A novel approach to building electrical distribution that addresses documented safety, efficiency, and infrastructure compatibility limitations in conventional residential and commercial systems. Originated as independent research into the gap between how buildings are wired and how modern electrical loads actually consume power.
Three documented limitations of conventional residential and commercial electrical distribution. The architecture being patented addresses all three.
Hazards in conventional residential branch circuits — arc faults, ground faults, in-wall heat events — are documented and live entirely inside the AC distribution model.
Every wall wart, LED driver, and PD charger converts back to DC at the load. Aggregate conversion losses are real, silent, and absorbed by the consumer.
USB-C PD, EVs, batteries, solar inverters, panels, comms gear — all native DC. The infrastructure assumes the load profile of 1955; the load profile of 2026 is different.
I built a working prototype to validate core technical principles. Measurements support the hypotheses behind the architecture, which justified continuing through the formal patent process.
I'm currently completing the formal patent application before publication. The architecture, conductor topology, and core control algorithms will appear here once the application clears the public-disclosure threshold.
Research spans electrical engineering, embedded systems, and smart home integration — three disciplines that, in this design, are not separable.
Power distribution, conductor sizing, fault-current modeling, code-compliance pathway.
Real-time fault detection, current/voltage sense, low-latency switching logic.
Native protocol fluency with modern DC loads and home-automation backplanes.
The architecture, prototype measurements, and patent claims will publish here the day publication restrictions lift. Until then: this page is the only public surface.
If you want a heads-up when the page unlocks, message me directly. No mailing list. No drip campaign.