Singapore : , : Springer, , [2022]

©2022

981-19-7052-1

1 online resource (79 pages)

SpringerBriefs in applied sciences and technology

541.345

Colloids

Nanoparticles

Semiconductor films

Inglese

Includes bibliographical references.

Intro -- Contents -- 1 Introduction -- References -- 2 Colloidal Semiconductor Nanocrystals -- 2.1 Colloidal Quantum Wells (Nanoplatelets) -- References -- 3 Self-Assembly of Colloidal Nanocrystals -- 3.1 Common Approaches to Colloidal NC Self-Assembly -- 3.1.1 Solvent Destabilization -- 3.1.2 Solvent Evaporation on Substrate -- 3.1.3 Langmuir-Blodgett Deposition -- 3.1.4 Self-Assembly at Liquid Interfaces -- 3.2 Self-Assembly of Anisotropic Nanocrystals -- References -- 4 Liquid Interface Self-Assembly with Colloidal Quantum Wells -- 4.1 Controlling the Orientation of Nanoplatelets on Liquid Interface -- 4.2 Multilayered Deposition of Self-Assembled NPLs -- 4.3 Other Approaches to Liquid Interface NPL Self-Assembly: Parameters that Affect NPL Orientation -- References -- 5 Liquid Interface Self-Assembly of Colloidal Nanoplatelets for Optoelectronics -- 5.1 Orientation-Controlled Nonradiative Energy Transfer with Self-Assembled Nanoplatelet Monolayers -- 5.1.1 Distance-Dependence of FRET from QDs to a Monolayer of NPLs -- 5.1.2 Theoretical Modeling of Orientation-Controlled FRET to NPLs -- 5.2 Optically Active Planar Waveguides of Self-Assembled NPL Multilayers: Enabling Ultrathin Gain Media -- 5.2.1 Dielectric-Assisted Enhancement of the Optical Confinement

in Self-Assembled NPL Waveguides -- 5.3 Other Applications for Liquid Interface NPL Assemblies: Photovoltaics, Displays, and Beyond -- References -- 6 Conclusions and Future Outlook -- References.

New York, : Wiley, 2001

9786610264773

9781280264771

1280264772

9780471464143

0471464147

9780471224389

0471224383

1 online resource (330 p.)

Wiley series on parallel and distributed computing

DowntonA. C

005.2/76

Embedded computer systems - Programming

Parallel computers - Programming

Inglese

Description based upon print version of record.

Foreword; Preface; Acknowledgments; Contents; Acronyms; Part I: Introduction and Basic Concepts; 1 Introduction; 1.1 Overview; 1.2 Origins; 1.3 Amdahl's Law and Structured Parallel Design; 1.4 Introduction to PPF Systems; 1.5 Conclusions; Appendix; 2 Basic Concepts; 2.1 Pipelined Processing; 2.2 Pipeline Types; 2.3 Data Farming and Demand-based Scheduling; 2.4 Data-farm Performance Criteria; 2.5 Conclusion; Appendix; 3 PPF in Practice; 3.1 Application Overview; 3.2 Parallelization of the Postcode Recognizer; 3.3 Parallelization of the address verifier; 3.4 Meeting the Specification

3.5 ConclusionAppendix; 4 Development of PPF Applications; 4.1 Analysis Tools; 4.2 Tool Characteristics; 4.3 Development Cycle; 4.4 Conclusion; Part II: Analysis and Partitioning of Sequential Applications;

5 Initial Development of an Application; 5.1 Confidence Building; 5.2 Automatic and Semi-automatic Parallelization; 5.3 Language Proliferation; 5.4 Size of Applications; 5.5 Semi-automatic Partitioning; 5.6 Porting Code; 5.7 Checking a Decomposition; 5.8 Optimizing Compilers; 5.9 Conclusion; 6 Graphical Simulation and Performance Analysis of PPFs; 6.1 Simulating Asynchronous Pipelines

6.2 Simulation Implementation6.3 Graphical Representation; 6.4 Display Features; 6.5 Cross-architectural Comparison; 6.6 Conclusion; 7 Template-based Implementation; 7.1 Template Design Principles; 7.2 Implementation Choices; 7.3 Parallel Logic Implementation; 7.4 Target Machine Implementation; 7.5 'NOW' Implementation for Logic Debugging; 7.6 Target Machine Implementations for Performance Tuning; 7.7 Patterns and Templates; 7.8 Conclusion; Part III: Case Studies; 8 Application Examples; 8.1 Case Study 1: H.261 Encoder; 8.2 Case Study 2: H263 Encoder/Decoder

8.3 Case Study 3: 'Eigenfaces' - Face Detection8.4 Case Study 4: Optical Flow; 8.5 Conclusion; 9 Design Studies; 9.1 Case Study 1: Karhunen-Loéve Transform (KLT); 9.2 Case Study 2: 2D- Wavelet Transform; 9.3 Case Study 3: Vector Quantization; 9.4 Conclusion; 10 Counter Examples; 10.1 Case Study 1: Large Vocabulary Continuous-Speech Recognition; 10.2 Case Study 2: Model-based Coding; 10.3 Case Study 3: Microphone Beam Array; 10.4 Conclusion; Part IV: Underlying Theory and Analysis; 11 Performance of PPFs; 11.1 Naming Conventions; 11.2 Performance Metrics; 11.3 Gathering Performance Data

11.4 Performance Prediction Equations11.5 Results; 11.6 Simulation Results; 11.7 Asynchronous Pipeline Estimate; 11.8 Ordering Constraints; 11.9 Task Scheduling; 11.10 Scheduling Results; 11.11 Conclusion; Appendix; 12 Instrumentation of Templates; 12.1 Global Time; 12.2 Processor Model; 12.3 Local Clock Requirements; 12.4 Steady-state Behavior; 12.5 Establishing a Refresh Interval; 12.6 Local Clock Adjustment; 12.7 Implementation on the Paramid; 12.8 Conclusion; Part V: Future Trends; 13 Future Trends; 13.1 Designing for Differing Embedded Hardware

13.2 Adapting to Mobile Networked Computation

This book outlines a methodology for the use of parallel processing in real time systems. It provides an introduction to parallel processing in general, and to embedded systems in particular. Among the embedded systems are processors in such applications as automobiles, various machinery, IPGAs (field programmable gate arrays), multimedia embedded systems such as those used in the computer game industry, and more.* Presents design and simulation tools as well as case studies.* First presentation of this material in book form.