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A Fast-Locking PLL Using Low-Power Cycle Slippage Compensation and Accumulated Phase Error Correctionopen access

Authors
Huynh, Phuoc B. T.Lee, Gyeong-SeokYun, Tae-Yeoul
Issue Date
May-2026
Publisher
Multidisciplinary Digital Publishing Institute (MDPI)
Keywords
finite state machine (FSM); low-power consumption; phase error correction; phase frequency detector (PFD); phase-locked loop
Citation
Electronics (Switzerland), v.15, no.10, pp 1 - 18
Pages
18
Indexed
SCIE
SCOPUS
Journal Title
Electronics (Switzerland)
Volume
15
Number
10
Start Page
1
End Page
18
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/213308
DOI
10.3390/electronics15101999
ISSN
2079-9292
2079-9292
Abstract
This article presents a fast-locking phase-locked loop (PLL) that incorporates a low-power extended phase frequency detector (LPEPFD) and a discriminator-aided phase detector (DAPD) to simultaneously address cycle slippage and frequency overshoot issues during frequency and phase acquisition, respectively. Specifically, the proposed LPEPFD introduces a novel finite state machine architecture that extends the linear range of a conventional PFD without requiring a power-hungry counter, thereby eliminating cycle slippage and reducing the time required for frequency acquisition while maintaining switching activity and power consumption comparable to those of the conventional design. Moreover, after frequency convergence, the DAPD quantizes the accumulated phase error, which is corrected by adaptively tuning the programmable delay lines without causing significant frequency overshoot seen in conventional PLLs, resulting in improved settling time. Fabricated using a 28 nm complementary metal oxide semiconductor (CMOS) process, the proposed fast-locking PLL occupies an area of 0.36 mm2 and operates over a frequency range of 2.6 to 3.2 GHz. Experimental results demonstrate a 0.84-μs settling time for a frequency hop from 2.6 to 3.1 GHz. The designed PLL consumes 5.6 mW of power from a supply of 1 V with an integral root-mean-square jitter of 1.27 ps from 1 kHz to 100 MHz.
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