| related words |
| achieve |
| target |
| advantage |
| implemented |
| national |
| reduce |
| choosing |
| efficient |
| sciences |
| depending |
| optimized |
| implement |
| difficult |
| unchanged |
| task |
| helpful |
| performing |
| combining |
| read |
| technology |
|
| related documents |
| The Precise Formula in a Sine Function Form of the norm of the Amplitude
and the Necessary and Sufficient Phase Condition for Any Quantum Algorithm
with Arbitrary Phase Rotations [0107010v3] |
| The Quantum Fourier Transform and Extensions of the Abelian Hidden
Subgroup Problem [0212002v1] |
| Remarks on Universal Quantum Computer [9908074v5] |
| Optical qubit generation by state truncation using an experimentally
feasible scheme [0204059v1] |
| What is Quantum Computation? [9909082v1] |
| Mimicking Time Evolution within a Quantum Ground State: Ground-State
Quantum Computation, Cloning, and Teleportation [0312083v1] |
| Limits on Efficient Computation in the Physical World [0412143v2] |
| Optimal Experiment Design for Quantum State and Process Tomography and
Hamiltonian Parameter Estimation [0411093v1] |
| Accuracy threshold for postselected quantum computation [0703264v2] |
| Controlling bi-partite entanglement in multi-qubit systems [0311069v1] |
| NMR Quantum Computation: a Critical Evaluation [0002085v1] |
| Distinguishability and Accessible Information in Quantum Theory [9601020v1] |
| Spin-1/2 particles moving on a 2D lattice with nearest-neighbor
interactions can realize an autonomous quantum computer [0506270v2] |
| Quantum cellular automata quantum computing with endohedral fullerenes [0210202v1] |
| Anyons from non-solvable finite groups are sufficient for universal
quantum computation [0206128v2] |
| Quantum optical implementation of quantum information processing [0405030v1] |
| Quantum phase estimation algorithms with delays: effects of dynamical
phases [0305038v2] |
| Analysis of Quantum Functions [9909012v4] |
| Adiabatic Quantum State Generation and Statistical Zero Knowledge [0301023v2] |
| Fault-tolerant quantum repeaters with minimal physical resources, and
implementations based on single photon emitters [0502112v1] |
|
| related topics |
| {cos, sin, state} |
| {qubit, qubits, gate} |
| {state, phys, rev} |
| {state, algorithm, problem} |
| {algorithm, log, probability} |
| {spin, pulse, spins} |
| {information, entropy, channel} |
| {vol, operators, histories} |
| {trap, ion, state} |
| {state, states, entangled} |
| {error, code, errors} |
| {let, theorem, proof} |
| {photon, photons, single} |
| {alice, bob, state} |
| {measurement, state, measurements} |
| {cavity, atom, atoms} |
| {group, space, representation} |
| {energy, gaussian, time} |
| {states, state, optimal} |
| {theory, mechanics, state} |
|