Invited Paper |
Invited Paper |
Invited Paper |
Invited Paper |
Invited Paper |
Invited Paper |
Invited Paper |
Invited Paper |
Invited Paper |
Invited Paper |
Invited Paper |
Integration of Traffic Simulation and Propulsion Modeling to Estimate Energy Consumption for Battery Electric Vehicles |
Integration of Traffic Simulation and Propulsion Modeling to Estimate Energy Consumption for Battery Electric Vehicles |
Integration of Traffic Simulation and Propulsion Modeling to Estimate Energy Consumption for Battery Electric Vehicles |
Integration of Traffic Simulation and Propulsion Modeling to Estimate Energy Consumption for Battery Electric Vehicles |
Integration of Traffic Simulation and Propulsion Modeling to Estimate Energy Consumption for Battery Electric Vehicles |
Integration of Traffic Simulation and Propulsion Modeling to Estimate Energy Consumption for Battery Electric Vehicles |
Integration of Traffic Simulation and Propulsion Modeling to Estimate Energy Consumption for Battery Electric Vehicles |
Full Papers |
Speeding Up the Evaluation of a Mathematical Model for VANETs Using OpenMP |
Speeding Up the Evaluation of a Mathematical Model for VANETs Using OpenMP |
Speeding Up the Evaluation of a Mathematical Model for VANETs Using OpenMP |
Speeding Up the Evaluation of a Mathematical Model for VANETs Using OpenMP |
Speeding Up the Evaluation of a Mathematical Model for VANETs Using OpenMP |
Speeding Up the Evaluation of a Mathematical Model for VANETs Using OpenMP |
Speeding Up the Evaluation of a Mathematical Model for VANETs Using OpenMP |
Speeding Up the Evaluation of a Mathematical Model for VANETs Using OpenMP |
Speeding Up the Evaluation of a Mathematical Model for VANETs Using OpenMP |
Speeding Up the Evaluation of a Mathematical Model for VANETs Using OpenMP |
Speeding Up the Evaluation of a Mathematical Model for VANETs Using OpenMP |
Speeding Up the Evaluation of a Mathematical Model for VANETs Using OpenMP |
Speeding Up the Evaluation of a Mathematical Model for VANETs Using OpenMP |
Speeding Up the Evaluation of a Mathematical Model for VANETs Using OpenMP |
Speeding Up the Evaluation of a Mathematical Model for VANETs Using OpenMP |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
The Stability Box for Minimizing TotalWeighted Flow Time under Uncertain Data |
Numerical Modelling of Nonlinear Diffusion Phenomena on a Sphere |
Numerical Modelling of Nonlinear Diffusion Phenomena on a Sphere |
Numerical Modelling of Nonlinear Diffusion Phenomena on a Sphere |
Numerical Modelling of Nonlinear Diffusion Phenomena on a Sphere |
Numerical Modelling of Nonlinear Diffusion Phenomena on a Sphere |
Numerical Modelling of Nonlinear Diffusion Phenomena on a Sphere |
Numerical Modelling of Nonlinear Diffusion Phenomena on a Sphere |
Numerical Modelling of Nonlinear Diffusion Phenomena on a Sphere |
Numerical Modelling of Nonlinear Diffusion Phenomena on a Sphere |
Numerical Modelling of Nonlinear Diffusion Phenomena on a Sphere |
Numerical Modelling of Nonlinear Diffusion Phenomena on a Sphere |
Numerical Modelling of Nonlinear Diffusion Phenomena on a Sphere |
Numerical Modelling of Nonlinear Diffusion Phenomena on a Sphere |
Numerical Modelling of Nonlinear Diffusion Phenomena on a Sphere |
Simulation, Parameter Estimation and Optimization of an Industrial-Scale Evaporation System |
Simulation, Parameter Estimation and Optimization of an Industrial-Scale Evaporation System |
Simulation, Parameter Estimation and Optimization of an Industrial-Scale Evaporation System |
Simulation, Parameter Estimation and Optimization of an Industrial-Scale Evaporation System |
Simulation, Parameter Estimation and Optimization of an Industrial-Scale Evaporation System |
Simulation, Parameter Estimation and Optimization of an Industrial-Scale Evaporation System |
Simulation, Parameter Estimation and Optimization of an Industrial-Scale Evaporation System |
Simulation, Parameter Estimation and Optimization of an Industrial-Scale Evaporation System |
Simulation, Parameter Estimation and Optimization of an Industrial-Scale Evaporation System |
Simulation, Parameter Estimation and Optimization of an Industrial-Scale Evaporation System |
Simulation, Parameter Estimation and Optimization of an Industrial-Scale Evaporation System |
Simulation, Parameter Estimation and Optimization of an Industrial-Scale Evaporation System |
Simulation, Parameter Estimation and Optimization of an Industrial-Scale Evaporation System |
Simulation, Parameter Estimation and Optimization of an Industrial-Scale Evaporation System |
High Detailed Lava Flows Hazard Maps by a Cellular Automata Approach |
High Detailed Lava Flows Hazard Maps by a Cellular Automata Approach |
High Detailed Lava Flows Hazard Maps by a Cellular Automata Approach |
High Detailed Lava Flows Hazard Maps by a Cellular Automata Approach |
High Detailed Lava Flows Hazard Maps by a Cellular Automata Approach |
High Detailed Lava Flows Hazard Maps by a Cellular Automata Approach |
High Detailed Lava Flows Hazard Maps by a Cellular Automata Approach |
High Detailed Lava Flows Hazard Maps by a Cellular Automata Approach |
High Detailed Lava Flows Hazard Maps by a Cellular Automata Approach |
High Detailed Lava Flows Hazard Maps by a Cellular Automata Approach |
High Detailed Lava Flows Hazard Maps by a Cellular Automata Approach |
High Detailed Lava Flows Hazard Maps by a Cellular Automata Approach |
High Detailed Lava Flows Hazard Maps by a Cellular Automata Approach |
High Detailed Lava Flows Hazard Maps by a Cellular Automata Approach |
High Detailed Lava Flows Hazard Maps by a Cellular Automata Approach |
A Consistent Preliminary Design Process for Mechatronic Systems |
A Consistent Preliminary Design Process for Mechatronic Systems |
A Consistent Preliminary Design Process for Mechatronic Systems |
A Consistent Preliminary Design Process for Mechatronic Systems |
A Consistent Preliminary Design Process for Mechatronic Systems |
A Consistent Preliminary Design Process for Mechatronic Systems |
A Consistent Preliminary Design Process for Mechatronic Systems |
A Consistent Preliminary Design Process for Mechatronic Systems |
A Consistent Preliminary Design Process for Mechatronic Systems |
A Consistent Preliminary Design Process for Mechatronic Systems |
A Consistent Preliminary Design Process for Mechatronic Systems |
A Consistent Preliminary Design Process for Mechatronic Systems |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
A Process Based on the Model-Driven Architecture to Enable the Definition of Platform-Independent Simulation Models |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Dynamic Response of a Wind Farm Consisting of Doubly-Fed Induction Generators to Network Disturbance |
Educational Simulators for Industrial Process Control |
Educational Simulators for Industrial Process Control |
Educational Simulators for Industrial Process Control |
Educational Simulators for Industrial Process Control |
Educational Simulators for Industrial Process Control |
Educational Simulators for Industrial Process Control |
Educational Simulators for Industrial Process Control |
Educational Simulators for Industrial Process Control |
Educational Simulators for Industrial Process Control |
Educational Simulators for Industrial Process Control |
Educational Simulators for Industrial Process Control |
Educational Simulators for Industrial Process Control |
Educational Simulators for Industrial Process Control |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Simulation-Based Development of Safety Related Interlocks |
Modelling Molecular Processes by Individual-Based Simulations Applied to Actin Polymerisation |
Modelling Molecular Processes by Individual-Based Simulations Applied to Actin Polymerisation |
Modelling Molecular Processes by Individual-Based Simulations Applied to Actin Polymerisation |
Modelling Molecular Processes by Individual-Based Simulations Applied to Actin Polymerisation |
Modelling Molecular Processes by Individual-Based Simulations Applied to Actin Polymerisation |
Modelling Molecular Processes by Individual-Based Simulations Applied to Actin Polymerisation |
Modelling Molecular Processes by Individual-Based Simulations Applied to Actin Polymerisation |
Modelling Molecular Processes by Individual-Based Simulations Applied to Actin Polymerisation |
Modelling Molecular Processes by Individual-Based Simulations Applied to Actin Polymerisation |
Marine Ecosystem Model Calibration through Enhanced Surrogate-Based Optimization |
Marine Ecosystem Model Calibration through Enhanced Surrogate-Based Optimization |
Marine Ecosystem Model Calibration through Enhanced Surrogate-Based Optimization |
Marine Ecosystem Model Calibration through Enhanced Surrogate-Based Optimization |
Marine Ecosystem Model Calibration through Enhanced Surrogate-Based Optimization |
Marine Ecosystem Model Calibration through Enhanced Surrogate-Based Optimization |
Marine Ecosystem Model Calibration through Enhanced Surrogate-Based Optimization |
Marine Ecosystem Model Calibration through Enhanced Surrogate-Based Optimization |
Marine Ecosystem Model Calibration through Enhanced Surrogate-Based Optimization |
Marine Ecosystem Model Calibration through Enhanced Surrogate-Based Optimization |
Marine Ecosystem Model Calibration through Enhanced Surrogate-Based Optimization |
Marine Ecosystem Model Calibration through Enhanced Surrogate-Based Optimization |
Marine Ecosystem Model Calibration through Enhanced Surrogate-Based Optimization |
Marine Ecosystem Model Calibration through Enhanced Surrogate-Based Optimization |
Marine Ecosystem Model Calibration through Enhanced Surrogate-Based Optimization |
Marine Ecosystem Model Calibration through Enhanced Surrogate-Based Optimization |
Hydrodynamic Shape Optimization of Axisymmetric Bodies Using Multi-fidelity Modeling |
Hydrodynamic Shape Optimization of Axisymmetric Bodies Using Multi-fidelity Modeling |
Hydrodynamic Shape Optimization of Axisymmetric Bodies Using Multi-fidelity Modeling |
Hydrodynamic Shape Optimization of Axisymmetric Bodies Using Multi-fidelity Modeling |
Hydrodynamic Shape Optimization of Axisymmetric Bodies Using Multi-fidelity Modeling |
Hydrodynamic Shape Optimization of Axisymmetric Bodies Using Multi-fidelity Modeling |
Hydrodynamic Shape Optimization of Axisymmetric Bodies Using Multi-fidelity Modeling |
Hydrodynamic Shape Optimization of Axisymmetric Bodies Using Multi-fidelity Modeling |
Hydrodynamic Shape Optimization of Axisymmetric Bodies Using Multi-fidelity Modeling |
Hydrodynamic Shape Optimization of Axisymmetric Bodies Using Multi-fidelity Modeling |
Hydrodynamic Shape Optimization of Axisymmetric Bodies Using Multi-fidelity Modeling |
Hydrodynamic Shape Optimization of Axisymmetric Bodies Using Multi-fidelity Modeling |
Hydrodynamic Shape Optimization of Axisymmetric Bodies Using Multi-fidelity Modeling |
Hydrodynamic Shape Optimization of Axisymmetric Bodies Using Multi-fidelity Modeling |
Hydrodynamic Shape Optimization of Axisymmetric Bodies Using Multi-fidelity Modeling |
Analysis of Bulky Crash Simulation Results: Deterministic and Stochastic Aspects |
Analysis of Bulky Crash Simulation Results: Deterministic and Stochastic Aspects |
Analysis of Bulky Crash Simulation Results: Deterministic and Stochastic Aspects |
Analysis of Bulky Crash Simulation Results: Deterministic and Stochastic Aspects |
Analysis of Bulky Crash Simulation Results: Deterministic and Stochastic Aspects |
Analysis of Bulky Crash Simulation Results: Deterministic and Stochastic Aspects |
Analysis of Bulky Crash Simulation Results: Deterministic and Stochastic Aspects |
Analysis of Bulky Crash Simulation Results: Deterministic and Stochastic Aspects |
Analysis of Bulky Crash Simulation Results: Deterministic and Stochastic Aspects |
Analysis of Bulky Crash Simulation Results: Deterministic and Stochastic Aspects |
Analysis of Bulky Crash Simulation Results: Deterministic and Stochastic Aspects |
Analysis of Bulky Crash Simulation Results: Deterministic and Stochastic Aspects |
Analysis of Bulky Crash Simulation Results: Deterministic and Stochastic Aspects |
Integration of Optimization to the Design of Pulp and Paper Production Processes |
Integration of Optimization to the Design of Pulp and Paper Production Processes |
Integration of Optimization to the Design of Pulp and Paper Production Processes |
Integration of Optimization to the Design of Pulp and Paper Production Processes |
Integration of Optimization to the Design of Pulp and Paper Production Processes |
Integration of Optimization to the Design of Pulp and Paper Production Processes |
Integration of Optimization to the Design of Pulp and Paper Production Processes |
Integration of Optimization to the Design of Pulp and Paper Production Processes |
Integration of Optimization to the Design of Pulp and Paper Production Processes |
Integration of Optimization to the Design of Pulp and Paper Production Processes |
Integration of Optimization to the Design of Pulp and Paper Production Processes |
Integration of Optimization to the Design of Pulp and Paper Production Processes |
Integration of Optimization to the Design of Pulp and Paper Production Processes |
Integration of Optimization to the Design of Pulp and Paper Production Processes |
Integration of Optimization to the Design of Pulp and Paper Production Processes |
Integration of Optimization to the Design of Pulp and Paper Production Processes |
Variation-Aware Circuit Macromodeling and Design Based on Surrogate Models |
Variation-Aware Circuit Macromodeling and Design Based on Surrogate Models |
Variation-Aware Circuit Macromodeling and Design Based on Surrogate Models |
Variation-Aware Circuit Macromodeling and Design Based on Surrogate Models |
Variation-Aware Circuit Macromodeling and Design Based on Surrogate Models |
Variation-Aware Circuit Macromodeling and Design Based on Surrogate Models |
Variation-Aware Circuit Macromodeling and Design Based on Surrogate Models |
Variation-Aware Circuit Macromodeling and Design Based on Surrogate Models |
Variation-Aware Circuit Macromodeling and Design Based on Surrogate Models |
Variation-Aware Circuit Macromodeling and Design Based on Surrogate Models |
Variation-Aware Circuit Macromodeling and Design Based on Surrogate Models |
Variation-Aware Circuit Macromodeling and Design Based on Surrogate Models |
Variation-Aware Circuit Macromodeling and Design Based on Surrogate Models |
Variation-Aware Circuit Macromodeling and Design Based on Surrogate Models |
Variation-Aware Circuit Macromodeling and Design Based on Surrogate Models |
Analysis and Optimization of Bevel Gear Cutting Processes by Means of Manufacturing Simulation |
Analysis and Optimization of Bevel Gear Cutting Processes by Means of Manufacturing Simulation |
Analysis and Optimization of Bevel Gear Cutting Processes by Means of Manufacturing Simulation |
Analysis and Optimization of Bevel Gear Cutting Processes by Means of Manufacturing Simulation |
Analysis and Optimization of Bevel Gear Cutting Processes by Means of Manufacturing Simulation |
Analysis and Optimization of Bevel Gear Cutting Processes by Means of Manufacturing Simulation |
Analysis and Optimization of Bevel Gear Cutting Processes by Means of Manufacturing Simulation |
Analysis and Optimization of Bevel Gear Cutting Processes by Means of Manufacturing Simulation |
Analysis and Optimization of Bevel Gear Cutting Processes by Means of Manufacturing Simulation |
Analysis and Optimization of Bevel Gear Cutting Processes by Means of Manufacturing Simulation |
Analysis and Optimization of Bevel Gear Cutting Processes by Means of Manufacturing Simulation |
Analysis and Optimization of Bevel Gear Cutting Processes by Means of Manufacturing Simulation |
Analysis and Optimization of Bevel Gear Cutting Processes by Means of Manufacturing Simulation |
Analysis and Optimization of Bevel Gear Cutting Processes by Means of Manufacturing Simulation |