UNCLASSIFIED

FSG-A // OPEN DRONE ENGINEERING REFERENCE // EDITION 2026-Q2

MILITARY DRONE
TECHNOLOGY

Author: Tiny — TCCC CLS, FPV/UAV Certified. 3+ years on contract with combat units in Ukraine.

AIR GROUND SEA EW ARCTIC Updated 2026-04-17

KEY TAKEAWAY

Open technical reference for building and deploying military drone capability. 7 clusters covering FPV construction, autonomous systems, electronic warfare, arctic operations, C-UAS vehicle upgrades, the Lisa 26 AI decision engine, and the Fischer 26 ISR platform. Intended as fork-and-adapt reference architecture for any Nordic or allied unit, industry integrator, reservist organisation, or research institution. Each claim is labelled: mathematically verified, simulation-verified (SITL), or theoretical — FSG-A has no own flight hours and no field measurements.

→ Lisa 26: AI Decision Engine Tactical FPV Build Autonomous Systems Arctic Operations

Chapters

Clusters

Pages

Languages

OPEN

Classification

v2.0

Version

Lisa 26 — AI Tactical Decision Engine (reference design for GUTE II)

Lisa 26 is an FSG-A reference design, not a product. It demonstrates the capabilities a modern brigade AI decision layer needs — threat fusion, L1/L2/L3 authority, IFF deconfliction, mesh topology, Nordic-specific models — so the organisations building the real system (GUTE II, FMV-contracted 2026-04-02 for 2027–2028 delivery) have a runnable reference. When GUTE II reaches full operational capability, Lisa 26's idea-source role is complete. Everything here is CC BY-SA 4.0 for exactly that reason: forkable, adaptable, extensible.

LISA 26 — DECISION LEVELS

L1 — AUTO ALERT

AI detects threat → soldier gets instant warning with position, heading, and classification. No human analysis required to trigger.

L2 — RECOMMEND

AI aggregates all drone feeds → suggests optimal route, identifies threats, recommends action. Soldier makes the decision.

L3 — AUTONOMOUS

Time-critical threats (incoming swarm, artillery observation) → system acts autonomously: re-tasks interceptors, triggers EW countermeasures.

CORE

System Architecture

Online real-time feed vs offline debrief. How data flows from sensor to commander's map.

Detection Pipeline

YOLOv8 → MGRS coordinate → Common Operating Picture. Automated target detection.

DECISION

L1 / L2 / L3 Engine

Alert, recommend, or act autonomously. Threat scoring, route optimization, interceptor tasking.

Reading Paths — Start Here Based on Your Role

This wiki has 109 pages. Rather than reading sequentially, pick the path that matches what you need to decide or evaluate. Each path is 4–6 pages long and takes 30–60 minutes to read fully. The Doctrine Index is the single-page synthesis of all four paths if you want the full picture first.

FOR PROCUREMENT OFFICERS

Cost & Doctrine Path

Tier A/B/C pricing, CPFH vs manned ISR, Ukraine innovation hub, expendability equation. Start: Fischer 26 whitepaper → antenna cluster → expendable ISR economics → formal documentation suite.

FOR SYSTEMS ENGINEERS

Technical Deep Dive

21-module SDK, NATO STANAG 4609/4671 endpoints, GUTE II integration, antenna cluster architecture, 10-target engagement energy, 73 executable proofs. Start: SDK → antenna cluster → energy budget → run provable_claims.py.

FOR BRIGADE OPERATORS

Operational Use

Lisa 26 architecture online/offline, L1/L2/L3 decision engine, IFF deconfliction, threat fusion, arctic operations. Start: Lisa 26 architecture → detection pipeline → decision engine → arctic-15-problems.

FOR FOI / ACADEMIC EVALUATORS

Methodology & TRL Honesty

Institutional context, methodology, what FSG-A has and has not validated. 73 mathematical proofs, 28 automated validators, explicit TRL markings per page. Start: About FSG-A → provable_claims.py → formal documentation → doctrine index.

7 Knowledge Clusters

CLUSTER 1 — AIR

FPV Construction

Component selection, soldering, wiring, tactical builds, fiber-optic FPV, thermal targeting. Parts to fieldable platform (per public documentation).

CLUSTER 2 — AUTONOMOUS

Autonomous Systems

EKF3, SLAM, path planning, behavior trees, swarm coordination, UGV, AUV, counter-UAS interceptors.

CLUSTER 3 — EW

Electronic Warfare

FHSS, SDR spectrum analysis, anti-jam, CRPA antennas, passive radar, cybersecurity.

CLUSTER 4 — ARCTIC

Arctic Operations

Component failure at -40°C, LiPo hardening, EKF drift from aurora, Norrbotten procedures.

CLUSTER 5 — C-UAS

Vehicle Anti-Drone Upgrades

Detection, soft kill, hard kill for 13 Swedish Army vehicles. Strv 122 to BV 206.

CLUSTER 6 — LISA 26

AI Decision Engine

Battlefield management. Online/offline data fusion, threat aggregation, LTE mesh C2, STANAG KLV.

CLUSTER 7 — FISCHER 26

Fischer 26 ISR/EW UAS

Open-source fixed-wing ISR/EW platform. Launch ramp, targeting, avionics, SOP, tactics.

Meta & Transparency

The mission statement explains why FSG-A exists and how Swedish Armed Forces, FMV, and FOI can use the material. The provable claims page lists every numerical assertion in this wiki with its formula and executable verification code.

Sources & Methodology

All technical content is built on ArduPilot documentation, ROS2/Nav2 official docs, manufacturer datasheets, published academic literature, and open-source analysis of Ukrainian drone operations 2022–2026 (Watling & Reynolds, "Meatgrinder" (RUSI 2023); Bronk, Reynolds & Watling, "Russian Air War" (RUSI 2022); ISW daily campaign assessments). Claims are labelled MATHEMATICALLY VERIFIED (reproducible via python3 provable_claims.py), SITL VERIFIED (ArduPilot simulation), or THEORETICAL / DESIGN GOAL. FSG-A has no own flight hours, no field measurements, and no operational experience. This is an open engineering reference intended for fork-and-adapt use by any competent implementing organisation — Nordic, allied, industry, academic, or volunteer.

MILITARY DRONETECHNOLOGY