Feedforward Equalizers for MDM–WDM in Multimode Fiber Interconnects

In this paper, we present new tap configurations of a feedforward equalizer to mitigate mode coupling in a 60-Gbps 18-channel mode-wavelength division multiplexing system in a 2.5-km-long multimode fiber. The performance of the equalization is measured through analyses on eye diagrams, power coupling coefficients and bit-error rates.

A Low-Complexity Decision Feedforward Equalizer Architecture for High-Speed Receivers on Highly Dispersive Channels

This paper presents an improved decision feedforward equalizer (DFFE) for high speed receivers in the presence of highly dispersive channels. This decision-aided equalizer technique has been recently proposed for multigigabit communication receivers, where the use of parallel processing is mandatory. Well-known parallel architectures for the typical decision feedback equalizer (DFE) have a complexity that grows exponentially with the channel memory. Instead, the new DFFE avoids that exponential increase in complexity by using tentative decisions to cancel iteratively the intersymbol interference (ISI). Here, we demostrate that the DFFE not only allows to obtain a similar performance to the typical DFE but it also reduces the compelxity in channels with large memory. Additionally, we propose a theoretical approximation for the error probability in each iteration. In fact, when the number of iteration increases, the error probability in the DFFE tends to approach the DFE. These benefits make the DFFE an excellent choice for the next generation of high-speed receivers.

A 10 GB/S EQUALIZER WITH INTEGRATED CLOCK AND DATA RECOVERY FOR OPTICAL COMMUNICATION SYSTEMS

A 10 Gb/s analog continuous-time equalizer with integrated clock and data recovery circuit is presented. It is designed to recover signals degraded by chromatic and polarization mode dispersion. The key components in the design are a feedforward equalizer and a decision feedback equalizer, the parameters of which are electronically adjustable. Both circuit blocks are fully described and characterized with emphasis on minimizing self-induced distortion and maximizing high-speed performance. In addition to the equalizer and the clock and data recovery, the circuit also includes an integrated automatic gain control. The circuit is implemented in a commercial 0.18 μm SiGe BiCMOS technology and consumes 900 mW. The capacity of the equalizer to mitigate signal impairments is demonstrated using three electrically generated channels.