Power Electronics Modeling and Simulation Training by Tonex
Power Electronics Modeling and Simulation Training by Tonex provides a practical, engineering-focused foundation for modeling converters, switching devices, control behavior, thermal effects, grid interfaces, batteries, and motor drives. Participants learn how to represent power electronic systems with accuracy, evaluate performance under operating stress, and support better design decisions for renewable energy, electric vehicles, industrial drives, and advanced electrical platforms. The course also addresses cybersecurity concerns in connected power electronics environments. Digitally controlled converters, EV chargers, grid-tied inverters, and energy storage systems can be exposed to firmware manipulation, unauthorized access, and data integrity risks. Engineers must understand how modeling supports safer design, anomaly detection, and resilient system behavior.
Learning Objectives
- Understand core modeling principles for power electronic circuits and systems.
- Analyze converter behavior across steady-state and transient operating conditions.
- Evaluate switching device characteristics, losses, and performance limitations.
- Develop PWM and control models for regulated power conversion.
- Assess thermal, reliability, and efficiency factors in power electronics design.
- Understand how cybersecurity affects connected converters, grid interfaces, EV chargers, and digitally controlled power systems.
Audience
- Power electronics engineers
- Electrical engineers
- Renewable energy engineers
- EV engineers
- Motor drive engineers
- Grid integration engineers
- Control system engineers
- Energy storage professionals
- Cybersecurity Professionals
Course Modules:
Module 1: Power Electronics Modeling Foundations
- Power conversion system overview
- Electrical model assumptions
- Continuous and discrete behavior
- Time-domain response analysis
- Steady-state operating points
- Model validation principles
Module 2: Converter Topology Analysis
- Buck converter behavior
- Boost converter operation
- Buck-boost conversion principles
- Inverter circuit structures
- Rectifier operating modes
- Isolated converter architectures
Module 3: Switching Device Models
- MOSFET electrical behavior
- IGBT performance characteristics
- Diode recovery effects
- Gate drive representation
- Switching loss estimation
- Device stress evaluation
Module 4: PWM Control Modeling
- PWM signal generation
- Duty-cycle control methods
- Closed-loop feedback behavior
- Current control techniques
- Voltage regulation methods
- Controller stability review
Module 5: Thermal Electrical Effects
- Heat generation mechanisms
- Junction temperature estimation
- Thermal resistance networks
- Cooling method evaluation
- Temperature-dependent losses
- Electrothermal model correlation
Module 6: Grid Battery Drive Systems
- Grid-connected inverter behavior
- Power factor control
- Battery converter interaction
- Motor drive performance
- Efficiency trend analysis
- Reliability risk assessment
Power Electronics Modeling and Simulation Training by Tonex helps engineering teams build stronger design judgment, improve converter performance, and support safer deployment of advanced electrified systems. Enroll in Power Electronics Modeling and Simulation Training by Tonex to strengthen practical power electronics modeling skills for modern energy, EV, and grid-connected applications.