9,609 research outputs found
Minimum Restraint Functions for unbounded dynamics: general and control-polynomial systems
We consider an exit-time minimum problem with a running cost, and
unbounded controls. The occurrence of points where can be regarded as a
transversality loss. Furthermore, since controls range over unbounded sets, the
family of admissible trajectories may lack important compactness properties. In
the first part of the paper we show that the existence of a -minimum
restraint function provides not only global asymptotic controllability (despite
non-transversality) but also a state-dependent upper bound for the value
function (provided ). This extends to unbounded dynamics a former result
which heavily relied on the compactness of the control set.
In the second part of the paper we apply the general result to the case when
the system is polynomial in the control variable. Some elementary, algebraic,
properties of the convex hull of vector-valued polynomials' ranges allow some
simplifications of the main result, in terms of either near-affine-control
systems or reduction to weak subsystems for the original dynamics.Comment: arXiv admin note: text overlap with arXiv:1503.0344
Transport properties of armchair graphene nanoribbon junctions between graphene electrodes
The transmission properties of armchair graphene nanoribbon junctions between
graphene electrodes are investigated by means of first-principles quantum
transport calculations. First the dependence of the transmission function on
the size of the nanoribbon has been studied. Two regimes are highlighted: for
small applied bias transport takes place via tunneling and the length of the
ribbon is the key parameter that determines the junction conductance; at higher
applied bias resonant transport through HOMO and LUMO starts to play a more
determinant role, and the transport properties depend on the details of the
geometry (width and length) of the carbon nanoribbon. In the case of the
thinnest ribbon it has been verified that a tilted geometry of the central
phenyl ring is the most stable configuration. As a consequence of this rotation
the conductance decreases due to the misalignment of the orbitals between
the phenyl ring and the remaining part of the junction. All the computed
transmission functions have shown a negligible dependence on different
saturations and reconstructions of the edges of the graphene leads, suggesting
a general validity of the reported results
The value function of an asymptotic exit-time optimal control problem
We consider a class of exit--time control problems for nonlinear systems with
a nonnegative vanishing Lagrangian. In general, the associated PDE may have
multiple solutions, and known regularity and stability properties do not hold.
In this paper we obtain such properties and a uniqueness result under some
explicit sufficient conditions. We briefly investigate also the infinite
horizon problem
The IMF as a function of supersonic turbulence
Recent studies seem to suggest that the stellar initial mass function (IMF)
in early-type galaxies might be different from a classical Kroupa or Chabrier
IMF, i.e. contain a larger fraction of the total mass in low-mass stars. From a
theoretical point of view, supersonic turbulence has been the subject of
interest in many analytical theories proposing a strong correlation with the
characteristic mass of the core mass function (CMF) in star forming regions,
and as a consequence with the stellar IMF. Performing two suites of smoothed
particles hydrodynamics (SPH) simulations with different mass resolutions, we
aim at testing the effects of variations in the turbulent properties of a
dense, star forming molecular cloud on the shape of the system mass function in
different density regimes. While analytical theories predict a shift of the
peak of the CMF towards lower masses with increasing velocity dispersion of the
cloud, we observe in the low-density regime the opposite trend, with high Mach
numbers giving rise to a top-heavy mass distribution. For the high-density
regime we do not find any trend correlating the Mach number with the
characteristic mass of the resulting IMF, implying that the dynamics of
protostellar accretion discs and fragmentation on small scales is not strongly
affected by turbulence driven at the scale of the cloud. Furthermore, we
suggest that a significant fraction of dense cores are disrupted by turbulence
before stars can be formed in their interior through gravitational collapse.
Although this particular study has limitations in its numerical resolution, we
suggest that our results, along with those from other studies, cast doubt on
the turbulent fragmentation models on the IMF that simply map the CMF to the
IMF.Comment: 12 pages, 7 figures, accepted by MNRA
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