161 research outputs found
Study on Negative Poisson Ratio and Energy Absorption Characteristics of Embedded Arrow Honeycomb Structure
Impact collision exists widely in people's daily life and threatens people's life safety. Negative Poisson's ratio structure has good mechanical properties. Therefore, it is of great significance to design and study the energy absorption structure with negative Poisson's ratio effect. Based on the traditional symmetrical concave honeycomb structure (SCHS) with negative Poisson's ratio, two modified negative Poisson's ratio honeycomb structures are proposed by adding embedded straight rib arrow structure and embedded curved rib arrow structure, which are respectively called embedded straight rib arrow honeycomb structure (SRAH) and embedded curved rib arrow honeycomb structure (CRAH). Through finite element simulation experiment, the negative Poisson's ratio characteristics of two cellular cells were studied and the influence of structural parameters of the cells on the Poisson's ratio was discussed. ANSYS/LS-DYNA was used to analyze the energy absorption of the proposed three cellular structures at different impact velocities. Numerical simulation results show that the SRHS and CRAH have greater stress platform value, specific energy absorption and impact force efficiency than SCHS, indicating that the SRAH and CRAH exhibited better energy absorption efficiency and impact resistance performance
Numerical Simulation of the Ion Transport Behavior in Concrete under Coupled Axial Loading and Sulfate Attack
During a sulfate attack on concrete, ions, which are transported to the interior of concrete through pores, react with the concrete components. The transport characteristics are affected by various factors. A chemical-mechanical coupling method for accurately evaluating the transport behavior of sulfate ions in concrete under stress conditions was proposed in this study to investigate the transport characteristics of these ions. The diffusion-reaction equations of sulfate ions were obtained based on the diffusion-reaction approach in combination with the mechanism of volume expansion under a sulfate attack and the influence of load on the concrete voidage. The constitutive response and crack density of the matrix were calculated according to the volumetric strain caused by external load and ettringite growth. Then, the diffusion coefficient of the equation was dynamically corrected. T\u27his phenomenon was a strongly coupled moving boundary problem, and the equations were solved using numerical method. A case study was conducted to analyze the distribution law of ionic concentration and volumetric strain obtained using the proposed method. Results demonstrate that the crack damage due to volumetric strain plays a major role in the diffusion of sulfate ions. The load has minimal effect on the transport behavior under a low stress level, and the water-cement ratio is negatively correlated with ion transport capacity. The proposed method serves as a reference for evaluating the durability of an underground structure in a sulfate formation
Online unicasting and multicasting in software-defined networks
Software-Defined Networking (SDN) has emerged as the paradigm of the next-generation networking through separating the control plane from the data plane. In a software-defined network, the forwarding table at each switch node usually is implemented by expensive and power-hungry Ternary Content Addressable Memory (TCAM) that only has limited numbers of entries. In addition, the bandwidth capacity at each link is limited as well. Provisioning quality services to users by admitting their requests subject to such critical network resource constraints is a fundamental problem, and very little attention has been paid. In this paper, we study online unicasting and multicasting in SDNs with an objective of maximizing the network throughput under network resource constraints, for which we first propose a novel cost model to accurately capture the usages of network resources at switch nodes and links. We then devise two online algorithms with competitive ratios O(log n) and O(Kϵlog n) for online unicasting and multicasting, respectively, where n is the network size, K is the maximum number of destinations in any multicast request, and ϵ is a constant with 0 < ϵ ≤ 1. We finally evaluate the proposed algorithms empirically through simulations. The simulation results demonstrate that the proposed algorithms are very promising
NARRATE: A Normal Assisted Free-View Portrait Stylizer
In this work, we propose NARRATE, a novel pipeline that enables
simultaneously editing portrait lighting and perspective in a photorealistic
manner. As a hybrid neural-physical face model, NARRATE leverages complementary
benefits of geometry-aware generative approaches and normal-assisted physical
face models. In a nutshell, NARRATE first inverts the input portrait to a
coarse geometry and employs neural rendering to generate images resembling the
input, as well as producing convincing pose changes. However, inversion step
introduces mismatch, bringing low-quality images with less facial details. As
such, we further estimate portrait normal to enhance the coarse geometry,
creating a high-fidelity physical face model. In particular, we fuse the neural
and physical renderings to compensate for the imperfect inversion, resulting in
both realistic and view-consistent novel perspective images. In relighting
stage, previous works focus on single view portrait relighting but ignoring
consistency between different perspectives as well, leading unstable and
inconsistent lighting effects for view changes. We extend Total Relighting to
fix this problem by unifying its multi-view input normal maps with the physical
face model. NARRATE conducts relighting with consistent normal maps, imposing
cross-view constraints and exhibiting stable and coherent illumination effects.
We experimentally demonstrate that NARRATE achieves more photorealistic,
reliable results over prior works. We further bridge NARRATE with animation and
style transfer tools, supporting pose change, light change, facial animation,
and style transfer, either separately or in combination, all at a photographic
quality. We showcase vivid free-view facial animations as well as 3D-aware
relightable stylization, which help facilitate various AR/VR applications like
virtual cinematography, 3D video conferencing, and post-production.Comment: 14 pages,13 figures https://youtu.be/mP4FV3evmy
HumanGen: Generating Human Radiance Fields with Explicit Priors
Recent years have witnessed the tremendous progress of 3D GANs for generating
view-consistent radiance fields with photo-realism. Yet, high-quality
generation of human radiance fields remains challenging, partially due to the
limited human-related priors adopted in existing methods. We present HumanGen,
a novel 3D human generation scheme with detailed geometry and
realistic free-view rendering. It explicitly marries the
3D human generation with various priors from the 2D generator and 3D
reconstructor of humans through the design of "anchor image". We introduce a
hybrid feature representation using the anchor image to bridge the latent space
of HumanGen with the existing 2D generator. We then adopt a pronged design to
disentangle the generation of geometry and appearance. With the aid of the
anchor image, we adapt a 3D reconstructor for fine-grained details synthesis
and propose a two-stage blending scheme to boost appearance generation.
Extensive experiments demonstrate our effectiveness for state-of-the-art 3D
human generation regarding geometry details, texture quality, and free-view
performance. Notably, HumanGen can also incorporate various off-the-shelf 2D
latent editing methods, seamlessly lifting them into 3D
Minimizing the Deployment Cost of UAVs for Delay-Sensitive Data Collection in IoT Networks
In this paper, we study the deployment of Unmanned Aerial Vehicles (UAVs) to collect data from IoT devices, by finding a data collection tour for each UAV. To ensure the \u27freshness\u27 of the collected data, the total time spent in the tour of each UAV that consists of the UAV flying time and data collection time must be no greater than a given delay B, e.g., 20 minutes. In this paper, we consider a problem of deploying the minimum number of UAVs and finding their data collection tours, subject to the constraint that the total time spent in each tour of any UAV is no greater than B. Specifically, we study two variants of the problem: one is that a UAV needs to fly to the location of each IoT device to collect its data; the other is that a UAV is able to collect the data of an IoT device if the Euclidean distance between them is no greater than the wireless transmission range of the IoT device. For the first variant of the problem, we propose a novel 4-approximation algorithm, which improves the best approximation ratio 4 4/7 for it so far. For the second variant, we devise the very first constant factor approximation algorithm. We also evaluate the performance of the proposed algorithms via extensive experiment simulations. Experimental results show that the numbers of UAVs deployed by the proposed algorithms are from 11% to 19% less than those by existing algorithms on average
Relightable Neural Human Assets from Multi-view Gradient Illuminations
Human modeling and relighting are two fundamental problems in computer vision
and graphics, where high-quality datasets can largely facilitate related
research. However, most existing human datasets only provide multi-view human
images captured under the same illumination. Although valuable for modeling
tasks, they are not readily used in relighting problems. To promote research in
both fields, in this paper, we present UltraStage, a new 3D human dataset that
contains more than 2,000 high-quality human assets captured under both
multi-view and multi-illumination settings. Specifically, for each example, we
provide 32 surrounding views illuminated with one white light and two gradient
illuminations. In addition to regular multi-view images, gradient illuminations
help recover detailed surface normal and spatially-varying material maps,
enabling various relighting applications. Inspired by recent advances in neural
representation, we further interpret each example into a neural human asset
which allows novel view synthesis under arbitrary lighting conditions. We show
our neural human assets can achieve extremely high capture performance and are
capable of representing fine details such as facial wrinkles and cloth folds.
We also validate UltraStage in single image relighting tasks, training neural
networks with virtual relighted data from neural assets and demonstrating
realistic rendering improvements over prior arts. UltraStage will be publicly
available to the community to stimulate significant future developments in
various human modeling and rendering tasks. The dataset is available at
https://miaoing.github.io/RNHA.Comment: Project page: https://miaoing.github.io/RNH
Integration of Distinct Analysis Strategies Improves Tissue-Trait Association Identification
Integrating genome-wide association studies (GWAS) with transcriptomic data, human complex traits and diseases have been linked to relevant tissues and cell types using different methods. However, different results from these methods generated confusion while no gold standard is currently accepted, making it difficult to evaluate the discoveries. Here, applying three methods on the same data source, we estimated the sensitivity and specificity of these methods in the absence of a gold standard. We established a more specific tissue-trait association atlas by combining the information captured by different methods. Our triangulation strategy improves the performance of existing methods in establishing tissue-trait associations. The results provide better etiological and functional insights for the tissues underlying different human complex traits and diseases
CoT-UNet++: A medical image segmentation method based on contextual transformer and dense connection
Accurate depiction of individual teeth from CBCT images is a critical step in the diagnosis of oral diseases, and the traditional methods are very tedious and laborious, so automatic segmentation of individual teeth in CBCT images is important to assist physicians in diagnosis and treatment. TransUNet has achieved success in medical image segmentation tasks, which combines the advantages of Transformer and CNN. However, the skip connection taken by TransUNet leads to unnecessary restrictive fusion and also ignores the rich context between adjacent keys. To solve these problems, this paper proposes a context-transformed TransUNet++ (CoT-UNet++) architecture, which consists of a hybrid encoder, a dense connection, and a decoder. To be specific, a hybrid encoder is first used to obtain the contextual information between adjacent keys by CoTNet and the global context encoded by Transformer. Then the decoder upsamples the encoded features by cascading upsamplers to recover the original resolution. Finally, the multi-scale fusion between the encoded and decoded features at different levels is performed by dense concatenation to obtain more accurate location information. In addition, we employ a weighted loss function consisting of focal, dice, and cross-entropy to reduce the training error and achieve pixel-level optimization. Experimental results demonstrate that the proposed CoT-UNet++ method outperforms the baseline models and can obtain better performance in tooth segmentation
Total genetic contribution assessment across the human genome
Quantifying the overall magnitude of every single locus' genetic effect on the widely measured human phenome is of great challenge. We introduce a unified modelling technique that can consistently provide a total genetic contribution assessment (TGCA) of a gene or genetic variant without thresholding genetic association signals. Genome-wide TGCA in five UK Biobank phenotype domains highlights loci such as the HLA locus for medical conditions, the bone mineral density locus WNT16 for physical measures, and the skin tanning locus MC1R and smoking behaviour locus CHRNA3 for lifestyle. Tissue-specificity investigation reveals several tissues associated with total genetic contributions, including the brain tissues for mental health. Such associations are driven by tissue-specific gene expressions, which share genetic basis with the total genetic contributions. TGCA can provide a genome-wide atlas for the overall genetic contributions in each particular domain of human complex traits. Quantifying the effects of individual loci on the human phenome is a challenging task. Here, the authors introduce a modelling technique, TGCA, that assesses total genetic contribution per locus and apply this to UK Biobank phenotype domains, revealing top loci and links to tissue-specific gene expression
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