Journals & Magazines >IEEE Transactions on Power El... >Volume: 21 Issue: 5

HF Characterization and Nonlinear Modeling of a Gapped Toroidal Magnetic Structure

Download PDF
Download References
Request Permissions
Save to
Alerts

Abstract:

The frequency dependent characteristics of a gapped toroidal structure are extracted empirically over a bandwidth that exceeds 30MHz. The analysis is complicated due to n...Show More

Metadata

Abstract:

The frequency dependent characteristics of a gapped toroidal structure are extracted empirically over a bandwidth that exceeds 30MHz. The analysis is complicated due to nonlinear flux distributions, magnetic properties of the core material, leakage inductance, stray capacitances, and eddy currents in the windings. A permeance model of the core is implemented to model the magnetic circuit. The model includes a linear lumped element equivalent circuit to approximate the nonlinear complex permeability of the core, which was measured empirically. Stray capacitance and inductance of the winding are also modeled. A gyrator is used to couple the electric and magnetic models for circuit simulation. The measured and simulated results of open-circuit impedance from the secondary winding and the transimpedance gain (V/A) of the current sensor are compared and discussed

Published in: IEEE Transactions on Power Electronics ( Volume: 21, Issue: 5, September 2006)

Page(s): 1167 - 1175

Date of Publication: 06 September 2006

ISSN Information:

DOI: 10.1109/TPEL.2006.880357

References is not available for this document.

Contents

I. Introduction

The wide-band characteristics of passive components are becoming increasingly important even for high power applications, for which there has been a steady increase in switching frequencies over recent years. Present microprocessors are more able to cope with high frequencies and enable tighter control bandwidth. The ability to predict conducted electromagnetic interference (EMI) in power electronics circuitry before even constructing a prototype has also become a reality. These are only some of the reasons why high frequency behavior will gain increasing interest for the accurate characterization, modeling, and design of circuit components, such as filters, inductors, capacitors, and sensors, for frequencies typically up to 30MHz.

Select All

G. Laimer and J. W. Kolar, "Wide-bandwidth low-complexity isolated current sensor tobe employed in a 10 kW/500 kHz three-phase unity power factor PWM rectifiersystem", Proc. Power Electron. Spec. Conf., pp. 1065-1070, 2002.

View Article

Google Scholar

C. Graziano, R. De Leo, V. M. Primiani, S. Pennesi and P. Russo, "Wide-band characterization of current probes", IEEE Trans. Electromagn. Compat., vol. 45, no. 4, pp. 616-625, Nov. 2003.

View Article

Google Scholar

E. C. Snelling, Soft Ferrites Properties and Applications, U.K., London:Butterworth, 1988.

Google Scholar

G. R. Skutt, High Frequency Dimensional Effects in Ferrite-Core Magnetic Devices, Oct. 1996.

Google Scholar

F. G. Brockman, P. H. Dowling and W. G. Steneck, "Dimensional effects resulting from a high dielectric constantfound in a ferromagnetic ferrite", Phys. Rev., vol. 77, no. 1, pp. 85-93, 1950.

CrossRef Google Scholar

Datasheets and Specifications, 2004.

Google Scholar

R. Prieto, V. Bataller, J. A. Cobos and J. Uceda, "Influence of the winding strategy in toroidal transformers", Proc. Ind. Electron. Soc. Conf., vol. 1, pp. 359-364, 1998-Aug./Sep.

View Article

Google Scholar

P. N. Murgatroyd, A. K. Y. Chu, G. K. Richardson, D. West, G. A. Yearley and A. J. Spencer, "MakingRogowski coils", Meas. Sci. Techol. (2) (Design Note), pp. 1218-1219, 1991.

CrossRef Google Scholar

R. L. Stoll, "Method of measuring alternating currents without disturbingthe conducting circuit", Proc. Inst. Elect. Eng., vol. 122, no. 10, pp. 1166-1167, Oct. 1975.

CrossRef Google Scholar

10.

D. G. Pellinen and P. W. Spence, "A nanosecond risetime megampere current monitor", Rev. Sci. Instrum., vol. 42, no. 11, pp. 1699-1701, Sep. 1971.

CrossRef Google Scholar

11.

R. W. Buntenbach, "Analogs between magnetic and electrical circuits", Electron. Prod., pp. 108-113, Oct. 1969.

Google Scholar

12.

P. G. Blanken and J. J. L. M. Van Vlerken, "Modeling of electromagneticsystems", IEEE Tran. Magn., vol. 27, no. 6, pp. 4509-4515, Nov. 1991.

View Article

Google Scholar

13.

J. J. L. M. Van Vlerken and P. G. Blanken, "Lumped modeling of rotary transformersheads and electronics for helical scan", IEEE Tran. Magn., vol. 31, no. 2, pp. 1050-1055, Mar. 1995.

View Article

Google Scholar

14.

B. Cogitore, J. P. Keradec and J. Barbaroux, "The two-winding transformer: an experimentalmethod to obtain a wide frequency range equivalent circuit", IEEE Trans. Instrum. Meas., vol. 43, no. 2, pp. 364-371, Apr. 1994.

View Article

Google Scholar

15.

A. Schellmanns, P. Fouassier, J. P. Keradec and J. L. Schanen, "Equivalent circuits for transformers basedon one-dimensional propagation: accounting for multilayer structure of windingsand ferrite losses", IEEE Tran. Magn., vol. 36, no. 5, pp. 3778-3784, Sep. 2000.

View Article

Google Scholar

16.

17.

P. Wallmeier, P. Ide, J. Kunze and B. Margaritis, "Effects in magnetic componentsfor switched mode applications in the MHz range", Proc. Appl. Power Electron. Conf. Expo, vol. 2, pp. 964-970, 2004.

View Article

Google Scholar

References is not available for this document.

HF Characterization and Nonlinear Modeling of a Gapped Toroidal Magnetic Structure

Abstract:

Metadata

Abstract:

ISSN Information:

I. Introduction

References

IEEE Account

Purchase Details

Profile Information

Need Help?

HF Characterization and Nonlinear Modeling of a Gapped Toroidal Magnetic Structure

Alerts

Abstract:

Metadata

Abstract:

ISSN Information:

I. Introduction

Authors

Figures

References

Citations

Keywords

Metrics

References

IEEE Account

Purchase Details

Profile Information

Need Help?