Broadband Direct RF Digitization Receivers [libro electrónico] / by Olivier Jamin.

RF Receiver Architecture State-of-the-Art -- System-Level Design Framework for Direct RF Digitization Receivers -- Application to the System Design of a Multi-Channel Cable Receiver -- Realization & Measurements -- Conclusions & Perspectives.

This book discusses the trade-offs involved in designing direct RF digitization receivers for the radio frequency and digital signal processing domains.  A system-level framework is developed, quantifying the relevant impairments of the signal processing chain, through a comprehensive system-level analysis.  Special focus is given to noise analysis (thermal noise, quantization noise, saturation noise, signal-dependent noise), broadband non-linear distortion analysis, including the impact of the sampling strategy (low-pass, band-pass), analysis of time-interleaved ADC channel mismatches, sampling clock purity and digital channel selection. The system-level framework described is applied to the design of a cable multi-channel RF direct digitization receiver. An optimum RF signal conditioning, and some algorithms (automatic gain control loop, RF front-end amplitude equalization control loop) are used to relax the requirements of a 2.7GHz 11-bit ADC. A two-chip implementation is presented, using BiCMOS and 65nm CMOS processes, together with the block and system-level measurement results. Readers will benefit from the techniques presented, which are highly competitive, both in terms of cost and RF performance, while drastically reducing power consumption.  ·         Provides system-level analysis of direct RF sampling & digitization receivers, from the antenna to the digital channel selection; ·         Includes analysis of broadband non-linearity, applicable for low-pass and band-pass sampling strategies; Describes system-level design of an application-optimized signal conditioner, including a single-inductance multi-slope programmable RF amplitude equalizer, together with its control algorithm and a mixed-signal AGC loop combining RMS and peak detection.  .