Your search keyword '"Ban X"' showing total 9 results

1. Turbulent Details Simulation for SPH Fluids via Vorticity Refinement

Author

Liu, S., Wang, X., Ban, X., Xu, Y., Zhou, J., Kosinka, J., Telea, A., Liu, S., Wang, X., Ban, X., Xu, Y., Zhou, J., Kosinka, J., and Telea, A.

Abstract

A major issue in smoothed particle hydrodynamics (SPH) approaches is the numerical dissipation during the projection process, especially under coarse discretizations. High‐frequency details, such as turbulence and vortices, are smoothed out, leading to unrealistic results. To address this issue, we introduce a vorticity refinement (VR) solver for SPH fluids with negligible computational overhead. In this method, the numerical dissipation of the vorticity field is recovered by the difference between the theoretical and the actual vorticity, so as to enhance turbulence details. Instead of solving the Biot‐Savart integrals, a stream function, which is easier and more efficient to solve, is used to relate the vorticity field to the velocity field. We obtain turbulence effects of different intensity levels by changing an adjustable parameter. Since the vorticity field is enhanced according to the curl field, our method can not only amplify existing vortices, but also capture additional turbulence. Our VR solver is straightforward to implement and can be easily integrated into existing SPH methods.

Published

2021

2. Turbulent Details Simulation for SPH Fluids via Vorticity Refinement

Author

Visualisation and Graphics, Dep Natuurkunde, Sub Visualisation and Graphics, Liu, S., Wang, X., Ban, X., Xu, Y., Zhou, J., Kosinka, J., Telea, A., Visualisation and Graphics, Dep Natuurkunde, Sub Visualisation and Graphics, Liu, S., Wang, X., Ban, X., Xu, Y., Zhou, J., Kosinka, J., and Telea, A.

Published

2021

3. Aircraft Observations of Dust and Pollutants over NE China: Insight into the Meteorological Mechanisms of Long-Range Transport

Author

Dickerson, Russell, Dickerson, Russell, Li, Can, Li, Zhanqing, Marufu, Lackson, Stehr, Jeffrey, Chen, H., Wang, P, Xia, X., Ban, X., Gong, F., Yaun, J., Yang, J., Dickerson, Russell, Dickerson, Russell, Li, Can, Li, Zhanqing, Marufu, Lackson, Stehr, Jeffrey, Chen, H., Wang, P, Xia, X., Ban, X., Gong, F., Yaun, J., and Yang, J.

Abstract

Substantial concentrations of trace gases and aerosols are lofted and carried from Asia over the Pacific producing an inter-hemispheric impact on atmospheric chemistry and climate. The meteorological mechanism leading to this large-scale transport of dust and pollutants remains a major uncertainty in quantifying the global effects of emissions from the developing world. Models and downwind measurements have identified isentropic advection associated with wave cyclones (warm conveyor belt circulation) as an important mechanism. We present data from a case study conducted over Shenyang in NE China as part of EAST-AIRE in April 2005 in which upstream convection, rather than WCB lofting appears to dominate. Observations from instrumented aircraft flights, back trajectories, and satellite images of clouds (GOES) and aerosols (MODIS) are analyzed. In this heavily industrialized and populated region, the warm-sector PBL air ahead of a cold front was highly polluted. In the free troposphere, between ~1000 and 4000 m altitude, concentrations of trace gases and aerosols were lower, but well above background; we measured ~70 ppb O3, ~300 ppb CO, ~2 ppb SO2, and ~ 8x10-5 m-1 aerosol scattering. These observations show that dry (non-precipitating) convection can be an important mechanism for converting local air pollution problems into regional or global atmospheric chemistry problems. Climatological data indicate that spring (MAM) precipitation over NE China is low, about 90 mm compared to 290 mm over the NE US. Cloud cover, however, is similar with cumulus clouds reported about 7% of the time over NE China and about 9% of the time over the NE US suggesting that lofting in dry convective events may be common over NE Asia. Evaluation of models’ convective schemes and further observations near the source regions are called for.

Published

2006

4. An implicitly stable mixture model for dynamic multi-fluid simulations

Author

Xu, Y., Wang, X., Wang, J., Song, C., Wang, T., Zhang, Y., Chang, Jian, Zhang, Jian Jun, Kosinka, J., Telea, A., Ban, X., Xu, Y., Wang, X., Wang, J., Song, C., Wang, T., Zhang, Y., Chang, Jian, Zhang, Jian Jun, Kosinka, J., Telea, A., and Ban, X.

Abstract

Particle-based simulations have become increasingly popular in real-time applications due to their efficiency and adaptability, especially for generating highly dynamic fluid effects. However, the swift and stable simulation of interactions among distinct fluids continues to pose challenges for current mixture model techniques. When using a single-mixture flow field to represent all fluid phases, numerical discontinuities in phase fields can result in significant losses of dynamic effects and unstable conservation of mass and momentum. To tackle these issues, we present an advanced implicit mixture model for smoothed particle hydrodynamics. Instead of relying on an explicit mixture field for all dynamic computations and phase transfers between particles, our approach calculates phase momentum sources from the mixture model to derive explicit and continuous velocity phase fields. We then implicitly obtain the mixture field using a phase-mixture momentum-mapping mechanism that ensures conservation of incompressibility, mass, and momentum. In addition, we propose a mixture viscosity model and establish viscous effects between the mixture and individual fluid phases to avoid instability under extreme inertia conditions. Through a series of experiments, we show that, compared to existing mixture models, our method effectively improves dynamic effects while reducing critical instability factors. This makes our approach especially well-suited for long-duration, efficiency-oriented virtual reality scenarios.

5. Implicit smoothed particle hydrodynamics model for simulating incompressible fluid-elastic coupling

Author

Wang, Xiaokun, Wang, T., Wang, J., Xu, Y., Ban, X., Huang, H., Zhu, Z., Chang, J., Zhang, Jian J., Wang, Xiaokun, Wang, T., Wang, J., Xu, Y., Ban, X., Huang, H., Zhu, Z., Chang, J., and Zhang, Jian J.

Abstract

Fluid simulation has been one of the most critical topics in computer graphics for its capacity to produce visually realistic effects. The intricacy of fluid simulation manifests most with interacting dynamic elements. The coupling for such scenarios has always been challenging to manage due to the numerical instability arising from the coupling boundary between different elements. Therefore, we propose an implicit smoothed particle hydrodynamics fluid-elastic coupling approach to reduce the instability issue for fluid-fluid, fluid-elastic, and elastic-elastic coupling circumstances. By deriving the relationship between the universal pressure field with the incompressible attribute of the fluid, we apply the number density scheme to solve the pressure Poisson equation for both fluid and elastic material to avoid the density error for multi-material coupling and conserve the non-penetration condition for elastic objects interacting with fluid particles. Experiments show that our method can effectively handle the multiphase fluids simulation with elastic objects under various physical properties.

6. Anisotropic screen space rendering for particle-based fluid simulation

Author

Xu, Y., Xiong, Y., Yin, D., Ban, X., Wang, X., Chang, Jian, Zhang, Jian J., Xu, Y., Xiong, Y., Yin, D., Ban, X., Wang, X., Chang, Jian, and Zhang, Jian J.

Abstract

This paper proposes a real-time fluid rendering method based on the screen space rendering scheme for particle-based fluid simulation. Our method applies anisotropic transformations to the point sprites to stretch the point sprites along appropriate axes, obtaining smooth fluid surfaces based on the weighted principal components analysis of the particle distribution. Then we combine the processed anisotropic point sprite information with popular screen space filters like curvature flow and narrow-range filters to process the depth information. Experiments show that the proposed method can efficiently resolve the issues of jagged edges and unevenness on the surface that existed in previous methods while preserving sharp high-frequency details.

7. Spatial adaptivity with boundary refinement for smoothed particle hydrodynamics fluid simulation

Author

Xu, Y., Song, C., Wang, Xiaokun, Ban, X., Wang, J., Zhang, Y., Chang, Jian, Xu, Y., Song, C., Wang, Xiaokun, Ban, X., Wang, J., Zhang, Y., and Chang, Jian

Abstract

Fluid simulation is well-known for being visually stunning while computationally expensive. Spatial adaptivity can effectively ease the computational cost by discretizing the simulation space with varying resolutions. Adaptive methods nowadays mainly focus on the mechanism of refining the fluid surfaces to obtain more vivid splashes and wave effects. But such techniques hinder further performance gain under the condition where most of the vast fluid surface is tranquil. Moreover, energetic flow beneath the surface cannot be adequately captured with the interior of the fluid still being simulated under coarse discretization. This article proposes a novel boundary-distance based adaptive method for smoothed particle hydrodynamics fluid simulation. The signed-distance field constructed with respect to the coupling boundary is introduced to determine particle resolution in different spatial positions. The resolution is maximal within a specific distance to the boundary and decreases smoothly as the distance increases until a threshold is reached. The sizes of the particles are then adjusted towards the resolution via splitting and merging. Additionally, a wake flow preservation mechanism is introduced to keep the particle resolution at a high level for a period of time after a particle flows through the boundary object to prevent the loss of flow details. Experiments show that our method can refine fluid–solid coupling details more efficiently and effectively capture dynamic effects beneath the surface.

8. Physics-based fluid simulation in computer graphics: Survey, research trends, and challenges

Author

Wang, Xiaokun, Xu, Y., Liu, S., Ren, B., Kosinka, J., Telea, A. C., Wang, J., Song, C., Chang, Jian, Li, C., Zhang, Jian Jun, Ban, X., Wang, Xiaokun, Xu, Y., Liu, S., Ren, B., Kosinka, J., Telea, A. C., Wang, J., Song, C., Chang, Jian, Li, C., Zhang, Jian Jun, and Ban, X.

Abstract

Physics-based fluid simulation has played an increasingly important role in the computer graphics community. Recent methods in this area have greatly improved the generation of complex visual effects and its computational efficiency. Novel techniques have emerged to deal with complex boundaries, multiphase fluids, gas–liquid interfaces, and fine details. The parallel use of machine learning, image processing, and fluid control technologies has brought many interesting and novel research perspectives. In this survey, we provide an introduction to theoretical concepts underpinning physics-based fluid simulation and their practical implementation, with the aim for it to serve as a guide for both newcomers and seasoned researchers to explore the field of physics-based fluid simulation, with a focus on developments in the last decade. Driven by the distribution of recent publications in the field, we structure our survey to cover physical background; discretization approaches; computational methods that address scalability; fluid interactions with other materials and interfaces; and methods for expressive aspects of surface detail and control. From a practical perspective, we give an overview of existing implementations available for the above methods. (Figure presented.)

9. HandDGCL: Two-hand 3D reconstruction based disturbing graph contrastive learning

Author

Han, B., Yao, C., Wang, X., Chang, Jian, Ban, X., Han, B., Yao, C., Wang, X., Chang, Jian, and Ban, X.

Abstract

Virtual reality (VR) and augmented reality (AR) applications are becoming increasingly prevalent. However, constructing realistic 3D hands, especially when two hands are interacting, from a single RGB image remains a major challenge due to severe mutual occlusion and the enormous diversity of hand poses. In this article, we propose a disturbing graph contrastive learning strategy for two-hand 3D reconstruction. This involves a graph disturbance network designed to generate graph feature pairs to enhance the consistency of the two-hand pose features. A contrastive learning module leverages high-quality generative features for a strong feature expression. We further propose a similarity distinguish method to divide positive and negative features for accelerating the model convergence. Additionally, a multi-term loss is designed to balance the relation among the hand pose, the visual scale and the viewpoint position. Our model has achieved state-of-the-art results in the InterHand2.6M benchmark. Ablation studies show the model's great ability to correct unreasonable hand movements. In subjective assessments, our graph disturbance learning method significantly improves the construction of realistic 3D hands, especially when two hands are interacting.