First LIGO-detected Electro-Magnetic wave signal • 14 September 2015 • Kinetiverse analysis
GW150914 is the first Electro-Magnetic wave signal ever detected by LIGO on 14 September 2015. Two dense kinematic mass ensembles (36 M_⊙ and 29 M_⊙) coalesced, releasing energy into the STE covariance field. LIGO recorded the resulting modulated Electro-Magnetic waves — the historic first direct detection of such a signal.
The entire signal is explained purely by F=ma + E=mc_t kinematics with c_t attached to the acceleration factor. The post-coalescence EM signal is a damped oscillation in the STE covariance field Σ — no free parameters, no additional postulates.
“The first LIGO-detected Electro-Magnetic wave signal is a damped STE covariance oscillation in the merged kinematic ensemble — pure motion, entangled domains, c_t attached to acceleration.”
Linearized STE Covariance Evolution (Law 5)
\[ \frac{d^2 \delta\Sigma}{dt^2} + 2\gamma_\text{STE} \frac{d\delta\Sigma}{dt} + \omega_\text{STE}^2 \delta\Sigma = 0 \]
ω_STE lowered by c_t attachment to F=ma (Δc_t / c ≈ 0.06)
γ_STE from Law 8 three-source dissipation
Two kinematic mass ensembles execute overlapping motions. F=ma + E=mc_t entanglement produces the rising-frequency Electro-Magnetic wave signal detected by LIGO.
Coalescence injects a clean perturbation δΣ into the STE covariance field, releasing energy as modulated Electro-Magnetic waves.
δΣ relaxes via the damped oscillator. c_t attachment to acceleration lowers the peak frequency and broadens the spectrum.
LIGO’s first detection of an Electro-Magnetic wave signal resolved the full kinematic signature. The data show a broadened peak at ~235 Hz with extended tail — exactly as required by F=ma + E=mc_t with c_t attached to acceleration.