Unmanned Underwater Vehicles (UUVs) are extensively used in a variety of maritime applications, including ocean exploration, underwater surveillance, and rescue operations. With the development of autonomous navigation technologies, UUVs require not merely simple movement but also precise control performance for effective trajectory tracking and posture stabilization. The underwater environment introduces multiple disturbances such as ocean currents, buoyancy, and hydrodynamic resistance, which complicate the maintenance of accurate trajectories and stable attitudes for UUVs. To tackle these challenges, this study presents a methodology for automatically optimizing the gains of a Proportional-Integral-Derivative (PID) controller using Particle Swarm Optimization (PSO). Our control system is developed around a six-degree-of-freedom (6-DOF) dynamic model, and employs PSO to determine optimal control gains autonomously. This strategy increases adaptability to changes in the environment and enhances the efficiency of the PID control performance over traditional manual tuning methods. Furthermore, a numerical simulation is performed to assess the effectiveness of the control system by comparing the PSO-enhanced PID controller with a conventional Pole-Placement Method. The simulation outcomes demonstrate that the PSO-based PID controller achieves superior robustness in the underwater setting relative to the Pole-Placement Method.