Network analyzers from small signal to large signal measurements

AbstractIn this paper, we report the analysis, design, and implementation of stacked transistors for power amplifiers realized on InP Double Heterojunction Bipolar Transistors (DHBTs) technology. A theoretical analysis based on the interstage matching between all the single transistors has been developed starting from the small-signal equivalent circuit. The analysis has been extended by including large-signal effects and layout-related limitations. An evaluation of the maximum number of transistors for positive incremental power and gain is also carried out. To validate the analysis, E-band three- and four-stacked InP DHBT matched power cells have been realized for the first time as monolithic microwave integrated circuits (MMICs). For the three-stacked transistor, a small-signal gain of 8.3 dB, a saturated output power of 15 dBm, and a peak power added efficiency (PAE) of 5.2% have been obtained at 81 GHz. At the same frequency, the four-stacked transistor achieves a small-signal gain of 11.5 dB, a saturated output power of 14.9 dBm and a peak PAE of 3.8%. A four-way combined three-stacked MMIC power amplifier has been implemented as well. It exhibits a linear gain of 8.1 dB, a saturated output power higher than 18 dBm, and a PAE higher than 3% at 84 GHz.

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Large Signal and Small Signal Building Blocks for Cellular Infrastructure

Low Power Emerging Wireless Technologies ◽

10.1201/b13870-7 ◽

2017 ◽

pp. 169-187

Author(s):

Mustafa Acar ◽

Jos Bergervoet ◽

Mark van der Heijden ◽

Domine Leenaerts ◽

Stefan Drude

Keyword(s):

Building Blocks ◽

Small Signal ◽

Large Signal

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Modeling and Control of Double-Sided LCC Compensation Topology with Semi-Bridgeless Active Rectifier for Inductive Power Transfer System

Energies ◽

10.3390/en12203921 ◽

2019 ◽

Vol 12 (20) ◽

pp. 3921

Author(s):

Cha ◽

Kim ◽

Park ◽

Choi

Keyword(s):

Steady State ◽

Equivalent Circuit ◽

Small Signal ◽

Power Transfer ◽

Large Signal ◽

Signal Model ◽

Worst Case ◽

Inductive Power Transfer ◽

Active Rectifier ◽

Inductive Power

This paper proposes the modeling and design of a controller for an inductive power transfer (IPT) system with a semi-bridgeless active rectifier (S-BAR). This system consists of a double-sided Inductor-Capacitor-Capacitor (LCC) compensation network and an S-BAR, and maintains a constant output voltage under load variation through the operation of the rectifier switches. Accurate modeling is essential to design a controller with good performance. However, most of the researches on S-BAR have focused on the control scheme for the rectifier switches and steady-state analysis. Therefore, modeling based on the extended describing function is proposed for an accurate dynamic analysis of an IPT system with an S-BAR. Detailed mathematical analyses of the large-signal model, steady-state operating solution, and small-signal model are provided. Nonlinear large-signal equivalent circuit and linearized small-signal equivalent circuit are presented for intuitive understanding. In addition, worst case condition is selected under various load conditions and a controller design process is provided. To demonstrate the effectiveness of the proposed modeling, experimental results using a 100 W prototype are presented.

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A Non-Quasi-Static, Relaxation-Time Small-Signal HEMT Model Compatible with Large-Signal Modeling

2006 European Microwave Integrated Circuits Conference ◽

10.1109/emicc.2006.282663 ◽

2006 ◽

Cited By ~ 1

Author(s):

Wolfram Stiebler

Keyword(s):

Relaxation Time ◽

Small Signal ◽

Signal Modeling ◽

Large Signal ◽

Static Relaxation

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Small-signal and large-signal noise analyses of nonlinear circuits in frequency domain

2001 Microwave Electronics: Measurement, Identification, Applications. Conference Proceedings. MEMIA'2001 (Cat. No.01EX474) ◽

10.1109/memia.2001.982313 ◽

2002 ◽

Author(s):

S.V. Troushin

Keyword(s):

Frequency Domain ◽

Nonlinear Circuits ◽

Small Signal ◽

Large Signal ◽

Signal Noise

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A New Method to Extract Gate Bias-Dependent Parasitic Resistances in GaAs pHEMTs

Electronics ◽

10.3390/electronics8030266 ◽

2019 ◽

Vol 8 (3) ◽

pp. 266

Author(s):

Ruirui Dang ◽

Lijie Yang ◽

Zhihao Lv ◽

Chunyi Song ◽

Zhiwei Xu

Keyword(s):

Parameter Extraction ◽

New Method ◽

Small Signal ◽

Gate Bias ◽

Large Signal ◽

S Parameter ◽

Proposed Model ◽

Measurement Results ◽

Parasitic Parameter ◽

Signal Models

Accurate large signal GaAs pHEMT models are essential for devices’ performance analysis and microwave circuit design. This, in turn, mandates precise small signal models. However, the accuracy of small signal models strongly depends on reliable parasitic parameter extraction of GaAs pHEMT, which also greatly influences the extraction of intrinsic elements. Specifically, the parasitic source and drain resistances, R s and R d , are gate bias-dependent, due to the two-dimensional charge variations. In this paper, we propose a new method to extract R s and R d directly from S-parameter measurements of the device under test (DUT), which save excessive measurements and complicated parameter extraction. We have validated the proposed method in both simulation and on-wafer measurement, which achieves better accuracy than the existing state-of-the-art in a frequency range of 0.5–40 GHz. Furthermore, we develop a GaAs pHEMT power amplifier (PA) to further validate the developed model. The measurement results of the PA at 9–15 GHz agree with the simulation results using the proposed model.

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Unusual Response of Thin LiTaO3 Films to Intense Microwave Pulses

Materials ◽

10.3390/ma12213588 ◽

2019 ◽

Vol 12 (21) ◽

pp. 3588

Author(s):

Haojia Chen ◽

Qiong Gao ◽

Baoliang Qian ◽

Lishan Zhao

Keyword(s):

Nonlinear Behaviour ◽

Small Signal ◽

Large Signal ◽

Signal Model ◽

Small Signal Model ◽

Wide Range ◽

Microwave Pulses ◽

Intense Fields ◽

Voltage Signal ◽

Wave Sensors

Fundamentally different responses of a LiTaO 3 thin film detector are observed when it is subjected to short microwave pulses as the pulse intensity is altered over a wide range. We start from weak microwave pulses which lead to only trivial pyroelectric peak response. However, when the microwave pulses become intense, the normally expected pyroelectric signal seems to be suppressed and the sign of the voltage signal can even be completely changed. Analysis indicates that while the traditional pyroelectric model, which is a linear model and works fine for our data in the small regime, it does not work anymore in the large signal regime. Since the small-signal model is the key foundation of electromagnetic-wave sensors based on pyroelectric effects, such as pyroelectric infrared detecters, the observation in this work suggests that one should be cautious when using these devices in intense fields. In addition, the evolution of detector signal with respect to excitation strength suggests that the main polarisation process is changed in the large signal regime. This is of fundamental importance to the understanding on how crystalline solids interact with intense microwaves. Possible causes of the nonlinear behaviour is discussed.

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