Autonomous AI Cybersecurity for Satellites
NOAH Nexus Orbital Core (NNOC)
NOAH Nexus Orbital Core (NNOC) is an autonomous, AI-native space cybersecurity architecture engineered to protect satellites and orbital infrastructures against cyber, RF, and post-quantum threats. As satellite constellations scale to thousands of assets, traditional ground-centric security cannot react in milliseconds to sophisticated attacks. NNOC shifts defense into orbit, enabling satellites to detect anomalies, defend critical payloads, and recover mission operations independently, without waiting for ground intervention.
Led by founder Noah Kouadri Khazar, NNOC introduces a new paradigm for resilient space systems: self-healing constellations that continuously learn from attacks, coordinate defenses across the network, and maintain service continuity even under jamming, spoofing, or cyber compromise. This architecture is designed for commercial, governmental, and defense operators who need verifiable, adaptive protection in increasingly contested orbits.
Autonomous Threat Detection
On-orbit AI models monitor telemetry, RF spectra, and network behavior in real time to identify cyber, jamming, and spoofing attempts within milliseconds.
In-Orbit Active Defense
Policy-driven response engines isolate compromised nodes, re-route traffic, and harden critical services without waiting for ground commands.
Post-Quantum Resilience
Cryptographic agility and quantum-safe key management protect command, control, and data links against emerging post-quantum adversaries.
Constellation Security Assessment
End-to-end risk and resilience review for existing or planned LEO, MEO, or GEO constellations, including cyber, RF, and PQ threat modeling.
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NNOC On-Orbit Integration
Design, integration, and validation of NNOC agents and control plane within your satellite platform and ground segment.
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Mission Resilience Advisory
Strategic guidance on architectures, standards, and operational playbooks for secure, autonomous space missions.
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What problem does NNOC solve for satellite operators?
NNOC addresses the growing gap between the speed and sophistication of attacks on space assets and the slower, ground-dependent security models used today. As constellations scale, manual monitoring and delayed responses are no longer sufficient. NNOC enables satellites to detect, defend, and recover autonomously, preserving mission continuity even when ground links are degraded or under attack.
How does NNOC handle RF jamming and spoofing?
NNOC continuously analyzes RF environments and navigation signals to detect anomalies such as jamming, spoofing, or interference. When threats are detected, it can adapt waveforms, switch channels, adjust routing, or degrade gracefully while preserving critical services. These responses are governed by operator-defined policies and validated safety constraints.
Is NNOC compatible with existing satellite platforms?
Yes. NNOC is designed as a modular architecture that can be integrated into new missions or retrofitted where compute and power budgets allow. It interfaces with onboard computers, radios, and ground systems through standard protocols, minimizing disruption to existing flight software and operations.
Who leads the NNOC initiative?
NNOC is led by Noah Kouadri Khazar, bringing together expertise in AI, cybersecurity, and space systems engineering. The initiative collaborates with industry partners, operators, and research institutions to validate and harden the architecture in realistic orbital scenarios.