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PWR-03 SYSTEM

Energy Management & Trigger Sequencing

Power Handshake Components

PWR-03-A D-D Tokamak Reactor
Output2.5 GW Continuous
Core Temp200 Million Kelvin
FuelDeuterium-Deuterium

Primary energy source. Feeds Neutral Injectors (MD-01-A) directly via high-temp exhaust bypass.

PWR-03-B Graphene Supercaps
Stored Energy12.1 GW (1ms Disch.)
MaterialGraphene-Sulphur Stack
Operating V2.5 V per cell

Stages the critical "Snap" pulse. Stacked modules minimize internal resistance for instant discharge.

PWR-03-C SiC MOSFET Bank
Array Size128 Parallel Switches
SubstrateSilicon Carbide
Switch SpeedFemto-second capable

The system's "Trigger Finger." Discharges 1.21 Giga-Watts from supercaps to stator coils in exactly 1ms.

BUS-01 High-Current Bus-Bars
MaterialAg + Graphene Rails (99.9%)
IsolationMLI Mylar/Kapton Stack
ShieldingMu-Metal 80% Ni Alloy

The power arteries delivering the massive impulse from the MOSFET bank to the superconducting coils without vaporizing.

PWR-03-E Voltage Snubbers
FunctionTransient Spike Prevention

Prevents high-voltage transient spikes and backflow from hitting the Tokamak reactor during the 1ms Snap.

PWR-03-F Grounding Braids
MaterialGold-plated Copper

Designed for massive EMI shunting away from the GaAs logic core to ensure jitter remains below 20fs.

Discharge Synchronicity & Metric Conversion

QUADRANT VOLTAGE DECAY GRAPH (1ms Snap)

Alpha Bank

1.000000000000 ms

Beta Bank

1.000000000000 ms

Gamma Bank

1.000000000000 ms

Delta Bank

1.000000000000 ms

SYNC_STATUS: OPTIMAL

ENERGY-TO-METRIC EFFICIENCY

Electrical to Curvature Ratio: 94.50%

Target > 94.0% with 4K BUS-01 transmission rails to prevent Fin saturation.

PWR-03-C MOSFET Slew Rate Monitor

TRIGGER-TO-ANCHOR LATENCY

The 1ms Snap relies on Femtosecond Determinism. The SiC MOSFETs must switch from 0 to 1.21 GW Flow in < 100 ns. If the slew rate is too slow, energy bleeds into the stator as Heat instead of Flux, causing a Thermal Quench before the Anchor can even shape the spacetime metric.

Trigger Rise Time

0 ns

Energy-to-Curvature

100%

100ns LIMIT

SWITCHING SPEED OPTIMAL