1,009 research outputs found
Hamiltonian Assignment for Open Quantum Systems
We investigate the problem of determining the Hamiltonian of a locally
interacting open-quantum system. To do so, we construct model estimators based
on inverting a set of stationary, or dynamical, Heisenberg-Langevin equations
of motion which rely on a polynomial number of measurements and parameters. We
validate our Hamiltonian assignment methods by numerically simulating
one-dimensional XX-interacting spin chains coupled to thermal reservoirs. We
study Hamiltonian learning in the presence of systematic noise and find that,
in certain time dependent cases, the Hamiltonian estimator accuracy increases
when relaxing the environment's physicality constraints.Comment: 5 pages, 3 figures, updated Fig 1 and reference
Guide of principles in main dog and cat skin’s afections topical aplications
The report is an attempt to remember of the updated general principles in the main dermatologic affects topical applications’ in in dog and cat. Initially are presented: general principles about drug topic formulation’s application, with the describing of skin’s anatomical bases and functions, active substance’s physic-chemicalproprieties, factors that affects transdermal passage, methods of transdermal amplification. Also are presented: characteristics of dog and cat’s skin, skin’s specific vascularisation, ecology and histochemy. In the last chapter are presented the main known dermatologic entities in dog and cat
A Language and Hardware Independent Approach to Quantum-Classical Computing
Heterogeneous high-performance computing (HPC) systems offer novel
architectures which accelerate specific workloads through judicious use of
specialized coprocessors. A promising architectural approach for future
scientific computations is provided by heterogeneous HPC systems integrating
quantum processing units (QPUs). To this end, we present XACC (eXtreme-scale
ACCelerator) --- a programming model and software framework that enables
quantum acceleration within standard or HPC software workflows. XACC follows a
coprocessor machine model that is independent of the underlying quantum
computing hardware, thereby enabling quantum programs to be defined and
executed on a variety of QPUs types through a unified application programming
interface. Moreover, XACC defines a polymorphic low-level intermediate
representation, and an extensible compiler frontend that enables language
independent quantum programming, thus promoting integration and
interoperability across the quantum programming landscape. In this work we
define the software architecture enabling our hardware and language independent
approach, and demonstrate its usefulness across a range of quantum computing
models through illustrative examples involving the compilation and execution of
gate and annealing-based quantum programs
Parity Mixed Doublets in A = 36 Nuclei
The -circular polarizations () and asymmetries
() of the parity forbidden M1 + E2 -decays: MeV) and MeV)
MeV) are investigated theoretically. We use the recently proposed
Warburton-Becker-Brown shell-model interaction. For the weak forces we discuss
comparatively different weak interaction models based on different assumptions
for evaluating the weak meson-hadron coupling constants. The results determine
a range of values from which we find the most probable values:
= for and = for .Comment: RevTeX, 17 pages; to appear in Phys. Rev.
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