Journal ArticleDOI
Device physics of TRAPATT oscillators
B.C. DeLoach,D.L. Scharfetter +1 more
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TLDR
In this paper, a simplified physical model was used to describe TRAPATT (TRApped Plasma Avalanche Triggered Transit) operation, and a complete high-efficiency device design was generated and the dependence of operation on physical parameters was elucidated.Abstract:
This paper utilizes a simplified physical model to describe TRAPATT (TRApped Plasma Avalanche Triggered Transit) operation. By yielding on computational accuracy, a complete high-efficiency device design is generated and the dependence of operation on physical parameters is elucidated. The extreme complexity of the precise differential equations describing TRAPATT operation has made the calculation of a single diode-circuit configuration a tour de force. However, by observing the important features of such a solution, a simplified approach giving realistic answers has been evolved. A theoretical device design has been evolved. This design provides device width and impurity density as a function of TRAPATT frequency, and indicates a decreasing degree of "reach through" with increasing frequency. In addition, the explicit dependence of width and impurity density on the diode's reverse saturation current has been obtained. The launching of the avalanche zone through the diode, and, in particular, the limitations implicit in the recovery to a swept-out state, are of broad significance in other types of diodes, particularly p-i-n switches and "snap" diodes.read more
Citations
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Proceedings ArticleDOI
Impedance Characteristics of TRAPATT Oscillator Circuits
J.D. Welch,P.T. Greiling +1 more
TL;DR: In this paper, an accurate, closed-form analysis was developed for calculating the harmonic matching impedance required for a time-delay-triggered TRAPATT oscillator, which was obtained with experimental impedance measurements on an S-band oscillator.
Book ChapterDOI
Avalanche-Diode Microwave Oscillators, Amplifiers, and Gunn Devices
TL;DR: The frequency range from 1 to 100 GHz is the most commonly used frequency band for mmWave systems as mentioned in this paper, where the frequency bands are L band, 1.0-2.6 GHz; S band, 2.60-3.95 GHz; C band, 4.90-7.05 GHz; X band, 8.20-12.40 GHz; Ku band, 15.3-18.0 GHz; and K band, 18.0−26.50 GHz.
Journal ArticleDOI
Harmonic effects in locking and initiation of TRAPATT oscillations
R. A. Minasian,J. R. Forrest +1 more
TL;DR: Injection phase locking measurements on a pulsed S-band TRAPATT oscillator at the fundamental and third harmonic frequencies were reported in this article, which indicated that the start of the oscillation pulse is associated with X-band frequencies, which lie in the IMPATT range for the diode, and that jitter arises in the transition to the TAPATT mode.
References
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Journal ArticleDOI
High-power, high-efficiency silicon avalanche diodes at ultra high frequencies
TL;DR: Silicon avalanche diodes with a pnn+mesa structure were made according to suitably chosen design parameters, and carefully fabricated to meet stringent pedormance specifications, operating under pulse conditions with a duty factor of approximately 10-3, efficiencies as high as 25 percent, and power outputs up to 435 watts at 425 megahertz as discussed by the authors.
Journal ArticleDOI
High-efficiency oscillations in germanium avalanche diodes below the transit-time frequency
TL;DR: In this paper, computer simulation of diode and circuit behavior has provided an explanation for the observed results of the Ge avalanche diodes at frequencies of 2-3 GHz at 2.5 GHz.
Journal ArticleDOI
Negative resistance and filamentary currents in avalanching silicon p + -i-n + junctions
M.W. Muller,H. Guckel +1 more
TL;DR: In this paper, a steady state can be found in which the generation of carriers in the filament by impact ionization is balanced by radial diffusion of carriers, and the total filament current is a decreasing function of the applied voltage.
Journal ArticleDOI
High-efficiency CW impatt operation
D.E. Iglesias,W.J. Evans +1 more
TL;DR: In this paper, room-temperature operation of Ge Impatt diodes with efficiencies as high as 43 percent in the 400 to 1000 MHz frequency range has been achieved.
Journal ArticleDOI
AVALANCHE SHOCK FRONTS IN p‐n JUNCTIONS
TL;DR: In this article, a new transient mode of avalanche breakdown in p−n junctions is described. And an approximate analysis is given, and compared with numerical calculations, in order to interpret the observed high efficiency microwave oscillations of the trapped plasmas ''TRAPATT'' mode.