The research introduced three foundational components for LiDAR system assessment:

1. Uncertainty Quantification Modeling – to evaluate system precision and error propagation.
2. Modulation Transfer Function (MTF) Analysis – both theoretical and empirical, to quantify resolution under varying conditions.
3. End-to-End System Performance Modeling – integrating platform behavior, environmental factors, and system specifications to simulate operational outcomes.

Underwater calibration targets, particularly line targets, were developed to empirically assess resolution. These were deployed in field campaigns and used to correlate environmental metrics with MTF-derived resolution values. Synthetic data generation supports machine learning validation and performance benchmarking.

Field data from Panama City, FL revealed critical limitations in the base OSS EDGE LiDAR system, particularly in mirror pointing accuracy. MTF and UQ analysis led to specific system upgrades, including reduced pointing error (from 0.25° to 0.01°), increased point density, and optimized flight parameters. Empirical MTF assessments validated these improvements and demonstrated enhanced resolution sufficient for detecting and classifying medium-to-large munitions (≥100 mm). End-to-end modeling identified key environmental constraints—such as water surface slope, turbidity, and sea state—that significantly impact resolution and informed Go/No-Go operational criteria.

This research provides a robust framework for evaluating and improving UAS-based bathymetric LiDAR systems. Key benefits include:

1. Operational Guidance: Clear Go/No-Go criteria based on environmental and system parameters.
2. System Optimization: Quantitative tools for refining LiDAR specifications to meet resolution requirements.
3. Standardization: MTF-based evaluation enables cross-validation with other instruments and related environmental conditions to make informed actionable decisions.
4. Machine Learning Support: Synthetic prelabeled datasets enhance unsupervised and semi-supervised classification capabilities.

These advancements enable more reliable detection and classification of underwater munitions, improving safety and mission effectiveness in shallow water environments. (Project Completion - 2025)