31,738 research outputs found
"Partial" Fidelities
For pairs, omega, rho, of density operators on a finite dimensional Hilbert
space of dimension d I call k-fidelity the d - k smallest eigenvalues of |
omega^1/2 rho^1/2 |. k-fidelities are jointly concave in omega, rho. This
follows by representing them as infima over linear functions. For k = 0 known
properties of fidelity and transition probability are reproduced. Partial
fidelities characterize equivalence classes which are partially ordered in a
natural way.Comment: LATEX2e, 14 page
H\"older regularity for Maxwell's equations under minimal assumptions on the coefficients
We prove global H\"older regularity for the solutions to the time-harmonic
anisotropic Maxwell's equations, under the assumptions of H\"older continuous
coefficients. The regularity hypotheses on the coefficients are minimal. The
same estimates hold also in the case of bianisotropic material parameters.Comment: 11 page
On multiple frequency power density measurements II. The full Maxwell's equations
We shall give conditions on the illuminations such that the
solutions to Maxwell's equations satisfy certain non-zero qualitative properties inside
the domain , provided that a finite number of frequencies are
chosen in a fixed range. The illuminations are explicitly constructed. This
theory finds applications in several hybrid imaging problems, where unknown
parameters have to be imaged from internal measurements. Some of these examples
are discussed. This paper naturally extends a previous work of the author
[Inverse Problems 29 (2013) 115007], where the Helmholtz equation was studied.Comment: 24 page
Absence of Critical Points of Solutions to the Helmholtz Equation in 3D
The focus of this paper is to show the absence of critical points for the
solutions to the Helmholtz equation in a bounded domain
, given by We prove that for an admissible there exists a finite
set of frequencies in a given interval and an open cover
such that for every and . The
set is explicitly constructed. If the spectrum of the above problem is
simple, which is true for a generic domain , the admissibility
condition on is a generic property.Comment: 14 page
Enforcing local non-zero constraints in PDEs and applications to hybrid imaging problems
We study the boundary control of solutions of the Helmholtz and Maxwell
equations to enforce local non-zero constraints. These constraints may
represent the local absence of nodal or critical points, or that certain
functionals depending on the solutions of the PDE do not vanish locally inside
the domain. Suitable boundary conditions are classically determined by using
complex geometric optics solutions. This work focuses on an alternative
approach to this issue based on the use of multiple frequencies. Simple
boundary conditions and a finite number of frequencies are explicitly
constructed independently of the coefficients of the PDE so that the
corresponding solutions satisfy the required constraints. This theory finds
applications in several hybrid imaging modalities: some examples are discussed.Comment: 24 pages, 2 figure
On Multiple Frequency Power Density Measurements
We shall give a priori conditions on the illuminations such that the
solutions to the Helmholtz equation in \Omega,
on , and their gradients satisfy certain non-zero
and linear independence properties inside the domain \Omega, provided that a
finite number of frequencies k are chosen in a fixed range. These conditions
are independent of the coefficients, in contrast to the illuminations
classically constructed by means of complex geometric optics solutions. This
theory finds applications in several hybrid problems, where unknown parameters
have to be imaged from internal power density measurements. As an example, we
discuss the microwave imaging by ultrasound deformation technique, for which we
prove new reconstruction formulae.Comment: 26 pages, 4 figure
Animating archaeology: local theories and conceptually open-ended methodologies
Animists’ theories of matter must be given equivalence at the level of theory if we are to understand adequately the nature of ontological difference in the past. The current model is of a natural ontological continuum that connects all cultures, grounding our culturally relativist worldviews in a common world. Indigenous peoples’ worlds are thought of as fascinating but ultimately mistaken ways of knowing the world. We demonstrate how ontologically oriented theorists Eduardo Viveiros de Castro, Karen Barad and Tim Ingold in conjuncture with an anti-representationalist methodology can provide the necessary conditions for alternative ontologies to emerge in archaeology. Anthropo-zoomorphic ‘body-pots’ from first-millennium ad northwest Argentina anticipate the possibility that matter was conceptualized as chronically unstable, inherently undifferentiated, and ultimately practice dependent
Self-gravitating Newtonian models of fermions with anisotropy and cutoff energy in their distribution function
Systems of self-gravitating fermions constitute a topic of great interest in
astrophysics, due to the wide field of applications. In this paper, we consider
the gravitational equilibrium of spherically symmetric Newtonian models of
collisionless semidegenerate fermions. We construct numerical solutions by
taking into account the effects of the anisotropy in the distribution function
and considering the prevalence of tangential velocity. In this way, our models
generalize the solutions obtained for isotropic Fermi-Dirac statistics. We also
extend the analysis to equilibrium configurations in the classical regime and
in the fully degenerate limit, recovering, for different levels of anisotropy,
hollow equilibrium configurations obtained in Maxwellian regime. Moreover, in
the limit of full degeneracy, we find a direct expression relating the
anisotropy with the mass of the particles composing the system.Comment: 32 pages, 10 figures, accepted for publication in Physical Review
Quantum walk of a Bose-Einstein condensate in the Brillouin zone
We propose a realistic scheme to implement discrete-time quantum walks in the
Brillouin zone (i.e., in quasimomentum space) with a spinor Bose-Einstein
condensate. Relying on a static optical lattice to suppress tunneling in real
space, the condensate is displaced in quasimomentum space in discrete steps
conditioned upon the internal state of the atoms, while short pulses
periodically couple the internal states. We show that tunable twisted boundary
conditions can be implemented in a fully natural way by exploiting the
periodicity of the Brillouin zone. The proposed setup does not suffer from
off-resonant scattering of photons and could allow a robust implementation of
quantum walks with several tens of steps at least. In addition, onsite
atom-atom interactions can be used to simulate interactions with infinitely
long range in the Brillouin zone.Comment: 9 pages, 4 figures; in the new version, added a discussion about
decoherence in the appendi
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