Real -Time Simulation for Verification and Validation of Diagnostic and Prognostic Algorithms

To verify that a health management system (HMS) performs as expected, a virtual system simulation capability, including interaction with the associated platfo rm or vehicle, very likely will need to be developed. The rationale for developing this capability is discussed and includes the limited capability to seed fault s into the actual target system due to the risk of potential damage to high value hardware. The capability envisioned would accurately reproduce the propagation of a faul t or failure as observed by sensors located at strategic locations on and around the target system and would also accurately reproduce the control system and vehicle response. In th is way, HMS operation can be exercised over a broad range of conditi ons to verify that it meets requirements for accurate, timely response to actual faults with adequate margin against false and missed detections . An overview is also presented of a real -ti me rocket propulsion health management system laboratory which is available for future rocket engine programs. The health management elements and approaches of this lab are directly applicable for future space systems. In this paper the various components are discussed and the general fault detection, diagnosis, isolation and the response (FDIR) concept is presented. Additionally, the complexities of V&V (Verification and Validation) for advanced algorithms and the simulation capabilities required to meet the changing state -of -the -art in HMS are discussed.