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Sliding Mode Control of Power Converters in Renewable Energy Systems
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Renewable energies are becoming a must to counteract the consequences of the global warming. More efficient devices and better control strategies are required in the generation, transport, and conversion of electricity. Energy is processed by power converters that are currently the key building blocks in modern power distribution systems. The associated electrical architecture is based on buses for energy distribution and uses a great number of converters for interfacing both input and output energy. This book shows that sliding-mode control is contributing to improve the performances of power converters by means of accurate theoretical analyses that result in efficient implementations. The sliding-mode control of power converters for renewable energy applications offers a panoramic view of the most recent uses of this regulation technique in practical cases. By presenting examples that range from dozens of kilowatts to only a few watts, the book covers control solutions for AC–DC and DC–AC generation, power factor correction, multilevel converters, constant-power load supply, wind energy systems, efficient lighting, digital control implementation, multiphase converters, and energy harvesting. The selected examples developed by recognized specialists are illustrated by means of detailed simulations and experiments to help the reader to understand the theoretical approach in each case considered in the book.
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Keywords
- AC-DC power converter
- adaptive-gain second-order sliding mode
- balanced and unbalanced grid voltage
- boost converter
- bridgeless rectifier
- buck converter
- constant power load
- constant power load (CPL)
- continuous signal generator
- Control
- DC distribution bus
- dc-dc converter
- DC-DC converters
- DC-DC power converter
- dc-to-dc converter
- Decision making
- design concept
- DFIG
- direct power control
- disturbance observer
- doubly-fed induction generator
- dual boost inverter
- dual-stator winding induction generator
- Electric vehicles
- Energy harvesting
- equivalent control
- fast dynamic response
- fixed switching frequency
- grid connection
- grid-side converter
- harmonic distortion
- Harvesting
- high power factor rectifier
- High-Intensity Discharge Lamps (HID)
- History of engineering & technology
- Induction Electrodeless Fluorescent Lamps (IEFL)
- inductive transducer
- input-output linearization
- inrush current mitigation
- isolated PFC rectifier
- isolated SEPIC converter
- loss free resistor
- loss-free resistor (LFR)
- Lyapunov stability
- Lyapunov-based filter design
- microinverter
- modular multilevel converter
- multi-objective optimisation
- multiphase converter
- output regulation
- power converter
- Power-Hardware-in-the-Loop
- PWM
- Renewable energy systems
- second order sliding mode
- second-order sliding-mode control
- series-series-compensated wireless power transfer system
- sliding mode
- Sliding mode control
- sliding mode control (SMC)
- sliding mode control (SMC), self-oscillating system
- Sliding Mode controlled power module
- sliding-mode control
- state feedback
- step-up inverter
- Technology, engineering, agriculture
- Technology: general issues
- Tuning
- two cascaded-boosts converters
- two-loop digital control
- unbalanced voltage
- Wind energy
- wind energy conversion system
- wind power generation
- zero dynamics stability
Links
DOI: 10.3390/books978-3-03928-099-5Editions