Dynamically Reconfigurable Systems: Architectures, Design Methods and Applications (Hardcover, 2010)

Part I Architectures. 1 Development and synthesis of adaptive multi-grained reconfigurable hardware architecture for dynamic function patterns; A.Thomas, J.Becker. 1.1 Introduction. 1.2 HoneyComb architecture. 1.3 Tool Support. 1.4 Future Work. 1.5 Conclusion. References. 2 Reconfigurable components for application-specific processor architectures; T.G. Noll, T.von Sydow, B.Neumann, J.Schleifer, T.Coenen, G.Kappen. 2.1 Introduction. 2.2 Parameterized eFPGA Target Architecture. 2.3 Physical Implementation of Application Class Specific eFPGAs. 2.4 Mapping and Configuration. 2.5 Examples of (Stand Alone) eFPGAs as SoC Building Blocks. 2.6 Examples of eFPGAs as Coprocessors to Standard RISC Processor Kernels. 2.7 Conclusion. References. 3 Erlangen Slot Machine: An FPGA-Based Dynamically Reconfigurable Computing Platform; J.Angermeier, C.Bobda, M.Majer, J.Teich. 3.1 Introduction. 3.2 Drawbacks of existing dynamically reconfigurable systems. 3.3 The Erlangen Slot Machine. 3.4 Inter-module Communications. 3.5 Reconfiguration Manager. 3.6 Case Study: Video and audio streaming. 3.7 Usage of the ESM in different fields. 3.8 Conclusions. References. Part II Design Methods and Tools - Modeling, Evaluation and Compilation 4 Models and Algorithms for Hyperreconfigurable Hardware; S.Lange, M.Middendorf. 4.1 Introduction. 4.2 Hyperreconfigurable Machines. 4.3 Example Architectures and Test Cases. 4.4 The Partition into Hypercontexts Problem. 4.5 Diverse Granularity in Multi-level Reconfigurable Systems. 4.6 Partial Reconfiguration and Hyperreconfiguration. 4.7 Conclusions. References. 5 Evaluation and Design Methods for Processor-Like Reconfigurable Architectures; S.Eisenhardt, T.Schweizer, J.Oliveira Filho, T.Kuhn, W.Rosenstiel. 5.1 Introduction. 5.2 Benefits and Costs of Processor-LikeReconfiguration. 5.3 Specialization / Instruction Set Extension. 5.4 Optimizing Power. 5.5 Optimizing External Reconfiguration . 5.6 Conclusion. References. 6 Adaptive Computing Systems and their Design Tools; A.Koch. 6.1 Introduction. 6.2 Execution Model. 6.3 ACS Architecture. 6.4 Hardware/Software Co-Compilation Flow. 6.5 Infrastructure. 6.6 Lessons Learned. 6.7 Future Work. 6.8 Conclusions. References. 7 POLYDYN- Object-oriented modelling and synthesis targeting dynamically reconfigurable FPGAs; A.Schallenberg, W.Nebel, A.Herrholz, P.A. Hartmann, K.Gruttner, F.Oppenheimer. 7.1 Introduction. 7.2 Related work. 7.3 Methodology. 7.4 Derived interface classes. 7.5 Modelling example: Car audio system. 7.6 Synthesising OSSS+R. 7.7 Evaluation. 7.8 Conclusion and Future Work. References. Part III Design Methods and Tools - Optimization and Runtime Systems 8 Design Methods and Tools for Improved Partial Dynamic Reconfiguration; M.Rullmann, R.Merker. 8.1 Introduction. 8.2 Motivation. 8.3 Reconfigurable Module Architecture and Partitioning. 8.4 Reconfiguration State Graph. 8.5 Module Mapping and Virtual Architecture. 8.6 High-Level Synthesis of Reconfigurable Modules. 8.7 Experiments. 8.8 System Design for Efficient Partial Dynamic Reconfiguration. References. 9 Dynamic Partial Reconfiguration by Means of Algorithmic Skeletons - A Case Study -; N.Montealegre, F.J. Rammig. 9.1 Introduction. 9.2 Overview of the overall system. 9.3 Library of Algorithmic Skeletons. 9.4 Application Scenario: Channel Vocoder Analyzer. 9.5 Conclusion. References. 10 ReCoNodes - Optimization Methods for Module Scheduling and Placement on Reconfigurable Hardware Devices; A.Ahmadinia, J.Angermeier, S.P. Fekete, T.Kamphans, D.Koch, M.Majer, N.Schweer, J.Teich, C.Tessars, J.C. van der Veen. 10.1 Introduction. 10.2 Offline and