Splitting & Merging

What if groups of objects can operate as coordinated swarms, split apart into multiple smaller units, or merge together into a single larger craft while maintaining flight performance?

Description of the Phenomenon

Swarm, splitting, and merging behaviors involve multiple UAP flying in close coordination, then separating into independent units or combining into one object. These actions often occur seamlessly during flight, with the resulting objects immediately demonstrating independent or continued group maneuvers.

Observed History and Locations

These events have been reported since the 1950s and have become more frequently documented with improved video technology. They appear worldwide, often near military installations, coastal waters, and urban areas. Civilian databases and military observations contain multiple accounts of objects exhibiting swarm-like coordination, splitting, or merging.

Observed Behaviors

Groups of orbs or lights fly in synchronized patterns, then split apart to perform individual maneuvers before rejoining or merging into a larger object. The process is typically silent and fluid, with no visible collision or mechanical docking. Smaller units may scout, interact with the environment, or return to the main object. These behaviors often combine with formation flying or erratic movement.

Attribution: Swarm, splitting, and merging behaviors are documented in NARCAP reports, military encounters, and large civilian sighting compilations. They extend formation flying and coordinated group dynamics within the broader “Five Observables” framework associated with Luis Elizondo’s work at the Pentagon’s Advanced Aerospace Threat Identification Program (AATIP) and U.S. government UAP assessments.

Hypothesized Tech Stack

This capability would likely use modular field-based construction or programmable matter that allows physical or energy-based separation and recombination. Shared propulsion and control fields could enable instant synchronization upon merging. Advanced distributed AI or unified energy systems would maintain performance across all units during transitions.

Understanding this technology could revolutionize modular spacecraft, reconfigurable drone systems, adaptive robotics, and on-demand assembly solutions for space exploration and terrestrial applications.