Your search keyword '"Jeffrey Klenzing"' showing total 3 results

1. A numerical study of geometry dependent errors in velocity, temperature, and density measurements from single grid planar retarding potential analyzers

Author

R. L. Davidson, Jeffrey Klenzing, Roderick A. Heelis, and Gregory Earle

Subjects

Physics, Planar, Plane (geometry), Aperture, Numerical analysis, Perpendicular, Plasma diagnostics, Geometry, Electric potential, Condensed Matter Physics, Grid, Computer Science::Distributed, Parallel, and Cluster Computing

Abstract

Planar retarding potential analyzers (RPAs) have been utilized numerous times on high profile missions such as the Communications/Navigation Outage Forecast System and the Defense Meteorological Satellite Program to measure plasma composition, temperature, density, and the velocity component perpendicular to the plane of the instrument aperture. These instruments use biased grids to approximate ideal biased planes. These grids introduce perturbations in the electric potential distribution inside the instrument and when unaccounted for cause errors in the measured plasma parameters. Traditionally, the grids utilized in RPAs have been made of fine wires woven into a mesh. Previous studies on the errors caused by grids in RPAs have approximated woven grids with a truly flat grid. Using a commercial ion optics software package, errors in inferred parameters caused by both woven and flat grids are examined. A flat grid geometry shows the smallest temperature and density errors, while the double thick flat grid...

Published

2010

2. A statistical analysis of systematic errors in temperature and ram velocity estimates from satellite-borne retarding potential analyzers

Author

Gregory Earle, Roderick A. Heelis, W. R. Coley, and Jeffrey Klenzing

Subjects

Physics, Spectrum analyzer, Drift velocity, Planar, Plasma diagnostics, Satellite, Statistical physics, Space physics, Condensed Matter Physics, Grid, Charged particle, Computational physics

Abstract

The use of biased grids as energy filters for charged particles is common in satellite-borne instruments such as a planar retarding potential analyzer (RPA). Planar RPAs are currently flown on missions such as the Communications/Navigation Outage Forecast System and the Defense Meteorological Satellites Program to obtain estimates of geophysical parameters including ion velocity and temperature. It has been shown previously that the use of biased grids in such instruments creates a nonuniform potential in the grid plane, which leads to inherent errors in the inferred parameters. A simulation of ion interactions with various configurations of biased grids has been developed using a commercial finite-element analysis software package. Using a statistical approach, the simulation calculates collected flux from Maxwellian ion distributions with three-dimensional drift relative to the instrument. Perturbations in the performance of flight instrumentation relative to expectations from the idealized RPA flux equation are discussed. Both single grid and dual-grid systems are modeled to investigate design considerations. Relative errors in the inferred parameters for each geometry are characterized as functions of ion temperature and drift velocity.

Published

2009

3. Errors in ram velocity and temperature measurements inferred from satellite-borne retarding potential analyzers

Author

Gregory Earle, Jeffrey Klenzing, and Roderick A. Heelis

Subjects

Physics, Observational error, Plane (geometry), Angle of attack, Electron temperature, Plasma diagnostics, Satellite, Statistical physics, Condensed Matter Physics, Grid, Temperature measurement, Computational physics

Abstract

Retarding potential analyzers (RPAs) [Heelis and Hanson, Measurement Techniques in Space Plasmas, in Geophys. Monogr. Ser., Vol. 102 (AGU, Washington, D.C., 1998), p. 61] have been used extensively in space science over the past five decades to provide in situ estimates of ion velocities and temperatures. It has been shown previously that the use of biased grids in such instruments creates a nonuniform potential in the grid plane, which leads to errors in inferred parameters. A simulation of ion interactions with biased grids has been developed using a commercial finite-element analysis software package. Using a statistical approach, perturbations to the idealized RPA equation are discussed with the intent of developing quantitative corrections for the inferred parameters. The transparency of the grid stacks is found to be a function of particle energy and angle of attack. A preliminary case study is presented and compared to previous work.

Published

2008