Automotive Radar Demonstrator : Phase-locked loop and filterdesign

Parash Par, Nima

January 2009

<p> </p><p>As technique and requirement of today’s products keeps expending, Acreo AB has been researching for automotive radar that fulfills these requirements, e.g. higher resolution, faster system and lower cost.</p><p>The purpose of this master thesis work has been to evaluate a previous design and implement changes. The work has resulted in a PCB card that will be used to compare the performance between two radar modules. The demonstrator has been developed in two versions – first based on the existing GaAs-chipset (Gallium Arsenide) and a second with the inclusion of a low cost SiGe-chipset (Silicon Germanium).</p><p>The outcome of this work proves that some requirements cannot be fulfilled and therefore a next-generation radar demonstrator has been proposed. The new radar demonstrator includes changes that can fulfill the requirements.</p><p> </p>

Radar

IF-filter

PLL

automotive

GaAs

SiGe

Electronics

Elektronik

Automotive Radar Demonstrator : Phase-locked loop and filterdesign

Parash Par, Nima

January 2009

As technique and requirement of today’s products keeps expending, Acreo AB has been researching for automotive radar that fulfills these requirements, e.g. higher resolution, faster system and lower cost. The purpose of this master thesis work has been to evaluate a previous design and implement changes. The work has resulted in a PCB card that will be used to compare the performance between two radar modules. The demonstrator has been developed in two versions – first based on the existing GaAs-chipset (Gallium Arsenide) and a second with the inclusion of a low cost SiGe-chipset (Silicon Germanium). The outcome of this work proves that some requirements cannot be fulfilled and therefore a next-generation radar demonstrator has been proposed. The new radar demonstrator includes changes that can fulfill the requirements.

Radar

IF-filter

PLL

automotive

GaAs

SiGe

Electronics

Elektronik

Analog integrated circuit design techniques for high-speed signal processing in communications systems

Hernandez Garduno, David

15 May 2009

This work presents design techniques for the implementation of high-speed analog integrated circuits for wireless and wireline communications systems. Limitations commonly found in high-speed switched-capacitor (SC) circuits used for intermediate frequency (IF) filters in wireless receivers are explored. A model to analyze the aliasing effects due to periodical non-uniform individual sampling, a technique used in high-Q high-speed SC filters, is presented along with practical expressions that estimate the power of the generated alias components. The results are verified through circuit simulation of a 10.7MHz bandpass SC filter in TSMC 0.35mu-m CMOS technology. Implications on the use of this technique on the design of IF filters are discussed. To improve the speed at which SC networks can operate, a continuous-time common-mode feedback (CMFB) with reduced loading capacitance is proposed. This increases the achievable gain-bandwidth product (GBW) of fully-differential ampli- fiers. The performance of the CMFB is demonstrated in the implementation of a second-order 10.7MHz bandpass SC filter and compared with that of an identical filter using the conventional switched-capacitor CMFB (SC-CMFB). The filter using the continuous-time CMFB reduces the error due to finite GBW and slew rate to less than 1% for clock frequencies up to 72MHz while providing a dynamic range of 59dB and a PSRR- > 22dB. The design of high-speed transversal equalizers for wireline transceivers requires the implementation of broadband delay lines. A delay line based on a third-order linear-phase filter is presented for the implementation of a fractionally-spaced 1Gb/s transversal equalizer. Two topologies for a broadband summing node which enable the placement of the parasitic poles at the output of the transversal equalizer beyond 650MHz are presented. Using these cells, a 5-tap 1Gb/s equalizer was implemented in TSMC 0.35mu-m CMOS technology. The results show a programmable frequency response able to compensate up to 25dB loss at 500MHz. The eye-pattern diagrams at 1Gb/s demonstrate the equalization of 15 meters and 23 meters of CAT5e twistedpair cable, with a vertical eye-opening improvement from 0% (before the equalizer) to 58% (after the equalizer) in the second case. The equalizer consumes 96mW and an area of 630mu-m x 490mu-m.

switched-capacitor

IF filter

equalizer

delay line

analog

circuit design