Key Capabilities:

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• Terminal effects replication for FPV, drone-delivered, and loitering munition threats

• Vehicle-, structure-, and bunker-mountable configurations

• Synchronized blast, flash, and acoustic cues at point of strike

• Wireless control with scripted or on-demand execution

• Rapid reset for repeated iterations and high-throughput training

• Range-compatible and integration-ready for existing TADSS and facilities

 

Product Explanation:

The Drone Strike Effects Simulation System (DSESS) is a fully self-contained, mountable training platform engineered to replicate the terminal effects of modern unmanned aerial threats. Built around OPCON’s EXS-80 effects architecture, DSESS delivers synchronized blast impulse, flash, acoustic signature, and impact cues at the point of strike—without deploying live munitions or airborne systems.

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Designed for vehicle, structure, and bunker emplacement, DSESS enables units to train against realistic FPV drone attacks, drone-delivered munitions, and loitering munition impacts within controlled, repeatable scenarios. The system integrates into existing ranges and facilities, supports scripted or instructor-initiated injects, and allows rapid reset between iterations—supporting sustained, high-tempo training.

 

Product Description:

DSESS provides commanders and trainers a credible means to represent drone strike outcomes, not flight or ISR. The system focuses on what matters at the moment of impact: shock, sound, visual signature, and perceived damage. By reproducing these effects precisely where a strike would occur, DSESS supports force protection drills, survivability assessment, immediate action rehearsals, and post-strike decision-making under stress.

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The platform is self-powered, remotely controlled through OPCON’s wireless command architecture, and configurable for static or semi-permanent installations. Modular construction and adjustable effect profiles allow DSESS to scale across mission sets—from light FPV impacts to heavier loitering munition signatures—while maintaining safety, reliability, and repeatability across training environments.