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PSpice for Power electronics. (S-HT MATPOWER)
PSpice Introduction Types of SPICE Types of Analysis PSPICE Platform PSpice Schematics Vs. OrCAD Capture SPICE Resources Circuit Descriptions Nodes Element Values, Circuit Elements, Element Models Sources Output Variables, Output Commands Types of Analysis PSpice Schematics Importing Microsim Schematics in OrCAD Capture Defining Output Variables DC Sweep and Transient Analysis AC Analysis Output Markers Noise Analysis Voltage and Current Sources Sources Modeling Independent Sources Dependent Sources Behavioral Device Modeling Passive Elements Gate/base drivers Modeling of Elements Operating Temperature RLC Elements Magnetic Elements and Transformers Lossless Transmission Lines Switches Dot Commands Models Types of Output Operating Temperature and End of Circuit Options DC Analysis AC Analysis Noise Analysis Transient Analysis Fourier Analysis Monte Carlo Analysis Sensitivity and Worst – Case Analysis Simulation Errors, Convergence Problems, and Other Difficulties Large Circuits Running Multiple Circuits Large Outputs Long Transient Runs Convergence Analysis Accuracy Negative Component Values Power Switching Circuits Floating Nodes Nodes with Fewer than Two Connections Voltage Source and Inductor Loops Running PSpice Files on Spice Running Spice Files on PSpice Using Earlier Version of Schematics PSpice FOR POWER ELECTRONICS Introduction to power Electronics and systems Definition and concepts Application Power semiconductor Switches Gate/base drivers Losses Snubbers. Modeling of Power Electronics Devices Power Diodes Power BJT Power MOSFET IGBT Thyristers Simulating power electronic circuits using PSpice V – I Characteristics of SCR Op Amp circuits Triggering Circuit Power MOSFET Characteristics IGBT Characteristics Triac Characteristics PSpice Based Simulation for Power Electronic Introduction Rectifier: AC to DC Converter Diode Rectifier Circuits Phase Controlled rectifiers DC Chopper: DC to DC converter DC to DC converter technology General Theory of Two-Level DC-DC Converters: Boost and Buck/Boost Converters Dynamic Modeling and Simulation of DC-DC converters Inverters: Converting DC to AC Single Phase Inverter Three Phase Inverter Multilevel Inverter AC Chopper: AC to AC Converter ON/OFF Control Phase Control Cyclo-converter: AC to AC Converter Single Phase Cyclo-converter Three Phase Cyclo-converter Additional Examples Comparator for Zero – Crossing Detection Sawtooth Wave Form Generation SPWM Inverter Driver Current Source Inverter Recent trends in modern power electronics Introduction Rectifier: AC to DC Converter Soft-Switching Single-Phase Three-Level Rectifier Vienna Converter 12 pulse Converter DC Chopper: DC to DC converter Six Leg Converter Interleaved Boost Converter Current Fed Resonance Boost DC – AC – DC Converter Inverters: Converting DC to AC Maximum Boost Z – Source Inverter Multi – input inverter Multi – inverter Topology AC Chopper: AC to AC Converter DC Modulated AC – AC Converter Matrix Converters
PSpice
Introduction Types of SPICE Types of Analysis PSPICE Platform PSpice Schematics Vs. OrCAD Capture SPICE Resources Circuit Descriptions Nodes Element Values, Circuit Elements, Element Models Sources Output Variables, Output Commands Types of Analysis PSpice Schematics Importing Microsim Schematics in OrCAD Capture Defining Output Variables DC Sweep and Transient Analysis AC Analysis Output Markers Noise Analysis Voltage and Current Sources Sources Modeling Independent Sources Dependent Sources Behavioral Device Modeling Passive Elements Gate/base drivers Modeling of Elements Operating Temperature RLC Elements Magnetic Elements and Transformers Lossless Transmission Lines Switches Dot Commands Models Types of Output Operating Temperature and End of Circuit Options DC Analysis AC Analysis Noise Analysis Transient Analysis Fourier Analysis Monte Carlo Analysis Sensitivity and Worst – Case Analysis Simulation Errors, Convergence Problems, and Other Difficulties Large Circuits Running Multiple Circuits Large Outputs Long Transient Runs Convergence Analysis Accuracy Negative Component Values Power Switching Circuits Floating Nodes Nodes with Fewer than Two Connections Voltage Source and Inductor Loops Running PSpice Files on Spice Running Spice Files on PSpice Using Earlier Version of Schematics PSpice FOR POWER ELECTRONICS Introduction to power Electronics and systems Definition and concepts Application Power semiconductor Switches Gate/base drivers Losses Snubbers. Modeling of Power Electronics Devices Power Diodes Power BJT Power MOSFET IGBT Thyristers Simulating power electronic circuits using PSpice V – I Characteristics of SCR Op Amp circuits Triggering Circuit Power MOSFET Characteristics IGBT Characteristics Triac Characteristics PSpice Based Simulation for Power Electronic Introduction Rectifier: AC to DC Converter Diode Rectifier Circuits Phase Controlled rectifiers DC Chopper: DC to DC converter DC to DC converter technology General Theory of Two-Level DC-DC Converters: Boost and Buck/Boost Converters Dynamic Modeling and Simulation of DC-DC converters Inverters: Converting DC to AC Single Phase Inverter Three Phase Inverter Multilevel Inverter AC Chopper: AC to AC Converter ON/OFF Control Phase Control Cyclo-converter: AC to AC Converter Single Phase Cyclo-converter Three Phase Cyclo-converter Additional Examples Comparator for Zero – Crossing Detection Sawtooth Wave Form Generation SPWM Inverter Driver Current Source Inverter Recent trends in modern power electronics Introduction Rectifier: AC to DC Converter Soft-Switching Single-Phase Three-Level Rectifier Vienna Converter 12 pulse Converter DC Chopper: DC to DC converter Six Leg Converter Interleaved Boost Converter Current Fed Resonance Boost DC – AC – DC Converter Inverters: Converting DC to AC Maximum Boost Z – Source Inverter Multi – input inverter Multi – inverter Topology AC Chopper: AC to AC Converter DC Modulated AC – AC Converter Matrix Converters
PSpice FOR POWER ELECTRONICS
