Examine the extreme ballistics and radar algorithms of the Phalanx CIWS, the autonomous Gatling gun that serves as a warship's last line of defense.
When a modern anti-ship missile breaks through a naval fleet's outer defenses, human reaction time is completely obsolete. Traveling at supersonic speeds just feet above the ocean waves, the incoming threat leaves merely seconds for interception. To survive, modern warships rely on a terrifyingly autonomous final layer of defense: the Phalanx Close-In Weapon System (CIWS).
Once the system detects an incoming threat that meets specific algorithmic criteria, it entirely cuts the human operator out of the loop. Its dual-radar system simultaneously tracks the incoming missile and the outgoing stream of its own depleted uranium or tungsten armor-piercing bullets. Firing up to 4,500 rounds per minute, the computer mathematically adjusts its aim in real-time, creating a literal wall of kinetic metal to shred the missile before impact.
This technical volume dissects the extreme ballistics and radar engineering of autonomous maritime defense. You will study the closed-loop tracking algorithms, the physics of rotary cannons, and the ethical dilemmas of completely delegating lethal force to a machine.
Stand on the deck of modern naval warfare. Understand the unyielding mathematical precision required to intercept supersonic death in the blink of an eye.
Anthony J. Thomas
Author
phalanx ciws naval defense systems autonomous military technology ballistics mathematics radar interception maritime security weapon engineering