502 research outputs found
Physical layer security jamming: Theoretical limits and practical designs in wireless networks
Physical layer security has been recently recognized as a promising new design paradigm to provide security in wireless networks. In addition to the existing conventional cryptographic methods, physical layer security exploits the dynamics of fading channels to enhance secured wireless links. In this approach, jamming plays a key role by generating noise signals to confuse the potential eavesdroppers, and significantly improves quality and reliability of secure communications between legitimate terminals. This article presents theoretical limits and practical designs of jamming approaches for physical layer security. In particular, the theoretical limits explore the achievable secrecy rates of user cooperation based jamming whilst the centralized, and game theoretic based precoding techniques are reviewed for practical implementations. In addition, the emerging wireless energy harvesting techniques are exploited to harvest the required energy to transmit jamming signals. Future directions of these approaches, and the associated research challenges are also briefly outlined
Teachersâ views of young childrenâs citizenship in Aotearoa: Discourses and power complexities
Childrenâs citizenship in early childhood education and care is the root of democracy, equity, and sustainability. In Aotearoa New Zealand, Te WhÄriki has a strong aspiration for children as competent and active citizens. Early childhood settings are sites where children may have opportunities to act as powerful citizens. Employing Foucaultâs theory of discourse and power, this article analyses interviews from 12 kindergarten teachers in Aotearoa. This article reveals multiple discourses underpinning power dynamics regarding childrenâs citizenship in selected Aotearoa kindergartens and offers insight into childrenâs citizenship as a power-sharing pedagogy
The Dimerization of H<sub>2</sub>NO
H<sub>2</sub>NO is the prototype
of aminoxyls, kinetically persistent
free radicals. The potential dimerization and reaction modes of H<sub>2</sub>NO are examined. The dimer potential energy surface features
a barely metastable OâO bound species and several locally bound
dimeric structures. One of these, a rectangular or rhomboid OâNâO-N
ring, is a characteristic structural feature of more stable aminoxyls
in the solid state. Its electronic structure is related to other four-center
six-electron systems. A general picture of the weak dimer binding
is constructed for these and other H<sub>2</sub>NO dimers from a balance
of four-electron repulsions between NO Ï electrons, and two-electron
attractive interaction between the singly occupied Ï* orbitals
of the diradical. The most stable diradical structure is a surprisingly
strongly hydrogen bonded dimer diradical. The barriers separating
the other isomers from this global minimum are calculated to be small
Renormalized Coupled Cluster Approaches in the Cluster-in-Molecule Framework: Predicting Vertical Electron Binding Energies of the Anionic Water Clusters (H<sub>2</sub>O)<sub><i>n</i></sub><sup>â</sup>
Anionic
water clusters are generally considered to be extremely
challenging to model using fragmentation approaches due to the diffuse
nature of the excess electron distribution. The local correlation
coupled cluster (CC) framework cluster-in-molecule (CIM) approach
combined with the completely renormalized CR-CCÂ(2,3) method [abbreviated
CIM/CR-CCÂ(2,3)] is shown to be a viable alternative for computing
the vertical electron binding energies (VEBE). CIM/CR-CCÂ(2,3) with
the threshold parameter ζ set to 0.001, as a trade-off between
accuracy and computational cost, demonstrates the reliability of predicting
the VEBE, with an average percentage error of âŒ15% compared
to the full ab initio calculation at the same level of theory. The
errors are predominantly from the electron correlation energy. The
CIM/CR-CCÂ(2,3) approach provides the ease of a black-box type calculation
with few threshold parameters to manipulate. The cluster sizes that
can be studied by high-level ab initio methods are significantly increased
in comparison with full CC calculations. Therefore, the VEBE computed
by the CIM/CR-CCÂ(2,3) method can be used as benchmarks for testing
model potential approaches in small-to-intermediate-sized water clusters
Supplemental material 2 for Automatic band selection algorithm for envelope analysis
<p>Supplemental material 2 for Automatic band selection algorithm for envelope analysis by Peng Xu, Ahmad Ghasemloonia and Qiao Sun in Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science</p
Cross-Interface Emulsification for Generating Size-Tunable Droplets
We
report cross-interface emulsification (XiE), a simple method
for the generation of monodisperse droplets of controllable volumes
from picoliter to nanoliter. A device is set up in which a fused-silica
capillary is vibrating across the surface of the continuous phase
(mineral oil) in a reservoir, and the flow of the dispersed phase
(aqueous solution) in the capillary is segmented into monodisperse
droplets at the air/oil interface. We find that the volume of droplets
is mainly dominated by the flow rate and vibrating frequency and not
significantly influenced by other factors, such as the viscosity of
the continuous phase and dispersed phase, the inner diameter of the
capillary (20â100 ÎŒm), or the shape of the tip (tapered
or flat). These features reflect high robustness, flexibility, and
precision of XiE for on-demand volume control of droplets. The droplets
automatically assemble into planar monolayer droplet arrays (PMDA)
in flat-bottomed microwells of 96-well plates, offering excellent
convenience for imaging of droplets. As a representative application,
we carry out digital loop-mediated isothermal amplification using
PMDAs with multivolume droplets for the absolute quantification of
nucleic acids. Our results demonstrate that XiE is simple and controllable
for the production of monodisperse size-tunable droplets, and it offers
opportunities for common laboratories, even without microfabrication
facilities, to perform digital quantification, single cell analysis,
and other biochemical assays with high throughput
Activated regions of different imaging tasks of Subject K1 for the four motor imaging tasks, left hand, right hand, foot and tongue movements.
<p>The values (<i>r<sup>2</sup></i>) in the figures are calculated according to equation (15). The optimal discrimination channels of different tasks were found to be located at C4 for left hand, C3 for right hand, Cz for foot and CP6 for tongue, respectively.</p
The Kappa coefficients of 5Ă10-fold cross validations with BLDA and EBLDA for the experiment dataset.
<p>The feature vectors are obtained by one-versus-one CSP methods. The performance of BLDA and EBLDA classification methods are estimated with different training sizes.</p
Cross-Interface Emulsification for Generating Size-Tunable Droplets
We
report cross-interface emulsification (XiE), a simple method
for the generation of monodisperse droplets of controllable volumes
from picoliter to nanoliter. A device is set up in which a fused-silica
capillary is vibrating across the surface of the continuous phase
(mineral oil) in a reservoir, and the flow of the dispersed phase
(aqueous solution) in the capillary is segmented into monodisperse
droplets at the air/oil interface. We find that the volume of droplets
is mainly dominated by the flow rate and vibrating frequency and not
significantly influenced by other factors, such as the viscosity of
the continuous phase and dispersed phase, the inner diameter of the
capillary (20â100 ÎŒm), or the shape of the tip (tapered
or flat). These features reflect high robustness, flexibility, and
precision of XiE for on-demand volume control of droplets. The droplets
automatically assemble into planar monolayer droplet arrays (PMDA)
in flat-bottomed microwells of 96-well plates, offering excellent
convenience for imaging of droplets. As a representative application,
we carry out digital loop-mediated isothermal amplification using
PMDAs with multivolume droplets for the absolute quantification of
nucleic acids. Our results demonstrate that XiE is simple and controllable
for the production of monodisperse size-tunable droplets, and it offers
opportunities for common laboratories, even without microfabrication
facilities, to perform digital quantification, single cell analysis,
and other biochemical assays with high throughput
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