Cluster State
Generating a cluster state begins with phase one, where a high-fidelity photon source is engineered to emit the entanglement-ready particles required for the quantum lattice. This is followed by phases two and three, which utilize gate manipulation to weave the photons into a multi-partite entangled state before specialized detectors perform the measurements necessary for computation.
Quantum Lattice Structure
Initial quantum register with interconnected qubits forming a lattice structure
Quantum Register Evolution
Quantum register evolving from input state through gate operations
Phase 1: High-Fidelity Photon Source
Engineering a photon source to emit entanglement-ready particles required for the quantum lattice.
Cluster State Implementation
This image shows the experimental setup for generating cluster states in quantum computing. The complex arrangement of optical components, lasers, and detection systems demonstrates the sophisticated infrastructure required to create and manipulate the multi-partite entangled states that form the foundation of cluster state quantum computation.