Concepts of Metaheuristics

Definition of Particle Swarm Optimization (PSO) Particle Swarm Optimization (PSO) is a population-based stochastic optimization technique inspired by the social behavior of birds flocking or fish schooling. In PSO, a group of candidate solutions, called particles, move around the search space to find the optimal solution through cooperation and communication. Brief history of PSO PSO was first introduced by Kennedy and Eberhart in 1995 as a way to optimize continuous nonlinear functions. Since then, it has been widely used in various fields such as engineering, economics, and biology for solving complex optimization problems. Importance of PSO in optimization problems PSO has proven to be effective in finding solutions to problems with high-dimensional search spaces and non-linear constraints. Its ability to quickly converge to near-optimal solutions makes it a valuable tool for researchers and practitioners facing complex optimization challenges. PSO's ability to efficiently explo

 The Moth Flame Optimization algorithm was first introduced in 2015 by Seyedali Mirjalili as a nature-inspired metaheuristic algorithm based on the behavior of moths seeking light sources in the dark.  This algorithm has shown promising results in solving complex optimization problems and has been compared favorably with other popular optimization algorithms such as Genetic Algorithms and Particle Swarm Optimization.  In various fields such as engineering, finance, and biology, MFO has been successfully applied to optimize parameters, design structures, and solve real-world problems efficiently.  One key advantage of the Moth Flame Optimization algorithm is its ability to quickly converge to the global optimum solution, making it a valuable tool for researchers and practitioners alike.  Additionally, MFO is known for its simplicity and ease of implementation, making it accessible to a wide range of users with varying levels of expertise in optimization techniques. Its effectiveness in

The concept of dynamic soaring by Albatrosses, a large seabird, can be used in optimization by flying long distances without using their muscles. This flight pattern, similar to riding a sidewinding rollercoaster, can fly up to 10,000 miles in a single journey and circumnavigate the earth in 46 days. Dynamic soaring consists of four phases: upward bend, upward climb, downward bend, and downward dive. Criteria for dynamic soaring include no wind, no waves, wave-slope soaring in swell without wind, and wind-shear soaring in wind without waves. Founding and Honorary Editor Innovate for Sustainability Subscribe to this blog Publish your book with EIS Publishers Instructor of Self Paced Course on Six-week course on Introduction to Remote Sensing and GIS Sponsored by Ashwagandha and Other Products for Enhancing Immunity.. Nutrilite(Use 13238584 as ABO ID) Procure Hydrology Themed T-Shirts from Innovate S Returns from commissions donated to NGOs after deducting the cost of honorarium and

Techniques known as "Cat Swarm Optimisation" (CSO) are based on an optimisation algorithm inspired by nature and the collective behaviour of cats. CSO mimics the cooperation and communication among a group of cats to tackle complex optimisation issues. It is inspired by the hunting behaviour and social interactions of cats. These methods' capacity to efficiently explore broad search spaces and identify ideal answers has drawn a lot of attention in recent years.  The capacity of CSO approaches to manage high-dimensional and non-linear optimisation issues is one of its main benefits. Because of this, they can be used in a variety of industries and domains, including data mining, engineering, and finance. Furthermore, CSO algorithms are renowned for their resilience and capacity to function in unpredictable and noisy conditions.  Founding and Honorary Editor Innovate for Sustainability Subscribe to this blog Publish your book with EIS Publishers Instructor of Self Paced Co