A short survey on nonlinear models of the classic Costas loop: Rigorous derivation and limitations of the classic analysis

Best, Roland; Kuznetsov, Nikolay; Леонов, Г. А.; Yuldashev, M. V.; Yuldashev, R. V.

doi:10.1109/acc.2015.7170912

Cited by 18 publications

(14 citation statements)

References 28 publications

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“…Also the errors caused by numerical integration (e.g. in MATLAB and SPICE) can lead to unreliable results [28,29,50,51].…”

Section: Remarks On Simulation Of Bpsk Costas Loopmentioning

confidence: 99%

“…The transfer functions for the loop filter and for the VCO have been given in Eqs. (26) and (29), respectively.…”

Section: Remarks On Simulation Of Bpsk Costas Loopmentioning

confidence: 99%

“…Based on the non linear model shown in Figure 11 and in Eqs. (26), (29), and (88) we can create a differential equation for the instantaneous difference frequency ∆ω as a function of time. For this type of Costas loop the differential equation has the…”

Section: Remarks On Simulation Of Bpsk Costas Loopmentioning

confidence: 99%

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Tutorial on dynamic analysis of the Costas loop

Best¹,

Kuznetsov

Леонов

et al. 2016

Annual Reviews in Control

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Costas loop is a classical phase-locked loop (PLL) based circuit for carrier recovery and signal demodulation.The PLL is an automatic control system that adjusts the phase of a local signal to match the phase of the input reference signal. This tutorial is devoted to the dynamic analysis of the Costas loop. In particular the acquisition process is analyzed. Acquisition is most conveniently described by a number of frequency and time parameters such as lock-in range, lock-in time, pull-in range, pull-in time, and hold-in range. While for the classical PLL equations all these parameters have been derived (many of them are approximations, some even crude approximations), this has not yet been carried out for the Costas loop. It is the aim of this analysis to close this gap. The paper starts with an overview on mathematical and physical models (exact and simplified) of the different variants of the Costas loop. Then equations for the above mentioned key parameters are derived. Finally, the lock-in range of the Costas loop for the case where a lead-lag filter is used for the loop filter is analyzed.

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“…Also the errors caused by numerical integration (e.g. in MATLAB and SPICE) can lead to unreliable results [28,29,50,51].…”

Section: Remarks On Simulation Of Bpsk Costas Loopmentioning

confidence: 99%

“…The transfer functions for the loop filter and for the VCO have been given in Eqs. (26) and (29), respectively.…”

Section: Remarks On Simulation Of Bpsk Costas Loopmentioning

confidence: 99%

See 1 more Smart Citation

Tutorial on dynamic analysis of the Costas loop

Best¹,

Kuznetsov

Леонов

et al. 2016

Annual Reviews in Control

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“…By contrast, the equations of model in the signal's phase space are autonomous (Gardner, 1966;Shakhgil'dyan and Lyakhovkin, 1966;Viterbi, 1966), what simplifies the study of PLL-based circuits. The application of averaging methods (Mitropolsky and Bogolubov, 1961;Samoilenko and Petryshyn, 2004) allows one to reduce the model of PLL-based circuits in the signals space to the model in the signal's phase space (see, e.g., (Leonov et al, 2012;Leonov and Kuznetsov, 2014;Kuznetsov et al, 2015b,a;Best et al, 2015).…”

Section: Filter G(t)mentioning

confidence: 99%

Lock-in range of classical PLL with impulse signals and proportionally-integrating filter

Aleksandrov,

Kuznetsov,

Leonov

et al. 2016

Preprint

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“…The models of classical Costas loop and two-phase Costas loop in the signal's phase space can be described by relations similar to (5) (PD characteristic of the circuits usually is a π-periodic function, and the approaches presented in this paper can be applied to these circuits as well) (see, e.g., (Best et al, 2014;Best et al, 2015)).…”

mentioning

confidence: 99%

Lock-in range of PLL-based circuits with proportionally-integrating filter and sinusoidal phase detector characteristic

Aleksandrov,

Kuznetsov,

Leonov

et al. 2016

Preprint

Self Cite

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In the present work PLL-based circuits with sinusoidal phase detector characteristic and active proportionally-integrating (PI) filter are considered. The notion of lock-in range -an important characteristic of PLL-based circuits, which corresponds to the synchronization without cycle slipping, is studied. For the lock-in range a rigorous mathematical definition is discussed. Numerical and analytical estimates for the lock-in range are obtained.

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A short survey on nonlinear models of the classic Costas loop: Rigorous derivation and limitations of the classic analysis

Cited by 18 publications

References 28 publications

Tutorial on dynamic analysis of the Costas loop

Tutorial on dynamic analysis of the Costas loop

Lock-in range of classical PLL with impulse signals and proportionally-integrating filter

Lock-in range of PLL-based circuits with proportionally-integrating filter and sinusoidal phase detector characteristic

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