• Title/Summary/Keyword: DLL(Delay Lock Loop)

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Wide Range Analog Dual-Loop Delay-Locked Loop (광대역 아날로그 이중 루프 Delay-Locked Loop)

  • Lee, Seok-Ho;Kim, Sam-Dong;Hwang, In-Seok
    • Journal of the Institute of Electronics Engineers of Korea SC
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    • v.44 no.1
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    • pp.74-84
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    • 2007
  • This paper presents a new dual-loop Delay Locked Loop(DLL) to expand the delay lock range of a conventional DLL. The proposed dual-loop DLL contains a Coarse_loop and a Fine_loop, and its operation utilizes one of the loops selected by comparing the initial time-difference among the reference clock and 2 internal clocks. The 2 internal clock signals are taken, respectively, at the midpoint and endpoint of a VCDL and thus are $180^{\circ}$ separated in phase. When the proposed DLL is out of the conventional lock range, the Coarse_loop is selected to push the DLL in the conventional lock range and then the Fine_loop is used to complete the locking process. Therefore, the proposed DLL is always stably locked in unless it is harmonically false-locked. Since the VCDL employed in the proposed DLL needs two control voltages to adjust the delay time, it uses TG-based inverters, instead of conventional, multi-stacked, current-starved inverters, to compose the delay line. The new VCDL provides a wider delay range than a conventional VCDL In overall, the proposed DLL demonstrates a more than 2 times wider lock range than a conventional DLL. The proposed DLL circuits have been designed, simulated and proved using 0.18um, 1.8V TSMC CMOS library and its operation frequency range is 100MHz${\sim}$1GHz. Finally, the maximum phase error of the DLL locked in at 1GHz is less than 11.2ps showing a high resolution and the simulated power consumption is 11.5mW.

An Anti-Boundary Switching Digital Delay-Locked Loop (안티-바운드리 스위칭 디지털 지연고정루프)

  • Yoon, Junsub;Kim, Jongsun
    • Journal of IKEEE
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    • v.21 no.4
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    • pp.416-419
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    • 2017
  • In this paper, we propose a new digital delay-locked loop (DLL) for high-speed DDR3/DDR4 SDRAMs. The proposed digital DLL adopts a fine delay line using phase interpolation to eliminate the jitter increase problem due to the boundary switching problem. In addition, the proposed digital DLL utilizes a new gradual search algorithm to eliminate the harmonic lock problem. The proposed digital DLL is designed with a 1.1 V, 38-nm CMOS DRAM process and has a frequency operating range of 0.25-2.0 GHz. It has a peak-to-peak jitter of 1.1 ps at 2.0 GHz and has a power consumption of about 13 mW.

Performance Analysis of Extended n-$\Delta$ Dely-Lock Loops (n-$\Delta$ Delay-Lock Loops의 성능 해석)

  • Ryu, Seung-Mun;Eun, Jung-Gwan;Kim, Jae-Gyun
    • Journal of the Korean Institute of Telematics and Electronics
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    • v.18 no.1
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    • pp.16-24
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    • 1981
  • The delay-lock loop (DLL) is a statistically optimum device for tracking the de]ay difference between two correlated waveforms. In this paper an extended n - $\Delta$ (n=1,2,3‥‥) DLL is described, and its baseband performance including the frequency to lose lock is analyzed. The present DLL system employs a correlator and a pseudonoise sequence synthesizer that has been improved from the previously used ones The shape of the correlator characterigtic has the form of expanded S-curve. Despite of increase noise, this extended DLL has desirable characteristics in tracking range and initial synchronization time. Comparing a 3 - $\Delta$ DLL with a 1 - A DLL, the former Bives three times faster initial synchronization time with the serial synchronization method, and gives two times immunity against doppler shift.

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A 500 MHz-to-1.2 GHz Reset Free Delay Locked Loop for Memory Controller with Hysteresis Coarse Lock Detector

  • Chi, Han-Kyu;Hwang, Moon-Sang;Yoo, Byoung-Joo;Choe, Won-Jun;Kim, Tae-Ho;Moon, Yong-Sam;Jeong, Deog-Kyoon
    • JSTS:Journal of Semiconductor Technology and Science
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    • v.11 no.2
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    • pp.73-79
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    • 2011
  • This paper describes a reset-free delay-locked loop (DLL) for a memory controller application, with the aid of a hysteresis coarse lock detector. The coarse lock loop in the proposed DLL adjusts the delay between input and output clock within the pull-in range of the main loop phase detector. In addition, it monitors the main loop's lock status by dividing the input clock and counting its multiphase edges. Moreover, by using hysteresis, it controls the coarse lock range, thus reduces jitter. The proposed DLL neither suffers from harmonic lock and stuck problems nor needs an external reset or start-up signal. In a 0.13-${\mu}m$ CMOS process, post-layout simulation demonstrates that, even with a switching supply noise, the peak-to-peak jitter is less than 30 ps over the operating range of 500-1200 MHz. It occupies 0.04 $mm^2$ and dissipates 16.6 mW at 1.2 GHz.

Fast Lock-Acquisition DLL by the Lock Detection (Lock detector를 사용하여 빠른 locking 시간을 갖는 DLL)

  • 조용기;이지행;진수종;이주애;김대정;민경식;김동명
    • Proceedings of the IEEK Conference
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    • 2003.07b
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    • pp.963-966
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    • 2003
  • This paper proposes a new locking algorithm of the delay locked loop (DLL) which reduces the lock-acquisition time and eliminates false locking problem to enlarge the operating frequency range. The proposed DLL uses the modified phase frequency detector (MPFD) and the modified charge pump (MCP) to avoid the false locking problem. Adopting a new lock detector that measures delay between elects helps the fast lock-acquisition time greatly. The idea has been confirmed by HSPICE simulations in a 0.35-${\mu}{\textrm}{m}$ CMOS process.

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Implementation of Power Line Transmission System using A New Digital Lock Loop (디지털 지연동기루프 개발에 의한 전력선 전송시스템 구현)

  • 정주수;박재운;변건식
    • Journal of the Korea Society of Computer and Information
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    • v.4 no.2
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    • pp.105-112
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    • 1999
  • Spread Spectrum Communication is a core technique in CDMA system, but the problem for SS Communication schemes is synchronous method. There are DLL(Delay Lock Loop), Tau-dither Loop, SO(Synchronous Osillator) etc., in the sychronous method. But since there are analog operations, the setting is difficult and circuit size is large. In this paper we proposed Digital Delay Lock Loop (DDLL) and estimated it's performance through the experiment.

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A 125 MHz CMOS Delay-Locked Loop with 64-phase Output Clock (64-위상 출력 클럭을 가지는 125 MHz CMOS 지연 고정 루프)

  • Lee, Pil-Ho;Jang, Young-Chan
    • Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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    • 2012.10a
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    • pp.259-262
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    • 2012
  • This paper describes a delay-locked loop (DLL) that generates a 64-phase clock with the operating frequency of 125MHz. The proposed DLL use a $4{\times}8$ matrix-based delay line to improve the linearity of a delay line. The output clock with 64-phase is generated by using a CMOS multiplex and a inverted-based interpolator from 32-phase clock which is the output clock of the $4{\times}8$ matrix-based delay line. The circuit for an initial phase lock, which is independent on the duty cycle ratio of the input clock, is used to prevent from the harmonic lock of a DLL. The proposed DLL is designed using a $0.18-{\mu}m$ CMOS process with a 1.8 V supply. The simulated operating frequency range is 40 MHz to 200 MHz. At the operating frequency of a 125 MHz, the worst phase error and jitter of a 64-phase clock are +11/-12 ps and 6.58 ps, respectively.

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An Analog Multi-phase DLL for Harmonic Lock Free (Harmonic Locking을 제거하기 위한 아날로그 Multi- phase DLL 설계)

  • 문장원;곽계달
    • Proceedings of the IEEK Conference
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    • 2001.06b
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    • pp.281-284
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    • 2001
  • This paper describes an analog multi-phase delay-locked loop (DLL) to solve the harmonic lock problem using current-starved inverter and shunt-capacitor delay cell. The DLL can be used not only as an internal clock buffer of microprocessors and memory It's but also as a multi-phase clock generator for gigabit serial interfaces. The proposed circuit was simulated in a 0.25${\mu}{\textrm}{m}$ CMOS technology to solve harmonic lock problem and to realize fast lock-on time and low-jitter we verified time interval less than 40 ps as the simulation results.

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A Digital DLL with 4-Cycle Lock Time and 1/4 NAND-Delay Accuracy

  • Kim, Sung-Yong;Jin, Xuefan;Chun, Jung-Hoon;Kwon, Kee-Won
    • JSTS:Journal of Semiconductor Technology and Science
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    • v.16 no.4
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    • pp.387-394
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    • 2016
  • This paper presents a fully digital delay locked loop (DLL) that can acquire lock in four clock cycles with a resolution of a 1/4 NAND-delay. The proposed DLL with a multi-dither-free phase detector acquires the initial lock in four clock cycles with 1/2 NAND-delay. Then, it utilizes a multi-dither-free phase detector, a region accumulator, and phase blenders, to improve the resolution to a 1/4 NAND-delay. The region accumulator which continuously steers the control registers and the phase blender, adaptively controls the tracking bandwidth depending on the amount of jitter, and effectively suppresses the dithering jitter. Fabricated in a 65 nm CMOS process, the proposed DLL occupies $0.0432mm^2$, and consumes 3.7 mW from a 1.2-V supply at 2 GHz.

Improved Delay-Locked Loop in a UWB Impulse Radio Time-Hopping Spread-Spectrum System

  • Zhang, Weihua;Shen, Hanbing;Kwak, Kyung-Sup
    • ETRI Journal
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    • v.29 no.6
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    • pp.716-724
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    • 2007
  • As ultra-wideband impulse radio (UWB-IR) uses short-duration impulse signals of nanoseconds, even a small number of timing errors can cause a detrimental effect on system performance. A delay-locked loop (DLL) is proposed to synchronize and reduce timing errors. The design of the DLL is vital for UWB systems. In this paper, an improved DLL is introduced to a UWB-IR time-hopping spread-spectrum system. Instead of using only two central correlator branches as in a conventional DLL, the proposed system uses two additional correlator branches with different delay parameters and different weight parameters. The performance of the proposed schemes with the optimal parameters is compared with that of traditional schemes through simulation: the proposed four-branch DLLs achieves less tracking jitter or a longer mean time to lose lock (MTLL) than the conventional two-branch DLLs if proper parameters are chosen.

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