| related words |
| implemented |
| implement |
| implementing |
| design |
| achieve |
| implementations |
| generate |
| techniques |
| realization |
| chuang |
| controlled |
| target |
| advantage |
| desired |
| lloyd |
| performance |
| operate |
| proposals |
| advantages |
| schemes |
|
| related documents |
| Spectral implementation of some quantum algorithms by one- and
two-dimensional nuclear magnetic resonance [0503101v1] |
| Optimized quantum implementation of elliptic curve arithmetic over
binary fields [0407095v1] |
| Optimal Realizations of Controlled Unitary Gates [0207157v1] |
| Non-local Operations: Purification, storage, compression, tomography,
and probabilistic implementation [0012148v1] |
| Fault-tolerant quantum repeaters with minimal physical resources, and
implementations based on single photon emitters [0502112v1] |
| Quantum Gate Design Metric [0605071v1] |
| Toward scalable quantum computation with cavity QED systems [0004107v1] |
| Implementation of quantum logic operations and creation of entanglement
in a silicon-based quantum computer with constant interaction [0512174v1] |
| Quantum phase gate and controlled entanglement with polar molecules [0608182v2] |
| Method for implementation of universal quantum logic gates in a scalable
Ising spin quantum computer [0212070v1] |
| Spin-1/2 particles moving on a 2D lattice with nearest-neighbor
interactions can realize an autonomous quantum computer [0506270v2] |
| Selective pulse implementation of two-qubit gates for spin-3/2 based
fullerene quantum information processing [0311178v2] |
| Programming physical realizations of quantum computers [0104085v1] |
| Qubitless Quantum Logic [0203059v2] |
| Universal Quantum Computation with the Exchange Interaction [0005116v2] |
| Quantum optical implementation of quantum information processing [0405030v1] |
| On the Problem of Programming Quantum Computers [0008015v2] |
| General implementation of all possible positive-operator-value
measurements of single photon polarization states [0408011v2] |
| One- and two-dimensional quantum walks in arrays of optical traps [0503084v2] |
| Theoretical analysis of the implementation of a quantum phase gate with
neutral atoms on atom chips [0603138v1] |
|
| related topics |
| {qubit, qubits, gate} |
| {state, phys, rev} |
| {spin, pulse, spins} |
| {state, algorithm, problem} |
| {trap, ion, state} |
| {key, protocol, security} |
| {cavity, atom, atoms} |
| {phase, path, phys} |
| {photon, photons, single} |
| {group, space, representation} |
| {algorithm, log, probability} |
| {energy, gaussian, time} |
| {state, states, entangled} |
| {observables, space, algebra} |
| {state, states, coherent} |
| {light, field, probe} |
| {vol, operators, histories} |
| {equation, function, exp} |
| {level, atom, field} |
| {time, decoherence, evolution} |
|