Maritime Surveillance Economics Dashboard

Why Ocean Surveillance Is Hard

361 million km2 of ocean. ~100,000 vessels in transit. A ship unobserved for 6 hours could be anywhere in a 160 km radius. Every sensor faces the same core physics problem: the target must produce a signal that exceeds the environmental background. The ocean makes this hard in every domain.

361M km²

Ocean surface area

16x

Power needed to double radar range

~67%

Cloud cover blocking optical sensors

3,300+

Dark fleet vessels evading AIS

Radar: The R⁴ Problem Explore →

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$$R_{\max} = \left[\frac{P_t \, G^2 \, \lambda^2 \, \sigma}{(4\pi)^3 \, S_{\min}}\right]^{1/4}$$

Range scales as the fourth root of power - doubling detection range requires 16x more power. But the ocean makes this worse: sea surface backscatter (clutter) is often stronger than the target return itself. Maritime radar is almost never noise-limited - it is clutter-limited. The K-distribution clutter penalty can be 12 dB, meaning a small boat at 25 km range may be invisible even to a 100 kW X-band radar.

This is why a ship-mounted radar at 30m height covers only ~1,250 km2, while a HALE UAV at 15 km altitude covers 7 million km2 per sortie. Altitude buys radar horizon. Cost per km2-hr varies by 3+ orders of magnitude across platforms.

Underwater: Sound Is All You Have Explore →

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$$\text{SE} = \text{SL} - \text{TL} - (\text{NL} - \text{DI}) - \text{DT}$$

Electromagnetic signals attenuate within meters in seawater. Only sound propagates at useful range. Detection requires signal excess > 0 dB. Modern quiet submarines radiate 90-120 dB - 30-40 dB quieter than Cold War boats, partially negating the ocean's acoustic advantages.

The SOFAR channel is unique physics. At ~1000m depth, sound energy is trapped by refraction, converting spherical spreading ($20\log R$) to cylindrical spreading ($10\log R$) - a 30 dB advantage at 1,000 km. This is why seabed nodes and deep-towed arrays can detect at hundreds of km, but submarines that stay above the channel can avoid detection entirely.

Resolution vs. Coverage: You Can't Have Both Explore →

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$$\dot{A}_{\text{coverage}} = \frac{V \times W_{\text{swath}}}{t_{\text{resolution}}}$$

Every sensor has finite information capacity per unit time. SAR satellites achieve ~1m resolution but revisit only every 1-12 days. OTHR covers 13 million km2 but at 50 km resolution - you can't tell a tanker from a warship. Optical sensors are blocked by cloud cover ~67% of the time.

This is information theory, not engineering failure. The layered architecture (wide-area cueing + narrow-area classification) is a consequence of physics. Three sensors at $P_d = 0.3$ each give $P_d = 0.66$ combined - the mathematical basis for why no single platform works.

AIS: A Cooperative System With No Authentication

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AIS is the backbone of vessel tracking - but it can be spoofed (false position), impersonated (false identity), or simply turned off. As of 2025: 3,300+ dark fleet tankers operate with AIS disabled. Spoofing incidents up 200%+ since 2022. 24,000+ vessels experienced GPS jamming in Q1-Q3 2025 alone.

90% of fishing vessels in marine protected areas are invisible to AIS (Science, 2025). The dark fleet grew to 3,300 vessels despite satellite monitoring. Detection without enforcement does not deter - the technology problem is being solved, but the governance problem is not.

These constraints define the economics below. Explore interactive physics visualizations →

Market Segments

Who pays for maritime surveillance, what they spend, and which platforms serve each buyer. Bottom-up sizing from observable budgets and contracts - not top-down TAM projections.

SAM = Serviceable Addressable Market for an autonomous surveillance startup. Bars show low-high range. Total realistic SAM: $2-5B/year (~10-15% of the $31.4B headline market).

USV Fleet-as-a-Service

Saildrone: 20 USVs, Caribbean Drug Interdiction

Operation Southern Spear (Jan 2025-present): 20 Voyager USVs deployed for JIATF-South. 95% detection rate. In June 2024, Saildrones shadowed Russian warships approaching Cuba. $2,500/day per USV - 10% the cost of a cutter.
Bluebottle (Jul 2024-present): 15 USVs, 200,000+ nm cumulative, 184-day longest deployment. A$176M for 40 more.

Sources: USNI News Jun 2024; Saildrone Jan 2025; AU Defence Minister Mar 2026

Dark Vessel Intelligence

Windward AI: 1,950 Dark Fleet Vessels Identified

VLCC Skipper seizure: AIS placed vessel 500+ nm from actual location. False Guyanese flag (registry ceased 2021). Windward analysis supported interdiction. HawkEye 360: RF detected CPT AHMAD II at sanctioned Tartus port during AIS gap. ICEYE/Spire: Argentine coast guard enforced against Chinese squid fleet detected dark in EEZ.

Sources: Windward 2024; HawkEye 360 Nov 2021; ICEYE Maritime 2024

Offshore Wind Surveillance

Germany BSH: First Radar Mandate for Wind Farms

Jan 2025: BSH requires EnBW and RWE to install radar and transmit to Cuxhaven security center. ScottishPower EA3: GBP 16M guard vessel + CTV contract (OEG + NR Marine). TenneT: EUR 3M cable survey, 3,400km Prysmian/N-Sea monitoring SLA. AP Sensing: 300km DTS/DAS at Kriegers Flak for Energinet. Near-zero adoption today - market inflection point.

Sources: Baltic Wind Apr 2025; ScottishPower Apr 2025; TenneT Oct 2024

Submarine Cable Protection

C-Lion1: Double Break Catalyzes Market

Cinia's Finland-Germany cable broke Nov 18 + Dec 25, 2024. Response: military (Finnish/Swedish/German coast guard), not commercial. 200 faults/year globally, 86% from fishing/anchoring. Power cable repair: $10-100M/incident. Monitoring at $100-500K/year/route = clear ROI. EU committed EUR 540M (2025-27). NATO Baltic Sentry launched Jan 2025.

Sources: Cinia Nov-Dec 2024; ICPC/SubOptic 2024; EU Action Plan Feb 2025

Smart Port Surveillance

Antwerp-Bruges: 460 Cameras, 22 Radars, 6 Drones

World's first BVLOS port drone network (2023). 5G real-time feed to coordination centre. Biometric access at PSA terminal. Rotterdam: Kongsberg VTMIS ~$10M. Digital twin. Singapore: AI NGVTMS predicts collisions 30min ahead (Kongsberg + Wartsila). Kongsberg dominates European VTS.

Sources: Maritime Executive May 2023; Technavio 2024; MPA Singapore 2024

IUU Fishing Enforcement

Indonesia: 500+ Vessels Destroyed, 90% Reduction

First nation to share VMS publicly (2017). AIS+VMS system on all vessels >30GT. Global Fishing Watch confirmed 90% reduction in foreign fishing. Thailand: VMS deployed nationwide in 90 days post-EU Yellow Card, EUR 87M invested. Galapagos 2020: 340 Chinese vessels detected via multi-sensor (AIS, SAR, RF, aerial). 43 AIS shutoffs documented.

Sources: GFW 2017; ORBCOMM 2015; Oceana Aug 2020

Coast Guard Drone Ops

4 National Models: Japan, Frontex, India, Philippines

Japan JCG: 3 MQ-9Bs from Kitakyushu, imaging Chinese ships at Senkaku. Fleet to 10 by FY2028. Frontex: 4,993 drone hours (2024, +50% YoY), 1,204 crossings detected. India: 46 Terma radar stations, 1,500 targets simultaneously, $95M Phase II. Philippines: 4 MANTAS USVs, Thitu Island station, USMC MQ-9A from Basa.

Sources: Japan Today 2025; Frontex 2024; Terma/India MOD 2016-25

Platform Counter-UAS

Aker + Kongsberg: North Sea Drone Detection

Drones breached Equinor Sleipner and Heidrun 500m perimeters. Norway deployed military post-Nord Stream. Joint demonstrator (2025): Drone Detection Radar + Mobile Broadband Radio + cameras + acoustic subsea sensors. Aramco Safaniyah: Marine surveillance radar + VTMS (Security Vault Systems). No oil major has deployed USVs for perimeter security yet.

Sources: OE Digital 2025; Kongsberg Discovery 2025; Security Vault Systems

ASW: USV-Towed Hydrophone

Saildrone + Thales: First Open-Ocean ASW Result

Saildrone Surveyor + Thales BlueSentry thin-line towed array: "exceptional operational performance during weeks-long mission," identified and tracked vessels of interest in real time. First confirmed USV ASW result at sea. IUSS/SURTASS: 5 T-AGOS ships, 161/181 days in SCS (2021). T-AGOS-25 replacement: $3.9B+. USV barrier: 20 units x 300km = GBP 40K/day vs. GBP 600K/day frigates (150x cheaper).

Sources: Thales Sea-Air-Space 2025; USNI News; CRS 2024-25

Year 1-2

Dual-use USV Fleet: Environmental + Coast Guard

Follow the Saildrone playbook: persistent USVs collecting ocean data at $2,500/day. Revenue: $5-15M from NOAA/Copernicus contracts. Simultaneously demonstrate coast guard surveillance (Australia Bluebottle precedent: A$176M for 40 USVs). Platform cost: $50-250K per unit.
Why first: Low regulatory barriers, proven demand, dual-use data justifies fleet investment.

Revenue$5-15M Fleet size20-50 USVs SegmentsEnvironmental, Coast Guard

Year 2-3

Offshore Wind Surveillance-as-a-Service

Target 129 European offshore wind farms as EU CER Directive compliance deadline approaches (risk assessments due Jan 2026, entity identification due Jul 2026). Offer: persistent USV patrol + vessel traffic monitoring + AIS anomaly alerting at $2-5M/farm/year. Market barely exists today - "only a few wind farms have installed radars" (Reuters 2024).
Why second: Regulatory catalyst creating time-bounded demand. No incumbents to displace.

Revenue$20-100M Fleet size50-200 USVs Segments+ Offshore Wind

Year 3-5

Defense + Undersea Infrastructure

Use operational fleet data to win defense evaluation contracts. The US Navy's $1.2B autonomy software line in FY2026 is a greenfield budget category. Expand to cable/pipeline protection monitoring (same platforms, different sensors). Cable operators face $10-100M per power cable repair - making $1-5M/year monitoring an obvious ROI.
Why third: Defense procurement is slow (2-5 years). Starting in dual-use builds the track record needed.

Revenue$50-200M+ Fleet size200-500+ USVs Segments+ Defense, Undersea Infra

Business Model Comparison

Model	Example	Revenue	Margin	Exit Benchmark
Hardware	Saronic	$392M OTA	20-30%	$4B valuation
Data Platform	Windward	$35M ARR	70-80%	$270M (7.5x rev)
Fleet-as-a-Service	Saildrone	$43M (+231% YoY)	40-60%	~$300M+ raised

The optimal strategy combines models 2+3: own the fleet to generate proprietary data that feeds a platform. The data moat comes from operating the sensors, not buying commodity AIS feeds.

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Annual Spend-

SAM (Low-High)-

Buyer Count-

Growth (5yr)-

Top Platforms-

Key Contracts / Signals-

Maritime Surveillance Economics

Why Ocean Surveillance Is Hard

Radar: The R⁴ Problem Explore →

Underwater: Sound Is All You Have Explore →

Resolution vs. Coverage: You Can't Have Both Explore →

AIS: A Cooperative System With No Authentication

Assumptions

Low-cost radar USV (surface surveillance)

Low-cost ASW USV (towed hydrophone)

Traditional benchmarks

Stratospheric UAV (custom platform)

Platform Cost Comparator

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Chokepoint Calculator

Comparison vs Traditional Patrol

Fleet Builder

Equivalent Cost Comparison

Matryoshka Strategy

Mothership Tier

ASV Tier

AUV Tier

Nesting vs Standalone Comparison

ASW Cost Comparison

Market Segments

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Maritime Surveillance Economics

Why Ocean Surveillance Is Hard

Radar: The R4 Problem Explore →

Underwater: Sound Is All You Have Explore →

Resolution vs. Coverage: You Can't Have Both Explore →

AIS: A Cooperative System With No Authentication

Assumptions

Low-cost radar USV (surface surveillance)

Low-cost ASW USV (towed hydrophone)

Traditional benchmarks

Stratospheric UAV (custom platform)

Platform Cost Comparator

-

Chokepoint Calculator

Comparison vs Traditional Patrol

Fleet Builder

Equivalent Cost Comparison

Matryoshka Strategy

Mothership Tier

ASV Tier

AUV Tier

Nesting vs Standalone Comparison

ASW Cost Comparison

Market Segments

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Radar: The R⁴ Problem Explore →