeneity creates a basic complication: an applied field, E ជ app , leads to a response field, E ជ res , that differs spatially and temporally from E ជ app within the biological system. Here E ជ app is the field that would exist if the biological system were replaced by a purely conductive medium.Many of these interactions have biological relevance. Fields guide ionic currents (1, 2) and cause Joule heating. At cell membranes fields drive conformational changes in macromolecules, particularly ion channels (7,13,14) and membrane-associated enzymes (6, 25), and cause electroporation (15-19, 26, 27) and the related events of electro-insertion (24) and electrofusion (22,26,27). Several of these interactions can take place simultaneously, although often one interaction dominates. Importantly, these interactions depend on the local electric field, not the average applied field usually reported in experimental studies or predicted by tissue-level simulations. Accordingly, it is important to create and solve increasingly realisti...

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Section: Resultssupporting

confidence: 55%

An approach to electrical modeling of single and multiple cells

Gowrishankar

Weaver

2003

Proc. Natl. Acad. Sci. U.S.A.

186

124

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“…Electrical analogues were first proposed for truss bridges (Bush 1934) or assembly of beam structures (Kron 1944;Carter and Kron 1944). Then, Kron extended the analysis to numerous differential equations as the compressible fluid flow equations, the electromagnetic field equations of Maxwell or the wave equations of Schrödinger (Kron 1945(Kron , 1948. Concerning the theory of elasticity, 3D models were introduced (Kron 1948;Barnoski and Freberg 1966) but real implementations of analogous networks were usually restrained to simpler cases involving one-or twodimensional structural members.…”

Section: Introductionmentioning

confidence: 99%

Design of a passive electrical analogue for piezoelectric damping of a plate

Lossouarn

Aucejo

Deü

et al. 2017

Journal of Intelligent Material Systems and Structures

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Vibrations of a mechanical structure can be reduced through a piezoelectric coupling to a passive electrical network exhibiting similar modal properties. For the control of a plate, the design of a two-dimensional analogous electrical network is considered. Depending on the mechanical boundary conditions, a finite difference formulation of the Kirchhoff-Love equation of motion shows that we need to ensure specific electrical connections along the edges of the analogous network. A numerical model involving an assembly of element matrices validates the electrical topology. Then, the passive electrical circuit is implemented with capacitors, inductors and transformers, whose practical design is closely described. Focusing on the analogue of a clamped plate, experiments prove the ability of the proposed electrical network to approximate the behavior of the mechanical structure.

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“…See, for example, [1], [6], [9], 10], 12]- [ 18]. In fact, some of these works employ infinite networks to model phenomena governed by partial differential equations [1], [6], [12]- [17]. However, not Until the recent works of H. Flanders [7], [8] was a general method for analyzing a fairly unrestricted class of infinite networks devised.…”

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confidence: 98%

The Complete Behavior of Certain Infinite Networks Under Kirchhoff’s Node and Loop Laws

Zemanian¹

1976

SIAM J. Appl. Math.

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The objective of this work is the investigation of all possible current distributions in an infinite electrical network subject only to Kirchhott's node and loop laws. These laws are in general not strong enough to yield a unique set of branch currents. All prior investigations of infinite networks imposed additional requirements, such as finiteness of the total power dissipation, in order to force uniqueness, but in doing so the other possible responses of a network were discarded.The main result of this work holds not for all infinite, locally finite networks but for some fairly general classes of such networks as well as for certain countably infinite networks that need not be locally finite. It states that if the currents in certain branches, called "joints," are arbitrarily chosen, then all other branch currents are uniquely determined. Moreover, all possible sets of branch currents satisfying only the node and loop laws are encompassed in this result; one need merely choose the joint currents properly in order to obtain any given permissible set of branch currents. Another result concerns the idea of a homogeneous current flow; this is a set of branch currents satisfying the node and loop laws when all sources are set equal to zero. The dimension of the linear space of all homogeneous current flows is shown to be equal to the cardinal number of the set of joints. Finally, it is worth noting that our analysis provides a method for calculating the current in any given branch through a finite number of computational steps.

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Numerical Solution of Ordinary and Partial Differential Equations by Means of Equivalent Circuits

Cited by 69 publications

References 6 publications

An approach to electrical modeling of single and multiple cells

An approach to electrical modeling of single and multiple cells

Design of a passive electrical analogue for piezoelectric damping of a plate

The Complete Behavior of Certain Infinite Networks Under Kirchhoff’s Node and Loop Laws

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