Engineer and deploy fully operational telecommunications network infrastructure on Mars.
We aim to engineer and deploy a fully operational telecommunications network infrastructure on Mars, supporting resilient connectivity for human and robotic operations. This represents the culmination of our technological evolution—from passive infrastructure to AI-native networks to interplanetary systems.
The Speed of Light $c \approx 299,792 \text{ km/s}$ constant dictates the latency floor.
High-gain antenna systems capable of maintaining reliable Earth-Mars data links across variable distances with minimal power consumption.
Radiation-hardened energy storage and solar/nuclear power generation systems designed for the Martian environment and dust storms.
Equipment capable of operating in extreme temperature swings from -125°C to +20°C with minimal maintenance requirements.
AI-driven network management that can operate independently during communication blackouts and respond to failures without Earth intervention.
Electronics designed to withstand cosmic rays and solar particle events without the protection of Earth's magnetic field.
Capability to produce replacement components using Martian resources to minimize dependency on Earth supply chains.
| $P_t$ | Transmit Power (dBW) |
|---|---|
| $G_t$ | Transmit Antenna Gain (dBi) |
| $G_r$ | Receive Antenna Gain (dBi) |
| $L_{path}$ | Free Space Path Loss (dB) |
|---|---|
| $T_s$ | System Noise Temperature (K) |
| $R$ | Data Rate (dB-Hz) |
Phase Dream builds upon the foundation laid in earlier phases. Each step brings us closer to interplanetary connectivity.
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