Noise modeling and SiGe profile design tradeoffs for RF applications HBTs

Noise modeling and SiGe profile design tradeoffs for RF applications HBTs

This paper investigates SiGe profile design tradeoffs for low-noise RF applications at a given technology generation (i.e., fixed minimum feature size and thermal cycle). An intuitive model relating structural parameters and biases to noise parameters is used to identify the noise limiting factors i...

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Veröffentlicht in:IEEE transactions on electron devices 2000-01, Vol.47 (11)
Hauptverfasser: Niu, Guofu, Zhang, Shiming, Cressler, J D, Joseph, A J, Fairbanks, J S, Larson, LE, Webster, C S, Ansley, W E, Harame, D L
Format: Artikel
Sprache:eng
Schlagworte:
Constraining
Gain
Germanium
Mathematical models
Noise
Radio frequencies
Silicon germanides
Stability
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Zusammenfassung:This paper investigates SiGe profile design tradeoffs for low-noise RF applications at a given technology generation (i.e., fixed minimum feature size and thermal cycle). An intuitive model relating structural parameters and biases to noise parameters is used to identify the noise limiting factors in a given technology. The noise performance can be improved by pushing more Ge into the base and creating a larger Ge gradient in the base. To maintain the SiGe film stability, the retrograding of the Ge into the collector has to be reduced, leading to a stronger f sub(T)-I sub(C) roll-off at high injection. Two low-noise profiles were designed and fabricated explicitly for improving minimum noise figure (NF sub(min)) without sacrificing gain, linearity, frequency response, or the stability of the SiGe strained layer. A 0.2 dB NF sub(min) was achieved at 2.0 GHz with an associated gain (G sub(assoc)) of 13 dB
ISSN:0018-9383
DOI:10.1109/16.877164