SIMULATION OF CURRENT WAVEFORMS IN HIGH VOLTAGE SPARK SOURCES - III. NUMERICAL INTEGRATION AND INCLUSION OF GAP DYNAMIC IMPEDANCE.

Alexander Scheeline

doi:10.1366/0003702844553991

SIMULATION OF CURRENT WAVEFORMS IN HIGH VOLTAGE SPARK SOURCES - III. NUMERICAL INTEGRATION AND INCLUSION OF GAP DYNAMIC IMPEDANCE.

Alexander Scheeline

Chemistry

Research output: Contribution to journal › Article › peer-review

Abstract

Procedures for simulating discharge currents and voltages in an adjustable waveform spark source are outlined, and comparisons are made between simulated and observed data. Bulirsch-Stoer numerical integration is used to allow solution of the requisite nine simultaneous differential equations. An approximate gap model is employed which demonstrates how dynamic gap properties may be incorporated into modeling. This provides a mechanism for coupling fundamental physical knowledge of gap processes to electrical engineering considerations in source design. Comparison to earlier work involving closed form solution of simpler models is made.

Original language	English (US)
Pages (from-to)	124-135
Number of pages	12
Journal	Applied Spectroscopy
Volume	38
Issue number	2
DOIs	https://doi.org/10.1366/0003702844553991
State	Published - 1984

ASJC Scopus subject areas

Instrumentation
Spectroscopy

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10.1366/0003702844553991

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AB - Procedures for simulating discharge currents and voltages in an adjustable waveform spark source are outlined, and comparisons are made between simulated and observed data. Bulirsch-Stoer numerical integration is used to allow solution of the requisite nine simultaneous differential equations. An approximate gap model is employed which demonstrates how dynamic gap properties may be incorporated into modeling. This provides a mechanism for coupling fundamental physical knowledge of gap processes to electrical engineering considerations in source design. Comparison to earlier work involving closed form solution of simpler models is made.

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SIMULATION OF CURRENT WAVEFORMS IN HIGH VOLTAGE SPARK SOURCES - III. NUMERICAL INTEGRATION AND INCLUSION OF GAP DYNAMIC IMPEDANCE.

Abstract

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