Adapted compressed sensing for effective hardware implementations : a design flow for signal-level optimization of compressed sensing stages
By: Mangia, Mauro
Title By: Pareschi, Fabio | Cambareri, Valerio | Rovatti, Riccardo | Setti , Gianluca
Material type:![](/opac-tmpl/lib/famfamfam/BK.png)
Item type | Home library | Call number | Status | Date due | Barcode | Item holds |
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REGULAR | University of Wollongong in Dubai Main Collection | 602.1 MA AD (Browse shelf) | Available | T0058969 |
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599.756 PA TI Tigers in red weather / | 599.935 LI BI The biology of belief : | 601.4 AC AD Academy-industry relationships and partnerships : | 602.1 MA AD Adapted compressed sensing for effective hardware implementations : | 604.2 BE FU Fundamentals of solid modeling and graphic communication | 604.2 MU MA Mastering Autodesk inventor 2016 and Autodesk inventor Lt 2016 | 604.2 SM DR Drawing for engineering / |
Chapter 1. Introduction to Compressed Sensing: Fundamentals and Guarantees --
Chapter 2.How (Well) Compressed Sensing Works in Practice --
Chapter 3. From Universal to Adapted Acquisition: Rake that Signal! --
Chapter 4.The Rakeness Problem with Implementation and Complexity Constraints --
Chapter 5.Generating Raking Matrices: a Fascinating Second-Order Problem --
Chapter 6.Architectures for Compressed Sensing --
Chapter 7.Analog-to-information Conversion --
Chapter 8.Low-complexity Biosignal Compression using Compressed Sensing --
Chapter 9.Security at the analog-to-information interface using Compressed Sensing.
This book describes algorithmic methods and hardware implementations that aim to help realize the promise of Compressed Sensing (CS), namely the ability to reconstruct high-dimensional signals from a properly chosen low-dimensional “portrait”. The authors describe a design flow and some low-resource physical realizations of sensing systems based on CS. They highlight the pros and cons of several design choices from a pragmatic point of view, and show how a lightweight and mild but effective form of adaptation to the target signals can be the key to consistent resource saving. The basic principle of the devised design flow can be applied to almost any CS-based sensing system, including analog-to-information converters, and has been proven to fit an extremely diverse set of applications. Many practical aspects required to put a CS-based sensing system to work are also addressed, including saturation, quantization, and leakage phenomena.