Analog Front-end Design Research Articles

A 1.8-V 10-Gb/s fully integrated CMOS optical receiver analog front-end

A fully integrated 10-Gb/s optical receiver analog front-end (AFE) design that includes a transimpedance amplifier (TIA) and a limiting amplifier (LA) is demonstrated to require less chip area and is suitable for both low-cost and low-voltage applications. The AFE is fabricated using a 0.18-/spl mu/m CMOS technology. The tiny photo current received by the receiver AFE is amplified to a differential voltage swing of 400 mV/sub (pp)/. In order to avoid off-chip noise interference, the TIA and LA are dc-coupled on the chip instead of ac-coupled though a large external capacitor. The receiver front-end provides a conversion gain of up to 87 dB/spl Omega/ and -3dB bandwidth of 7.6 GHz. The measured sensitivity of the optical receiver is -12dBm at a bit-error rate of 10/sup -12/ with a 2/sup 31/-1 pseudorandom test pattern. Three-dimensional symmetric transformers are utilized in the AFE design for bandwidth enhancement. Operating under a 1.8-V supply, the power dissipation is 210 mW, and the chip size is 1028 /spl mu/m/spl times/1796 /spl mu/m.

The design of analog front ends for 1000base-t receivers

This paper explores the design of analog front ends (AFEs) for a 1000BASE-T receiver. We consider having the AFE perform partial equalization or partial echo cancellation in addition to the required low-pass filtering function. Different architectures that can realize one of these two functions are presented, and these architectures are optimized to enable the receiver to achieve the best overall performance. A higher performance AFE enables a lower-complexity digital backend to be used, thereby simplifying the overall receiver. These architectures are compared in terms of power dissipation, chip area, and performance (using system-level simulations). The effects of varying cable lengths are also analyzed. The reductions in ADC resolution, or digital filter length, enabled by these architectures are estimated. Our results show that by properly selecting the AFE architecture, the overall receiver can be simplified without sacrificing performance.

Analysis and compact behavioral modeling of nonlinear distortion in analog communication circuits

The design of analog front-ends of digital telecommunication transceivers requires mixed-signal simulations at the architectural level. The nonlinear nature of the analog front-end blocks is a complication for their modeling at the architectural level, especially when the nonlinear behavior is frequency dependent. This paper describes an analysis and modeling method based on Volterra theory. The method derives bottom-up models of nonlinear analog continuous-time circuits. These behavioral models predict the dominant nonlinear effects using a composition of linear transfer functions and multiplications. This makes it possible to accurately model frequency dependencies and to gain insight into the dominant nonlinear sources of the circuit. The basic models are afterwards described using its multicarrier complex low-pass representation to enable their efficient cosimulation with the digital circuits in a dataflow simulation environment. The multicarrier representation is a direct extension of the classically used complex low-pass equivalent models, which considers the modulation of a single carrier only. The accuracy of the multicarrier representation is higher than classical complex low-pass equivalent models since out-of-band nonlinear distortion is taken into account. The main advantage of the proposed technique is that it yields both insight in the nonlinear behavior at the circuit level and that it provides an important gain in simulation efficiency of RF integrated circuits at the system level. Both aspects are demonstrated on a 5-GHz WLAN design.

An all digital receiver architecture for bandwidth efficient transmission at high data rates

Using the maximum-likelihood approach, algorithms for detection and synchronization are derived that are well suited for VLSI implementation. Special emphasis is placed on an all-digital implementation where carrier and clock synchronization do not require a feedback of signals to the analog part, which simplifies the analog front-end design (mixing oscillator and A/D converter sampling clock run at fixed frequency). An important advantage of the proposed algorithms is that a high clock rate is not required; only two-four times the symbol rate is needed, depending on amplitude quantization. Implementation aspects, e.g. architecture, and quantization, are considered. A prototype is described which was implemented to prove the feasibility of the concept and to evaluate the performance under practical conditions.< <ETX xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">&gt;</ETX>