1. Radiometric Doors â Uranium Ore Quality Control
1983
Automated gamma-detection gates installed at "Rudnik urana Ĺ˝irovski Vrh" (Slovenia) were designed to monitor the radioactivity of extracted ore during trial mining. These checkpoints ensured efficient processing by identifying economically viable uranium concentrations. On 1st of May 1986 (4 days after Chernobyl accident - 26th April 1986) system registered unusual radiation levelsâa spike that was initially dismissed as a false reading. Only later was it understood to be detection of the Chernobyl disaster, making these gates one of the first instruments in Europe to register the fallout. 2 days after Chernobyl accident, personnel at the Forsmark nuclear power station in Sweden also measured increasing levels of radioactivity on workers passing their radiation portal monitors.
A quiet witness to history, this tool demonstrated how even local systems can become global sensorsâaccidentally prophetic in their precision.
After the Chernobyl accident, designers were called in to investigate what were thought to be faulty radiation readingsâbut the data was completely accurate.
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2. MapCad⢠â Semi Automatic Vectorizer
1991
A DOS -based software for semi automatic vectorizing scanned cadastral maps. Featuring advanced snap-on geometry toolsâcenter of line, point in circle, intersection construction, ...
The following statement from one the leading geodesists speaks for itself: âDuring the pivotal era of cadastral digitalization, MapCad⢠and AutoCAD Map formed the ultimate duo of software tools for the Geodetic Office of Murska Sobota (Slovenia). Together, they enabled a superior, comprehensive, and high-quality transformation of analog cadastral maps into precise digital vector format.â
â Dr. Joc Triglav, Murska Sobota, September 2025
The image displays three elements:
A sample cadastral map (background)
⢠The MapCad⢠test file used during development and training (right),
⢠A fully vectorized land area (left) 691 km² with over 400,000 parcel lots processed entirely through MapCadâ˘
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3. Interactive Atlas of Slovenija (IAS)
1997
Awarded Best Product at the INFOS Fair, this groundbreaking atlas transformed the printed Atlas Slovenije into a fully digital experience. It featured multi-scale topographic maps, city overlays, and internet integration via a bundled Internet Explorer browserâallowing users to explore Slovenia interactively, both offline and online.
IAS was ahead of its time: a national-scale, multimedia-rich atlas designed for non-experts, with intuitive navigation and early web integration. It bridged cartography, education, and digital publishing in a way few countries had attempted.
IAS was ahead of its time: a national-scale, multimedia-rich atlas designed for non-experts, with intuitive navigation and early web integration.
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4. Viator Vehicle Tracking System â Logistics and Monitoring
2004
A GPS and Low earth satelite (LEO) based fleet monitoring system designed for Viator & Vektorâs logistics operations. It provided 24/7 cargo tracking across Europe, optimizing delivery routes and ensuring compliance with ADR and CMR standards. The system was embedded directly into truck cockpits, enabling real-time location and movement logging.
In 2004, the system proved its critical value when a fatal accident involving two casualties occurred. Investigators retrieved vital evidence from the onboard tracking device, which allowed them to fully reconstruct the accidentâincluding vehicle behaviour, timing, and location. This event highlighted the systemâs role not just in logistics, but in forensic reconstruction and legal clarity.
MapPoint was integrated into the cockpit computer to provide seamless coverage across Europe, helping with location tracking and navigation.
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5. QUO & SARMAN â Search & Rescue Mapping Systems
2006
Developed for Mountain Rescue England & Wales, QUO is a GPS-integrated mapping platform for terrain navigation and team coordination. Paired with SARMANâ˘, a modular rescue coordination system, it enables route planning, team tracking, and incident management in remote terrain.
Aimed to outdoor enthusiats as well.
Quo and Sarman were adopted by SAR teams across the UK.
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6. S3-FAST â Nuclear Disaster Simulation & Real-World Response Management
2009
Developed with International Safety Research (ISR), S3-FAST is a dual-mode system for nuclear emergency preparedness. It combines simulation training with real-time response tools, allowing operators to model radiological scenarios, assess impact zones, and coordinate field teams.
S3-FAST also includes a training module equipped with a scenario designer, enabling users to simulate nuclear disaster scenarios and tailor response actions to specific conditions and objectives
A training team responded to a simulated dirty bomb scenario as part of their exercise.
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7. Discover and Experience Slovenia
2013
A3 size, 194 printed topographic maps spiral bundled as atlas with 194 QR codes to get access to online content for each prinetd map. Content is impressive: 2000 trees of national importance, 5000 points of natural heritage, 150 waterfalls, 9000 entries into Slovene underground world, 200 points of cultural heritage,... and may more.
What made this project unique was its ability to generate a print-ready Atlas PDF with a single click. Instead of relying on conventional cartographic software, 194 externally sourced maps were arranged and placed through a one-off programming processâeliminating the need for manual drawing, reusable templates, or scripting. A dedicated web portal was also created to serve QR codes, all created by a single button press.
Although a printed atlas may seem outdated, it remains a valuable tool for exploring the unknown.
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8. DofE Expedition Tracker â Satellite-Linked Field Monitoring
2015
A specialized mapping and management system developed for the Duke of Edinburghâs Award (DofE) expeditions across bronze, silver, and gold levels. This platform connected directly to SPOT and Delorme (Garmin) satellite devices, enabling real-time tracking of participant groups in remote areas. It monitored progress, logged field events, and sent automated SMS alerts when neededâensuring safety and coordination even in signal-deprived terrain.
What set this system apart was its integration of individual medical profiles for each participant. In case of emergency, rescuers and coordinators could instantly access relevant health informationâstreamlining medical response and reducing risk. It was a vital tool for expedition leaders, combining geospatial awareness with human-centred care.
The system integrates satellite communications and terrestrial SMS to ensure optimal coordinationâenabling real-time tactical updates with team leaders in the field.
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9. sarOS⢠â Alpine Rescue Operating System
2016
Built for Mountain Search and Rescue Slovenia (GRZS), sarOS⢠is a fully offline-capable rescue coordination platform. It integrates topographic maps, orthophotos, and LiDAR data, enabling rapid decision-making in Sloveniaâs mountainous terrain.
sarOS⢠was built to support mission-critical operationsâdesigned to remain fully functional even when all other systems fail. In disaster scenarios where connectivity is lost, it continues to operate autonomously. Once connection to the outside world is reestablished, the system seamlessly integrates external services to enhance coordination and situational awareness.
Based on the initial official data (the missing person was found deceased at an altitude of approximately 1,000 meters between Krvavec 1.853 m and the settlement of Kokra 899 m), the location of the find was re-determined within one minute using tools and data from the sarOS⢠system. Although few believed such precision was possible at first, the result proved to be completely accurate.
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10. Accident Reconstruction with MapMind⢠â Forensic GIS Intervention
2020
In a complex car crash investigation involving one casualty, elements of the emerging MapMind⢠platform were used to reconstruct the incident with forensic precision. The system used a built-in tool to reconstruct vehicle movement before the crash and until the situation settled, relying solely on tachograph data from a bus and a truckâcontaining only speed and time. Despite the limited input, the calculation precision reached down to a meter, enabling a detailed and reliable reconstruction.
The result completely overturned the official account of what had happened, providing clarity and truth in a case clouded by uncertainty. MapMind⢠demonstrated its power not just as a GIS engine, but as a tool for justice.
MapMind⢠introduces a sophisticated method for merging disparate time-based data into a unified timelineâessential for reconstructing what truly happened during a car crash. By aligning GPS tracks with tachograph records, significant time offsets always exist, the system reveals a coherent sequence of events that would otherwise remain fragmented or misunderstood.
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11. Past2Present Mapper â Historical Topography Meets Live Data
2021
This tool (build in MapMindâ˘) merges high-detail historical topographic maps with modern OpenStreetMap (OSM) data, preserving the full richness of both eras. It allows users to see how the landscape was and how it is now, side by sideâcreating a layered understanding of terrain evolution.
The final map can be viewed in switchable layers (old vs. new), or as a merged compositeâready for display or print. While cartographic purists may raise an eyebrow at the fusion, users are consistently delighted by the clarity and context it provides.
For outdoor enthusiasts, itâs a gateway to rediscover forgotten trails, vanished landmarks, and the natural shifts in geography. For first responders and investigators, itâs a forensic lensârevealing how past terrain may influence present-day incidents, and helping to identify potential causes rooted in environmental change.
Whether for exploration or emergency response, Past2Present Mapper offers a unique perspective on how the future builds upon the pastâwithout erasing it.
Overlaying old topographic maps with new features is essential for revealing changes over time. In this example, the red arrow points to a group of buildings that no longer existâhighlighting how historical layers can expose lost structures, forgotten layouts, or shifts in terrain that modern maps alone cannot convey.
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12. Subtitling Landscape â Viewpoint Experience Tool
2023
As part of the evolving MapMind⢠platform, the Subtitling Landscape tool was introduced to create an unparalleled visitor experience at scenic viewpoints. This system generates a complete PDF layout for CNC machining a circular, curved horizontal dibond plateâdesigned to visually narrate the landscape.
Visitors simply touch the inner circle with their belly, and the plateâs radial layout guides their gaze outward, explaining what lies in each direction. Mountains, towns, rivers, and landmarks are annotated with precision and elegance. From the same data source, a full-featured web app is generated, offering interactive exploration for remote users or digital kiosks.
This fusion of physical storytelling and digital augmentation turns passive sightseeing into immersive geographic interpretationâbridging cartography, design, and public engagement.
Transforming a panoramic, cylindrical view into a curved horizontal plate proved particularly challenging. The landscape, originally presented in a vertical orientation, required more than simple curvatureâdemanding precise spatial logic and visual reinterpretation to preserve depth, scale, and orientation.
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13. OMMP⢠â Medical Continuity Reconsidered
2026
Developed through long-term collaboration with anaesthesiologists and surgeons,
OMMP⢠introduces a fundamentally different direction for healthcare information systems.
A subset of the architecture has already been deployed successfully within a small surgical environment.
Rather than treating medicine primarily as centrally mutable repository state,
OMMP⢠approaches healthcare as a sequence of evolving semantic medical events.
The direction emphasizes immutable continuity, progressive evidence accumulation,
runtime reconstruction, structural decoupling, and long-term archival durability.
OMMP⢠intentionally separates:
semantic continuity,
authorization infrastructure,
analytical extraction,
interoperability,
rendering,
and workflow evolution.
Existing medical recordsâhowever they were originally representedâmay coexist naturally within the broader continuity structure.
Legacy records therefore remain preserved as the frozen truth of what happened,
without requiring destructive migration or forced reinterpretation.
The direction remains compatible with established ecosystems such as HL7, FHIR, openEHR, and DICOM,
while avoiding unnecessary long-term structural coupling to any single implementation philosophy.
One of the central observations behind OMMP⢠is that medicine naturally behaves as longitudinal continuity composed of evolving incidents, evidence, and contextual reconstruction.
The architecture therefore seeks simplification through deeper decomposition rather than increased systemic complexity.
14. MapMind⢠- Mapping Reimagined for Action and Awareness
2027 (release year)
As the culmination of decades of development, the leader of TimelessMind⢠reunited a new generation of innovators six years ago to build a system that could unify everything that came beforeâand go far beyond. In 2023, the final missing member was added to the team: artificial intelligence.
MapMind⢠is a next-generation spatial system built to serve explorers, responders, planners, and institutions alike. More than a platform, itâs a living archive of TimelessMindâ˘âs legacyâreimagined for clarity, coordination, and meaningful engagement with the outdoors.
MapMind⢠introduces a suite of foundational featuresâmost notably, a redefinition of the shapefile standard that resolves long-standing limitations long overdue for correction. The image presents a MapMind⢠ââ Google Earth Live Link centered on Buckingham Palace, precisely aligned with a specific window. Sunrise is expected 11 hours and 46 minutes after the moment of capture, occurring at 08:03 CET (07:03 UK time). To enhance the visibility of directional lines, the topographic layer was rendered with reduced opacity, allowing spatial vectors to emerge with greater clarity and intent.
TimelessMindâ˘