The deployed operations infrastructure layer for contested, remote, and humanitarian environments.
Deploy anywhere. Operate indefinitely.

Software-defined, self-sustaining clinical pods with intelligent energy management. Deployable in hours, operational for weeks without resupply. Purpose-built for the environments where reliable infrastructure doesn't exist yet.

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4 hours
Deploy Time
99.97%
Uptime Target
72h+
WITHOUT RESUPPLY
The Challenge

The infrastructure gap is a strategic vulnerability

Military medical capability drops catastrophically between Role 1 and Role 2. Humanitarian organisations deploy tents while patients need surgical suites. Remote communities wait years for facilities that never arrive. The gap isn't clinical expertise — it's deployable, self-sustaining infrastructure that works from the moment it arrives.

4-6 weeks
TO BUILD A FIELD HOSPITAL
60%
POWER FAILURES IN DEPLOYED MEDICAL
0
INTEGRATED SYSTEMS ON MARKET
Who This Is For

One Platform, Four Mission Profiles

Every deployment is different. The underlying infrastructure challenge is the same: you need clinical capability where none exists, with energy you can depend on and software that keeps everything running.

Forward operating base with modular containerised infrastructure at dusk
Defence & Security

Forward Base & Theatre Medical

Role 1 through Role 2E medical capability for forward operating bases. Integrated energy management supports clinical, communications, and UAS operations from a single containerised footprint. STANAG-interoperable, ITAR-free — built for non-US allied forces. Deployable by C-17 or flatbed.

  • Role 1 through Role 2E clinical capability in ISO container form factor
  • Autonomous energy for 72+ hours without resupply
  • STANAG-interoperable, ITAR-free
  • Non-US allied market compatible
Humanitarian medical response with modular clinical containers
Humanitarian Response

Disaster & Crisis Deployment

Rapidly deployable clinical infrastructure for disaster response, refugee health, and emergency medical operations. Arrives self-powered, operates independently of damaged local grid, and scales by linking additional modules.

  • Operational within hours of arrival on site
  • No dependency on local power or water infrastructure
  • Modular scaling — add surgical, lab, or pharmacy units
  • WHO EMT Type 2 alignment
Containerised medical pod deployed in a remote rural community
Remote Communities

Primary Care for Underserved Regions

Permanent or semi-permanent clinical facilities for communities that lack healthcare infrastructure. Solar-primary energy with battery storage provides reliable power without fuel logistics. Clinical OS enables remote clinical oversight.

  • Solar-primary with battery backup for sustained operation
  • Telemedicine bridging to specialist centres
  • Cold chain management for vaccine and pharmaceutical storage
  • Designed for tropical, arid, and extreme cold environments
Healthcare professional using portable diagnostic device in clinical setting
Public Health & Hospital Upgrades

Surge Capacity Without Construction

Add clinical capability to existing hospital campuses without breaking ground. Surge capacity — pandemics, mass casualty, seasonal demand — deployed without permanent construction. Plug into existing systems or operate standalone.

  • Deploy on any hospital car park or adjacent land
  • HL7 FHIR integration with existing hospital information systems
  • IEC 62304 and ISO 13485 regulatory pathway
  • Can operate grid-tied or energy-independent
In the Field

Built for the Operational Edge

From joint operations centres to forward surgical nodes, the platform performs across every environment where the mission demands reliable infrastructure.

Military joint operations centre with fleet management on wall displays

Joint Operations Centre — theatre-wide fleet visibility

Senior military officers at briefing with fleet analytics screen

Defence Briefing — fleet analytics for senior leadership

Medic with ruggedised tablet inside surgical container

Stored protocols & governance follows framework nations’ lead

Field operations centre — real-time cluster monitoring with tactical communications

FIELD OPERATIONS CENTRE — REAL-TIME CLUSTER MONITORING WITH TACTICAL COMMUNICATIONS

Clinical Infrastructure

What Ships in the Container

Three integrated layers — hardware, software, and energy — ship as one system. The hardware is modular, the Clinical OS is intelligent, and the energy is integrated, not bolted on.

Interior of containerised clinical pod with teal LED lighting, monitoring displays, and integrated medical equipment
Tricorder Systems multi-container deployment — aerial view of six ISO container units including Forward Surgical Node, Triage and Stabilization, Diagnostics Lab, Medical Command, and Power Systems Module at a desert forward operating base
Complete deployment configuration — six modular units forming a self-sustaining clinical complex at a forward operating base

Containerised Form Factor

Standard ISO 20ft and 40ft containers. Transportable by road, rail, sea, or C-130 air. Arrives ready to operate — no assembly, no construction, no specialist installation team.

Clinical-Grade Environment

HEPA filtration, climate control, medical gas provisions, and clean power. Meets the environmental standards required for diagnostics, minor surgery, and patient stabilisation.

Modular Expansion

Start with one pod. Add surgical, laboratory, pharmacy, or accommodation modules as the mission demands. Each module connects to the shared energy backbone and Clinical OS network.

Integrated Energy

Battery storage, solar input, and generator failover are built into the container — not a separate logistics problem. The Clinical OS manages every watt so clinical systems never lose power.

Regulatory Pathway

Designed from day one for IEC 62304 software lifecycle, ISO 13485 quality management, and CE marking. Built-in audit trails and version control support the regulatory evidence package.

Remote Fleet Management

Monitor and manage every deployed pod from a central operations dashboard. Firmware updates, diagnostic data, energy status, and clinical throughput — all visible in real time over satellite or cellular backhaul.

Clinical OS

The Software That Runs Everything

Clinical OS is the patentable intelligence layer that sits between the hardware and the mission. It orchestrates clinical workflows with NEWS2 and qSOFA scoring, manages energy as a clinical resource, monitors environmental conditions, and gives remote operators total visibility — so the people on the ground can focus on patients. It is explicitly not autonomous AI triage or clinician replacement.

Mission Applications
Diagnostics, Triage, Telemedicine, Reporting
Clinical OS Middleware
Orchestration, Scheduling, Compliance, APIs
Energy Management Core
Load Balancing, Prediction, Failover, Metering
Hardware Abstraction
Batteries, Solar, Generators, Sensors, Devices
Patentable IP
01

Clinical-Aware Energy Orchestration

ClinicalOS Energy pre-stages power for scheduled procedures, prioritises life-critical loads like ventilators, and sheds non-critical systems automatically. Power becomes a clinical resource managed by software, not a background utility.

02

Vendor-Agnostic Abstraction

Works with any battery chemistry, solar configuration, or generator through a unified API. Swap hardware without rewriting software.

03

Clinical Workflow Engine

NEWS2 and qSOFA patient scoring, automated triage protocols, diagnostic queuing, cross-pod patient handover, and telemedicine bridging. Configurable per mission profile — mass casualty, primary care, or specialist clinic.

04

Regulatory-Ready Architecture

IEC 62304 compliant software lifecycle with built-in audit trails, version control, and safety classification. The evidence package grows as the system operates.

05

Real-Time Fleet Telemetry

Every pod reports energy state, device health, environmental conditions, and clinical throughput. Anomaly detection flags issues before they become failures.

Three Zoom Levels. One Picture.

ClinicalOS organises deployable medical infrastructure into three hierarchical views — giving commanders, cluster leads, and pod operators exactly the information they need.

Theatre Overview Global fleet. Single pane of glass.
ClinicalOS Theatre Overview — global fleet command dashboard with world map, cluster status indicators, and fleet KPIs
Cluster View
ClinicalOS Cluster View — site-level operational dashboard showing pod status, bed management, and environmental data
Site-level operational picture — pod inventory, bed management, environmental monitoring
Pod Detail
ClinicalOS Pod Detail — individual pod workstation showing patient vitals, environmental telemetry, and equipment status
Inside the container — patient census, vital signs, environmental telemetry, equipment status
ClinicalOS Energy

Command and Control of Power, Driven by Clinical Need

Power isn't a background utility — it's a clinical resource. ClinicalOS Energy treats every watt as a decision, pre-staging reserves for surgery, prioritising ventilators over lighting, and extending autonomous operation through intelligent load management. Every pod ships with battery storage, solar input, and generator failover — managed as one integrated system.

energy.tricorder-systems.com
Battery
87%
Load
4.2 kW
Solar In
2.8 kW
Reserve
18h

Battery-First Architecture

High-density lithium storage provides 72+ hours of autonomous clinical operation. The system prioritises battery health and longevity through intelligent cycling algorithms.

Renewable-Primary When Available

Deployable solar arrays charge the battery bank during daylight. For sustained operations, solar extends the time between generator runs or resupply by 60-80%.

Automatic Failover

If any source fails, the system reroutes power within milliseconds. Clinical equipment on the critical bus never sees an interruption — the handoff is invisible to operators and patients.

Software-Managed Load Priority

Clinical OS classifies every load — life-critical, mission-essential, or deferrable. When energy is constrained, non-critical systems are shed automatically. Clinicians never have to choose.

TC-600 Power Pod
100 kWh LFP battery 60 kW genset 400V DC bus Solar array input
Get Started

Request a Briefing

Tell us about your operational requirements. We'll arrange a technical briefing tailored to your mission profile — whether that's defence, humanitarian, remote deployment, or hospital expansion.

London, United Kingdom
Founders Factory, 180 Strand
Email
hello@tricorder-systems.com
Designed to meet
IEC 62304 ISO 13485 CE Marking HL7 FHIR STANAG WHO EMT
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