Application of FPGA to real-time machine learning : hardware reservoir computers and software image processing / Piotr Antonik.
Antonik, Piotr, author.
2018
Q325.5
Available Online

Linked e-resources

Linked Resource Online Access
Concurrent users Unlimited
Authorized users Authorized users
Document Delivery Supplied Can lend chapters, not whole ebooks

Details

Title Application of FPGA to real-time machine learning : hardware reservoir computers and software image processing / Piotr Antonik.
Author Antonik, Piotr, author.
ISBN 9783319910536 (electronic book)
3319910531 (electronic book)
9783319910529
3319910523
DOI https://doi.org/10.1007/978-3-319-91053-6
Published Cham, Switzerland : Springer, 2018.
Language English
Description 1 online resource (xxii, 171 pages) : illustrations.
Item Number 10.1007/978-3-319-91053-6 doi
Call Number Q325.5
Dewey Decimal Classification 006.3/1
Summary This book lies at the interface of machine learning – a subfield of computer science that develops algorithms for challenging tasks such as shape or image recognition, where traditional algorithms fail – and photonics – the physical science of light, which underlies many of the optical communications technologies used in our information society. It provides a thorough introduction to reservoir computing and field-programmable gate arrays (FPGAs). Recently, photonic implementations of reservoir computing (a machine learning algorithm based on artificial neural networks) have made a breakthrough in optical computing possible. In this book, the author pushes the performance of these systems significantly beyond what was achieved before. By interfacing a photonic reservoir computer with a high-speed electronic device (an FPGA), the author successfully interacts with the reservoir computer in real time, allowing him to considerably expand its capabilities and range of possible applications. Furthermore, the author draws on his expertise in machine learning and FPGA programming to make progress on a very different problem, namely the real-time image analysis of optical coherence tomography for atherosclerotic arteries.
Note "Doctoral thesis accepted by the Université libre de Bruxelles, Brussels, Belgium."
Bibliography, etc. Note Includes bibliographical references.
Access Note Access limited to authorized users.
Digital File Characteristics text file PDF
Source of Description Online resource; title from PDF title page (SpringerLink, viewed May 21, 2018).
Series Springer theses.
Available in Other Form Print version: 9783319910529
Linked Resources Online Access
Record Appears in Online Resources > Ebooks
All Resources
Intro; Supervisor's Foreword; Abstract; Preface; Acknowledgements; Contents; 1 Introduction; 1.1 From Machine Learning to Reservoir Computing; 1.1.1 Machine Learning Algorithms; 1.1.2 Artificial Neural Networks; 1.1.3 Reservoir Computing; 1.1.4 Benchmark Tasks; 1.2 Hardware Implementations: Opto-Electronic Delay Systems; 1.2.1 Time-Multiplexing; 1.2.2 Conceptual Setup; 1.2.3 Desynchronisation; 1.2.4 Experimental Setup; 1.3 Field-Programmable Gate Arrays; 1.3.1 History; 1.3.2 Market and Applications; 1.3.3 Xilinx Virtex 6: Architecture and Operation; 1.3.4 Design Flow and Implementation Tools

2.6.4 Equalisation of a Switching Channel2.6.5 Influence of Channel Model Parameters on Equaliser Performance; 2.7 Challenges and Solutions; 2.8 Conclusion; References; 3 Backpropagation with Photonics; 3.1 Introduction; 3.2 Backpropagation Through Time; 3.2.1 General Idea and New Notations; 3.2.2 Setting Up the Problem; 3.2.3 Output Mask Gradient; 3.2.4 Input Mask Gradient; 3.2.5 Multiple Inputs/Outputs; 3.3 Experimental Setup; 3.3.1 Online Multiplication Using Cascaded MZMs; 3.3.2 Mask Parametrisation; 3.4 FPGA Design; 3.5 Results; 3.5.1 Tasks; 3.5.2 NARMA10 and VARDEL5; 3.5.3 TIMIT

3.5.4 Gradient Descent3.5.5 Robustness; 3.6 Challenges and Solutions; 3.7 Conclusion; References; 4 Photonic Reservoir Computer with Output Feedback; 4.1 Introduction; 4.2 Reservoir Computing with Output Feedback; 4.3 Time Series Generation Tasks; 4.3.1 Frequency Generation; 4.3.2 Random Pattern Generation; 4.3.3 Mackey-Glass Chaotic Series Prediction; 4.3.4 Lorenz Chaotic Series Prediction; 4.4 Experimental Setup; 4.5 FPGA Design; 4.6 Numerical Simulations; 4.7 Results; 4.7.1 Noisy Reservoir; 4.7.2 Frequency Generation; 4.7.3 Random Pattern Generation; 4.7.4 Mackey-Glass Series Prediction

4.7.5 Lorenz Series Prediction4.8 Challenges and Solutions; 4.9 Conclusion; References; 5 Towards Online-Trained Analogue Readout Layer; 5.1 Introduction; 5.2 Methods; 5.3 Proposed Experimental Setup; 5.3.1 Analogue Readout Layer; 5.3.2 FPGA Board; 5.4 Numerical Simulations; 5.5 Results; 5.5.1 Linear Readout: RC Circuit; 5.5.2 Nonlinear Readout; 5.6 Conclusion; References; 6 Real-Time Automated Tissue Characterisation for Intravascular OCT Scans; 6.1 Introduction; 6.2 Feature Extraction; 6.2.1 GLCM Features; 6.2.2 Methods; 6.2.3 Operation Principle; 6.2.4 FPGA Design; 6.2.5 Results

Browse Subjects

Show more subjects...

Statistics

from
to
Export