43 research outputs found
Quasiparticle band alignment and stacking-independent exciton in MAZ (M = Mo, W, Ti; A= Si, Ge; Z = N, P, As)
Motivated by the recently synthesized two-dimensional semiconducting
MoSiN, we systematically investigate the quasiparticle band alignment
and exciton in monolayer MAZ (M = Mo, W, Ti; A= Si, Ge; Z = N, P, As)
using ab initio GW and Bethe-Salpeter equation calculations. Compared with the
results from density functional theory (DFT), our GW calculations reveal
substantially more significant band gaps and different absolute quasiparticle
energy but predict the same types of band alignments
An Efficient Top-k Query Scheme Based on Multilayer Grouping
The top-k query is to find the k data that has the highest scores from a candidate dataset. Sorting is a common method to find out top-k results. However, most of existing methods are not efficient enough. To remove this issue, we propose an efficient top-k query scheme based on multilayer grouping. First, we find the reference item by computing the average score of the candidate dataset. Second, we group the candidate dataset into three datasets: winner set, middle set and loser set based on the reference item. Third, we further group the winner set to the second-layer three datasets according to k value. And so on, until the data number of winner set is close to k value. Meanwhile, if k value is larger than the data number of winner set, we directly return the winner set to the user as a part of top-k results almost without sorting. In this case, we also return the top results with the highest scores from the middle set almost without sorting. Based on above innovations, we almost minimize the sorting. Experimental results show that our scheme significantly outperforms the current classical method on the performance of memory consumption and top-k query
An Efficient Feature Extraction Scheme for Mobile Anti-Shake in Augmented Reality
In recent years, augmented reality on mobile devices has become popular. Mobile shakes are the most typical type of interference in mobile augmented reality. To negate such interference, anti-shake is an urgent requirement. To enhance anti-shake efficiency, we propose an efficient feature extraction scheme for mobile anti-shake in augmented reality. The scheme directly detects corners to avoid the non-extreme constraint such that the efficiency of feature extraction is improved. Meanwhile, the scheme only updates the added corners during mobile shakes, which improves the accuracy of feature extraction. In the experiments, the memory consumption of existing methods is almost double compared to that in our scheme. Further, the runtime of our scheme is only half of the runtime of the existing methods. The experimental results demonstrate that our scheme performs better than the existing classic methods on mobile anti-shake in terms of memory consumption, efficiency, and accuracy
Reversible Watermarking Using Prediction-Error Expansion and Extreme Learning Machine
Currently, the research for reversible watermarking focuses on the decreasing of image distortion. Aiming at this issue, this paper presents an improvement method to lower the embedding distortion based on the prediction-error expansion (PE) technique. Firstly, the extreme learning machine (ELM) with good generalization ability is utilized to enhance the prediction accuracy for image pixel value during the watermarking embedding, and the lower prediction error results in the reduction of image distortion. Moreover, an optimization operation for strengthening the performance of ELM is taken to further lessen the embedding distortion. With two popular predictors, that is, median edge detector (MED) predictor and gradient-adjusted predictor (GAP), the experimental results for the classical images and Kodak image set indicate that the proposed scheme achieves improvement for the lowering of image distortion compared with the classical PE scheme proposed by Thodi et al. and outperforms the improvement method presented by Coltuc and other existing approaches
A Survey on Generative Diffusion Model
Deep learning shows excellent potential in generation tasks thanks to deep
latent representation. Generative models are classes of models that can
generate observations randomly concerning certain implied parameters. Recently,
the diffusion Model has become a rising class of generative models by its
power-generating ability. Nowadays, great achievements have been reached. More
applications except for computer vision, speech generation, bioinformatics, and
natural language processing are to be explored in this field. However, the
diffusion model has its genuine drawback of a slow generation process, single
data types, low likelihood, and the inability for dimension reduction. They are
leading to many enhanced works. This survey makes a summary of the field of the
diffusion model. We first state the main problem with two landmark works --
DDPM and DSM, and a unified landmark work -- Score SDE. Then, we present
improved techniques for existing problems in the diffusion-based model field,
including speed-up improvement For model speed-up improvement, data structure
diversification, likelihood optimization, and dimension reduction. Regarding
existing models, we also provide a benchmark of FID score, IS, and NLL
according to specific NFE. Moreover, applications with diffusion models are
introduced including computer vision, sequence modeling, audio, and AI for
science. Finally, there is a summarization of this field together with
limitations \& further directions. The summation of existing well-classified
methods is in our
Github:https://github.com/chq1155/A-Survey-on-Generative-Diffusion-Model
DISCO: Distribution-Aware Calibration for Object Detection with Noisy Bounding Boxes
Large-scale well-annotated datasets are of great importance for training an
effective object detector. However, obtaining accurate bounding box annotations
is laborious and demanding. Unfortunately, the resultant noisy bounding boxes
could cause corrupt supervision signals and thus diminish detection
performance. Motivated by the observation that the real ground-truth is usually
situated in the aggregation region of the proposals assigned to a noisy
ground-truth, we propose DIStribution-aware CalibratiOn (DISCO) to model the
spatial distribution of proposals for calibrating supervision signals. In
DISCO, spatial distribution modeling is performed to statistically extract the
potential locations of objects. Based on the modeled distribution, three
distribution-aware techniques, i.e., distribution-aware proposal augmentation
(DA-Aug), distribution-aware box refinement (DA-Ref), and distribution-aware
confidence estimation (DA-Est), are developed to improve classification,
localization, and interpretability, respectively. Extensive experiments on
large-scale noisy image datasets (i.e., Pascal VOC and MS-COCO) demonstrate
that DISCO can achieve state-of-the-art detection performance, especially at
high noise levels.Comment: 12 pages, 9 figure
Disorder-induced excitation continuum in a spin-1/2 cobaltate on a triangular lattice
A spin-1/2 triangular-lattice antiferromagnet is a prototypical frustrated
quantum magnet, which exhibits remarkable quantum many-body effects that arise
from the synergy between geometric spin frustration and quantum fluctuations.
It can host quantum frustrated magnetic topological phenomena like quantum spin
liquid (QSL) states, highlighted by the presence of fractionalized
quasiparticles within a continuum of magnetic excitations. In this work, we use
neutron scattering to study CoZnMoO, which has a triangular lattice of
Jeff = 1/2 Co2+ ions with octahedral coordination. We found a
wave-vector-dependent excitation continuum at low energy that disappears with
increasing temperature. Although these excitations are reminiscent of a spin
excitation continuum in a QSL state, their presence in CoZnMoO
originates from magnetic intersite disorder-induced dynamic spin states with
peculiar excitations. Our results, therefore, give direct experimental evidence
for the presence of a disorder-induced spin excitation continuum
Therapeutic evaluation of a patient with ruptured intracranial aneurysm without subarachnoid hemorrhage by CT imaging: a case report
Abstract Background The majority of ruptured intracranial aneurysms are combined with subarachnoid hemorrhage, but patients with only intracerebral hematoma without any subarachnoid hemorrhage are extremely rare. Case presentation The patient was hospitalized due to sudden dizziness combined with slurred speech. The patient showed considerable decreased physical activity without any nuchal rigidity. Head CT showed hematoma in the left temporal lobe, and the shape of hematoma was extremely irregular. MRI indicated the absence of any vascular malformations. The patient was diagnosed with middle cerebral artery bifurcation aneurysm in the left by head CTA. Intracranial aneurysm clip and removal of hematoma in the left temporal lobe were performed under general anesthesia. The patient did not show any significant neurological dysfunction after the surgery and was followed up for 4 months after discharge with GOS score of 5 points. Conclusions Intracranial hematoma with irregular morphology around the lateral fissure of the brain should be considered critical in order to avoid misdiagnosis and any possibility of missed diagnosis of vascular lesions, so as to ensure an exact therapeutic strategy with good prognosis for the patients