In the trenchesSeeing clearly through the fog (and dust and snow) of war

Published 22 September 2014

Degraded visibility — which encompasses diverse environmental conditions including severe weather, dust kicked up during takeoff and landing, and poor visual contrast among different parts of terrain — often puts both the safety and effectiveness of tactical helicopter operations at risk. Current sensor systems that can provide the necessary visualization through obscurants struggle with latency and are too large, heavy, and power-intensive to comply with military rotary wing operations.

Particulates effectively blind the pilot and the instruments // Source: .youmaker.com

Degraded visibility — which encompasses diverse environmental conditions including severe weather, dust kicked up during takeoff and landing, and poor visual contrast among different parts of terrain — often puts both the safety and effectiveness of tactical helicopter operations at risk. Current sensor systems that can provide the necessary visualization through obscurants struggle with latency and are too large, heavy, and power-intensive to comply with military rotary wing operations.

DARPA says that its Multifunction RF (MFRF) program seeks to overcome these challenges and enhance the survivability and combat effectiveness of helicopters facing degraded visibility. The program aims to develop multifunction sensor technology that would enable sensor packages small, light and efficient enough for installation on existing and future helicopter designs. MFRF would enable pilots to:

  • Take off, fly and land safely in degraded and zero-visibility conditions
  • Avoid collisions with other aircraft, terrain and man-made obstacles (e.g. power lines)
  • Improve target detection, identification and engagement

MFRF completed successful flight demonstrations on a UH-60L Black Hawk combat helicopter to demonstrate the Synthetic Vision Avionics Backbone (SVAB) technology portion of the program. The SVAB technology demonstration fused millimeter-wave radar with multiple terrain databases and onboard platform navigation to create high-resolution 2-D and 3-D visualizations of local environmental conditions. Pilots referred to the visualizations in real time to distinguish terrain features (slope, roughness, landing suitability), detect objects in a landing zone, detect and avoid obstacles, and navigate in GPS-denied conditions.

The software architecture of the SVAB also demonstrated plug-and-play sensor control and display.

“These successful tests take us closer to future cost-effective, ‘plug-and-play’ systems that would improve situational awareness and mission effectiveness for manned and unmanned platforms alike,” said Bruce Wallace, DARPA program manager.