Reimagining communication across the stars with autonomous, delay-tolerant systems designed for the extreme conditions of deep space.
interplanetary-comm-protocols (In progress)
Protocols designed to enable seamless and reliable communication between planets, spacecraft, and mission control on Earth, tackling the extreme distances, delays, and limitations inherent in interplanetary communication.
dtn-messaging-system (In progress)
Core implementation of delay-tolerant networking (DTN), allowing messages to be reliably sent and received across vast distances and through intermittent connectivity, ensuring communication continuity even during disruptions.
astro-messaging-system (In progress)
A system crafted specifically for the extreme conditions of space exploration, where temperature extremes, cosmic radiation, and vast distances challenge traditional communication methods. This messaging system is designed to maintain signal integrity and reliability in the harshest space environments.
space-relay-comm (In progress)
A network of autonomous relay nodes (e.g., spacecraft, satellites) that ensure message forwarding across great distances. Each node acts as an intelligent router, optimizing message delivery by dynamically adjusting routes based on availability and proximity of other nodes.
autonomous-space-comms (TODO)
An autonomous communication system where each node (spacecraft, rover, satellite) operates independently, storing and forwarding messages, prioritizing data transmission based on criticality, and routing around network failures without human intervention.
latency-tolerant-messaging (TODO)
Designed specifically for handling extreme latency conditions found in deep-space missions, this messaging system uses smart scheduling, batching, and queuing techniques to ensure reliable communication despite delays that may last minutes or even hours.
stars-and-signals (TODO)
A poetic exploration of how signals traverse the vast emptiness of space, connecting distant spacecraft and planets. This system focuses on the elegant flow of data across the cosmos, ensuring that each signal finds its way, no matter the obstacles in its path.
astrocomm-protocols (TODO)
Advanced communication protocols tailored for astronomy and space exploration, ensuring secure and efficient data transmission across celestial distances, leveraging space-specific routing algorithms and error correction techniques.
offworld-messaging (TODO)
Specialized messaging systems designed for environments beyond Earth. These systems focus on creating reliable communication channels for extraterrestrial missions, whether it's Mars colonies, lunar bases, or interstellar expeditions.
dtn-prototype (TODO)
A prototype implementation of a Delay-Tolerant Networking (DTN) system, showcasing real-world applications of store-and-forward techniques in simulated deep-space communication scenarios.
autonomous-nodes (TODO)
Simulates autonomous communication nodes that can independently manage message storage, routing, and prioritization. These nodes can continue to operate and communicate without relying on central control, even in the face of network failures or interruptions.
message-batching (TODO)
This system aggregates multiple messages into batches for more efficient transmission during limited communication windows, reducing overhead and optimizing bandwidth usage when communicating across deep-space environments.
message-integrity (TODO)
A system designed to ensure the integrity and reliability of messages transmitted in space. Using techniques like checksums, hashes, and redundant storage across nodes, this system guarantees that messages arrive intact, even after traveling vast distances.
latency-tolerant-protocols (TODO)
Communication protocols that embrace and adapt to the long delays inherent in space communication. These protocols focus on queuing, scheduling, and predictive routing to optimize communication in high-latency environments, ensuring that data is delivered efficiently and securely.
interplanetary-routing (TODO)
A dynamic routing system designed to handle communication across planets, moons, and spacecraft. This system uses intelligent algorithms to determine the most efficient paths for data transmission, accounting for signal delays, network disruptions, and planetary movement.