Thermodynamic and Kinematic Breakdown of Variable-Mass Hypersonic Projectiles Under Coordinated Orbital Directed Energy Engagements

This paper presents a rigorous analytical model
exploring the thermodynamic, kinematic, and spatial mechanics
required to neutralize a Kh-47M2 Kinzhal hypersonic weapon
system using space-based directed energy. Expanding on foun-
dational energy principles rooted in classical mechanics and
deterministic fields—continuing the intellectual lineage of Louis
de Broglie and Prof. Dr. Ing. Marius Borneas—we derive higher-
order kinematic derivatives alongside variable-mass terms. We
establish the complete coordinate transformation matrices from
Earth-Centered Inertial (ECI) coordinates to a satellite tracking
frame, identify precise telemetry latency bounds for an orbital
network operating with a regional C2 hub in Warsaw, Poland,
and define the explicit latitude-dependent visibility equations
for a 216-satellite constellation. Finally, we provide a complete
simulation trace of a successful triple-pulse engagement over
Kharkiv, verifying that the myth of hypersonic invincibility can
be systematically neutralized through calculated structural and
thermodynamic disruption.