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Phase locking, oscillations and cycle slipping in synchronization systems. / Smirnova, Vera; Proskurnikov, Anton V.

2016 European Control Conference, ECC 2016. Institute of Electrical and Electronics Engineers Inc., 2017. p. 873-878 7810399.

Research output: Chapter in Book/Report/Conference proceedingConference contributionpeer-review

Harvard

Smirnova, V & Proskurnikov, AV 2017, Phase locking, oscillations and cycle slipping in synchronization systems. in 2016 European Control Conference, ECC 2016., 7810399, Institute of Electrical and Electronics Engineers Inc., pp. 873-878, European Control Conference, ECC 2016, Aalborg, Denmark, 29/06/16. https://doi.org/10.1109/ECC.2016.7810399

APA

Smirnova, V., & Proskurnikov, A. V. (2017). Phase locking, oscillations and cycle slipping in synchronization systems. In 2016 European Control Conference, ECC 2016 (pp. 873-878). [7810399] Institute of Electrical and Electronics Engineers Inc.. https://doi.org/10.1109/ECC.2016.7810399

Vancouver

Smirnova V, Proskurnikov AV. Phase locking, oscillations and cycle slipping in synchronization systems. In 2016 European Control Conference, ECC 2016. Institute of Electrical and Electronics Engineers Inc. 2017. p. 873-878. 7810399 https://doi.org/10.1109/ECC.2016.7810399

Author

Smirnova, Vera ; Proskurnikov, Anton V. / Phase locking, oscillations and cycle slipping in synchronization systems. 2016 European Control Conference, ECC 2016. Institute of Electrical and Electronics Engineers Inc., 2017. pp. 873-878

BibTeX

@inproceedings{a83c4a3b6f1d40f6a187d3fa645fee7e,
title = "Phase locking, oscillations and cycle slipping in synchronization systems",
abstract = "Many engineering applications employ nonlinear systems, representable as a feedback interconnection of a linear time-invariant dynamic block and a periodic nonlinearity. Such models naturally describe phase-locked loops (PLLs), which are widely used for synchronization of built-in computer clocks, demodulation and frequency synthesis. Other example include, but are not limited to, dynamics of pendulum-like mechanical systems, coupled vibrational units and electric machines. Systems with periodic nonlinearities, often referred to as synchronization systems, are usually featured by the existence of an infinite sequence of equilibria (stable or unstable). The central problem, concerning dynamics of synchronization systems, is the convergence of solutions to equilibria, treated in engineering applications as phase locking. In general, not any solution is convergent ('phase-locked'). This raises a natural question which oscillatory trajectories (such as e.g. periodic solutions) are possible. Even when the solution converges, the transient process can be unsatisfactory due to cycle slippings, leading to demodulation errors. In this paper, we address the mentioned three problems and offer novel criteria for phase locking, estimates for the number of slipped cycles and possible frequencies of periodic oscillations. The methods used in this paper are based on the method of integral quadratic constraints, stemming from Popov's technique of 'a priori integral indices.'",
keywords = "delay, frequency domain methods, integral equations, Nonlinear systems, oscillations, periodic nonlinearity, stability",
author = "Vera Smirnova and Proskurnikov, {Anton V.}",
year = "2017",
month = jan,
day = "6",
doi = "10.1109/ECC.2016.7810399",
language = "English",
pages = "873--878",
booktitle = "2016 European Control Conference, ECC 2016",
publisher = "Institute of Electrical and Electronics Engineers Inc.",
address = "United States",
note = "European Control Conference, ECC 2016 ; Conference date: 29-06-2016 Through 01-07-2016",

}

RIS

TY - GEN

T1 - Phase locking, oscillations and cycle slipping in synchronization systems

AU - Smirnova, Vera

AU - Proskurnikov, Anton V.

PY - 2017/1/6

Y1 - 2017/1/6

N2 - Many engineering applications employ nonlinear systems, representable as a feedback interconnection of a linear time-invariant dynamic block and a periodic nonlinearity. Such models naturally describe phase-locked loops (PLLs), which are widely used for synchronization of built-in computer clocks, demodulation and frequency synthesis. Other example include, but are not limited to, dynamics of pendulum-like mechanical systems, coupled vibrational units and electric machines. Systems with periodic nonlinearities, often referred to as synchronization systems, are usually featured by the existence of an infinite sequence of equilibria (stable or unstable). The central problem, concerning dynamics of synchronization systems, is the convergence of solutions to equilibria, treated in engineering applications as phase locking. In general, not any solution is convergent ('phase-locked'). This raises a natural question which oscillatory trajectories (such as e.g. periodic solutions) are possible. Even when the solution converges, the transient process can be unsatisfactory due to cycle slippings, leading to demodulation errors. In this paper, we address the mentioned three problems and offer novel criteria for phase locking, estimates for the number of slipped cycles and possible frequencies of periodic oscillations. The methods used in this paper are based on the method of integral quadratic constraints, stemming from Popov's technique of 'a priori integral indices.'

AB - Many engineering applications employ nonlinear systems, representable as a feedback interconnection of a linear time-invariant dynamic block and a periodic nonlinearity. Such models naturally describe phase-locked loops (PLLs), which are widely used for synchronization of built-in computer clocks, demodulation and frequency synthesis. Other example include, but are not limited to, dynamics of pendulum-like mechanical systems, coupled vibrational units and electric machines. Systems with periodic nonlinearities, often referred to as synchronization systems, are usually featured by the existence of an infinite sequence of equilibria (stable or unstable). The central problem, concerning dynamics of synchronization systems, is the convergence of solutions to equilibria, treated in engineering applications as phase locking. In general, not any solution is convergent ('phase-locked'). This raises a natural question which oscillatory trajectories (such as e.g. periodic solutions) are possible. Even when the solution converges, the transient process can be unsatisfactory due to cycle slippings, leading to demodulation errors. In this paper, we address the mentioned three problems and offer novel criteria for phase locking, estimates for the number of slipped cycles and possible frequencies of periodic oscillations. The methods used in this paper are based on the method of integral quadratic constraints, stemming from Popov's technique of 'a priori integral indices.'

KW - delay

KW - frequency domain methods

KW - integral equations

KW - Nonlinear systems

KW - oscillations

KW - periodic nonlinearity

KW - stability

UR - http://www.scopus.com/inward/record.url?scp=84988320593&partnerID=8YFLogxK

U2 - 10.1109/ECC.2016.7810399

DO - 10.1109/ECC.2016.7810399

M3 - Conference contribution

SP - 873

EP - 878

BT - 2016 European Control Conference, ECC 2016

PB - Institute of Electrical and Electronics Engineers Inc.

T2 - European Control Conference, ECC 2016

Y2 - 29 June 2016 through 1 July 2016

ER -

ID: 7629293