G1305 Investigation into Interface Treatment in Fluid-Structure Coupling Method with Level Set Function(1)

When the level set algorithm is used to segment an image, the level set function must be initialized periodically to ensure that it remains a signed distance function (SDF). To avoid this defect, an improved regularized level set method-based image segmentation approach is presented. First, a new potential function is defined and introduced to reconstruct a new distance regularization term to solve this issue of periodically initializing the level set function. Second, by combining the distance regularization term with the internal and external energy terms, a new energy functional is developed. Then, the process of the new energy functional evolution is derived by using the calculus of variations and the steepest descent approach, and a partial differential equation is designed. Finally, an improved regularized level set-based image segmentation (IRLS-IS) method is proposed. Numerical experimental results demonstrate that the IRLS-IS method is not only effective and robust to segment noise and intensity-inhomogeneous images but can also analyze complex medical images well.

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A Method for Tracking a Solid Body in a Fluid Field in Immersed Boundary Methods

Volume 1: Flow Manipulation and Active Control; Bio-Inspired Fluid Mechanics; Boundary Layer and High-Speed Flows; Fluids Engineering Education; Transport Phenomena in Energy Conversion and Mixing; Turbulent Flows; Vortex Dynamics; DNS/LES and Hybrid RANS/LES Methods; Fluid Structure Interaction; Fluid Dynamics of Wind Energy; Bubble, Droplet, and Aerosol Dynamics ◽

10.1115/fedsm2018-83012 ◽

2018 ◽

Author(s):

Guangfa Yao

Keyword(s):

Level Set ◽

Solid Body ◽

Volume Fraction ◽

Transformation Matrix ◽

The Body ◽

New Method ◽

Immersed Boundary ◽

Body Interaction ◽

Level Set Function ◽

Set Function

Immersed boundary method has got increasing attention in modeling fluid-solid body interaction using computational fluid dynamics due to its robustness and simplicity. It usually simulates fluid-solid body interaction by adding a body force in the momentum equation. This eliminates the body conforming mesh generation that frequently requires a very labor-intensive and challenging task. But accurately tracking an arbitrary solid body is required to simulate most real world problems. In this paper, a few methods that are used to track a rigid solid body in a fluid domain are briefly reviewed. A new method is presented to track an arbitrary rigid solid body by solving a transformation matrix and identifying it using a level set function. Knowing level set function, the solid volume fraction can be derived if needed. A three-dimensional example is used to study a few methods used to represent and solve the transformation matrix, and demonstrate the presented new method.

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Cardiac Image Segmentation Using Generalized Polynomial Chaos Expansion and Level Set Function

Level Set Method in Medical Imaging Segmentation ◽

10.1201/b22435-9 ◽

2019 ◽

pp. 261-288

Author(s):

Yuncheng Du ◽

Dongping Du

Keyword(s):

Image Segmentation ◽

Level Set ◽

Polynomial Chaos ◽

Chaos Expansion ◽

Generalized Polynomial Chaos ◽

Cardiac Image ◽

Level Set Function ◽

Generalized Polynomial ◽

Set Function ◽

Cardiac Image Segmentation

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Low-Dimensional Components of Flows With Large Free/Moving-Surface Motion

Journal of Offshore Mechanics and Arctic Engineering ◽

10.1115/1.4041016 ◽

2018 ◽

Vol 141 (2) ◽

Author(s):

Yi Zhang ◽

Solomon C. Yim

Keyword(s):

Flow Field ◽

Level Set ◽

Wave Impact ◽

Moving Surface ◽

Surface Motion ◽

Level Set Function ◽

Highly Nonlinear ◽

Flow Systems ◽

Low Dimensional ◽

Set Function

Flow systems with highly nonlinear free/moving surface motion are common in engineering applications, such as wave impact and fluid-structure interaction (FSI) problems. In order to reveal the dynamics of such flows, as well as provide a reduced-order modeling (ROM) for large-scale applications, we propose a proper orthogonal decomposition (POD) technique that couples the velocity flow field and the level-set function field, as well as a proper normalization for the snapshots data so that the low-dimensional components of the flow can be retrieved with a priori knowledge of equal distribution of the total variance between velocity and level-set function data. Through numerical examples of a sloshing problem and a water entry problem, we show that the low-dimensional components obtained provide an efficient and accurate approximation of the flow field. Moreover, we show that the velocity contour and orbits projected on the space of the reduced basis greatly facilitate understanding of the intrinsic dynamics of the flow systems.

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