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International Journal of System Dynamics Applications (IJSDA) Volume 3, Issue 3

Book Description

The International Journal of System Dynamics Applications (IJSDA) publishes original scientific and quality research on the theory of and advances in dynamical systems with analyses of measure-theoretical and topological aspects. This interdisciplinary journal provides audiences with an extensive exploration of the perspectives and methods of system dynamics and system thinking, which are applied to systems in the fields of engineering, soft computing, economics, management, and medicine, among others. The journal also covers strongly related research areas including control, automation, soft-computing and systems. IJSDA publishes original articles, reviews, technical reports, patent alerts, and case studies on the latest innovative findings of new methodologies and techniques. The journal welcomes active participation and contribution by researchers, not only by submitting original works but also by making constructive suggestions for improving the journal. IJSDA appeals to academics, researchers, and professionals in the fields of engineering, modeling, and computer simulation, decision analysis, soft computing, control systems, biomedical modeling, dynamical systems, applied mathematics, statistics, natural sciences, policy analysis, management science, economics, and behavioural sciences.

This issue contains the following articles:

  • Load Frequency Control in Power System via Improving PID Controller Based on Particle Swarm Optimization and ANFIS Techniques
  • Synthesis of Controllers for MIMO Systems with Time Response Specifications
  • A Remote and Sensorless Stator Winding Temperature Estimation Method for Thermal Protection for Induction Motor
  • Voltage Swell Mitigation Using Flexible AC Transmission Systems Based on Evolutionary Computing Methods
  • A System Dynamics Approach to Humanitarian Logistics and the Transportation of Relief Supplies
  • Neural Networks Predictive Controller Using an Adaptive Control Rate

Table of Contents

  1. Cover
  2. Masthead
  3. Call For Articles
  4. Load Frequency Control in Power System via Improving PID Controller Based on Particle Swarm Optimization and ANFIS Techniques
    1. ABSTRACT
    2. 1. INTRODUCTION
    3. 2. LITERATURE REVIEW
    4. 3. OVERVIEW ON PRACTICAL SWARM OPTIMIZATION TECHNIQUE
    5. 4. PREFACE TO FUZZY LOGIC
    6. 5. CASES STUDY
    7. 6. COMPARATIVE STUDY
    8. 7. CONCLUSION
    9. REFERENCES
  5. Synthesis of Controllers for MIMO Systems with Time Response Specifications
    1. ABSTRACT
    2. INTRODUCTION
    3. DECOPLING SYSTEM TECHNIQUE
    4. PROBLEM STATEMENT
    5. DESIGN OF CONTROLLERS
    6. GENERALIZED GEOMETRIC PROGRAMMING METHOD
    7. SIMULATION RESULTS
    8. DISCUSSION
    9. CONCLUSION AND FUTURE WORK
    10. REFERENCES
    11. APPENDIX B
  6. A Remote and Sensorless Stator Winding Temperature Estimation Method for Thermal Protection for Induction Motor
    1. ABSTRACT
    2. 1. INTRODUCTION
    3. 2. THERMAL BEHAVIOR FOR INDUCTION MOTOR
    4. 3. THE MODIFIED MOTOR MODEL RESULTS
    5. 4. RESULTS AND ANALYSIS
    6. 5. STATOR WINDING TEMPERATURE ESTIMATION RESULTS
    7. 6. CONCLUSION
    8. REFERENCES
  7. Voltage Swell Mitigation Using Flexible AC Transmission Systems Based on Evolutionary Computing Methods
    1. ABSTRACT
    2. 1. INTRODUCTION
    3. 2. FACTS TECHNOLOGY
    4. 3. PARTICLE SWARM OPTIMIZATION TECHNIQUE
    5. 4. RESULTS FOR SYSTEMS UNDER SIMULATIONS STUDY
    6. 5. CONCLUSION
    7. ACKNOWLEDGMENT
    8. REFERENCES
  8. A System Dynamics Approach to Humanitarian Logistics and the Transportation of Relief Supplies
    1. ABSTRACT
    2. INTRODUCTION
    3. LITERATURE REVIEW
    4. METHODOLOGY
    5. CONCLUSION
    6. LIMITATIONS AND FUTURE WORK
    7. REFERENCES
  9. Neural Networks Predictive Controller Using an Adaptive Control Rate
    1. ABSTRACT
    2. 1. INTRODUCTION
    3. 2. RELATED WORK
    4. 3. PROBLEM STATEMENT
    5. 4. PREDICTIVE CONTROL BASED ON NEURAL NETWORKS MODEL
    6. 5. STABILITY ANALYSIS
    7. 6. SIMULATION RESULTS
    8. 7. CONCLUSION
    9. REFERENCES
  10. Call For Articles