Computer‐aided design of electron guns and deflection yokes: A review (Part 2)

Alig, R. Casanova; Fields, J. R.

doi:10.1889/1.1828745

Cited by 2 publications

(1 citation statement)

References 31 publications

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“…The horizontally enlarged spot degrades horizontal resolution while the vertically compressed spot causes scanning moire. In order to overcome these problems, some technologies [3][4][5] and computer-aided simulation techniques 6,7 have been developed. Computer-aided numerical simulation is useful and convenient to predict the spot shape on the screen by taking various design parameters into account.…”

Section: Introductionmentioning

confidence: 99%

A study on spot distortion for an in‐line self‐converging system for color CRTs

Wada

2008

J Soc Info Display

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The spot distortion at the screen periphery of an in-line self-converging CRT is formulated by considering four factors; (a) oblique incidence of the beam at the screen periphery, (b) increased path length of the beam, (c) beam compression due to the deflection, and (d) the astigmatism due to the deflection field. The analytic spot size calculated with the formulas agrees well with measurement, though the effects of a particular gun system, spherical aberration, and space-charge repulsion are not taken into consideration in the formulas while assuming an ideal deflection field. The analytic formulas enable easy evaluation of spot distortion at the screen periphery because they give an intuitive understanding of beam behavior in the in-line self-converging system. In addition to the derivation of the formulas, "transposed scanning" is analyzed with the use of the formulas for one of the ways to optimize the spot distortion at the screen periphery.

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Section: Introductionmentioning

confidence: 99%

A study on spot distortion for an in‐line self‐converging system for color CRTs

Wada

2008

J Soc Info Display

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Model for intensity calculation in electron guns

Doyen

Conto

Garnier

et al. 2007

Journal of Applied Physics

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International audienceThe calculation of the current in an electron gun structure is one of the main investigations involved in the electron gun physics understanding. In particular, various simulation codes exist but often present some important discrepancies with experiments. Moreover, those differences cannot be reduced because of the lack of physical information in these codes. We present a simple physical three-dimensional model, valid for all kinds of gun geometries. This model presents a better precision than all the other simulation codes and models encountered and allows the real understanding of the electron gun physics. It is based only on the calculation of the Laplace electric field at the cathode, the use of the classical Child-Langmuir's current density, and a geometrical correction to this law. Finally, the intensity versus voltage characteristic curve can be precisely described with only a few physical parameters. Indeed, we have showed that only the shape of the electric field at the cathode without beam, and a distance of an equivalent infinite planar diode gap, govern mainly the electron gun current generation

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Computer‐aided design of electron guns and deflection yokes: A review (Part 2)

Cited by 2 publications

References 31 publications

A study on spot distortion for an in‐line self‐converging system for color CRTs

A study on spot distortion for an in‐line self‐converging system for color CRTs

Model for intensity calculation in electron guns

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