Piet Wambacq

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Kansas State University

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UNL - New University of Lisbon

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Dublin Institute of Technology

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Nepal College of Information Technology

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Graduate Center of the City University of New York

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University of Technology Sydney

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Eötvös Loránd University

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Ataturk University

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Dokuz Eylül University

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Symbolic simulation of harmonic distortion in analog integrated circuits with weak nonlinearities

A method for the symbolic calculation of harmonic distortion in weakly nonlinear, continuous-time... more A method for the symbolic calculation of harmonic distortion in weakly nonlinear, continuous-time analog integrated circuits is presented. The method is based upon a simplified approach to Volterra series in the frequency domain. It is built into an already existing symbolic simulator for linear characteristics of analog circuit, called ISAAC. Symbolic expressions for the second and third harmonic and for the harmonic distortion are generated as a function of the fundamental frequency and the symbolic circuit parameters. For large circuits, simplified expressions are derived using an approximation method. In this way, the major contributions to the harmonic distortion can be identified, providing insight into the nonlinear behavior of analog circuits

Compact modeling of nonlinear distortion in analog communication circuits

The design of analog front-ends of digital telecommunication transceivers requires simulations at... more The design of analog front-ends of digital telecommunication transceivers requires simulations at the architectural level. The nonlinear nature of the analog front-end blocks is a complication for their modeling at the architectural level, especially when the nonlinear behavior is frequency dependent. This paper describes a method to derive a bottom-up model of nonlinear analog continuous-time circuits used in communication systems. The models take into account frequency dependence of the nonlinear behavior, making them suitable for wideband applications. Such model consists of a block diagram that corresponds to the most important contributions to the second- and third-order Volterra kernels of the output quantity (voltage or current) of a circuit. The examples in this paper, a high-level model of a CMOS low-noise amplifier and an active lowpass filter, demonstrate that the generated models can be efficiently evaluated in high-level dataflow-type simulations of mixed-signal front-ends and that they yield insight in the nonlinear behavior of the analog front-end blocks

An ultra-wideband body area propagation channel Model-from statistics to implementation

IEEE Transactions on Microwave Theory and Techniques, 2006

... the size and profile requirements typical of body worn sensor devices [2 ... Donnay, and P. D... more

A Mixed-Signal Design Roadmap

IEEE Design & Test of Computers, 2001

The article presents a roadmap for the 2001 International Technology Roadmap for Semiconductors. ... more The article presents a roadmap for the 2001 International Technology Roadmap for Semiconductors. It uses performance figures of merit (FoMs) derived from basic circuits critical to mixed-signal design performance. Extrapolations from the FoMs to future performance values establish the device parameters necessary for design progress

An ESD-Protected DC-to-6GHz 9.7mW LNA in 90nm Digital CMOS

A 50times35mum2 DC-to-6GHz LNA is designed in a digital 90nm CMOS process. It draws 8.1 mA from a... more A 50times35mum2 DC-to-6GHz LNA is designed in a digital 90nm CMOS process. It draws 8.1 mA from a 1.2V supply and achieves a minimum NF of 2.8dB and 17dB of gain. In the 6GHz bandwidth, S11 is below -10dB and the IIP3 varies between -16 and -7dBm. ESD protection of 3.2kV HBM is implemented, as well as an optional second stage with gain selection adding up to 4dB of gain

Efficient symbolic computation of approximated small-signal characteristics

A symbolic analysis tool is presented that generates approximate symbolic expressions for the sma... more A symbolic analysis tool is presented that generates approximate symbolic expressions for the small-signal characteristics of large analog integrated circuits. The expressions are approximated while they are computed, so that only those terms are generated which remain in the final expression. This principle causes drastic savings in CPU time and memory, largely increasing the maximum size of circuits that can be analyzed. By taking into account a range for the value of a circuit parameter rather than one single number, the generated expressions are generally valid. Mismatch handling is explicitly taken into account in the new algorithm. The capabilities of the new tool are illustrated with several experimental results

Piet Wambacq

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