Title :
A Bounded and Discretized Nelder-Mead Algorithm Suitable for RFIC Calibration
Author :
Wyers, E.J. ; Steer, Michael B. ; Kelley, C.T. ; Franzon, Paul D.
Author_Institution :
Dept. of Electr. & Comput. Eng., North Carolina State Univ., Raleigh, NC, USA
Abstract :
This paper describes a calibration technique for noisy and nonconvex circuit responses based on the Nelder-Mead direct search algorithm. As Nelder-Mead is intended for unconstrained optimization problems, we present an implementation of the algorithm which is suitable for bounded and discretized RFIC calibration problems. We apply the proposed algorithm to the problem of spurious tone reduction via VCO control line ripple minimization for a PLL operating at a frequency of 12 GHz. For this nonconvex calibration test case, we show that a gradient descent-based algorithm has difficulty in reducing the VCO control line ripple, while the proposed algorithm reduces the relative power of the first harmonic reference spurs by at least 10 dBc and effectively enables design complexity reduction in the supporting analog calibration circuitry.
Keywords :
calibration; circuit complexity; circuit optimisation; gradient methods; integrated circuit noise; radiofrequency integrated circuits; search problems; voltage-controlled oscillators; Nelder-Mead direct search algorithm; PLL; VCO control line ripple minimization; analog calibration circuitry; bounded Nelder-Mead algorithm; bounded RFIC calibration problem; complexity reduction; discretized Nelder-Mead algorithm; discretized RFIC calibration problem; frequency 12 GHz; gradient descent-based algorithm; harmonic reference spur; noisy circuit response; nonconvex calibration test case; nonconvex circuit responses; tone reduction; unconstrained optimization; Calibration; Nelder-Mead direct search algorithm; PLL spurious tone reduction; derivative-free optimization; radio frequency integrated circuit calibration;
Journal_Title :
Circuits and Systems I: Regular Papers, IEEE Transactions on
DOI :
10.1109/TCSI.2012.2230496
