Quantum Internet Protocol

Experimental

The World's First Quantum Internet

Enable distributed quantum computing across the globe with quantum teleportation, entanglement distribution, and topologically protected routing. Connect to 8 global quantum nodes for unprecedented computational power.

Quantum teleportation with Bell measurements

Global entanglement distribution network

Topologically protected quantum routing

Space-based quantum links (coming soon)

Nodes

95%

Fidelity

Links

∞

Distance

Global Quantum Network

MIT

Boston, USA

Processing

Memory

CERN

Geneva, Switzerland

Processing

Entanglement

Oxford

Oxford, UK

Processing

Memory

Tokyo

Tokyo, Japan

Memory

Repeater

Sydney

Sydney, Australia

Processing

Teleportation

Waterloo

Waterloo, Canada

Entanglement

Repeater

Singapore

Processing

Teleportation

Zurich

Zurich, Switzerland

Memory

Processing

Core Capabilities

Quantum Teleportation

Instantly transfer quantum states between nodes using entanglement and classical communication.

ProtocolBennett-Brassard

Bell StatesΦ+, Φ-, Ψ+, Ψ-

Fidelity70-99%

Entanglement Distribution

Generate and distribute Bell pairs across the network for secure communication and computation.

Generation Rate1000 pairs/s

Coherence Time10-100ms

Max DistanceGlobal

Quantum Routing

Topologically protected routing ensures reliable quantum communication even with node failures.

AlgorithmQ-Dijkstra

Redundancy3x paths

Latency<100ms

Implementation Guide

Node Setup & Teleportation

Create quantum nodes and perform basic teleportation

import { QuantumInternetNode, quantumInternet } from '@q-intercept/sdk';

// Create a quantum node
const myNode = new QuantumInternetNode(
  'my-quantum-node',
  { latitude: 37.7749, longitude: -122.4194 }, // San Francisco
  [
    { type: 'processing', fidelity: 0.98, maxQubits: 100, coherenceTime: 10000 },
    { type: 'memory', fidelity: 0.95, maxQubits: 50, coherenceTime: 50000 }
  ]
);

// Register node with global network
quantumInternet.registerNode(myNode);

// Teleport quantum state to MIT node
const quantumState = {
  numQubits: 1,
  amplitudes: [
    { real: 0.707, imag: 0 },
    { real: 0.707, imag: 0 }
  ]
};

const mitNode = quantumInternet.getNode('qnode-mit');
const result = await myNode.teleport(quantumState, mitNode);

console.log(`Teleportation success: ${result.success}`);
console.log(`Fidelity: ${(result.fidelity * 100).toFixed(1)}%`);
console.log(`Duration: ${result.duration}ms`);

Revolutionary Applications

Distributed Quantum Computing

Execute quantum algorithms across multiple nodes for problems too large for a single quantum computer.

Example: Factor 2048-bit RSA keys using distributed Shor's algorithm across MIT, CERN, and Oxford nodes.

Quantum Secure Communication

Enable perfectly secure communication using quantum key distribution and teleportation protocols.

Example: Establish quantum-safe communication channels for financial transactions between global banks.

Quantum Cloud Services

Offer quantum computing as a service with automatic routing to the best available quantum resources.

Example: Run quantum machine learning workloads on the nearest available high-fidelity quantum processor.

Quantum Sensor Networks

Create ultra-sensitive distributed quantum sensors for gravitational wave detection and other applications.

Example: Synchronize quantum clocks globally for unprecedented timing precision in GPS systems.

Network Performance

Teleportation Metrics

Success Rate98.5%

Average Fidelity94.2%

Throughput1000 qubits/s

Network Statistics

Active Nodes8

Quantum Links16

Active Entanglements124

Total Distance40,075 km

Network Uptime99.95%

Future Expansion

Satellite quantum nodes for global coverage
100+ nodes by 2025
Quantum repeaters for unlimited distance
Error correction for 99.99% fidelity