Nonlinear analysis of DC-DC converter using symbolic sequence method
Details
Power converters are found to be the indispensable part in power supplies. Under the influence of wide load variations and supply disturbances, they invariably exhibit various complex dynamic behaviors owing to its inherent nonlinearity. To operate a system in the stable period-1 regime for wide range of parameter space, effective controller designs have been a challenge to researchers in power electronics field. In spite of several control schemes are in vogue, still there is the prevalence of anomalous behavior in such systems. In this book, the complex behavior of buck-boost converter is investigated in detail using symbolic sequences and complexity measures. Input voltage is taken as bifurcation parameter for analysis. Primary and secondary symbolic sequences are built and utilized to categorize different types of smooth and non-smooth bifurcations. The concept of weight complexity, Lempel and Ziv (L-Z) complexity, and block entropy are implemented to quantify the bifurcation phenomenon of the system. The stability is known from the stability index based on weight and L-Z complexities. Such analysis of the system is essential to provide a route path for design engineers.
Autorentext
Kavitha Muppala Kumar: Received B.E. degree from Madras University and M.E. degree in power electronics and drives from the College of Engineering, Guindy, Anna University. Assistant Professor at SRM Institute of Science and Technology, Kattankulathur and have more than 10 years teaching experience. Life Member of ISTE and an annual member of ISCA.
Weitere Informationen
- Allgemeine Informationen- GTIN 09786139814350
- Sprache Englisch
- Größe H220mm x B150mm x T4mm
- Jahr 2018
- EAN 9786139814350
- Format Kartonierter Einband
- ISBN 6139814359
- Veröffentlichung 16.05.2018
- Titel Nonlinear analysis of DC-DC converter using symbolic sequence method
- Autor Kavitha Muppala Kumar , Kavitha Anbukumar
- Gewicht 96g
- Herausgeber LAP LAMBERT Academic Publishing
- Anzahl Seiten 52
- Genre Mathematik
 
 
    
