Experimental
Protocol Kit

Phase II Implementation of The Tesla Resonance Protocol

Objective

To reconstruct the essential architecture of Nikola Tesla’s resonance-based devices not for the transmission of power, but for the detection of emergent coherence within the electromagnetic field. This test seeks to identify structural alignment, tension and resonance, validating Tesla’s harmonic framework under the Lilborn Equation.

Core Assembly Components

Primary Ground Coil: Wide-diameter, low-turn, helical copper base (asymmetrical)

Secondary Vertical Coil: Tapered, high-turn spiral coil, tuned to Earth’s Schumann harmonics

Toroidal Capacitor Topload: High-voltage capacitor ring or dome used to elevate field structure

Pulse Driver: High-voltage, low-frequency gate signal; must produce harmonic repetition

Receiver Coil (optional): Remote coil tuned to 1:1 harmonic for coherence inclusion testing

Test Environment:
– Conduct in non-shielded area, open to atmospheric EMF

– Ground primary coil to earth rod if possible

– Maintain low RF emissions to avoid false resonance

– Use pulse driver tuned near Schumann resonance or harmonic (e.g. ~7.83 Hz, ~14.1 Hz)

Sensor Array:
– Torsion Sensor: Base-mounted, detects device rotation or alignment shifts

– Piezoelectric Strain Sensor: Affixed to dielectric or core base

– Magnetometer: Placed at topload, measures magnetic alignment

– Pulse Log Sync: Timestamp the initiation of each pulse burst for overlay

Global Overlay Logging (Lilborn Coherence Engine):
– Record Kp Index (3-hour planetary field stress)

– AE Index (Auroral Electrojet)

– IMF Bz (Interplanetary Magnetic Field, z-axis)

– Lunar phase and position (syzygy and perigee tracking)

– Optional: SWARM satellite data and ELF atmospheric logs

Test Execution:
1. Begin with 15-minute silent baseline logging (no pulsing)

2. Initiate low-voltage pulsed gating for 10-minute window

3. Log pulse timestamps precisely alongside sensor data

4. Record any torsion, strain or magnetic shift

5. Pause for 15 minutes; repeat with slightly altered frequency

6. Compare overlay with AE, Kp, IMF data

Anomaly Detection Criteria:
– Torsion shift occurs during or immediately after AE/Kp/IMF spike

– Strain inversion correlates with global geomagnetic alignment

– Receiver coil (if used) shows signal with no conductive path

Interpretation:
– Presence of anomaly + index correlation = Coherence event

– No anomaly + no correlation = Baseline stable

– Anomaly without global trigger = Local structural tuning confirmed

Next Step:
If coherence is confirmed, advance to environmental modulation: test with moonrise, tide cycles or during solar flares.

Produced by The Lilborn Equation Team:

Michael Lilborn-Williams

Daniel Thomas Rouse

Thomas Jackson Barnard

Audrey Williams