Popis: |
In industrial environments, efficient indoor transportation is a cornerstone of streamlined operations. However, the availability of high-end robotic transportation systems often poses a challenge for small-scale manufacturers due to their prohibitive costs. Addressing this disparity, this research introduces “Pony”, an innovative and cost-effective semi-autonomous self-driven robotic system tailored for indoor transportation purposes. Built upon a microcontroller-based platform, Pony harnesses low-cost technology to create and store m-graphs effectively, facilitating seamless navigation within indoor facilities. Moreover, the study presents a novel Pruned-BFS (P-BFS) algorithm designed to efficiently traverse m-graphs, outperforming conventional graph-traversal approaches. Furthermore, the experimental validation in the study encompasses a comprehensive evaluation of Pony’s performance across a range of scenarios. Randomly generated graphs, varying in complexity from 26 to 200 nodes, serve as the testing ground. Notably, four distinct algorithms—Breadth First Seach (BFS), Depth First Search (DFS), Iterative DFS (ID), and P-BFS are put through their paces during numerous random walks on each graph. A meticulously executed full factorial design of the experiment demonstrates statistical significance in execution time, and the number of nodes traversed, further underscoring Pony’s prowess. By converging affordability, AI-driven intelligence, and robust performance, Pony heralds a promising evolution in the landscape of indoor robotic transportation. |