Frequency stability of InP HBT over 0.2 to 220 GHz

Zhijiang Zhou; Kun Ren; Jun Liu; Wei Cheng; Haiyan Lu; Lingling Sun

doi:10.1088/1674-4926/36/2/024006

J. Semicond. > 2015, Volume 36 > Issue 2 > 024006, doi: 10.1088/1674-4926/36/2/024006

SEMICONDUCTOR DEVICES

Frequency stability of InP HBT over 0.2 to 220 GHz

Zhijiang Zhou^{1, 2}, Kun Ren^1,, Jun Liu¹, Wei Cheng², Haiyan Lu² and Lingling Sun¹

+ Author Affiliations

Corresponding author: Kun Ren, E-mail: hbrenkun@163.com

Abstract: The frequency stabilities of InP DHBTs in a broadband over 1 to 220 GHz are investigated. A hybrid π-topology small-signal model is used to accurately capture the parasitics of devices. The model parameters are extracted from measurements analytically. The investigation results show that the excellent agreement between the measured and simulated data is obtained in the frequency range 200 MHz to 220 GHz. The dominant parameters of the π-topology model, bias conditions and emitter area have significant effects on the stability factor K. The HBT model can be unconditionally stable by reasonable selection of the proper bias condition and the physical layout of the device.

Key words: double heterojunction bipolar transistor (DHBT), small-signal model, stability factor

References

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Fig. 1. InP HBT equivalent circuit. (a) Cross-section of InP DHBT physical model. (b) Hybrid $\pi$-topology small-signal equivalent circuit.

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Fig. 2. (Color online) Comparison between simulated versus measured $S$-parameters from 200 MHz to 220 GHz, at $i_{\rm b}$ $=$ 400 $\mu$A, $i_{\rm c}$ $=$ 1.5 V. (a) Imag($S_{11}$) and Imag($S_{22}$). (b) Real($S_{11}$) and Real($S_{22}$). (c) Imag($S_{21}$). (d) Real($S_{21}$).

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Fig. 3. Stability factor-$K$ versus emitter area

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Fig. 4. Stability factor-$K$ versus bias $i_{\rm b}$ $=$ 400, 600 and 800 $\mu$A.

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Fig. 5. Stability factor-$K$ versus capacitor parameters.

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Fig. 6. Stability factor-$K$ versus resistor parameters.

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Fig. 7. Stability factor-$K$ curve versus parameter $g_{\rm m}$.

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Table 1. Extracted model parameter values of an InP DHBT with one emitter finger. The width and length of the emitter finger are 6 $\mu$m and 0.5 $\mu$m, respectively.

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Received: 27 July 2014 Revised: Online: Published: 01 February 2015

The frequency stabilities of InP DHBTs in a broadband over 1 to 220 GHz are investigated. A hybrid π-topology small-signal model is used to accurately capture the parasitics of devices. The model parameters are extracted from measurements analytically. The investigation results show that the excellent agreement between the measured and simulated data is obtained in the frequency range 200 MHz to 220 GHz. The dominant parameters of the π-topology model, bias conditions and emitter area have significant effects on the stability factor K. The HBT model can be unconditionally stable by reasonable selection of the proper bias condition and the physical layout of the device.

Frequency stability of InP HBT over 0.2 to 220 GHz

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