Every year a million pilgrims travel to the shrine of Lord Ayyappa in Sabarimala in what has become the second-largest pilgrimage phenomenon in the world. The origins of the deity Ayyappa can be traced to antiquity; however, it is only in the last four decades that the movement has gained momentum and popularity, spreading beyond the parochial limits of Kerala. This book gives a detailed study of the activities associated with the temple and deity.
Every year a million pilgrims travel to the shrine of Lord Ayyappa in Sabarimala in what has become the second-largest pilgrimage phenomenon in the world. The origins of the deity Ayyappa can be traced to antiquity; however, it is only in the last four decades that the movement has gained momentum and popularity, spreading beyond the parochial limits of Kerala. This book gives a detailed study of the activities associated with the temple and deity.
Approximate Analytical Methods for Solving Ordinary Differential Equations (ODEs) is the first book to present all of the available approximate methods for solving ODEs, eliminating the need to wade through multiple books and articles. It covers both well-established techniques and recently developed procedures, including the classical series solution method, diverse perturbation methods, pioneering asymptotic methods, and the latest homotopy methods. The book is suitable not only for mathematicians and engineers but also for biologists, physicists, and economists. It gives a complete description of the methods without going deep into rigorous mathematical aspects. Detailed examples illustrate the application of the methods to solve real-world problems. The authors introduce the classical power series method for solving differential equations before moving on to asymptotic methods. They next show how perturbation methods are used to understand physical phenomena whose mathematical formulation involves a perturbation parameter and explain how the multiple-scale technique solves problems whose solution cannot be completely described on a single timescale. They then describe the Wentzel, Kramers, and Brillown (WKB) method that helps solve both problems that oscillate rapidly and problems that have a sudden change in the behavior of the solution function at a point in the interval. The book concludes with recent nonperturbation methods that provide solutions to a much wider class of problems and recent analytical methods based on the concept of homotopy of topology.
Thank you for visiting our website. Would you like to provide feedback on how we could improve your experience?
This site does not use any third party cookies with one exception — it uses cookies from Google to deliver its services and to analyze traffic.Learn More.