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Many-vs-Many Missile Guidance via Virtual Targets

reinforcement-learning › multi-agent

📄 Abstract

Abstract: This paper presents a novel approach to many-vs-many missile guidance using virtual targets (VTs) generated by a Normalizing Flows-based trajectory predictor. Rather than assigning n interceptors directly to m physical targets through conventional weapon target assignment algorithms, we propose a centralized strategy that constructs n VT trajectories representing probabilistic predictions of maneuvering target behavior. Each interceptor is guided toward its assigned VT using Zero-Effort-Miss guidance during midcourse flight, transitioning to Proportional Navigation guidance for terminal interception. This approach treats many-vs-many engagements as many-vs-distribution scenarios, exploiting numerical superiority (n > m) by distributing interceptors across diverse trajectory hypotheses rather than pursuing identical deterministic predictions. Monte Carlo simulations across various target-interceptor configurations (1-6 targets, 1-8 interceptors) demonstrate that the VT method matches or exceeds baseline straight-line prediction performance by 0-4.1% when n = m, with improvements increasing to 5.8-14.4% when n > m. The results confirm that probabilistic VTs enable effective exploitation of numerical superiority, significantly increasing interception probability in many-vs-many scenarios.

Key Contributions

This paper introduces a novel many-vs-many missile guidance strategy using virtual targets (VTs) generated by Normalizing Flows. This approach transforms engagements into many-vs-distribution scenarios, allowing interceptors to pursue probabilistic trajectory hypotheses, thereby improving interception success rates compared to deterministic assignment methods.

Business Value

Enhances the effectiveness of missile defense systems, potentially reducing the impact of saturation attacks and improving strategic defense capabilities.

Paper Metadata

Innovation Type

Algorithmic & Strategic

Deployment Feasibility

Moderate. Requires integration into complex missile systems, validation through extensive simulations and testing. Normalizing Flows can be computationally intensive.

Limitations Addressed

Conventional weapon target assignment algorithms struggle with maneuvering targets and many-vs-many scenarios. This method addresses the challenge by using probabilistic predictions and distributing interceptors across diverse hypotheses.

Performance Gains

Demonstrated improved interception success rates via Monte Carlo simulations.

Technical Tags

missile guidancemany-vs-many engagementvirtual targetsNormalizing Flowstrajectory predictionZero-Effort-Miss (ZEM)Proportional Navigation (PN)weapon target assignmentprobabilistic predictionMonte Carlo simulation

Research Topics

Guidance, Navigation, and Control (GNC)Operations ResearchMachine LearningDefense TechnologyMulti-Agent Systems

Methods & Architectures

Normalizing FlowsVirtual Target generationZero-Effort-Miss (ZEM) guidanceProportional Navigation (PN) guidanceMonte Carlo simulations Normalizing Flows

Applications & Tasks

Missile Defense Systems Aerospace Military Strategy Many-vs-many missile engagementProbabilistic target predictionInterceptor assignment optimization Missile guidanceInterceptor allocationTarget tracking and interception

Related Fields

Aerospace EngineeringControl SystemsOperations ResearchMachine LearningDefense

Keywords

missile guidancemany-vs-manyvirtual targetsNormalizing Flowstrajectory predictionZEMPNdefenseprobabilisticinterceptors

Academic Context

#Guidance, Navigation, and Control (GNC)#Operations Research#Machine Learning#Defense Technology#Multi-Agent Systems

Technology Stack

Frameworks & Libraries

Normalizing Flows

Commercial Potential

Potential Products

Advanced missile guidance systemsInterceptor allocation software

Target Industries

DefenseAerospace

Use Case Examples

Guiding multiple interceptors against a swarm of incoming missiles.Optimizing engagement strategies in complex air defense scenarios.

Competitive Edge

Offers a novel probabilistic approach to many-vs-many engagements, overcoming limitations of deterministic assignment methods.

Market Opportunity

Significant defense spending on missile systems and countermeasures.

Revenue Models

Integration into new weapon systemsupgrades to existing systems.

Resource Requirements

Compute Needs

High (for Normalizing Flows and real-time guidance calculations)

Data Requirements

Simulated target trajectories, missile dynamics data.

Deployment Constraints

Real-time processing requirements, integration with existing hardware, stringent reliability and safety standards.

Scalability

Scalability depends on the computational efficiency of the Normalizing Flow model and the guidance algorithms.

Regulatory Considerations

Export controlsdefense technology regulations.

Production Readiness

Maturity Level

Research

Time to Market

5-10 years (extensive testing and integration)

Patent Potential

High (novel guidance strategy)

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