Real-Life Impact
When conventional infrastructure fails, people build their own. Click a node to decrypt the full operational logs.
System Online
Phones themselves become
the network.
A Decentralized Communication System for Internet Blackouts. Instead of relying on telecom infrastructure, devices create their own encrypted mesh network.
The Core Problem
During wars, disasters, or government shutdowns, internet infrastructure often stops working. Cell towers are destroyed, power grids fail, or governments unilaterally shut down ISPs.
Whether it's the Ukraine war, Iran internet shutdowns, Myanmar protests, or massive earthquake zones, the conventional network (Phone → Cell tower → ISP → Internet) disappears. People cannot call for help, coordinate evacuations, or share evidence with the outside world.
System Failure
Multi-Hop Communication
In a regular network, you communicate via a centralized cell tower. In ResilienceNet, messages hop across devices: Phone A → Phone B → Phone C → Phone D.
A
B
1. Message Stored
The user sends a message. It is stored locally waiting for a nearby peer using Opportunistic Networking (DTN).
2. Message Relayed
The device encounters another node briefly. It forwards the message via Bluetooth or Wi-Fi Direct automatically.
3. Gateway Reached
The relayed message eventually reaches a Gateway Node with global internet access and is broadcast to the world.
Crisis Simulator
Select a disaster scenario to observe autonomous network self-healing and vector-rerouting in real time.
Offline
Offline
Offline
Vector Re-routing Sequence Active
Zero-Trust Encryption
The most hostile environments demand the highest grade of security. Privacy by design, end-to-end, utilizing battle-tested algorithms like libsodium and NaCl.
Click to Toggle X25519 Encryption Layer
Network Architecture
Mesh Network Layer
Peer Discovery
When initializing, nodes send high-frequency broadcast chirps to negotiate keys without a centralized certificate authority.
Opportunistic Networking
Store & Forward
Orphaned target? Packets map to the closest geographic node buffer until the destination enters uplink range.
Bridge Protocol
Gateway Node
Any node with an active WAN connection instantly elevates to a tier-1 Gateway, opening a pipeline for all local nodes.
Live Prototype Demo
Interactive Simulation Ready
1. Three devices open app
2. Internet disabled
3. Device A sends message
4. Device B relays message
5. Device C receives message
6. Device C gets internet & forwards to server
Tactical Advantages
Stay Connected in Crises
No central towers? Direct device-to-device tunneling ensures communication never drops.
Decentralized Resilience
Auto-healing Flood Routing and Delay-Tolerant Networking (DTN) algorithms bypass offline nodes in milliseconds.
Military-Grade Encryption
X25519 elliptic curve keys lock payloads before packets leave your hardware.
Community Infrastructure
The software-defined grid gets faster and more redundant with every new user.
Infinite Scalability
ResilienceNet is not limited by physical infrastructure. The network mathematically strengthens as more nodes join. Our vision is an inter-country mesh grid, completely decentralized, powering millions of discrete connections per second.
Hackathon Journey
48 Hours of Code
Friday 6 PM
Phase 1: Inception
Identified critical vulnerability in centralized comms during crises.
Saturday 2 AM
Phase 2: Protocol Design
Engineered Vector Routing algorithm to bypass failing nodes.
Saturday 3 PM
Phase 3: Prototype
First successful multi-hop message transmitted via BLE between 3 devices.
Sunday 4 AM
Phase 4: Optimization
Integrated X25519 Encryption and completed the interactive web dashboard.
Sunday 10 AM
Phase 5: Deployment
Final codebase merged. ResilienceNet goes live.
Tech Deep Dive
Click to decrypt system protocols
How does peer-to-peer mesh work?
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What is device discovery?
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How do Gateways function?
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The Hackers Behind ResilienceNet
Decentralized Engineering Team
ARHAM KHAN
Frontend Developer
Engineered the cutting-edge holographic UI and cinematic user experience, bringing the immersive dark-mode aesthetic to life.
PRANJAL KUMAR
Backend & Android Developer
Forged the robust backend infrastructure and native Android ecosystem, ensuring flawless cross-device communication.
NIHAL KUMAR
P2P Systems Developer
Architected the decentralized peer-to-peer communication framework, enabling devices to instantly construct a resilient mesh network.
GAURAV BANSAL
QA & Reliability Developer
Battle-tested the platform through rigorous product testing, certifying the software against extreme edge cases for mission-critical stability.