Implementation and Evaluation of Signal Processing Circuits for Optical Communication
Doktorsavhandling, 2024

The digital signal processing (DSP) circuits used in the fiber-optic communication links that make up the backbone of the Internet can be a significant contributor the over-all power dissipation of a link. As the number of connected users and their bandwidth requirements are expected to continue to grow over the coming years, the development of power-efficient high-throughput DSP systems is a critical factor in enabling this growth. Unfortunately, DSP designers can no longer depend on foundries delivering faster and more power-efficient circuits for each new process node, due to both economical and physical limitations. As a result, more stringent speed and power requirements are put on the circuit designs.

Carrier phase recovery (CPR) is one subsystem of a typical DSP system for fiber-optic communication. In this thesis, we explore and evaluate circuit designs of multiple types of CPR, with a focus on single-mode systems. The circuit designs allow us to uncover trade-offs between power dissipation, area, throughput and signal degradation, for different types of systems employing a range of modulation formats. Coupled-core multi-mode fiber systems have been suggested as a way to increase throughput by utilizing also the spatial dimension, and this thesis describes a multiple-input multiple-output adaptive equalizer targeting these systems. The equalizer circuit enables exploration of how this critical subsystem scales to higher core counts. Additionally, we describe a circuit verification and evaluation environment that has the potential to speed up simulations by orders of magnitude by emulating a fiber-optic link onboard an application-specific integrated circuit or a field-programmable gate array.

Adaptive Equalization

Carrier Phase Recovery

Digital Signal Processing

Application-Specific Integrated Circuits

Communication Systems

Fiber-Optic Communication

EA-salen, Hörsalsvägen 11
Opponent: Prof. Seb Savory, University of Cambridge, Cambridge, UK

Författare

Erik Börjeson

VLSI-system

VLSI Implementations of Carrier Phase Recovery Algorithms for M-QAM Fiber-Optic Systems

Journal of Lightwave Technology,;Vol. 38(2020)p. 3616-3623

Artikel i vetenskaplig tidskrift

Energy-Efficient Implementation of Carrier Phase Recovery for Higher-Order Modulation Formats

Journal of Lightwave Technology,;Vol. 39(2021)p. 505-510

Artikel i vetenskaplig tidskrift

Benchmarking of Carrier Phase Recovery Circuits for M-QAM Coherent Systems

Optical Fiber Communication Conference, OFC 2021,;(2021)

Paper i proceeding

Multi-Format Carrier Phase Recovery Using a Programmable Circuit

Optics InfoBase Conference Papers,;(2021)

Paper i proceeding

Circuit Implementation of Pilot-Based Dynamic MIMO Equalization for Coupled-Core Fibers

Optical Fiber Communication Conference, OFC 2024,;(2024)

Paper i proceeding

Fiber-on-Chip: Digital Emulation of Channel Impairments for Real-Time DSP Evaluation

Journal of Lightwave Technology,;Vol. 41(2023)p. 888-896

Artikel i vetenskaplig tidskrift

Fiber-optic communication links provide the foundation for the networks that enable our modern interconnected society. Over these links, huge amounts of data are transmitted every second using laser-generated light, which is sent through fiber-optic cables and received at the other end. Due to the properties of the fiber-optic cable and other parts of a link, the light is affected by a range of effects that corrupt the transmitted signal. As a result, the received signal can differ significantly from the transmitted signal, which makes it hard for the receiver to recover the information that was originally transmitted.

To compensate for these effects, custom-designed integrated circuits are used. These circuits process the received data to recover the transmitted information. As we want to maximize the amount of data we can transmit over a link, the circuits need to have high processing speeds. Energy efficiency is another important aspect, as these circuits can account for a significant portion of the total energy consumption of a link. Striking a balance between these two, often conflicting demands, can be a big challenge for the designers of fiber-optic links.

In this thesis, we investigate trade-offs between processing speed, energy efficiency and quality of compensation, for a selection of processing stages and methods. Additionally, we present a way to speed up the evaluation of these circuit designs, a task that can be very time-consuming using conventional methods.

Ämneskategorier

Kommunikationssystem

Inbäddad systemteknik

Signalbehandling

ISBN

978-91-8103-015-0

Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 5473

Utgivare

Chalmers

EA-salen, Hörsalsvägen 11

Opponent: Prof. Seb Savory, University of Cambridge, Cambridge, UK

Mer information

Senast uppdaterat

2024-04-15