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[Author] Sung-Wook JUNG(2hit)

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  • A 3 V Low Power 156/622/1244 Mbps CMOS Parallel Clock and Data Recovery Circuit for Optical Communications

    Hae-Moon SEO  Chang-Gene WOO  Sang-Won OH  Sung-Wook JUNG  Pyung CHOI  

     
    PAPER-General Fundamentals and Boundaries

      Vol:
    E83-A No:8
      Page(s):
    1720-1727

    This paper presents the implementation of a 3 V low power multi-rate of 156, 622, and 1244 Mbps clock and data recovery circuit (CDR) for optical communications tranceiver using new parallel clock recovery architecture based on dual charge-pump PLL. Designed circuit recovers eight-phase clock signals which are one-eighth frequency of the input signal. While the typical system uses the method that compares the input data with recovered clock, the proposed circuit compares a 1/2-bit delayed input data with the serial data generated by the recovered eight-phase clock signals. The advantage of the circuit is that the implementation is easy, since each sub blocks have one-eighth frequency of the input data signal. Morevover, since the circuit works at one-eighth frequency of the input data, it dissipates less power than conventional CMOS recovery circuit. Simulation results show that this recovery circuit can work with power dissipation of less than 40 mW with a single 3 V supply. All the simulations are based on HYUNDAI 0.65 µm N-Well CMOS double-poly double-metal technology.

  • Design and Implementation of a Fourth-Order Quadrature Band-Pass Delta-Sigma Modulator for Low-IF Receivers

    Sung-Wook JUNG  Chang-Gene WOO  Sang-Won OH  Hae-Moon SEO  Pyung CHOI  

     
    PAPER-Analog Signal Processing

      Vol:
    E83-A No:12
      Page(s):
    2649-2656

    The delta-sigma modulator (DSM) is an excellent choice for high-resolution analog-to-digital converters. Recently, a band-pass DSM has been a desirable choice for direct conversion of an IF signal into a digital bit stream. This paper proposes a quadrature band-pass DSM for digitizing a narrow-band IF signal. This modulator can achieve a lower total order, higher signal-to-noise ratio (SNR), and higher bandwidth when compared with conventional band-pass modulators. An experimental prototype employing the quadrature topology has been integrated in 0.6 µm, double-poly, double-metal CMOS technology with capacitors synthesized from a stacked poly structure. This system clocked at 13 MHz and digitized a 200 kHz bandwidth signal centered at 4.875 MHz with 100 dB of dynamic range. Power consumption is 190 mW at 5 V.