Subject: Universal Neural Handler Interface // Holo Viewer 5000 tactical hardware
Project Burnwood Link: A proprietary dual-interface ecosystem designed for the uncompromised synchronisation of Agent and Handler. This dossier details the technical synergy between the Neural Handler Interface—a specialised mobile-web uplink—and the Holo Viewer 5000 hardware. Together, they facilitate an uninterrupted strategic tether, manifesting live intelligence data into a physical, 3D tactical asset.
A web-based software ecosystem that transforms any modern smartphone into a direct tactical conduit. This ensures field operatives can utilise personal hardware to establish a high-fidelity radio uplink to ICA Command via secure local network protocols.
The system integrates a long-term memory module, functioning as her persistent recollection of operative interactions and past contract data. This allows for a continuous, evolving relationship where every tactical decision and field observation is stored and retrieved to provide deeper strategic context in future engagements.
Fully compatible with all smartphone hardware via standard web protocols (HTTPS/SSL). Display scaling and luminosity are handled dynamically by the frontend interface to maintain visual clarity regardless of device manufacturer or OS.
Requires a local PC-hosted Python backend. This "Neural Brain" leverages Gemini 3 Flash to process complex queries, ensuring intensive intel retrieval occurs off-device to maximise mobile responsiveness.
Intelligence persistence is managed via a dedicated SQLite memory database. The interface records and retrieves mission-critical variables—such as restricted door codes and target movement profiles—in real-time.
Communication is humanised via a local viseme rendering engine. This system matches phonetic transitions to the en-GB "Martha" vocal synthesis at a 1:1 duration, ensuring perfectly timed speech patterns locally on the mobile device.
The physical platform for the Handler Interface. A 3D-printed, modular chassis engineered for field durability, featuring a precision-fit universal cradle to anchor the digital handler within the physical environment.
Utilises a passive Pepper's Ghost optical array to achieve 3D manifestation. By reflecting the high-luminosity mobile display off a high-transparency 45-degree refraction plate, digital assets are anchored within the physical viewing chamber with tangible depth of field.
The structural foundation is defined through programmatic OpenSCAD geometry. This code-driven approach allows for parametric scaling, ensuring the optical refraction chamber is mathematically optimised for specific device dimensions before the 3D-printing phase.
Features a precision-engineered tension-mount cradle. This modular design has been verified to achieve optical focus across a wide spectrum of mobile device screen dimensions, ranging from 4.7" to 6.8". However, due to variable device thicknesses and screen-to-chassis ratios, the external print dimensions are dynamically adjusted via the OpenSCAD parametric core to maintain structural and optical integrity for specific operative hardware.
The Burnwood Link began as a singular vision: to bring the Agency's most iconic strategic asset out of the screen and into the physical environment. The initial plan was to create a simple radio-visual bridge, but the project quickly evolved into a rigorous exercise in dual-hemisphere engineering. The development of the visual assets alone—recreating the Agency's signature high-contrast interface—was an intensive multi-week phase to ensure total immersion.
The software development was a marathon of logic. Over several weeks, the project moved from basic API pings to a complex ecosystem involving a local Python backend, a high-performance Gemini 3 Flash neural bridge, and a custom phonetic viseme engine. Perfecting the zero-latency synchronisation between the en-GB 'Martha' vocal synthesis and the mobile-web frontend was the primary technical hurdle, requiring hundreds of hours of iterative testing to achieve the current 'seamless' feel.
Simultaneously, the hardware development pushed the limits of parametric CAD. Moving from static sketches to a fully dynamic OpenSCAD architecture took nearly a month of trial-and-error. Calculating the exact 45-degree refraction geometry and focal depths for the Pepper’s Ghost array required dozens of 3D-printing prototypes to account for varying device luminosities and chassis tolerances. What we ended up with is more than just a dock; it is a manifestation of months of work spent bridging the gap between digital ghost-intel and physical reality.