Guan, Xin (2008-05). Development of RF CMOS receiver front-ends for ultrawideband. Doctoral Dissertation. Thesis uri icon

abstract

  • Ultra-Wideband (UWB) technology has become one of the hottest topics in wireless communications, for it provides cost-effective, power-efficient, high bandwidth solution for relaying data in the immediate area (up to 10 meters). This work demonstrates two different solutions for the RF front-end designs in the UWB receivers, one is distributed topology, and the other is based on traditional lumped element topology. The distributed amplifier is one of the attractive candidates for UWB Low Noise Amplifier (LNA). The design, analysis and operation of the distributed amplifiers will be presented. A distributed amplifier is designed with Coplanar Waveguide (CPW) transmission lines in 0.25-?m CMOS process for time domain UWB applications. New design techniques and new topologies are developed to enhance the power-efficiency and reduce the chip area. A compact and high performance distributed amplifier with Patterned Grounded Shield (PGS) inductors is developed in 0.25-?m CMOS process. The amplifier has a measurement result of 7.2dB gain, 4.2-6dB noise figure, and less than -10dB return loss through 0-11GHz. A new distributed amplifier implementing cascade common source gain cells is presented in 0.18-?m CMOS. The new amplifier demonstrates a high gain of 16dB at a power consumption of 100mW, and a gain of 10dB at a low power consumption of 19mW. A UWB LNA utilizing resistive shunt feedback technique is reported in 0.18-?m CMOS process. The measurement results of the UWB LNA demonstrate a maximum gain of 10.5dB and a noise figure of 3.3-4.5dB from 3-9.5GHz, while only consuming 9mW power. Based on the distributed amplifier and resistive shunt-feedback amplifier designs, two UWB RF front-ends are developed. One is a distributed LNA-Mixer. Unlike the conventional distributed mixer, which can only deliver low gain and high noise figure, the proposed distributed LNA-Mixer demonstrates 12-14dB gain ,4-5dB noise figure and higher than 10dB return loss at RF and LO ports over 2-16GHz. To overcome the power consumption and chip area problems encountered in distributed circuits, another UWB RF front-end is also designed with lumped elements. This front-end, employing resistive shunt-feedback technique into its LNA design, can achieve a gain of 12dB and noise figure of 8-10dB through 3-10GHz, the return loss of less than -10dB from 3- 10GHz at RF port, and less than -7dB at LO port, while only consuming 25mA current from 1.8V voltage supply.
  • Ultra-Wideband (UWB) technology has become one of the hottest topics in
    wireless communications, for it provides cost-effective, power-efficient, high bandwidth
    solution for relaying data in the immediate area (up to 10 meters). This work
    demonstrates two different solutions for the RF front-end designs in the UWB receivers,
    one is distributed topology, and the other is based on traditional lumped element
    topology.
    The distributed amplifier is one of the attractive candidates for UWB Low Noise
    Amplifier (LNA). The design, analysis and operation of the distributed amplifiers will be
    presented. A distributed amplifier is designed with Coplanar Waveguide (CPW)
    transmission lines in 0.25-?m CMOS process for time domain UWB applications. New
    design techniques and new topologies are developed to enhance the power-efficiency
    and reduce the chip area. A compact and high performance distributed amplifier with
    Patterned Grounded Shield (PGS) inductors is developed in 0.25-?m CMOS process.
    The amplifier has a measurement result of 7.2dB gain, 4.2-6dB noise figure, and less than -10dB return loss through 0-11GHz. A new distributed amplifier implementing
    cascade common source gain cells is presented in 0.18-?m CMOS. The new amplifier
    demonstrates a high gain of 16dB at a power consumption of 100mW, and a gain of
    10dB at a low power consumption of 19mW.
    A UWB LNA utilizing resistive shunt feedback technique is reported in 0.18-?m
    CMOS process. The measurement results of the UWB LNA demonstrate a maximum
    gain of 10.5dB and a noise figure of 3.3-4.5dB from 3-9.5GHz, while only consuming
    9mW power.
    Based on the distributed amplifier and resistive shunt-feedback amplifier designs,
    two UWB RF front-ends are developed. One is a distributed LNA-Mixer. Unlike the
    conventional distributed mixer, which can only deliver low gain and high noise figure,
    the proposed distributed LNA-Mixer demonstrates 12-14dB gain ,4-5dB noise figure
    and higher than 10dB return loss at RF and LO ports over 2-16GHz. To overcome the
    power consumption and chip area problems encountered in distributed circuits, another
    UWB RF front-end is also designed with lumped elements. This front-end, employing
    resistive shunt-feedback technique into its LNA design, can achieve a gain of 12dB and
    noise figure of 8-10dB through 3-10GHz, the return loss of less than -10dB from 3-
    10GHz at RF port, and less than -7dB at LO port, while only consuming 25mA current
    from 1.8V voltage supply.

publication date

  • May 2008