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This paper presents circuit models for the description of the frequency-dependent behavior of coils for horizontal deflection in CRTs. This enables CRT circuit designers to use circuit simulation programs to predict the high-frequency behavior of the interaction between the deflection coils and the drive circuit. An overview is given of the major phenomena that occur in CRT deflection coils at various frequencies. Models are presented for the dissipative, the capacitive, and the resonant behavior in successive frequency intervals. With these models, phenomena such as power dissipation and ringing can not only be related to design parameters, but can also be calculated from impedance characteristics which are relatively easy to measure.

- Publication
- IEICE TRANSACTIONS on Electronics Vol.E85-C No.11 pp.1870-1876

- Publication Date
- 2002/11/01

- Publicized

- Online ISSN

- DOI

- Type of Manuscript
- Special Section INVITED PAPER (Special Issue on Electronic Displays)

- Category
- CRTs

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Dirk Willem HARBERTS, "Electrical Modeling of the Horizontal Deflection of CRTs" in IEICE TRANSACTIONS on Electronics,
vol. E85-C, no. 11, pp. 1870-1876, November 2002, doi: .

Abstract: This paper presents circuit models for the description of the frequency-dependent behavior of coils for horizontal deflection in CRTs. This enables CRT circuit designers to use circuit simulation programs to predict the high-frequency behavior of the interaction between the deflection coils and the drive circuit. An overview is given of the major phenomena that occur in CRT deflection coils at various frequencies. Models are presented for the dissipative, the capacitive, and the resonant behavior in successive frequency intervals. With these models, phenomena such as power dissipation and ringing can not only be related to design parameters, but can also be calculated from impedance characteristics which are relatively easy to measure.

URL: https://global.ieice.org/en_transactions/electronics/10.1587/e85-c_11_1870/_p

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@ARTICLE{e85-c_11_1870,

author={Dirk Willem HARBERTS, },

journal={IEICE TRANSACTIONS on Electronics},

title={Electrical Modeling of the Horizontal Deflection of CRTs},

year={2002},

volume={E85-C},

number={11},

pages={1870-1876},

abstract={This paper presents circuit models for the description of the frequency-dependent behavior of coils for horizontal deflection in CRTs. This enables CRT circuit designers to use circuit simulation programs to predict the high-frequency behavior of the interaction between the deflection coils and the drive circuit. An overview is given of the major phenomena that occur in CRT deflection coils at various frequencies. Models are presented for the dissipative, the capacitive, and the resonant behavior in successive frequency intervals. With these models, phenomena such as power dissipation and ringing can not only be related to design parameters, but can also be calculated from impedance characteristics which are relatively easy to measure.},

keywords={},

doi={},

ISSN={},

month={November},}

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TY - JOUR

TI - Electrical Modeling of the Horizontal Deflection of CRTs

T2 - IEICE TRANSACTIONS on Electronics

SP - 1870

EP - 1876

AU - Dirk Willem HARBERTS

PY - 2002

DO -

JO - IEICE TRANSACTIONS on Electronics

SN -

VL - E85-C

IS - 11

JA - IEICE TRANSACTIONS on Electronics

Y1 - November 2002

AB - This paper presents circuit models for the description of the frequency-dependent behavior of coils for horizontal deflection in CRTs. This enables CRT circuit designers to use circuit simulation programs to predict the high-frequency behavior of the interaction between the deflection coils and the drive circuit. An overview is given of the major phenomena that occur in CRT deflection coils at various frequencies. Models are presented for the dissipative, the capacitive, and the resonant behavior in successive frequency intervals. With these models, phenomena such as power dissipation and ringing can not only be related to design parameters, but can also be calculated from impedance characteristics which are relatively easy to measure.

ER -