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SPS Software - Smart Power Simulations Software
A tool for efficient simulation of power systems and power electronics applications combined.
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Table of Contents
- Getting Started
- Blocks, Functions and Tools by Library
- Basics
- Power Converters
- Machines
- Power Transmission and Distribution
- Renewables
- Control and Measurements
- Simulation and Analysis
- powergui
- Load Flow Bus
- power_analyze
- power_init
- power_initstates
- power_report
- power_statespace
- power_steadystate
- power_ltiview
- FFT Analyzer
- Load Flow Analyzer
- Measurements and States Analyzer
- Impedance Measurement Tool
- Cable Parameter Calculator
- Linear System Analyzer
- Report Generator
- Statistical Flicker Level Analyzer
- Transformer Hysteresis Design Tool
- FACTS
- SPS-bibliography
- Example Models
- Command-Based Access to SPS Examples
- Get Started with SPS — Examples
- Steady-State Analysis of a Linear Circuit
- Transient Analysis of a Linear Circuit
- Full-Wave Rectifier
- Three-Phase Rectifier
- Variable Inductance Modeling
- Switching an Inductive Circuit Using a Breaker with No Snubber
- Three-Winding Distribution Transformer
- Three-Phase Saturable Transformer
- Current Transformer Saturation
- Use of Surge Arresters in Transmission System
- Time and Frequency Domain Testing of a Single Phase Line
- Single-Phase Energization of a Three-Phase Line
- Dynamic Load and Programmable Voltage Source
- Single Phase Dynamic Load Block
- Saturable Transformer with Hysteresis
- Cassie and Mayr Arc Models for a Circuit Breaker
- Inductive Current Chopping
- Three-Phase Three-Limb (Core-Type) Two-Winding Transformer
- Three-Phase Five-Limb (Shell-Type) Three-Winding Transformer
- Power Converters — Examples
- Boost Converter Example
- Buck Converter Example
- Voltage-Controlled Buck Converter
- Synchronous Buck Converter
- Buck Boost Converter
- Cuk Converter
- Forward Converter
- Flyback Converter with Transformer Leakage
- Resonant LLC Converter
- Regulated Resonant LLC Converter
- Series Load Resonant Converter
- Two-Quadrant DC/DC Converter Example
- Dual Active Bridge Converter DC/DC Converter
- AC/DC/AC Converter
- Single-Phase PWM Inverter
- AC/DC Three-Level PWM Converter
- Watkins-Johnson Converter
- Space-Vector PWM modulator
- Three-Level NPC Inverter Using Space-Vector PWM with Neutral-Point Voltage Control
- Five-Cell Multi-Level Converter
- Three-Phase 48-Pulse GTO Converter
- Three-Phase Matrix Converter
- Six-Pulse Cycloconverter
- Thyristor Rectifiers
- Current-Controlled Thyristor Rectifier
- Zener Diode Regulator
- Two- and Three-Level Voltage Source Controllers
- Switching Function Converter Controlled by Averaged Firing Pulses
- Speed Control of a DC Motor Using BJT H-Bridge
- Multilevel Multiphase Space-Vector PWM
- Two-Level PWM Converter and Dead Time
- Neutral Point Clamp Inverter and Dead Time
- Loss Calculation in a Three-Phase 3-Level Inverter
- Modular Multi-Level Converter
- Power Converters Modeling Techniques
- Energy Management Systems for a Hybrid Electric Source (Application for a More Electric Aircraft)
- Supercapacitor Model
- 6 kW 45 Vdc Fuel Cell Stack
- Machines — Examples
- Simplified Synchronous Machine - Speed Regulation
- Synchronous Machine
- Starting a Synchronous Motor
- Mechanical Coupling of Synchronous Generator with Exciter System Using the Simscape Mechanical Rotational Port
- Mechanical Coupling of Synchronous Generator with Exciter System
- Three-Phase Asynchronous Machine
- Saturation in Three-Phase Asynchronous Machine
- Single-Phase Asynchronous Machine
- Voltage Control of Auxiliary Winding of a Single-Phase Asynchronous Machine
- Vector Control of a Single-Phase Asynchronous Machine
- Permanent Magnet Synchronous Machine Example
- Brushless DC Motor Fed by Six-Step Inverter
- Five-Phase Permanent Magnet Synchronous Machine
- Starting a DC Motor
- Subsyncronous Resonance in Steam Turbine and Governor System
- Emergency Diesel-Generator and Asynchronous Motor
- Switched Reluctance Motor Example
- Six-Phase Synchronous Machine with Post-Fault Operating Strategy
- Stepper Motor Drive
- Motor Drives — Examples
- Speed Regulation of Brushless DC Motor Drive Using a Hysteresis-Based Current Controller
- Speed Regulation of a Brushless DC Motor Drive Using a Variable DC Link Six-Step Inverter
- Direct Torque Control of an Induction Motor Drive
- Direct Torque Control with Space Vector Modulation of an Induction Motor Drive
- Field-Oriented Control of an Induction Motor Drive Used in a Ground Transportation System
- Field-Oriented Control of an Interior Permanent Magnet Synchronous Motor
- Field-Oriented Control of a Surface Mounted Permanent Magnet Synchronous Motor
- Speed Regulation of a 6/4 Switched Reluctance Motor
- 1.5-MVA Multicell Motor Drive
- Mechanical Shaft Example
- Speed Reducer Example
- Mechanical Coupling of Two Motor Drives I
- Mechanical Coupling of Two Motor Drives II
- Winding Machine Example
- Robot Axis Control Using Brushless DC Motor Drives
- AC Drives - Examples
- DC Drives - Examples
- Power Transmission and Distribution — Examples
- OLTC Regulating Transformer
- Impact of GIC on Autotransformer Saturation
- MMC-STATCOM with 22 Power Modules per Phase
- MMC-STATCOM Connected to a 735-kV Transmission System
- HVDC-MMC Interconnection (1000-MW, +/- 320 kV)
- Thyristor-Based HVDC Transmission System
- Thyristor-Based HVDC Transmission System Average Model
- VSC-Based HVDC Transmission System
- STATCOM Phasor Model
- STATCOM
- D-STATCOM
- D-STATCOM Average Model
- Static Synchronous Series Compensator
- Static Var Compensator (SVC) Phasor Model
- Static Var Compensator (SVC)
- Thyristor Controlled Series Capacitor (TCSC) Phasor Model
- Thyristor Controlled Series Capacitor (TCSC)
- Static Var Compensator (SVC) and Power System Stabilizers (PSS)
- Unified Power Flow Controller (UPFC) Phasor Model
- Unified Power Flow Controller (UPFC)
- Delta-Hexagonal Phase Shifting Transformer
- OLTC Regulating Transformer Phasor Model
- Performance of Three PSS for Interarea Oscillations
- Power Flow Control and Line Deicing Using a Bundle-Controlled Line Impedance Modulator (LIM)
- Three-Phase Series Compensated Network
- Simple 6-Pulse HVDC Transmission System
- Three-Phase Harmonic Filters
- Three-Phase Active Harmonic Filter
- Single-Pole Reclosing of a Three-Phase Line
- Distance Protection Relay
- Renewables — Examples
- Single-Phase, 240 Vrms, 3500 W Transformerless Grid-Connected PV Array
- 250-kW Grid-Connected PV Array
- 400-kW Grid-Connected PV Farm
- Partial Shading of a PV Module
- PV Home On-Grid Solar System
- Detailed Model of a 100-kW Grid-Connected PV Array
- Average Model of a 100-kW Grid-Connected PV Array
- 2-MW PV Farm Connected to a 25-kV Distribution System
- Wind Farm - Induction Generator
- Wind-Turbine Asynchronous Generator in Isolated Network
- Wind Farm - Doubly-Fed Induction Generator (DFIG) Phasor Model
- Wind Farm - Doubly-Fed Induction Generator (DFIG)
- Wind Farm - Doubly-Fed Induction Generator (DFIG) Average Model
- Wind Farm - Synchronous Generator and Full Scale Converter (Type 4) Detailed Model
- Wind Farm - Synchronous Generator and Full Scale Converter (Type 4) Average Model
- Solid-Oxide Fuel Cell Connected to Three-Phase Electrical Power System
- Islanded Operation of an Inverter-based Microgrid Using Droop Control Technique
- Simplified Model of a Small Scale Micro-Grid
- 24-hour Simulation of a Vehicle-to-Grid (V2G) System
- One-Year Simulation in One Minute
- Control and Measurements — Examples
- Three-Phase Programmable Source, V-I Measurement and Sequence Analyzer
- Three-Phase Programmable Source, PLL, Voltage and Power Measurement
- Performance of Frequency Measurement (Phasor)
- Kundur's Two-Area System with PMU
- PMU (PLL-based, Positive-Sequence) Benchmark
- Flickermeter Statistical Analysis Module
- Flickermeter on a Distribution STATCOM
- Simulation and Analysis — Examples
- IEEE 13 Node Test Feeder
- Initializing a 5-Bus Network with the Load Flow Tool of Powergui
- Initializing a 29-Bus, 7-Power Plant Network with the Load Flow Tool of Powergui
- Four Coupled 66-kV Cables
- Interfacing Simulink Models with SPS
- Interfacing Simscape Models with SPS
- Increased Accuracy and Simulation Speed Using Interpolation
- Additional — Examples
- Acknowledgments