• Title/Summary/Keyword: PLL(Phase Lock Loop)

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Design of Carrier Recovery Circuit for High-Order QAM - Part II : Performance Analysis and Design of the Gear-shift PLL with ATC(Automatic Transfer-mode Controller) and Average-mode-change Circuit (High-Order QAM에 적합한 반송파 동기회로 설계 - II부. 자동모드전환시점 검출기 및 평균모드전환회로를 적용한 Gear-Shift PLL 설계 및 성능평가)

  • Kim, Ki-Yun;Kim, Sin-Jae;Choi, Hyung-Jin
    • Journal of the Institute of Electronics Engineers of Korea TC
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    • v.38 no.4
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    • pp.18-26
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    • 2001
  • In this paper, we propose an ATC(Automatic Transfer mode Controller) algorithm and an average-mode-change method for use in Gear shift PLL which can automatically change loop gain. The proposed ATC algorithm accurately detects proper timing or the mode change and has a very simpler structure - than the conventional lock detector algorithm often used in QPSK. And the proposed average mode change method can obtain low errors of estimated frequency offset by averaging the loop filter output of frequency component in shift register. These algorithms are also useful in designing ASIC, since these algorithms occupy small circuit area and are adaptable for high speed digital processing. We also present phase tracking performance of proposed Gear-shift PLL, which is composed of polarity decision PD, ATC and average mode change circuit, and analyze the results by examining constellation at each mode.

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Design of a 960MHz CMOS PLL Frequency Synthesizer with Quadrature LC VCO (960MHz Quadrature LC VCO를 이용한 CMOS PLL 주파수 합성기 설계)

  • Kim, Shin-Woong;Kim, Young-Sik
    • Journal of the Institute of Electronics Engineers of Korea SD
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    • v.46 no.7
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    • pp.61-67
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    • 2009
  • This paper reports an Integer-N phase locked loop (PLL) frequency synthesizer which was implemented in a 250nm standard digital CMOS process for a UHF RFID wireless communication system. The main blocks of PLL have been designed including voltage controlled oscillator, phase frequency detector, and charge pump. The LC VCO has been used for a better noise property and low-power design. The source and drain juntions of PMOS transistors are used as the varactor diodes. The ADF4111 of Analog Device has been used for the external pre-scaler and N-divider to divide VCO frequency and a third order RC filter is designed for the loop filter. The measured results show that the RF output power is -13dBm with 50$\Omega$ load, the phase noise is -91.33dBc/Hz at 100KHz offset frequency, and the maximum lock-in time is less than 600us from 930MHz to 970MHz.

Fractional-N PLL Frequency Synthesizer Design (Fractional-N PLL (Phase-Locked Loop) 주파수 합성기 설계)

  • Kim Sun-Cheo;Won Hee-Seok;Kim Young-Sik
    • Journal of the Institute of Electronics Engineers of Korea TC
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    • v.42 no.7 s.337
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    • pp.35-40
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    • 2005
  • This paper proposes a fractional-N phase-locked loop (PLL) frequency synthesizer using the 3rd order ${\Delta}{\sum}$ modulator for 900MHz medium speed wireless link. The LC voltage-controlled oscillator (VCO) is used for the good phase noise property. To reduce the lock-in time, a charge pump has been developed to control the pumping current according to the frequency steps and the reference frequency is increased up to 3MHz. A 36/37 fractional-N divider is used to increase the reference frequency of the phase frequency detector (PFD) and to reduce the minimum frequency step simultaneously. A 3rd order ${\Delta}{\sum}$ modulator has been developed to reduce the fractional spur VCO, Divider by 8 Prescaler, PFD and Charge pump have been developed with 0.25um CMOS, and the fractional-N divider and the third order ${\Delta}{\sum}$ modulator have been designed with the VHDL code, and they are implemented through the FPGA board of the Xilinx Spartan2E. The measured results show that the output power of the PLL is about -lldBm and the phase noise is -77.75dBc/Hz at 100kHz offset frequency. The minimum frequency step and the maximum lock-in time are 10kHz and around 800us for the maximum frequency change of 10MHz, respectively.

40 GHz optical phase lock loop circuit for ultrahigh speed optical time division demultiplexing system (초고속 광시분할 다중시스템의 DEMUX용 40GHz 위상 동기 회로)

  • 김동환
    • Korean Journal of Optics and Photonics
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    • v.11 no.5
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    • pp.330-334
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    • 2000
  • A new pha~e lock loop (PLL) IS proposed and demonstrated fat clock recovery from 40 Gblt/s time-dIvision-multiplexed (TDM) optical pulse tri.lin, The proposed clock lecovery scheme lmproves the Jitter effecl cOlmng from the clock. pulse laser of harmonically-mode locked flber laser The cross-corrdation frequency component between the optical Signa] and an optical clock pulse tram is deteCled as a fonr-wave-mixing (FWM) SIgnal generated in SOA. The lock-in freqnency range of the clod. recovery IS found to be within 10 KHz. 0 KHz.

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Design of a High Speed CMOS PLL with a Two-stage Self-feedback Ring Oscillator (자체귀환형 2단 고리발진기를 이용한 고속 CMOS PLL 설계)

  • 문연국;윤광섭
    • Proceedings of the IEEK Conference
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    • 1999.06a
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    • pp.353-356
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    • 1999
  • A 3.3V PLL(Phase Locked loop) is designed for a high frequency, low voltage, and low power applications. This paper proposes a new PLL architecture to improve voltage to frequency linearity of VCO(Voltage controlled oscillator) with new delay cell. The proposed VCO operates at a wide frequency range of 30MHz~1㎓ with a good linearity. The DC-DC voltage up/down converter is utilized to regulate the control voltage of the two-stage VCO. The designed PLL architecture is implemented on a 0.6${\mu}{\textrm}{m}$ n-well CMOS process. The simulation results show a locking time of 2.6$\mu$sec at 1Hz, Lock in range of 100MHz~1㎓, and a power dissipation of 112㎽.

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Sensorless Speed Control of PMSM using Stator Flux Estimation and PLL (고정자 자속 추정과 PLL을 이용한 동기모터의 센서리스 속도 제어)

  • Kim, Min Ho;Yang, Oh
    • Journal of the Semiconductor & Display Technology
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    • v.14 no.2
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    • pp.35-40
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    • 2015
  • This paper presents the sensorless position control of the Permanent Magnet Synchronous Motor (PMSM) using stator flux estimation and Phase Lock Loop (PLL). The field current and the torque current are required in order to perform the vector control of the PMSM. At this time, it is necessary for the torque to know the exact position of the magnetic flux generated by the permanent magnet, because the torque must be applied torque current in the direction orthogonal to the permanent magnet. In general the speed of the PMSM is controlled by using a magnetic position sensor. However, this paper, we estimates the stator flux by using the PLL method without the magnetic position sensor. This method is simple and easy, in addition it has the advantage of a stabile estimation of the rotor. Finally the proposed algorithm was confirmed by experimental results and showed the good performance.

Design of Clock and Data Recovery Circuit for 622Mbps Optical Network (622Mbps급 광 통신망용 버스트모드 클럭/데이터 복원회로 설계)

  • Moon, Sung-Young;Lee, Sung-Chul;Moon, Gyu
    • Journal of the Institute of Electronics Engineers of Korea SD
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    • v.46 no.2
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    • pp.57-63
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    • 2009
  • In this Paper, a novel 622Mbps burst-mode clock and data recovery (CDR) circuit is proposed for passive optical network (PON) applications. The CDR circuit is composed of CDR(Clock and Data Recovery) block and PLL(Phase Locked Loop) block. Lock dynamics is accomplished on the first data transition and data are sampled in the optimal point. The CDR circuit is realized in 0.35um CMOS process technology. With input pseudo-random bit sequences(PRBS) of $2^7-1$, the simulations show 17ps peak-to-peak retimed data jitter characteristics. The experimental results show that the proposed CDR circuits are operating as expected, recovering an incoming 622Mbps burst-mode input data without errors.

Design of a CMOS Charge Pump PLL of UWB System LO Generation (초광대역 시스템 Hopping Carrier 발생을 위한 0.18um 4.224GHz CMOS PLL 설계)

  • Lee, J.K.;Kang, K.S.;Park, J.T.;Yu, C.G.
    • Proceedings of the IEEK Conference
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    • 2005.11a
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    • pp.845-848
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    • 2005
  • This paper describes a 4.224GHz CMOS charge pump PLL for Mode 1 MB-OFDM UWB hopping carrier generation. It includes a qudrature VCO of which the frequency range is from 3.98GHz to 4.47GHz(@ 0.4 to 1.5 V), a divider, a PFD, a loop filter, a charge pump, and a lock detector. Designed in a 0.18um CMOS technology, the PLL draws 6.6mA from a 1.8V supply. The phase noise of the designed VCO is -133dBc/Hz@3MHz.

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Sinusoidal Current Control of Single-Phase PWM Converters under Voltage Source Distortion Using Composite Observer (왜곡된 전원 전압하에서 Composite 관측기를 이용한단상 PWM 컨버터의 정현파 전류 제어)

  • Nguyen, Thanh Hai;Lee, Dong-Choon;Lee, Suk-Gyu
    • The Transactions of the Korean Institute of Power Electronics
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    • v.16 no.5
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    • pp.466-476
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    • 2011
  • In this paper, a high-performance current control for the single-phase PWM converter under distorted source voltages is proposed using a composite observer. By applying the composite observer, the fundamental and high-order harmonic components of the source voltage and current are extracted without a delay. The extracted fundamental component is used for a phase-lock loop (PLL) system to detect the phase angle of the source voltage. A multi-PR (proportional-resonant) controller is employed to regulate the single-phase line current. The high-order harmonic components of the line current are easily eliminated, resulting in the sinusoidal line current. The simulation and experimental results have verified the validity of the proposed method.

Design of a CMOS Frequency Synthesizer for FRS Band (UHF FRS 대역 CMOS PLL 주파수 합성기 설계)

  • Lee, Jeung-Jin;Kim, Young-Sik
    • The Journal of Korean Institute of Electromagnetic Engineering and Science
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    • v.28 no.12
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    • pp.941-947
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    • 2017
  • This paper reports a fractional-N phase-locked-loop(PLL) frequency synthesizer that is implemented in a $0.35-{\mu}m$ standard CMOS process and generates a quadrature signal for an FRS terminal. The synthesizer consists of a voltage-controlled oscillator(VCO), a charge pump(CP), loop filter(LF), a phase frequency detector(PFD), and a frequency divider. The VCO has been designed with an LC resonant circuit to provide better phase noise and power characteristics, and the CP is designed to be able to adjust the pumping current according to the PFD output. The frequency divider has been designed by a 16-divider pre-scaler and fractional-N divider based on the third delta-sigma modulator($3^{rd}$ DSM). The LF is a third-order RC filter. The measured results show that the proposed device has a dynamic frequency range of 460~510 MHz and -3.86 dBm radio-frequency output power. The phase noise of the output signal is -94.8 dBc/Hz, and the lock-in time is $300{\mu}s$.