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Spur Analysis and Linearity Enhancement in Fractional-N Phase Locked Loops Through Parallel Sigma–Delta Modulators With Time Offsets

Holmstedt, Johan LU and Sjöland, Henrik LU orcid (2026) In IEEE Open Journal of Circuits and Systems 7. p.21-32
Abstract

This article presents a theoretical framework for deriving simple analytical expressions for spurs resulting from second and third order nonlinearities in fractional-N phase locked loops (PLL). Furthermore, a previously proposed linearization technique where several sigma-delta modulators (SDMs) operate in parallel with relative time offsets between them, is further analyzed using the periodic nonlinearity noise (PNN) framework. Closed form expressions are derived for the spur components associated with second and third order nonlinearities, as well as for the expected suppression achieved by the linearization technique depending on the number of SDMs used. In particular, the effect of the accompanying phase rotation introduced by... (More)

This article presents a theoretical framework for deriving simple analytical expressions for spurs resulting from second and third order nonlinearities in fractional-N phase locked loops (PLL). Furthermore, a previously proposed linearization technique where several sigma-delta modulators (SDMs) operate in parallel with relative time offsets between them, is further analyzed using the periodic nonlinearity noise (PNN) framework. Closed form expressions are derived for the spur components associated with second and third order nonlinearities, as well as for the expected suppression achieved by the linearization technique depending on the number of SDMs used. In particular, the effect of the accompanying phase rotation introduced by time-offsetting the SDMs is investigated under two conditions: one in which the phase rotation is compensated, and another in which it is left uncompensated. The analysis shows that effective suppression of third order nonlinearities requires compensating for this phase rotation. However, the suppression of second order nonlinearities remains largely insensitive to phase alignment, demonstrating robustness of the technique to phase offsets in that case. In addition, the quantization-noise interaction between the different parallel SDM paths is examined and characterized through simulations. The results demonstrate that the technique significantly improves linearity while also suppressing quantization noise from the SDM. Finally, an efficient hardware implementation is proposed.

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author
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organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
fractional spur, fractional-N, frequency synthesizer, linearization, non-linearity, phase detector (PD), Phase-locked loop (PLL)
in
IEEE Open Journal of Circuits and Systems
volume
7
pages
12 pages
publisher
IEEE - Institute of Electrical and Electronics Engineers Inc.
external identifiers
  • scopus:105028426299
ISSN
2644-1225
DOI
10.1109/OJCAS.2026.3655136
language
English
LU publication?
yes
additional info
Publisher Copyright: © 2020 IEEE.
id
abdc19f9-b3a8-4e7b-ae1d-febe281a9675
date added to LUP
2026-02-23 17:05:28
date last changed
2026-02-23 17:06:10
@article{abdc19f9-b3a8-4e7b-ae1d-febe281a9675,
  abstract     = {{<p>This article presents a theoretical framework for deriving simple analytical expressions for spurs resulting from second and third order nonlinearities in fractional-N phase locked loops (PLL). Furthermore, a previously proposed linearization technique where several sigma-delta modulators (SDMs) operate in parallel with relative time offsets between them, is further analyzed using the periodic nonlinearity noise (PNN) framework. Closed form expressions are derived for the spur components associated with second and third order nonlinearities, as well as for the expected suppression achieved by the linearization technique depending on the number of SDMs used. In particular, the effect of the accompanying phase rotation introduced by time-offsetting the SDMs is investigated under two conditions: one in which the phase rotation is compensated, and another in which it is left uncompensated. The analysis shows that effective suppression of third order nonlinearities requires compensating for this phase rotation. However, the suppression of second order nonlinearities remains largely insensitive to phase alignment, demonstrating robustness of the technique to phase offsets in that case. In addition, the quantization-noise interaction between the different parallel SDM paths is examined and characterized through simulations. The results demonstrate that the technique significantly improves linearity while also suppressing quantization noise from the SDM. Finally, an efficient hardware implementation is proposed.</p>}},
  author       = {{Holmstedt, Johan and Sjöland, Henrik}},
  issn         = {{2644-1225}},
  keywords     = {{fractional spur; fractional-N; frequency synthesizer; linearization; non-linearity; phase detector (PD); Phase-locked loop (PLL)}},
  language     = {{eng}},
  pages        = {{21--32}},
  publisher    = {{IEEE - Institute of Electrical and Electronics Engineers Inc.}},
  series       = {{IEEE Open Journal of Circuits and Systems}},
  title        = {{Spur Analysis and Linearity Enhancement in Fractional-N Phase Locked Loops Through Parallel Sigma–Delta Modulators With Time Offsets}},
  url          = {{http://dx.doi.org/10.1109/OJCAS.2026.3655136}},
  doi          = {{10.1109/OJCAS.2026.3655136}},
  volume       = {{7}},
  year         = {{2026}},
}