Laser products descriptions.- Laser One dimensional flow and bifurcation.- Laser Negative Differential Resistance (NDR) circuits as a dynamical system, Laser circuits in topological structures, Laser circuits behavior investigation based on Eigen solutions and Eigenvalues characteristics and bifurcation.- Laser circuits two dimensional flow.- laser circuits with time delay parameters.- Laser circuits with time delay parameters Eigen solutions and Eigenvalues characteristics and bifurcation.- Laser circuits chaos characteristics.- Lasers bifurcation behaviors – Investigation, comparison and conclusion.

Dr. Ofer Aluf is a graduate of Ben-Gurion University (Israel), and holds a BSc degree in Electrical Engineering and an MSc in Physics. He has many years of experience on the high tech market in the following areas: system and integration engineering; application and support; wafers testing; chip design; RF and microwave systems verification; and semiconductors. His specialties include: circuits and systems; RF and microwave systems; RF and microwave antennas – design, simulation and analysis; RFID systems – design and simulation; electro-optics; High Power Laser Systems (HPLS); Laser Devices; Plasma Physics; Biological systems; non-linear dynamics; optical and electro-optical systems; RF/RFIC circuits – simulation and analysis; and biological systems analysis. He has published numerous refereed papers in professional and IEEE journals.   

This book on Advance Elements of Laser circuits and systems Nonlinearity applications in engineering addresses two separate engineering and scientific areas, and presents advanced analysis methods for Laser circuits and systems that cover a broad range of engineering and scientific applications. The book analyzed Laser circuits and systems as linear and nonlinear dynamical systems and there limit cycles, bifurcation, and limit cycle stability by using nonlinear dynamic theory. Further, it discussed a broad range of bifurcations related to Laser systems and circuits, starting from laser system differential equations and their bifurcations, delay differential equations (DDEs) are a function of time delays, delay dependent parameters, followed by phase plane analysis, limit cycles and their bifurcations, chaos, iterated maps, period doubling.