Real-time contamination modeling with physics-accurate 3D hazard prediction. Agent-specific vapor dynamics, wind-driven dispersion over real terrain, ground deposition, dosimetry tracking, and live hazard streaming to any connected viewer.
Each CBRN agent has its own physical model based on real thermodynamic and chemical properties. Different agents behave differently — vapor pressure, particle dynamics, ground interaction, and decay rates are all agent-specific. The simulation uses real chemistry.
Tracks airborne vapor, aerosol particles, ground surface deposition, and resuspension from wind disturbance — simultaneously. A sarin release produces a vapor cloud that advects downwind while liquid droplets deposit on surfaces and create a persistent ground hazard.
The simulation initiates from NATO NBC1 through NBC6 reports per STANAG 4701 / ATP-45 — the report is parsed, the agent identified, and the physics started automatically. Or, if the customer has CBRN sensors in the field, their readings feed directly into the World Model and refine the simulation against ground truth in real time. Reports start the model. Sensors keep it honest.
Tracks cumulative radiation dose per entity for radiological scenarios. Computes dose rate fields from source activity and distance. Alerts when AEGL thresholds are approached or exceeded.
Contamination plumes advect with real wind data over real terrain. The physics handles diffusion, settling, and atmospheric stability. Urban canyon effects modify wind flow through built-up areas. The plume goes where the physics says it goes.
The contamination field feeds directly into the safety field and corridor planner. Routes update in real time as the plume evolves. No manual hazard area plotting. No stale overlays from an hour-old ATP-45 template.
Varindor's CBRN model runs the actual physics. Every agent has real thermodynamic properties. Wind drives advection. Terrain occludes and channels. Ground temperature affects evaporation rate. The simulation runs continuously at 30Hz, so the hazard picture evolves in real time as conditions change — accounting for ridgelines that block plumes, temperature that affects evaporation rates, and urban canyons that channel airflow.
The result is a 3D hazard volume that any viewer can subscribe to — not a static overlay, but a live field that updates as the plume moves, as the wind shifts, and as responders change the situation on the ground.
The same physics that models a sarin release on a battlefield models a chlorine leak at a water treatment plant, an ammonia spill at an industrial facility, or a radiological incident at a nuclear site. The agents are different. The physics is the same.
Civil protection agencies, first responders, and emergency management teams benefit from the same physics-accurate modeling the military gets. A real-time 3D hazard picture that accounts for terrain, wind, and agent chemistry is as valuable to a fire commander evacuating a neighborhood as it is to a CBRN officer planning a route.
The civil command console provides the same live contamination picture with appropriate access controls — no military classification, no targeting data, just the hazard and the safe corridors.
Every agent property in the system — vapor pressure, toxicology thresholds, degradation rates — is derived from publicly available scientific literature, NATO unclassified publications, and open reference standards.
There is nothing secret in the models. The physics is published science. What Varindor adds is the engineering to run these models in real time over real terrain with real wind — and stream the result to customers who need it.