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Quantum evolution with classical fields

Christof Wetterich

Abstract

Wave guides for classical electromagnetic fields can realize the quantum evolution of the wave function for a system of qubits. Phase shifts, switches and beam splits allow for the construction of arbitrary quantum gates. They can act at once on a large number of qubits. For this correlation based photonic quantum computer the channels of the wave guides represent basis states of a multi-qubit system rather than individual qubits. The classical probabilistic implementation of a quantum evolution sheds new light on the foundations of quantum mechanics.

Quantum evolution with classical fields

Abstract

Wave guides for classical electromagnetic fields can realize the quantum evolution of the wave function for a system of qubits. Phase shifts, switches and beam splits allow for the construction of arbitrary quantum gates. They can act at once on a large number of qubits. For this correlation based photonic quantum computer the channels of the wave guides represent basis states of a multi-qubit system rather than individual qubits. The classical probabilistic implementation of a quantum evolution sheds new light on the foundations of quantum mechanics.

Paper Structure

This paper contains 10 sections, 35 equations.

Table of Contents

  1. Probabilities and classical wave function
  2. Complex structure and unitary evolution
  3. Qubits
  4. Quantum gates
  5. Phase shift
  6. Switch
  7. Unitary beam split
  8. Quantum computer
  9. Probabilistic quantum computing
  10. Discussion