484 research outputs found
Fast performance estimation of block codes
Importance sampling is used in this paper to address the classical yet important problem of performance estimation of block codes. Simulation distributions that comprise discreteand continuous-mixture probability densities are motivated and used for this application. These mixtures are employed in concert with the so-called g-method, which is a conditional importance sampling technique that more effectively exploits knowledge of underlying input distributions. For performance estimation, the emphasis is on bit by bit maximum a-posteriori probability decoding, but message passing algorithms for certain codes have also been investigated. Considered here are single parity check codes, multidimensional product codes, and briefly, low-density parity-check codes. Several error rate results are presented for these various codes, together with performances of the simulation techniques
Modulation of Thermal Conductivity in Kinked Silicon Nanowires: Phonon Interchanging and Pinching Effects
We perform molecular dynamics simulations to investigate the reduction of the
thermal conductivity by kinks in silicon nanowires. The reduction percentage
can be as high as 70% at room temperature. The temperature dependence of the
reduction is also calculated. By calculating phonon polarization vectors, two
mechanisms are found to be responsible for the reduced thermal conductivity:
(1) the interchanging effect between the longitudinal and transverse phonon
modes and (2) the pinching effect, i.e a new type of localization, for the
twisting and transverse phonon modes in the kinked silicon nanowires. Our work
demonstrates that the phonon interchanging and pinching effects, induced by
kinking, are brand new and effective ways in modulating heat transfer in
nanowires, which enables the kinked silicon nanowires to be a promising
candidate for thermoelectric materials.Comment: Nano. Lett. accepted (2013
Thermal rectification and negative differential thermal resistance in lattices with mass gradient
We study thermal properties of one dimensional(1D) harmonic and anharmonic
lattices with mass gradient. It is found that the temperature gradient can be
built up in the 1D harmonic lattice with mass gradient due to the existence of
gradons. The heat flow is asymmetric in the anharmonic lattices with mass
gradient. Moreover, in a certain temperature region the {\it negative
differential thermal resistance} is observed. Possible applications in
constructing thermal rectifier and thermal transistor by using the graded
material are discussed.Comment: 4 pages 5 eps figs. Accepted for pub. in Phys. Rev. B Rap. Com
MR-GNN: Multi-Resolution and Dual Graph Neural Network for Predicting Structured Entity Interactions
Predicting interactions between structured entities lies at the core of
numerous tasks such as drug regimen and new material design. In recent years,
graph neural networks have become attractive. They represent structured
entities as graphs and then extract features from each individual graph using
graph convolution operations. However, these methods have some limitations: i)
their networks only extract features from a fix-sized subgraph structure (i.e.,
a fix-sized receptive field) of each node, and ignore features in substructures
of different sizes, and ii) features are extracted by considering each entity
independently, which may not effectively reflect the interaction between two
entities. To resolve these problems, we present MR-GNN, an end-to-end graph
neural network with the following features: i) it uses a multi-resolution based
architecture to extract node features from different neighborhoods of each
node, and, ii) it uses dual graph-state long short-term memory networks
(L-STMs) to summarize local features of each graph and extracts the interaction
features between pairwise graphs. Experiments conducted on real-world datasets
show that MR-GNN improves the prediction of state-of-the-art methods.Comment: Accepted by IJCAI 201
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