INTERACTIVE SIMULATION
Mars Quantum Simulator
Transmit a message to Mars via the Ansible quantum channel. Adjust parameters, compare to classical radio delay, and observe error correction in action.
Orbital Relay Network
6 geostationary satellites maintain entangled photon pairs in the vacuum of space
Theoretical Framework
Modified non-local Hamiltonian enables controlled FTL correlational information transfer
THE F_* THRESHOLD
A hard activation boundary, not a dial.
The proposed mechanism activates only when pair fidelity exceeds F_* — an ER-bridge traversability threshold analogous to the Gao–Jafferis–Wall construction. Below F_*, the channel is silent; above it, correlated evolution begins. That sharp edge is the testable prediction.
INTERPRETING RESULTS
Both outcomes advance the program.
- Success:non-trivial correlation between Alice’s and Bob’s local observables — one that cannot be explained by any pre-established classical record — detected only above F_*.
- Null:the honest expected outcome per §12.2. A null tightens the upper bound on λ_NL and disciplines the research program. Both outcomes are scientifically valuable.
● LINK ACTIVE
FRAME · ECI-J2000
FIDELITY 99.87%
PAIR RATE 1,200,000/s
BITS SENT 0
PROGRESS 0%
CH · QC-01
STANDBY
EARTH-MARS LINK
RADIO DELAY: 3m 2s
QUANTUM PARAMS
λ · LAMBDA1.00
κ · KAPPA0.15
CAPACITY91.9%
TRANSMISSION
EC
320 BITS
LATENCY COMPARISON
ANSIBLE
— —
RADIO · c
3m 2s
SIMULATION · ANSIBLE FRAMEWORK · THEORETICAL