Title :
A quantum neural network computes its own relative phase
Author :
Behrman, Elizabeth C. ; Steck, James E.
Author_Institution :
Dept. of Math., Stat., & Phys., Wichita State Univ., Wichita, KS, USA
Abstract :
Complete characterization of the state of a quantum system made up of subsystems requires determination of relative phase, because of interference effects between the subsystems. For a system of qubits used as a quantum computer this is especially vital, because the entanglement, which is the basis for the quantum advantage in computing, depends intricately on phase. We present here a first step towards that determination, in which we use a two-qubit quantum system as a quantum neural network, which is trained to compute and output its own relative phase.
Keywords :
learning (artificial intelligence); neural nets; quantum computing; quantum entanglement; entanglement; interference effects; quantum computer; quantum neural network training; quantum system state characterization; relative phase; subsystems; two-qubit quantum system; Mathematical model; Neural networks; Quantum computing; Quantum entanglement; Testing; Time measurement; Training;
Conference_Titel :
Swarm Intelligence (SIS), 2013 IEEE Symposium on
Conference_Location :
Singapore
DOI :
10.1109/SIS.2013.6615168
