Kooperativer Bibliotheksverbund

UID:

Format: 1 online resource (561 p.)

Edition: Jade ed.

ISBN: 1-283-28820-6 , 9786613288202 , 0-12-385964-6

Series Statement: Applications of GPU computing series

Content: "Since the introduction of CUDA in 2007, more than 100 million computers with CUDA capable GPUs have been shipped to end users. GPU computing application developers can now expect their application to have a mass market. With the introduction of OpenCL in 2010, researchers can now expect to develop GPU applications that can run on hardware from multiple vendors"--

Note: Description based upon print version of record. , Machine generated contents note: Part 1: Parallel Algorithms and Data Structures - Paulius Micikevicius, NVIDIA 1 Large-Scale GPU Search 2 Edge v. Node Parallelism for Graph Centrality Metrics 3 Optimizing parallel prefix operations for the Fermi architecture 4 Building an Efficient Hash Table on the GPU 5 An Efficient CUDA Algorithm for the Maximum Network Flow Problem 6 On Improved Memory Access Patterns for Cellular Automata Using CUDA 7 Fast Minimum Spanning Tree Computation on Large Graphs 8 Fast in-place sorting with CUDA based on bitonic sort Part 2: Numerical Algorithms - Frank Jargstorff, NVIDIA 9 Interval Arithmetic in CUDA 10 Approximating the erfinv Function 11 A Hybrid Method for Solving Tridiagonal Systems on the GPU 12 LU Decomposition in CULA 13 GPU Accelerated Derivative-free Optimization Part 3: Engineering Simulation - Peng Wang, NVIDIA 14 Large-scale gas turbine simulations on GPU clusters 15 GPU acceleration of rarefied gas dynamic simulations 16 Assembly of Finite Element Methods on Graphics Processors 17 CUDA implementation of Vertex-Centered, Finite Volume CFD methods on Unstructured Grids with Flow Control Applications 18 Solving Wave Equations on Unstructured Geometries 19 Fast electromagnetic integral equation solvers on graphics processing units (GPUs) Part 4: Interactive Physics for Games and Engineering Simulation - Richard Tonge, NVIDIA 20 Solving Large Multi-Body Dynamics Problems on the GPU 21 Implicit FEM Solver in CUDA 22 Real-time Adaptive GPU multi-agent path planning Part 5: Computational Finance - Thomas Bradley, NVIDIA 23 High performance finite difference PDE solvers on GPUs for financial option pricing 24 Identifying and Mitigating Credit Risk using Large-scale Economic Capital Simulations 25 Financial Market Value-at-Risk Estimation using the Monte Carlo Method Part 6: Programming Tools and Techniques - Cliff Wooley, NVIDIA 26 Thrust: A Productivity-Oriented Library for CUDA 27 GPU Scripting and Code Generation with PyCUDA 28 Jacket: GPU Powered MATLAB Acceleration 29 Accelerating Development and Execution Speed with Just In Time GPU Code Generation 30 GPU Application Development, Debugging, and Performance Tuning with GPU Ocelot 31 Abstraction for AoS and SoA Layout in C++ 32 Processing Device Arrays with C++ Metaprogramming 33 GPU Metaprogramming: A Case Study in Biologically-Inspired Machine Vision 34 A Hybridization Methodology for High-Performance Linear Algebra Software for GPUs 35 Dynamic Load Balancing using Work-Stealing 36 Applying software-managed caching and CPU/GPU task scheduling for accelerating dynamic workloads. , English

Additional Edition: ISBN 0-12-385963-8

Language: English

UID:

Format: Online Ressource (xvi, 541 p., [16] p. of plates) , ill. (some col.)

Edition: Jade ed.

Edition: Online-Ausg.

ISBN: 0123859638 , 9780123859631 , 9780123859648 , 0123859646 , 1283288206 , 9781283288200

Series Statement: Applications of GPU computing series

Content: "Since the introduction of CUDA in 2007, more than 100 million computers with CUDA capable GPUs have been shipped to end users. GPU computing application developers can now expect their application to have a mass market. With the introduction of OpenCL in 2010, researchers can now expect to develop GPU applications that can run on hardware from multiple vendors"--

Note: Includes bibliographical references and index. - Description based on print version record , Large-scale GPU searchEdge v. node parallelism for graph centrality metrics -- Optimizing parallel prefix operations for the Fermi architecture -- Building an efficient hash table on the GPU -- Efficient CUDA algorithms for the maximum network flow problem -- Optimizing memory access patterns for cellular automata on GPUs -- Fast minimum spanning tree computation -- Comparison-based in-place sorting with CUDA -- Interval arithmetic in CUDA -- Approximating the erfinv function -- A hybrid method for solving tridiagonal systems on the GPU -- Accelerating CULA linear algebra routines with hybrid GPU and multicore computing -- GPU accelerated derivative-free mesh optimization -- Large-scale gas turbine simulations on GPU clusters -- GPU acceleration of rarefied gas dynamic simulations -- Application of assembly of finite element methods on graphics processors for real-time elastodynamics -- CUDA implementation of vertex-centered, finite volume CFD methods on unstructured grids with flow control applications -- Solving wave equations on unstructured geometries -- Fast electromagnetic integral equation solvers on graphics processing units (GPUs) -- Solving large multibody dynamics problems on the GPU -- Implicit FEM solver on GPU for interactive deformation simulation -- Real-time adaptive GPU multiagent path planning -- Pricing financial derivatives with high performance finite difference solvers on GPUs -- Large-scale credit risk loss simulation -- Monte Carlo-based financial market value-at-risk estimation on GPUs --Thrust : a productivity-oriented library for CUDA -- GPU scripting and code generation with PyCUDA -- Jacket : GPU powered MATLAB acceleration -- Accelerating development and execution speed with just-in-time GPU code generation -- GPU application development, debugging, and performance tuning with GPU Ocelot -- Abstraction for AoS and SoA layout in C++ -- Processing device arrays with C++ metaprogramming -- GPU metaprogramming : a case study in biologically inspired machine vision -- A hybridization methodology for high-performance linear algebra software for GPUs -- Dynamic load balancing using work-stealing -- Applying software-managed caching and CPU/GPU task scheduling for accelerating dynamic workloads. , Machine generated contents note: Part 1: Parallel Algorithms and Data Structures -- Paulius Micikevicius, NVIDIA 1 Large-Scale GPU Search 2 Edge v. Node Parallelism for Graph Centrality Metrics 3 Optimizing parallel prefix operations for the Fermi architecture 4 Building an Efficient Hash Table on the GPU 5 An Efficient CUDA Algorithm for the Maximum Network Flow Problem 6 On Improved Memory Access Patterns for Cellular Automata Using CUDA 7 Fast Minimum Spanning Tree Computation on Large Graphs 8 Fast in-place sorting with CUDA based on bitonic sort Part 2: Numerical Algorithms -- Frank Jargstorff, NVIDIA 9 Interval Arithmetic in CUDA 10 Approximating the erfinv Function 11 A Hybrid Method for Solving Tridiagonal Systems on the GPU 12 LU Decomposition in CULA 13 GPU Accelerated Derivative-free Optimization Part 3: Engineering Simulation -- Peng Wang, NVIDIA 14 Large-scale gas turbine simulations on GPU clusters 15 GPU acceleration of rarefied gas dynamic simulations 16 Assembly of Finite Element Methods on Graphics Processors 17 CUDA implementation of Vertex-Centered, Finite Volume CFD methods on Unstructured Grids with Flow Control Applications 18 Solving Wave Equations on Unstructured Geometries 19 Fast electromagnetic integral equation solvers on graphics processing units (GPUs) Part 4: Interactive Physics for Games and Engineering Simulation -- Richard Tonge, NVIDIA 20 Solving Large Multi-Body Dynamics Problems on the GPU 21 Implicit FEM Solver in CUDA 22 Real-time Adaptive GPU multi-agent path planning Part 5: Computational Finance -- Thomas Bradley, NVIDIA 23 High performance finite difference PDE solvers on GPUs for financial option pricing 24 Identifying and Mitigating Credit Risk using Large-scale Economic Capital Simulations 25 Financial Market Value-at-Risk Estimation using the Monte Carlo Method Part 6: Programming Tools and Techniques -- Cliff Wooley, NVIDIA 26 Thrust: A Productivity-Oriented Library for CUDA 27 GPU Scripting and Code Generation with PyCUDA 28 Jacket: GPU Powered MATLAB Acceleration 29 Accelerating Development and Execution Speed with Just In Time GPU Code Generation 30 GPU Application Development, Debugging, and Performance Tuning with GPU Ocelot 31 Abstraction for AoS and SoA Layout in C++ 32 Processing Device Arrays with C++ Metaprogramming 33 GPU Metaprogramming: A Case Study in Biologically-Inspired Machine Vision 34 A Hybridization Methodology for High-Performance Linear Algebra Software for GPUs 35 Dynamic Load Balancing using Work-Stealing 36 Applying software-managed caching and CPU/GPU task scheduling for accelerating dynamic workloads. , Part 1: Parallel Algorithms and Data Structures - Paulius Micikevicius, NVIDIA 1 Large-Scale GPU Search 2 Edge v. Node Parallelism for Graph Centrality Metrics 3 Optimizing parallel prefix operations for the Fermi architecture 4 Building an Efficient Hash Table on the GPU 5 An Efficient CUDA Algorithm for the Maximum Network Flow Problem 6 On Improved Memory Access Patterns for Cellular Automata Using CUDA 7 Fast Minimum Spanning Tree Computation on Large Graphs 8 Fast in-place sorting with CUDA based on bitonic sort Part 2: Numerical Algorithms - Frank Jargstorff, NVIDIA 9 Interval Arithmetic in CUDA 10 Approximating the erfinv Function 11 A Hybrid Method for Solving Tridiagonal Systems on the GPU 12 LU Decomposition in CULA 13 GPU Accelerated Derivative-free Optimization Part 3: Engineering Simulation - Peng Wang, NVIDIA 14 Large-scale gas turbine simulations on GPU clusters 15 GPU acceleration of rarefied gas dynamic simulations 16 Assembly of Finite Element Methods on Graphics Processors 17 CUDA implementation of Vertex-Centered, Finite Volume CFD methods on Unstructured Grids with Flow Control Applications 18 Solving Wave Equations on Unstructured Geometries 19 Fast electromagnetic integral equation solvers on graphics processing units (GPUs) Part 4: Interactive Physics for Games and Engineering Simulation - Richard Tonge, NVIDIA 20 Solving Large Multi-Body Dynamics Problems on the GPU 21 Implicit FEM Solver in CUDA 22 Real-time Adaptive GPU multi-agent path planning Part 5: Computational Finance - Thomas Bradley, NVIDIA 23 High performance finite difference PDE solvers on GPUs for financial option pricing 24 Identifying and Mitigating Credit Risk using Large-scale Economic Capital Simulations 25 Financial Market Value-at-Risk Estimation using the Monte Carlo Method Part 6: Programming Tools and Techniques - Cliff Wooley, NVIDIA 26 Thrust: A Productivity-Oriented Library for CUDA 27 GPU Scripting and Code Generation with PyCUDA 28 Jacket: GPU Powered MATLAB Acceleration 29 Accelerating Development and Execution Speed with Just In Time GPU Code Generation 30 GPU Application Development, Debugging, and Performance Tuning with GPU Ocelot 31 Abstraction for AoS and SoA Layout in C++ 32 Processing Device Arrays with C++ Metaprogramming 33 GPU Metaprogramming: A Case Study in Biologically-Inspired Machine Vision 34 A Hybridization Methodology for High-Performance Linear Algebra Software for GPUs 35 Dynamic Load Balancing using Work-Stealing 36 Applying software-managed caching and CPU/GPU task scheduling for accelerating dynamic workloads.

Additional Edition: ISBN 0123859646

Additional Edition: ISBN 1283288206

Additional Edition: Druckausg. GPU computing gems Waltham, MA : Morgan Kaufmann, 2012 ISBN 9780123859631

Additional Edition: ISBN 0123859638

Language: English

Keywords: Grafikprozessor ; Bildverarbeitung ; Parallelverarbeitung ; Electronic books ; Electronic books ; Electronic books

URL: lizenzpflichtig

URL: Volltext

UID:

Format: XVI, 541 S. : , Ill., graph. Darst.

Edition: Jade ed.

ISBN: 978-0-12-385963-1

Series Statement: Morgan Kaufmann's applications of GPU computing series

Subjects: Computer Science

Keywords: Grafikprozessor ; CUDA ; Grafikprozessor ; Bildverarbeitung ; Parallelverarbeitung ; Aufsatzsammlung

UID:

Format: 1 Online-Ressource (xvi, 541 p., [16] p. of plates)

Edition: Jade ed

ISBN: 9780123859631 , 0123859638 , 9780123859648 , 0123859646 , 9781283288200 , 1283288206

Series Statement: Applications of GPU computing

Note: This is the second volume of Morgan Kaufmann's GPU Computing Gems, offering an all-new set of insights, ideas, and practical "hands-on" skills from researchers and developers worldwide. Each chapter gives you a window into the work being performed across a variety of application domains, and the opportunity to witness the impact of parallel GPU computing on the efficiency of scientific research. GPU Computing Gems: Jade Edition showcases the latest research solutions with GPGPU and CUDA, including: Improving memory access patterns for cellular automata using CUDA Large-scale gas turbine simulations on GPU clusters Identifying and mitigating credit risk using large-scale economic capital simulations GPU-powered MATLAB acceleration with Jacket Biologically-inspired machine vision An efficient CUDA algorithm for the maximum network flow problem 30 more chapters of innovative GPU computing ideas, written to be accessible to researchers from any industry GPU Computing Gems: Jade Edition contains 100% new material covering a variety of application domains: algorithms and data structures, engineering, interactive physics for games, computational finance, and programming tools. This second volume of GPU Computing Gems offers 100% new material of interest across industry, including finance, medicine, imaging, engineering, gaming, environmental science, green computing, and more Covers new tools and frameworks for productive GPU computing application development and offers immediate benefit to researchers developing improved programming environments for GPUs Even more hands-on, proven techniques demonstrating how general purpose GPU computing is changing scientific research Distills the best practices of the community of CUDA programmers; each chapter provides insights and ideas as well as 'hands on' skills applicable to a variety of fields , "Since the introduction of CUDA in 2007, more than 100 million computers with CUDA capable GPUs have been shipped to end users. GPU computing application developers can now expect their application to have a mass market. With the introduction of OpenCL in 2010, researchers can now expect to develop GPU applications that can run on hardware from multiple vendors"-- , Includes bibliographical references and index

Language: English

Keywords: Grafikprozessor ; Bildverarbeitung ; Parallelverarbeitung ; Grafikprozessor ; CUDA ; Aufsatzsammlung

URL: Volltext