Abstract
This prior art document establishes a standardized industrial framework for a non-invasive neural bypass architecture. The subject of this addendum is a Distributed Neural Tracking System that utilizes sub-dermal Osseous Wells as localized signal repeaters and an external, wearable Jumper Hub as a central predictive processor. Unlike conventional brain-computer interfaces (BCIs) that rely on high-risk dural penetration and static internal leads, this protocol utilizes a Solid-State Phased Array to maintain a trans-dermal data link. The vertebral Osseous Wells function as an intra-body tracking network, communicating the position of Local Field Potential (LFP) macro-waves to the external Jumper Hub. This enables the system to calculate exact temporal arrival and execute Predictive Pre-Charging of the spinal bridge at the 12-microvolt LFP threshold, effectively eliminating biological and algorithmic latency. By utilizing a Hybrid Adhesive Docking system, the architecture ensures high-fidelity alignment and field-serviceability without permanent dermal breaches.
Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 License.
Recommended Citation
Gossett, Jon S., "The Gossett Protocol: Trans-Dermal Optical Bus and Distributed Neural Tracking (Technical Addendum to Article #9369)", Technical Disclosure Commons, (March 05, 2026)
https://www.tdcommons.org/dpubs_series/9466