Table of Contents

Overview: Turning Fibre Into a Leak Detection System

Openreach has launched innovative trials that repurpose its full-fibre broadband network into a nationwide sensing system capable of detecting water leaks underground.

Uses existing fibre cables already deployed across the UK
Converts them into real-time monitoring sensors
Focuses on early detection of leaks and infrastructure faults

This transforms telecom infrastructure into a multi-purpose utility platform, not just a broadband network.

How the Technology Works

Distributed Acoustic Sensing (DAS)

The core technology is Distributed Acoustic Sensing (DAS):

Fibre optic cables carry pulses of laser light
Nearby vibrations (e.g., leaks, pipe bursts, digging) disturb the light signal
These disturbances are detected and analyzed

Machine learning is then used to:

Filter out background noise (traffic, trains, etc.)
Pinpoint the exact location of a leak (Total Telecom)

In simple terms:
The fibre cable acts like a giant underground microphone.

AI + Real-Time Monitoring

Data is analyzed continuously (24/7 monitoring)
Algorithms identify anomalies linked to leaks or faults
Provides utilities with precise, actionable alerts

This enables a shift from:

Reactive repairs → Predictive maintenance

Key Partnerships Driving the Trials

1. Multi-Utility Consortium Trial (London)

Partners include:

Arcadis
Thames Water
Cadent

Location: Hounslow, West London
Duration: 6-month pilot

Goals:

Detect water and gas leaks early
Reduce costly emergency repairs
Minimize disruption from roadworks

Emergency utility works currently cost ~£750 million annually in London alone (Total Telecom)

2. Water-Focused Trial with Affinity Water

Partners:

Affinity Water
Lightsonic

Technology:

Distributed Fibre Optic Sensing (DFOS)
Converts fibre into thousands of virtual sensors

Focus:

Detect leaks in drinking water pipelines
Support long-term leakage reduction targets

The UK currently loses ~3 billion litres of water daily, making this a critical use case (Water Magazine)

Pilot Results & Real-World Impact

Large-Scale Field Trial Outcomes

Monitored 400+ miles (650 km) of water pipes
Covered multiple UK locations including:
- Walton-on-Thames
- Luton
- Hemel Hempstead
- Chesham/Amersham
- Ware

Results (within 3 months):

100+ leaks detected and repaired
Saved over 2 million litres of water per day (Tom’s Hardware)

That’s enough water annually to supply 10,000+ people.

Key Benefits of the Approach

1. Cost Efficiency

Uses existing fibre infrastructure
No need to install new sensor networks
Shared across multiple utilities (water, gas, telecoms)

2. Faster Leak Detection

Continuous monitoring vs manual inspections
Detects leaks before they become major failures

3. Reduced Disruption

Fewer emergency roadworks
Repairs can be scheduled during off-peak hours

4. Environmental Impact

Reduces water waste
Supports national sustainability goals

Future Potential

Toward Smart Cities

If scaled, the system could:

Turn cities into “underground early warning networks”
Monitor:
- Water systems
- Gas pipelines
- Transport infrastructure

Nationwide Expansion

Openreach’s fibre network already covers tens of millions of premises
Provides a ready-made platform for UK-wide deployment

Multi-Industry Applications

The same technology could be used for:

Detecting cable damage or sabotage
Monitoring railways and roads
Environmental sensing (e.g., earthquakes)

Expert & Industry Commentary

Openreach Perspective

Openreach highlights that:

Its fibre network can deliver value “far beyond broadband”
Could help solve real-world challenges like water conservation (Water Magazine)

Utility Industry View

Water companies see this as:

A “transformative moment” for leakage strategies
A shift toward data-driven infrastructure management (Total Telecom)

Technology Insight

Experts note:

Fibre sensing has been used in:
- Earthquake detection
- Subsea monitoring
This is one of the first large-scale urban utility applications (ISPreview)

Key Takeaways

Openreach is turning fibre broadband into a smart sensing network
Trials show strong early success (100+ leaks found, millions of litres saved)
Technology combines DAS + AI + existing infrastructure
Could reshape how cities manage water, energy, and infrastructure

Bottom Line

Openreach’s fibre leak-detection trials represent a major innovation in infrastructure convergence—where telecom networks double as intelligent monitoring systems.

If scaled nationwide, this could become a game-changing solution for water conservation, cost reduction, and smart city development in the UK and beyond.

Here are detailed case studies and expert commentary showing how Openreach is using its fibre network to detect water leaks in real-world UK trials—and what it means for utilities and infrastructure.

Case Studies: Real-World Trials & Results

Case Study 1: Affinity Water + Lightsonic Pilot (Multi-City Trial)

Scenario:
A large-scale trial using fibre sensing to monitor drinking water pipelines across multiple UK towns.

Setup:

Partners: Affinity Water and Lightsonic
Coverage: 400+ miles (650 km) of pipelines
Locations: Walton-on-Thames, Luton, Hemel Hempstead, Chesham/Amersham, Ware

Technology Used:

Distributed Acoustic Sensing (DAS) + machine learning
Fibre cables act as continuous underground sensors

Results (within 3 months):

100+ leaks detected and repaired
2 million litres of water saved per day (Tom’s Hardware)

Outcome:

Shift from manual inspection → 24/7 automated monitoring
Faster identification of hidden leaks

Insight: This proves fibre networks can deliver measurable environmental and operational benefits at scale.

Case Study 2: London Smart Infrastructure Trial (Hounslow)

Scenario:
A multi-utility pilot aimed at detecting both water and gas leaks in a dense urban environment.

Partners:

Arcadis
Thames Water
Cadent

Location: Hounslow, West London
Duration: 6 months

Key Goals:

Detect leaks early
Reduce emergency roadworks
Minimize urban disruption

Key Findings:

Fibre sensing enables real-time leak detection and precise location tracking
Helps utilities fix issues before pipe bursts occur (Arcadis)

Impact:

Potential to reduce £750 million annual cost of emergency works in London (Total Telecom)
Repairs can be scheduled during off-peak times

Insight: Fibre sensing acts like an “underground early-warning radar system” for cities.

Case Study 3: National-Scale Potential Using Existing Fibre

Scenario:
Testing whether Openreach’s nationwide FTTP network can double as a sensing grid.

Approach:

Use existing fibre infrastructure (no new sensors required)
Convert cables into thousands of “virtual sensors”

Key Findings:

System can detect:
- Leaks
- Blockages
- External interference (e.g., digging near pipes)
Machine learning filters out noise like traffic vibrations (ISPreview)

Outcome:

Highly scalable model
Cost-efficient due to shared infrastructure

Insight: This creates a multi-utility monitoring platform, not just a telecom network.

Case Study 4: Preventive Maintenance vs Reactive Repairs

Scenario:
Traditional leak detection vs fibre-enabled monitoring.

Before:

Manual inspections
Reactive fixes after pipe bursts
Limited coverage at any one time

After (with fibre sensing):

Continuous monitoring
Early detection of small leaks
Predictive maintenance

Result:

Reduced water loss (UK loses ~3 billion litres daily) (Total Telecom)
Less disruption from emergency works

Insight: Fibre sensing enables a fundamental shift in utility operations.

Industry Commentary & Expert Insights

1. “Game-Changer” for Water Leakage

Executives at Affinity Water describe the technology as:

A “transformative moment” for leakage strategy (Total Telecom)

Interpretation:

Moves utilities from:
- Reactive maintenance → data-driven, proactive systems

2. Multi-Utility Cost Sharing Model

Experts highlight:

One fibre sensing network can serve:
- Water
- Gas
- Telecoms
Reduces need for separate infrastructure (Arcadis)

Implication:

Strong economic case for scaling nationwide

3. AI + Fibre = Smart Infrastructure

Technology combines:

Acoustic sensing (detect vibrations)
Machine learning (identify real leaks vs noise)

Expert view:

Enables high-precision, real-time diagnostics
Works even in noisy urban environments (iTWire)

4. Environmental Impact & Sustainability

Industry analysts emphasize:

Millions of litres of water saved daily
Reduced energy and treatment waste

Insight:

Fibre sensing aligns with climate and sustainability goals
Supports long-term water conservation

5. Smart City Transformation Potential

Experts believe:

Cities could become fully monitored underground networks
London could be the first large-scale deployment if trials succeed (Arcadis)

Implication:

Telecom infrastructure becomes critical national sensing infrastructure

6. Challenges & Open Questions

Despite success, experts note:

Scaling across entire UK still unproven
Requires:
- Integration with utility systems
- Investment in analytics platforms
Regulatory and data-sharing considerations

Insight: The technology is promising—but commercial rollout is still evolving.

Key Takeaways

What the Case Studies Show

Proven ability to detect leaks at scale (100+ leaks found quickly)
Strong results in both urban and regional trials
Significant cost and water savings

What Experts Agree On

This is a major shift toward smart infrastructure
Fibre networks can serve multiple industries simultaneously
AI-driven sensing is the future of utility management

What Happens Next

Potential expansion to:
- London-wide deployment
- Nationwide rollout
Broader use cases (gas, electricity, transport monitoring)

Bottom Line

Openreach’s trials show that fibre broadband networks can evolve into a nationwide sensing platform, delivering real-time insights into critical infrastructure.

The combination of existing fibre + acoustic sensing + AI is not just improving leak detection—it’s redefining how cities manage water, energy, and underground systems.