The integration of high-performance but non-deterministic AI into safety-critical control loops remains a fundamental challenge for verifiable autonomy. We present a runtime assurance framework in the simplex family, in which a monitored primary controller is paired with a certified fallback safety controller. The monitor is a neuromorphic anomaly detector that we model as a stochastic sensor and characterize directly in this manuscript via end-to-end measurements of its detection latency distribution and its false negative and false positive rates. Using these measured quantities, we derive a probabilistic bound on closed-loop failure risk over a finite horizon that explicitly links monitor reliability and response time to safety. We validate the framework in a high-fidelity cislunar rover simulation under combined adversarial and environmental faults, where timely intervention yields an absolute mission-success gain of 84 percentage points. The result is an auditable methodology for deploying advanced AI in control systems where rapid and reliable fault detection is required.
Sylvester Kaczmarek (Mon,) studied this question.
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