Polynomial noise modeling of silicon‐based GaN HEMTs

Colangeli, Sergio; Bentini, Andrea; Ciccognani, Walter; Limiti, Ernesto

doi:10.1002/jnm.1907

Cited by 19 publications

(23 citation statements)

References 35 publications

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“…3(g) is (7) where the skin effect is taken into account with (8) Analogously to (2), and can be extracted by a linear regression of the real part of on the FW-EM simulation data of region (III), (9) while can be determined by mean (10) where the mean value is calculated over the whole frequency range.…”

Section: B Via-hole Parameter Extractionmentioning

confidence: 99%

GaN HEMT Noise Model Based on Electromagnetic Simulations

Nalli

Raffo

Crupi

et al. 2015

IEEE Trans. Microwave Theory Techn.

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This paper presents a new approach for the definition and identification of a transistor model suitable for low-noise amplifier (LNA) design. The resulting model is very robust to layout modifications (i.e., source degeneration) providing accurate predictions of device noise-performance and small-signal parameters. Moreover, the described procedure is very robust since it does not require any numerical optimization, with possibly related problems like local minima and unphysical model parameters. The adopted model topology is based on a lumped element parasitic network and a black-box intrinsic device, which are both identified on the basis of full-wave lectromagnetic simulations, as well as noise and -parameter measurements. The procedure has been applied to three GaN HEMTs having different peripheries and a Ku-band LNA has been designed, demonstrating a very good agreement between measurements and predicted results

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Section: B Via-hole Parameter Extractionmentioning

confidence: 99%

GaN HEMT Noise Model Based on Electromagnetic Simulations

Nalli

Raffo

Crupi

et al. 2015

IEEE Trans. Microwave Theory Techn.

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“…This link often is established via modeling and simulation (M&S), which enables the prediction of device performance in real-world circuits operating under tight accuracy constraints. M&S often allows for a characterization of the worst-case performance of noiseimpacted circuits without the need to account for excessively conservative safety margins or engage in costly iterative design approaches [15][16][17][18][19][20][21][22].The goal of this special issue is to assemble recent results and up-to-date surveys addressing the topic of modeling, simulation, and characterization of noise processes in advanced GaAs, GaN, Si, and SiGe devices, ranging from the low-frequency regime to millimeter wave frequencies. A total of 14 refereed papers (including this editorial) comprising 4 invited and 10 contributed papers are included in this special issue:…”

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confidence: 99%

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confidence: 99%

Guest editorial for the special issue on noise modeling of high‐frequency semiconductor devices

Caddemi

Limiti

2015

Int J Numerical Modelling

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Noise processes in active solid-state devices govern their fundamental operational limits when high sensitivity is required or tight accuracy constraints are in play [1][2][3][4]. Moreover, noise generated in devices often is considered a measure of their quality and reliability.Complex noise processes are inherent to any semiconductor material [5][6][7]. That said, a deep knowledge of the underlying physics often is not required to accomplish the accurate design of a low-noise circuit. What is needed is a clear link between parameters governing microscopic noise processes and macroscopic behavior [8][9][10][11][12][13][14]. This link often is established via modeling and simulation (M&S), which enables the prediction of device performance in real-world circuits operating under tight accuracy constraints. M&S often allows for a characterization of the worst-case performance of noiseimpacted circuits without the need to account for excessively conservative safety margins or engage in costly iterative design approaches [15][16][17][18][19][20][21][22].The goal of this special issue is to assemble recent results and up-to-date surveys addressing the topic of modeling, simulation, and characterization of noise processes in advanced GaAs, GaN, Si, and SiGe devices, ranging from the low-frequency regime to millimeter wave frequencies. A total of 14 refereed papers (including this editorial) comprising 4 invited and 10 contributed papers are included in this special issue:➢ Balestra F, Ghibaudo G, Jomaah J. Modeling of low-frequency noise in advanced CMOS devices.Invited paper. ➢ Randa J. Numerical modeling and uncertainty analysis of transistor noise parameter measurements. Invited paper. ➢ Yu P, Chen B, Gao J. Microwave noise modeling for MOSFETs. Invited paper. ➢ Boglione L. A novel theoretical analysis for the determination of the noise parameters applicable to millimeter-wave frequencies. Invited paper. ➢ Bonani F, Donati Guerrieri S, Ghione G. Cyclostationary noise modeling of radio frequency devices. It is worth noting that our Call for Papers resulted in a geographically balanced contribution of papers, demonstrating a widespread and timely interest by the international research community in the topic. INTERNATIONAL JOURNAL OF NUMERICAL MODELLING: ELECTRONIC NETWORKS, DEVICES AND FIELDSInt. J. Numer. Model. 2015; 28:611-612 Published online 25 August 2015 in Wiley Online Library (wileyonlinelibrary.com).

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Section: Introductionmentioning

confidence: 99%

“…Many noise models have been reported in the literature: the wellknown Fukui's model [6], the equivalent noise temperature model by Pospieszalski [7] and the flicker noise model for HEMTs [8]. Many approaches on HEMT's noise parameters characterization ware investigated [9][10][11].In 1974, R.A. Pucel proposed a charge control based approach for a noise model in FET devices, the model is known as the PRC noise model [12]. Later in 1988, the model was used for HEMT devices in [13] and later improved by Zhi [14] where they included, in the PRC model, the temperature coefficients in order to calculate precise noise parameters for HEMTs.…”

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confidence: 99%

Noise Characterization in InAlAs/InGaAs/InP pHEMTs for Low Noise Applications

Djennati

Ghaffour

2017

IJECE

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In this paper, a noise revision of an InAlAs/InGaAs/InP psoeudomorphic high electron mobility transistor (pHEMT) in presented. The noise performances of the device were predicted over a range of frequencies from 1GHz to 100GHz. The minimum noise figure (NFmin), the noise resistance (Rn) and optimum source impedance (Zopt) were extracted using two approaches. A physical model that includes diffusion noise and G-R noise models and an analytical model based on an improved PRC noise model that considers the feedback capacitance Cgd. The two approaches presented matched results allowing a good prediction of the noise behaviour. The pHEMT was used to design a single stage S-band low noise amplifier (LNA). The LNA demonstrated a gain of 12.6dB with a return loss coefficient of 2.6dB at the input and greater than -7dB in the output and an overall noise figure less than 1dB. Keyword:InAlAs INTRODUCTIONThe InAlAs/InGaAs/InP psoeudomorphic high electron mobility transistors (pHEMT) have exhibited excellent performances in terms of noise figure compared to MOSFET devices at RF and microwave fields [1]. In addition, they are mostly used in the design of low noise amplifiers [2-4] and proven to be more advantageous that the AlGaAs/InGaAs pHEMTs [5].Advanced circuit design that uses pHEMT, needs precise and accurate noise models, especially for their application in low noise MMIC. Many noise models have been reported in the literature: the wellknown Fukui's model [6], the equivalent noise temperature model by Pospieszalski [7] and the flicker noise model for HEMTs [8]. Many approaches on HEMT's noise parameters characterization ware investigated [9][10][11].In 1974, R.A. Pucel proposed a charge control based approach for a noise model in FET devices, the model is known as the PRC noise model [12]. Later in 1988, the model was used for HEMT devices in [13] and later improved by Zhi [14] where they included, in the PRC model, the temperature coefficients in order to calculate precise noise parameters for HEMTs.In this paper, we try to predict the noise performances at high frequency of an InAlAs/InGaAs/InP pHEMT by extracting the basic noise parameters using two approaches: a physical modelling and a mathematical modelling. This work is organized as follow: first, we discuss the different sources of noise in the pHEMT devices. Then, we make use of ATLAS from SILVACO TCAD suit, to simulate the noise behavior of a fabricated InAlAs/InGaAs/InP 250 nm gate length pHEMT. Next, we describe the analytical model based on the 2-port small-signal equivalent circuit of the device mentioned before and we calculate the

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Polynomial noise modeling of silicon‐based GaN HEMTs

Cited by 19 publications

References 35 publications

GaN HEMT Noise Model Based on Electromagnetic Simulations

GaN HEMT Noise Model Based on Electromagnetic Simulations

Guest editorial for the special issue on noise modeling of high‐frequency semiconductor devices

Noise Characterization in InAlAs/InGaAs/InP pHEMTs for Low Noise Applications

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