Michael Kalcher scite author profile

This article presents a novel digital predistortion (DPD) approach to compensate for nonlinear dynamic distortions caused by the supply network of capacitive radio frequency digital-to-analog converters (RF-DACs). The developed DPD concept recreates the voltage distortion on the RF-DAC's supply network and modulates the input signal such that the effects on the output signal of the RF-DAC are canceled. In contrast to conventional DPD approaches such as pruned Volterra series or memory polynomials, the complexity of the proposed concept is reduced to a feasible level, allowing for implementation in integrated circuits. Furthermore, the derived DPD model allows to use linear estimation algorithms for coefficient training. The presented DPD is demonstrated by measurements of two different capacitive RF-DAC designs and compared with conventional DPD approaches. EVM and adjacent channel power ratio (ACPR) can be improved by up to 6 and 7 dB, respectively, outperforming conventional approaches. Index Terms-Digital predistortion (DPD), memory effects, memory polynomial (MP), power amplifier (PA), radio frequency digital-to-analog converter (RF-DAC), switched-capacitor power amplifier (SCPA), Volterra series. I. INTRODUCTION T HE demand for high data rates, robust transmissions, and power efficiency poses stringent requirements on the design of integrated wireless transceiver systems. Increasing the data rate, while simultaneously providing a reliable and power-efficient transmission, is closely related to the linearity of the communication systems. In radio frequency (RF) wireless communication transmitters, the key component in terms of linearity and Manuscript

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1–3-GHz Self-Aligned Open-Loop Local Quadrature Phase Generator With Phase Error Below 0.4°

Kalcher

Gruber²,

Ponton³

2020

IEEE Trans. Microwave Theory Techn.

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Using a remote lab for teaching energy harvesting enhanced wireless sensor networks

Hormann

Steinberger

Kalcher

et al. 2013

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Michael Kalcher

Modeling Non-Idealities of Capacitive RF-DACs with a Switched State-Space Model

Fully-digital transmitter architectures and circuits for the next generation of wireless communications

A Circuit-Inspired Digital Predistortion of Supply Network Effects for Capacitive RF-DACs

1–3-GHz Self-Aligned Open-Loop Local Quadrature Phase Generator With Phase Error Below 0.4°

Using a remote lab for teaching energy harvesting enhanced wireless sensor networks

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