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Author Fengming Zhang ♦ Lee, Y.J. ♦ Kane, T. ♦ Schiano, L. ♦ Momenzadeh, M. ♦ Kim, Y.-B. ♦ Meyer, F.J. ♦ Lombardi, F. ♦ Max, S. ♦ Perkinson, P.
Sponsorship IEEE Comput. Soc. Test Technol. Tech. Council ♦ IEEE Comput. Soc. Tech. Committee on Fault-Tolerant Comput
Source IEEE Xplore Digital Library
Content type Text
Publisher Institute of Electrical and Electronics Engineers, Inc. (IEEE)
File Format PDF
Copyright Year ©2003
Language English
Subject Domain (in DDC) Natural sciences & mathematics ♦ Physics ♦ Electricity & electronics ♦ Technology ♦ Engineering & allied operations ♦ Applied physics
Subject Keyword Bandwidth ♦ Power generation ♦ Automatic test equipment ♦ Solenoids ♦ Driver circuits ♦ Voltage ♦ Switches ♦ Predictive models ♦ Timing jitter ♦ Design methodology
Abstract Recent research on modeling timing jitter has raised a requirement for a predictable, high magnitude, uniform, and wide bandwidth H-field. In this paper, a novel H-field generator design methodology is proposed. It consists of a single layer air core solenoid and a digital power switch driver that takes advantage of low power, wide bandwidth, and big current-driven capability. With input overdrive voltage, the digital switch can drive rail-to-rail voltage with output current up to 16 A and power bandwidth more than 3 MHz. This paper demonstrates a novel solenoid driver circuit to generate an accurate H-field by comparing digital and analog approaches and comparing the experimental data with the theoretical data.
Description Author affiliation: Dept. of Electr. & Comput. Eng., Northeastern Univ., Boston, MA, USA (Fengming Zhang; Lee, Y.J.)
ISBN 0769520421
ISSN 15505774
Educational Role Student ♦ Teacher
Age Range above 22 year
Educational Use Research ♦ Reading
Education Level UG and PG
Learning Resource Type Article
Publisher Date 2003-11-05
Publisher Place USA
Rights Holder Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Size (in Bytes) 251.31 kB
Page Count 8
Starting Page 159
Ending Page 166


Source: IEEE Xplore Digital Library