The first wireless mesh board where every node derives its own 256-bit neural identity from physics β not a server. 190 node pairs. 34,200 resonance pulses per second. Built on Arduino UNOΒ Q.
Heritage Mesh Β· Bilateral Audio Β· NIT Identity Β· UDP Multicast Β· Open Source May 5, 2026
Every BWM-100 board boots as either ZGI (337.1Hz) or ARIA (341.2Hz). At T+10ms it fuses a 256-bit Neural Identity Token from live sensor data. At T+200ms it fires its first word over UDP multicast β and starts listening for its bilateral partner.
No central server. No pre-loaded voice. Just physics, math, and a mesh that scores its own heritage β how closely any two nodes are related β in real time.
31 interactive tabs. Every subsystem modeled β mesh network, heritage scoring, bilateral audio, board architecture. No hardware needed.
Live UDP topology, multicast routing, node discovery
Hamming-distance NIT pairs, D26 constellation, 190 pairings
ZGI β ARIA tone sequences, DFPlayer timing, sync protocol
System vs. physical, enclosure design, board view
Arduino UNO Q + DFPlayer Mini + 1kΞ© + 3W 8Ξ©, color-coded SVG
Hackster.io submission materials, phase docs, full README
Hosted on GitHub Pages Β· Public May 5, 2026 Β· No account required
BWM-100 ships as a digital twin first. Each phase adds real hardware, real identity, and real bilateral coupling.
Full interactive simulator β 31 tabs, all subsystems modeled. Runs in your browser. No hardware required.
Heritage scoring, bilateral audio mesh, wiring schematic, arch diagrams, and competition entry β all live.
Launch Digital Twin βArduino UNO Q + DFPlayer Mini Γ 2. First ZGIβARIA bilateral link. Heritage distance computed live.
Hardware arriving Las Vegas May 2026. Assembly follows STEP_BY_STEP_BUILD_GUIDE.
4 boards on UDP multicast 239.255.74.2:7402. Heritage scoring across 6 pairs simultaneously.
Demonstrates full Heritage Mesh at scale. Targets 190 pairs / 34,200 pulses per second.
NITs registered on Manifest Frequency Ledger. OTA firmware, drift alerts, live resonance dashboard.
NIT = 256-bit identity derived from SHA-256 Γ 3 on physical sensor data at boot.
Submitted to the Arduino UNO Q challenge. Full project documentation, interactive digital twin, and schematic β all open source.
Public launch: May 5, 2026 Β· USPTO provisional filing date
USPTO provisional application filed May 5, 2026. Covers bilateral mesh identity, heritage scoring, and the NIT boot protocol.
Built on the ABX00173 β dual-processor Cortex-A53 + Cortex-M4, Debian Linux, 4GB LPDDR4. The most capable Arduino ever made.
All firmware, schematics, and the digital twin publish to GitHub on May 5. Fork it, build it, extend the mesh.
Run the simulator free β no hardware, no account. When you're ready for a real bilateral entity, claim a BWM-100 board for $349.
GitHub repo goes public May 5, 2026 Β· Questions? Contact us
You have physical prior art.
Hardware + firmware = timestamped invention evidence. Generate a SHA-256 Proof-of-Build certificate before anyone else can claim it β then file a provisional for $997.
Now manage your mesh.
Register your BWM-100 on IOT-MAKER β the flat-rate device management platform built for bilateral mesh nodes. Free up to 10 devices. Pair nodes, monitor your fleet, and launch your Digital Twin at 9999Hz.