Water Supply Infrastructure & Project Integration This meeting with SIMAS (Serviços Intermunicipalizados de Água e Saneamento de Oeiras e Sintra) focused on evaluating existing water supply contingency solutions and aligning the PIC project with current infrastructure, communication technologies, and potential collaboration opportunities.

Key points discussed included:

• overview of existing high-capacity water tanks in Amadora and Oeiras, which ensure temporary supply during EPAL distribution failures but do not cover failures within SIMAS pipelines

• recognition that the PIC project solution complements the current infrastructure, addressing scenarios not covered by existing emergency tanks

• discussion on communication technologies, comparing private 5G networks with LoRa — with LoRa identified as the most suitable solution for the project’s scale and requirements, also considering regulatory constraints from ANACOM

• evaluation of potential collaboration between SIMAS and the project team, including access to physical workspace, support from the SIMAS water laboratory for prototype testing, and a guided visit to SIMAS facilities

• confirmation of SIMAS’s openness to support the project and willingness to strengthen cooperation in future development phases

Meeting_Min_SIMAS.pdf

Emergency Water Supply

This meeting with the Lisbon Civil Protection Authority focused on defining the operational and deployment requirements for the emergency water supply system, covering tank infrastructure, distribution logistics, and water quality integration.

Key points discussed included:

• direct connection to the EPAL public network as the primary filling method, with Storz-compatible caps enabling supplementary supply via tanker trucks

• a city-wide distribution strategy spanning 86 designated emergency points across Lisbon, with additional mobile units and dedicated fire-fighting support points in Monsanto

• deployment modes distinguishing between standard gravity-fed operation for everyday supply disruptions and emergency access — which, beyond standard authentication, grants designated Civil Protection operatives a privileged control layer for crisis scenarios

• evaluation of cost-effective ATP testing solutions to ensure water quality assurance in field conditions

• structural considerations including a spring-based mounting system for seismic resilience and height-adjustable supports to maintain adequate gravitational pressure

Meeting-PC-Minutes.pdf

Meeting with Bombeiros Lisbonenses

Emergency Water System

This meeting with Bombeiros Lisbonenses focused on evaluating and improving the emergency water supply system, including operational strategies, population coverage, and system integration.

Key points discussed included:

• review of the presentation for Civil Protection, with the need to improve its structure and prepare more informed questions based on a better understanding of the organization

• revision of population estimates, expanding scenarios from 1,000,000 to 4,000,000 people to reflect Lisbon’s real daily population

• water management strategies, including reuse and treatment of tank renewal water to make it suitable for human consumption

• implementation of an automatic water renewal system integrated into the public network to reduce human error and improve efficiency

• clarification that project tanks are complementary to main reservoirs, increasing distribution and territorial coverage

• potential connection to the electrical grid during normal operation to enhance system efficiency and allow use of higher-power equipment

Next steps:

• deepen the study of Civil Protection structure and hierarchy

• prepare specific questions for the next meeting

• revise project parameters, particularly population modelling and technical system design

MeetingMin_BL.pdf

Water Quality Monitoring

This meeting with our partner Laist focused on discussing the key water quality parameters required to maintain drinkable water during both normal operation and deployment scenarios.

Key points discussed included:

• selection of water quality parameters (pH, conductivity, turbidity, temperature)

• UV as the main disinfection strategy, reducing the need for chlorine and avoiding harmful by-products

• microbiological control considerations, including temperature, water movement, and the potential use of an ATP unit.

• potential use of activated carbon to mitigate taste and odor issues during deployment

Meeting Laist Minutes.pdf

Emergency Water Supply System

This meeting aimed to review the current status of the PIC project, align technical decisions regarding the system architecture, and define the next development steps.

The discussion covered:

• institutional contacts
• tank architecture
• sensors and actuators
• LoRa communication
• user authentication
• macro architecture of the tank network

📄 Meeting 1 Minutes

We’ve just finished our Revised Project Proposal after several productive meetings with at LAIST and INESC!

In this document we introduce our team, outline the problem we’re addressing, and present our proposed solution. We also cover the previous work that informed our approach, the key solution requirements, the validation metrics we plan to use, and our roadmap for the project moving forward.

Feel free to take a look at the proposal and follow along with our progress!

📄 Read the Revised Project Proposal

Orbis Platform — Version 1 Release

Today we're releasing the first version of the Orbis platform: a website and future operational interface for a modular, resilient water distribution system designed for cities under stress.

This release moves the project from concept to something visible, navigable, and technically grounded. For the first time, Orbis exists as a real product layer: built to communicate, manage, and eventually operate an urban emergency water network.

Why this exists

Urban water systems are centralized, rigid, and optimized for normal conditions. But "normal" is becoming less reliable.

Conflicts, earthquakes, droughts, and contamination events have shown how quickly access to drinking water can collapse. In the first 72 hours after a disruption, water access becomes a matter of public safety, health, and stability — not just logistics.

Our approach is a redundant, modular, point-to-point water system that can be deployed across a city and activated when the main network fails. The platform is the digital backbone that makes that system manageable.

More than a website

The site isn't just a landing page — it's structured as a future operational portal.

Even in this first version, the architecture reflects that goal. It introduces the motivation, the risks, and the proposed solution in a clear way, while laying the groundwork for a role-based interface where different actors (municipalities, civil protection, emergency services) can access different layers of information.

In future iterations, operators will be able to monitor node status, storage levels, water quality indicators, and distribution points in real time through this same platform.

Technical foundation

Version 1 is built with Django, chosen for its robustness and strong ecosystem for data-driven platforms. It gives us clean separation between logic, data, and presentation; a powerful admin interface that will evolve into an internal control dashboard; secure authentication and permission management; and the flexibility to grow from an informational site into a full operational tool.

The templating system is already structured around component-based sections, which lets us iterate on design while maintaining consistency across the site.

Geospatial layer with PostGIS

Because this system is inherently spatial, we're integrating PostgreSQL with PostGIS from the start. This allows us to store the location of each modular water node, map distribution zones and coverage areas, analyse proximity to critical infrastructure (hospitals, shelters, dense neighbourhoods), simulate service gaps during network failure, and plan optimal deployment locations in advance.

In later versions, this will power an interactive map interface where users can visualize the network and understand coverage in real time.

What Version 1 includes — and what it doesn't

This release is intentionally lightweight in functionality but strong in structure. The design system, layout components, and data architecture are prepared to scale into real-time monitoring dashboards, activation workflows for emergency scenarios, integration with IoT sensors and telemetry, multi-role access for institutions and responders, and public-facing interfaces for citizens during crises.

Everything in this version is foundation work for that evolution.

Dual use by design

Although the platform targets catastrophic scenarios, the physical system is also designed for everyday use. During normal conditions, the modular water nodes can support firefighters, civil protection units, and temporary operations in areas with limited water access. This dual-use model ensures the system stays maintained, tested, and ready — rather than sitting idle waiting for a disaster.

Next steps

With Version 1 live, we're now working on live data simulation, the map-based interface powered by PostGIS, and expanding the backend into a full operational dashboard for authorities and emergency services. In parallel, we're refining the physical deployment model and exploring partnerships for real-world pilot testing.

More updates to follow.