Seeking to improve “Speed to Fleet,” a team from across the Naval Air Warfare Center Aircraft Division (NAWCAD) test and evaluation community created, developed and successfully completed capabilities-based testing and evaluation in a Live, Virtual and Constructive (LVC) environment for P-8A Poseidon mission systems.

“There were two firsts in this test event,” said David DeMauro, senior engineer with the Integrated Battlespace Simulation and Test (IBST) department at the time. “It was the first time ever that a successful dynamic Identification Friend or Foe (IFF) Interrogator (IFFI) simulation was executed on the ground where both the test aircraft and the targets were moving in a simulated flight environment; and the first time that an entire P-8A was immersed in this type of dynamic LVC environment to test its mission systems on the deck,” he explained.

The team determined that by using this LVC testing process, instead of testing inflight, the schedule and costs were reduced from six months and $12 million, to less than four weeks and $800,000. In addition, the data produced increased from an expected four hours to approximately 15 hours.

The P-8A Poseidon, an anti-submarine warfare jet based on a 737 airframe, undergoes dynamic testing in the Naval Air Warfare Center Aircraft Division (NAWCAD) Integrated Battlespace Simulation and Test (IBST) department anechoic chamber. The test marked the first time an entire P-8A was immersed in a dynamic environment with dynamic targets to test its mission systems.

“The resounding success of this testing event highlighted how we can use our infrastructure more effectively — testing both capability and the mission thread,” said Leslie Taylor, NAWCAD executive director, and deputy assistant commander for Test and Evaluation, Naval Air Systems Command (NAVAIR). “The cost and schedule savings alone validate the significance of LVC testing in fielding products for the warfighter.”

Over the past decade, as aircraft platforms, networks, weapons and sensors have grown in complexity, it has become increasingly difficult to test and evaluate mission systems in a live environment. Security, cost, and range or open-air limits are all are factors that have led to the growth in LVC testing. LVC is the ability to integrate actual aircraft (live) with ground-based simulation computers (virtual) and with computer-generated threats (constructive).

Dynamic testing involves running the aircraft’s systems and seeing how they respond when subjected to variables that change with time in both normal and adverse operating conditions.Testing for the P-8A, a patrol and reconnaissance aircraft, took place in the IBST anechoic chamber and used many of the tools available in the IBST Advanced Systems Integration Lab, including the Multi-Jammer Characterization (MJC) Wall.

In the chamber, instrumentation on the P-8A was given simulated motion, position and altitude, allowing both the aircraft mission system and the targets to “fly” in several different airborne environments, including in theatres of operation and in all global hemispheres, and to engage with other simulated systems and platforms.

In addition to IFFI, testing involved the P-8A’s electronic surveillance system, radar, the Global Positioning System (GPS), and other communications and navigation systems.

According to DeMauro, the future plan is to use this capabilities- based testing method in an LVC environment to conduct Air Traffic Control Radar Beacon System IFF Mark IIA System (AIMS) certification flights on the ground, since the aircraft interrogator also transmitted and received live radio frequency signals from multiple targets at a time. The AIMS program office is now looking at using these test methods for other naval aircraft attempting to obtain this certification.

During these simulations, the test team also capitalized on the opportunity to look at the effects of cyberattacks on the aircraft’s mission systems. The data captured will be used for future system development.