Add to ORKGnovel quantum landscape optimization with respect to bias field control inputs is developed with the goal of achieving optimal transfer fidelity subject to robustness against bias field, spin couplings and other uncertainties. This objective is achieved by minimization of a convex combination of fidelity error and worst-case perturbation of fidelity error under directional perturbation of uncertain parameters. The novelty is that the end-point perturbations of the parameters are points of a random uniform sampling of the sphere centered at the nominal values of the parameters. This reveals that the previously developed perfect state transfer with zero sensitivity solution keeps high fidelity and robustness under large rather than differenti...
Propagation of information encoded in spin degrees of freedom through networks of coupled spins enab...
We explore the use of policy gradient methods in reinforcement learning for quantum control via ener...
The transmission of quantum states through spin chains is an important element in the implementation...
novel quantum landscape optimization with respect to bias field control inputs is developed with the...
Control laws for selective transfer of information encoded in excitations of a quantum network, base...
Selective transfer of information between spin-1/2 particles arranged in a ring is achieved by optim...
Networks of interacting spin-1/2 particles form the basis for a wide range o...
Selective transfer of information between spin-1/2 particles arranged in a ring is achieved by optim...
The design and analysis of controllers to regulate excitation transport in quantum spin rings presen...
Recent achievements in quantum control have resulted in advanced techniques for designing controller...
Spin networks are endowed with an Information Transfer Fidelity (ITF), which defines an absolute upp...
The precise, human control of quantum systems, by its definition, must combine models of the classic...
The design and analysis of controllers to regulate excitation transport in quantum spin rings presen...
Information encoded in networks of stationary, interacting spin-1/2 particles is central for many ap...
Propagation of information encoded in spin degrees of freedom through networks of coupled spins ena...
Propagation of information encoded in spin degrees of freedom through networks of coupled spins enab...
We explore the use of policy gradient methods in reinforcement learning for quantum control via ener...
The transmission of quantum states through spin chains is an important element in the implementation...
novel quantum landscape optimization with respect to bias field control inputs is developed with the...
Control laws for selective transfer of information encoded in excitations of a quantum network, base...
Selective transfer of information between spin-1/2 particles arranged in a ring is achieved by optim...
Networks of interacting spin-1/2 particles form the basis for a wide range o...
Selective transfer of information between spin-1/2 particles arranged in a ring is achieved by optim...
The design and analysis of controllers to regulate excitation transport in quantum spin rings presen...
Recent achievements in quantum control have resulted in advanced techniques for designing controller...
Spin networks are endowed with an Information Transfer Fidelity (ITF), which defines an absolute upp...
The precise, human control of quantum systems, by its definition, must combine models of the classic...
The design and analysis of controllers to regulate excitation transport in quantum spin rings presen...
Information encoded in networks of stationary, interacting spin-1/2 particles is central for many ap...
Propagation of information encoded in spin degrees of freedom through networks of coupled spins ena...
Propagation of information encoded in spin degrees of freedom through networks of coupled spins enab...
We explore the use of policy gradient methods in reinforcement learning for quantum control via ener...
The transmission of quantum states through spin chains is an important element in the implementation...