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Suggestion for Optical Implementation of Hadamard Gate. Amir Feizpour Physics Department Sharif University of Technology. Contents Motivation Implementation Methods Optical Implementations The Main Problem Solution Model Proposed Results. Contents of my talk. Motivation
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Suggestion for Optical Implementation of Hadamard Gate Amir Feizpour Physics Department Sharif University of Technology
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results Contents of my talk • Motivation • Implementation Methods • Optical Implementations • The main Problem • Solution • Model Proposed • Results
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results Why QI & QC? • Quantum Computation • Reduces the needed steps to accomplish a certain job • Quantum Information • Reduces the amount of data needed to transmit a certain amount of Information
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results Quantum Computer • DiVincenzo’s Criteria • A scalable physical system with well characterized qubits. • The ability to initialize the state of the qubits to a simple fiducial state. • A universal set of quantum gates such as generic one-qubit gates and a two-qubit gate. • A qubit-specific measurement capability. • Long relevant decoherence times, much longer than the gate operation time.
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results Implementation Candidates • NMR • Ion trap and neutral atom trap • Schemes based on solid state physics • Quantum dot qubits • Superconducting qubits • Schemes based on quantum optics
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results Why Photons? • Advantages of using photons as qubit • Quantum optics is a well developed field. • Photons decohere slowly. • Photons travel well. • Photons can be experimented with at room temperature.
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results How to use optics? • From the view point of qubit • Single photon, • Coherent states. • From the view point of gates • Linear optics, • Non-linear optics.
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results Optical Schemes • Early optical quantum computer based on non-linearities • Qantum optical Fredkin gate (Milburn 1989) • N- port interferometers and optical circuits • Decomposition of unitary (Zielinger et. al, 1998) • Optical Simulation of Quantum Logic (Cerf et. al, 1998)
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results Optical Schemes (Continued) • KLM theory (Knill et al, 2001) • Linear optics (beam splitter and phase shifter) • Probabilistic gates • Teleported gates • Schemes based on coherent state • Non-linear optics • Linear optics
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results What’s the problem? • Single photon • Photons do not interact directly, making two qubit gates very difficult • Coherent State • Producing superposition states is a hard to accomplish
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results What’s the way out? • Pay more to get what you want • KLM theory: ancila bits and post-measurement • Using a intermediate medium: optical non-linearities • But optical non-linearities are usually weak
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results There’s yet another way • Enhance the effective non-linearity of the medium • Trapping the photons in the medium • Thus: Increasing the interaction time • How to do that? • Micro-resonator • Photonic crystal
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results Qubit • Coherent state with a - phase difference and the same average number of photons • Larger values of make the chosen basis more nearly orthogonal
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results Semi-Hadamard Gate • Consider this example: The fidelity can be used as a proper criteria This transformation is possible using a Kerr media which produces a phase change.
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results Gate: CROW • A coupled resonator optical waveguide made up of micro-rings with large Kerr coefficient
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results Dispersion Relation • Transfer Matrix Method
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results Unitary Evolution • Effective unitary evolution • where
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results Fidelity • Fidelity of obtained output to the desired output for
Contents • Motivation • Implementation Methods • Optical Implementations • The Main Problem • Solution • Model Proposed • Results Size Sensitivity
Acknowledgement At the end, I must thank my advisors Prof. A. R. Bahrampour and Prof. V.Karimipour, and all members of Quantum Information Group and Optics Group at Sharif University of Technology.