Your search keyword '"Panozzo, Daniele"' showing total 88 results

1. Cut‐Cell Microstructures for Two‐scale Structural Optimization.

Author

Tozoni, Davi Colli, Huang, Zizhou, Panozzo, Daniele, and Zorin, Denis

Subjects

STRUCTURAL optimization, MICROSTRUCTURE, TILES, TOPOLOGY, GEOMETRY

Abstract

Two‐scale topology optimization, combined with the design of microstructure families with a broad range of effective material parameters, is widely used in many fabrication applications to achieve a target deformation behavior for a variety of objects. The main idea of this approach is to optimize the distribution of material properties in the object partitioned into relatively coarse cells, and then replace each cell with microstructure geometry that mimics these material properties. In this paper, we focus on adapting this approach to complex shapes in situations when preserving the shape's surface is essential. Our approach extends any regular (i.e. defined on a regular lattice grid) microstructure family to complex shapes, by enriching it with tiles adapted to the geometry of the cut‐cell. We propose a fully automated and robust pipeline based on this approach, and we show that the performance of the regular microstructure family is only minimally affected by our extension while allowing its use on 2D and 3D shapes of high complexity. [ABSTRACT FROM AUTHOR]

Published

2024

2. Differentiable solver for time-dependent deformation problems with contact.

Author

ZIZHOU HUANG, COLLI TOZONI, DAVI, GJOKA, ARVI, FERGUSON, ZACHARY, SCHNEIDER, TESEO, PANOZZO, DANIELE, and ZORIN, DENIS

Subjects

ADJOINT differential equations, NONLINEAR equations, FINITE element method

Abstract

We introduce a general differentiable solver for time-dependent deformation problems with contact and friction. Our approach uses a finite element discretization with a high-order time integrator coupled with the recently proposed incremental potential contact method for handling contact and friction forces to solve ODE- and PDE-constrained optimization problems on scenes with complex geometry. It supports static and dynamic problems and differentiation with respect to all physical parameters involved in the physical problem description, which include shape, material parameters, friction parameters, and initial conditions. Our analytically derived adjoint formulation is efficient, with a small overhead (typically less than 10% for nonlinear problems) over the forward simulation, and shares many similarities with the forward problem, allowing the reuse of large parts of existing forward simulator code. We implement our approach on top of the open-source PolyFEM library and demonstrate the applicability of our solver to shape design, initial condition optimization, and material estimation on both simulated results and physical validations. [ABSTRACT FROM AUTHOR]

Published

2024

3. Constrained Delaunay Tetrahedrization: A Robust and Practical Approach.

Author

Diazzi, Lorenzo, Panozzo, Daniele, Vaxman, Amir, and Attene, Marco

Abstract

We present a numerically robust algorithm for computing the constrained Delaunay tetrahedrization (CDT) of a piecewise-linear complex, which has a 100% success rate on the 4408 valid models in the Thingi10k dataset. We build on the underlying theory of the well-known tetgen software, but use a floating-point implementation based on indirect geometric predicates to implicitly represent Steiner points: this new approach dramatically simplifies the implementation, removing the need for ad-hoc tolerances in geometric operations. Our approach leads to a robust and parameter-free implementation, with an empirically manageable number of added Steiner points. Furthermore, our algorithm addresses a major gap in tetgen's theory which may lead to algorithmic failure on valid models, even when assuming perfect precision in the calculations. Our output tetrahedrization conforms with the input geometry without approximations. We can further round our output to floating-point coordinates for downstream applications, which almost always results in valid floating-point meshes unless the input triangulation is very close to being degenerate. [ABSTRACT FROM AUTHOR]

Published

2023

4. Generation of Spatially-Variant Anisotropic Metamaterials in 3D Volumetric Circuits.

Author

Gulib, Asad U. H., Dumas, Jeremie, Valle, Cesar L., Bustamante, Edgar, Panozzo, Daniele, and Rumpf, Raymond C.

Subjects

METAMATERIALS, COMPUTER-aided design software, ELECTROMAGNETIC interference, INDUSTRIAL electronics, THREE-dimensional printing

Abstract

3D printing is revolutionizing manufacturing and is now being considered in the electronics industry. The creation of the first 3D volumetric circuit (3DVC) has created a way to make circuits smaller, lighter, into unconventional form factors and exploit physics like anisotropy more effectively than planar geometries can. While this is exciting, many problems must be solved to make 3DVCs a reality. One of these problems is electromagnetic interference and mutual coupling between components that are expected to be highly problematic in high frequency 3DVCs. Spatially-variant anisotropic metamaterials (SVAMs) could be a solution to overcome this difficulty, but research in this area is not possible without a way to generate SVAMs around multiple components. In this paper, an algorithm is integrated into CAD software that can generate SVAMs for 3D circuits which will enable future studies of SVAMs. [ABSTRACT FROM AUTHOR]

Published

2023

5. In-Timestep Remeshing for Contacting Elastodynamics.

Author

Ferguson, Zachary, Schneider, Teseo, Kaufman, Danny, and Panozzo, Daniele

Subjects

ELASTODYNAMICS, ALGORITHMS, GEOMETRY

Abstract

We propose In-Timestep Remeshing, a fully coupled, adaptive meshing algorithm for contacting elastodynamics where remeshing steps are tightly integrated, implicitly, within the timestep solve. Our algorithm refines and coarsens the domain automatically by measuring physical energy changes within each ongoing timestep solve. This provides consistent, degree-of-freedom-efficient, productive remeshing that, by construction, is physics-aware and so avoids the errors, over-refinements, artifacts, per-example hand-tuning, and instabilities commonly encountered when remeshing with timestepping methods. Our in-timestep computation then ensures that each simulation step's output is both a converged stable solution on the updated mesh and a temporally consistent trajectory with respect to the model and solution of the last timestep. At the same time, the output is guaranteed safe (intersection- and inversion-free) across all operations. We demonstrate applications across a wide range of extreme stress tests with challenging contacts, sharp geometries, extreme compressions, large timesteps, and wide material stiffness ranges - all scenarios well-appreciated to challenge existing remeshing methods. [ABSTRACT FROM AUTHOR]

Published

2023

6. Declarative Specification for Unstructured Mesh Editing Algorithms.

Author

Jiang, Zhongshi, Dai, Jiacheng, Hu, Yixin, Zhou, Yunfan, Dumas, Jeremie, Zhou, Qingnan, Bajwa, Gurkirat Singh, Zorin, Denis, Panozzo, Daniele, and Schneider, Teseo

Subjects

ALGORITHMS, GEOMETRIC modeling, SATISFACTION, EDITING

Abstract

We introduce a novel approach to describe mesh generation, mesh adaptation, and geometric modeling algorithms relying on changing mesh connectivity using a high-level abstraction. The main motivation is to enable easy customization and development of these algorithms via a declarative specification consisting of a set of per-element invariants, operation scheduling, and attribute transfer for each editing operation. We demonstrate that widely used algorithms editing surfaces and volumes can be compactly expressed with our abstraction, and their implementation within our framework is simple, automatically parallelizable on shared-memory architectures, and with guaranteed satisfaction of the prescribed invariants. These algorithms are readable and easy to customize for specific use cases. We introduce a software library implementing this abstraction and providing automatic shared-memory parallelization. [ABSTRACT FROM AUTHOR]

Published

2022

7. Sparsity-Specific Code Optimization using Expression Trees.

Author

Herholz, Philipp, Tang, Xuan, Schneider, Teseo, Kamil, Shoaib, Panozzo, Daniele, and Sorkine-Hornung, Olga

Subjects

COMPUTER graphics, CODE generators, SCIENTIFIC computing, APPLICATION software, ALGORITHMS

Abstract

We introduce a code generator that converts unoptimized C++ code operating on sparse data into vectorized and parallel CPU or GPU kernels. Our approach unrolls the computation into a massive expression graph, performs redundant expression elimination, grouping, and then generates an architecture-specific kernel to solve the same problem, assuming that the sparsity pattern is fixed, which is a common scenario in many applications in computer graphics and scientific computing. We show that our approach scales to large problems and can achieve speedups of two orders of magnitude on CPUs and three orders of magnitude on GPUs, compared to a set of manually optimized CPU baselines. To demonstrate the practical applicability of our approach, we employ it to optimize popular algorithms with applications to physical simulation and interactive mesh deformation. [ABSTRACT FROM AUTHOR]

Published

2022

8. Which cross fields can be quadrangulated?: global parameterization from prescribed holonomy signatures.

Author

Shen, Hanxiao, Zhu, Leyi, Capouellez, Ryan, Panozzo, Daniele, Campen, Marcel, and Zorin, Denis

Subjects

PARAMETERIZATION, TOPOLOGY, CONFORMAL mapping, SPLINES

Abstract

We describe a method for the generation of seamless surface parametrizations with guaranteed local injectivity and full control over holonomy. Previous methods guarantee only one of the two. Local injectivity is required to enable these parametrizations' use in applications such as surface quadrangulation and spline construction. Holonomy control is crucial to enable guidance or prescription of the parametrization's isocurves based on directional information, in particular from cross-fields or feature curves, and more generally to constrain the parametrization topologically. To this end we investigate the relation between cross-field topology and seamless parametrization topology. Leveraging previous results on locally injective parametrization and combining them with insights on this relation in terms of holonomy, we propose an algorithm that meets these requirements. A key component relies on the insight that arbitrary surface cut graphs, as required for global parametrization, can be homeomorphically modified to assume almost any set of turning numbers with respect to a given target cross-field. [ABSTRACT FROM AUTHOR]

Published

2022

9. DEF: deep estimation of sharp geometric features in 3D shapes.

Author

Matveev, Albert, Rakhimov, Ruslan, Artemov, Alexey, Bobrovskikh, Gleb, Egiazarian, Vage, Bogomolov, Emil, Panozzo, Daniele, Zorin, Denis, and Burnaev, Evgeny

Subjects

POINT cloud, SCALAR field theory, DEEP learning, DATA modeling

Abstract

We propose Deep Estimators of Features (DEFs), a learning-based framework for predicting sharp geometric features in sampled 3D shapes. Differently from existing data-driven methods, which reduce this problem to feature classification, we propose to regress a scalar field representing the distance from point samples to the closest feature line on local patches. Our approach is the first that scales to massive point clouds by fusing distance-to-feature estimates obtained on individual patches. We extensively evaluate our approach against related state-of-the-art methods on newly proposed synthetic and real-world 3D CAD model benchmarks. Our approach not only outperforms these (with improvements in Recall and False Positives Rates), but generalizes to real-world scans after training our model on synthetic data and fine-tuning it on a small dataset of scanned data. We demonstrate a downstream application, where we reconstruct an explicit representation of straight and curved sharp feature lines from range scan data. We make code, pre-trained models, and our training and evaluation datasets available at https://github.com/artonson/def. [ABSTRACT FROM AUTHOR]

Published

2022

10. A Large-Scale Comparison of Tetrahedral and Hexahedral Elements for Solving Elliptic PDEs with the Finite Element Method.

Author

Schneider, Teseo, Hu, Yixin, Gao, Xifeng, Dumas, Jérémie, Zorin, Denis, and Panozzo, Daniele

Subjects

FINITE element method, BENCHMARK problems (Computer science), PARTIAL differential equations, REYNOLDS number, ANALYTICAL solutions

Abstract

The Finite Element Method (FEM) is widely used to solve discrete Partial Differential Equations (PDEs) in engineering and graphics applications. The popularity of FEM led to the development of a large family of variants, most of which require a tetrahedral or hexahedral mesh to construct the basis. While the theoretical properties of FEM basis (such as convergence rate, stability, etc.) are well understood under specific assumptions on the mesh quality, their practical performance, influenced both by the choice of the basis construction and quality of mesh generation, have not been systematically documented for large collections of automatically meshed 3D geometries. We introduce a set of benchmark problems involving most commonly solved elliptic PDEs, starting from simple cases with an analytical solution, moving to commonly used test problem setups, and using manufactured solutions for thousands of real-world, automatically meshed geometries. For all these cases, we use state-of-the-art meshing tools to create both tetrahedral and hexahedral meshes, and compare the performance of different element types for common elliptic PDEs. The goal of this benchmark is to enable comparison of complete FEM pipelines, from mesh generation to algebraic solver, and exploration of relative impact of different factors on the overall system performance. As a specific application of our geometry and benchmark dataset, we explore the question of relative advantages of unstructured (triangular/ tetrahedral) and structured (quadrilateral/hexahedral) discretizations. We observe that for Lagrange-type elements, while linear tetrahedral elements perform poorly, quadratic tetrahedral elements perform equally well or outperform hexahedral elements for our set of problems and currently available mesh generation algorithms. This observation suggests that for common problems in structural analysis, thermal analysis, and low Reynolds number flows, high-quality results can be obtained with unstructured tetrahedral meshes, which can be created robustly and automatically. We release the description of the benchmark problems, meshes, and reference implementation of our testing infrastructure to enable statistically significant comparisons between different FE methods, which we hope will be helpful in the development of new meshing and FEA techniques. [ABSTRACT FROM AUTHOR]

Published

2022

11. Fast and Exact Root Parity for Continuous Collision Detection.

Author

Wang, Bolun, Ferguson, Zachary, Jiang, Xin, Attene, Marco, Panozzo, Daniele, and Schneider, Teseo

Subjects

POLYNOMIALS, ALGORITHMS, MATHEMATICS, COLLECTIONS

Abstract

We introduce the first exact root parity counter for continuous collision detection (CCD). That is, our algorithm computes the parity (even or odd) of the number of roots of the cubic polynomial arising from a CCD query. We note that the parity is unable to differentiate between zero (no collisions) and the rare case of two roots (collisions). Our method does not have numerical parameters to tune, has a performance comparable to efficient approximate algorithms, and is exact. We test our approach on a large collection of synthetic tests and real simulations, and we demonstrate that it can be easily integrated into existing simulators. [ABSTRACT FROM AUTHOR]

Published

2022

12. Efficient and robust discrete conformal equivalence with boundary.

Author

Campen, Marcel, Capouellez, Ryan, Shen, Hanxiao, Zhu, Leyi, Panozzo, Daniele, and Zorin, Denis

Subjects

GAUSSIAN curvature, DEGREES of freedom, TRIANGULATION, GEOGRAPHIC boundaries, GEODESICS, SYMMETRY

Abstract

We describe an efficient algorithm to compute a discrete metric with prescribed Gaussian curvature at all interior vertices and prescribed geodesic curvature along the boundary of a mesh. The metric is (discretely) conformally equivalent to the input metric. Its construction is based on theory developed in [Gu et al. 2018b] and [Springborn 2020], relying on results on hyperbolic ideal Delaunay triangulations. Generality is achieved by considering the surface's intrinsic triangulation as a degree of freedom, and particular attention is paid to the proper treatment of surface boundaries. While via a double cover approach the case with boundary can be reduced to the case without boundary quite naturally, the implied symmetry of the setting causes additional challenges related to stable Delaunay-critical configurations that we address explicitly. We furthermore explore the numerical limits of the approach and derive continuous maps from the discrete metrics. [ABSTRACT FROM AUTHOR]

Published

2021

13. A Large-scale Benchmark and an Inclusion-based Algorithm for Continuous Collision Detection.

Author

Wang, Bolun, Ferguson, Zachary, Schneider, Teseo, Jiang, Xin, Attene, Marco, and Panozzo, Daniele

Subjects

ALGORITHMS, DESIGN techniques, COMPUTATIONAL geometry

Abstract

We introduce a large-scale benchmark for continuous collision detection (CCD) algorithms, composed of queries manually constructed to highlight challenging degenerate cases and automatically generated using existing simulators to cover common cases. We use the benchmark to evaluate the accuracy, correctness, and efficiency of state-of-the-art continuous collision detection algorithms, both with and without minimal separation. We discover that, despite the widespread use of CCD algorithms, existing algorithms are (1) correct but impractically slow; (2) efficient but incorrect, introducing false negatives that will lead to interpenetration; or (3) correct but over conservative, reporting a large number of false positives that might lead to inaccuracies when integrated in a simulator. By combining the seminal interval root finding algorithm introduced by Snyder in 1992 with modern predicate design techniques, we propose a simple and efficient CCD algorithm. This algorithm is competitive with state-of-the-art methods in terms of runtime while conservatively reporting the time of impact and allowing explicit tradeoff between runtime efficiency and number of false positives reported. [ABSTRACT FROM AUTHOR]

Published

2021

14. Intersection-free rigid body dynamics.

Author

Ferguson, Zachary, Li, Minchen, Schneider, Teseo, Gil-Ureta, Francisca, Langlois, Timothy, Jiang, Chenfanfu, Zorin, Denis, Kaufman, Danny M., and Panozzo, Daniele

Subjects

RIGID body mechanics, RIGID bodies, ALGORITHMS, FRICTION, CONTACT mechanics

Abstract

We introduce the first implicit time-stepping algorithm for rigid body dynamics, with contact and friction, that guarantees intersection-free configurations at every time step. Our algorithm explicitly models the curved trajectories traced by rigid bodies in both collision detection and response. For collision detection, we propose a conservative narrow phase collision detection algorithm for curved trajectories, which reduces the problem to a sequence of linear CCD queries with minimal separation. For time integration and contact response, we extend the recently proposed incremental potential contact framework to reduced coordinates and rigid body dynamics. We introduce a benchmark for rigid body simulation and show that our approach, while less efficient than alternatives, can robustly handle a wide array of complex scenes, which cannot be simulated with competing methods, without requiring per-scene parameter tuning. [ABSTRACT FROM AUTHOR]

Published

2021

15. Orienting point clouds with dipole propagation.

Author

Metzer, Gal, Hanocka, Rana, Zorin, Denis, Giryes, Raja, Panozzo, Daniele, and Cohen-Or, Daniel

Subjects

POINT cloud, DEEP learning, SURFACE structure, ELECTRIC fields, SURFACE reconstruction

Abstract

Establishing a consistent normal orientation for point clouds is a notoriously difficult problem in geometry processing, requiring attention to both local and global shape characteristics. The normal direction of a point is a function of the local surface neighborhood; yet, point clouds do not disclose the full underlying surface structure. Even assuming known geodesic proximity, calculating a consistent normal orientation requires the global context. In this work, we introduce a novel approach for establishing a globally consistent normal orientation for point clouds. Our solution separates the local and global components into two different sub-problems. In the local phase, we train a neural network to learn a coherent normal direction per patch (i.e., consistently oriented normals within a single patch). In the global phase, we propagate the orientation across all coherent patches using a dipole propagation. Our dipole propagation decides to orient each patch using the electric field defined by all previously orientated patches. This gives rise to a global propagation that is stable, as well as being robust to nearby surfaces, holes, sharp features and noise. [ABSTRACT FROM AUTHOR]

Published

2021

16. Bijective and coarse high-order tetrahedral meshes.

Author

Jiang, Zhongshi, Zhang, Ziyi, Hu, Yixin, Schneider, Teseo, Zorin, Denis, and Panozzo, Daniele

Subjects

LINEAR operators, ALGORITHMS, CURVED surfaces, MESH networks, POINT cloud

Abstract

We introduce a robust and automatic algorithm to convert linear triangle meshes with feature annotated into coarse tetrahedral meshes with curved elements. Our construction guarantees that the high-order meshes are free of element inversion or self-intersection. A user-specified maximal geometrical error from the input mesh controls the faithfulness of the curved approximation. The boundary of the output mesh is in bijective correspondence to the input, enabling attribute transfer between them, such as boundary conditions for simulations, making our curved mesh an ideal replacement or complement for the original input geometry. The availability of a bijective shell around the input surface is employed to ensure robust curving, prevent self-intersections, and compute a bijective map between the linear input and curved output surface. As necessary building blocks of our algorithm, we extend the bijective shell formulation to support features and propose a robust approach for boundary-preserving linear tetrahedral meshing. We demonstrate the robustness and effectiveness of our algorithm by generating high-order meshes for a large collection of complex 3D models. [ABSTRACT FROM AUTHOR]

Published

2021

17. Half-Space Power Diagrams and Discrete Surface Offsets.

Author

Chen, Zhen, Panozzo, Daniele, and Dumas, Jeremie

Subjects

ALGORITHMS, CHARTS, diagrams, etc., RAPID prototyping, DATA structures, DIGITAL libraries

Abstract

We present an efficient, trivially parallelizable algorithm to compute offset surfaces of shapes discretized using a dexel data structure. Our algorithm is based on a two-stage sweeping procedure that is simple to implement and efficient, entirely avoiding volumetric distance field computations typical of existing methods. Our construction is based on properties of half-space power diagrams, where each seed is only visible by a half-space, which were never used before for the computation of surface offsets. The primary application of our method is interactive modeling for digital fabrication. Our technique enables a user to interactively process high-resolution models. It is also useful in a plethora of other geometry processing tasks requiring fast, approximate offsets, such as topology optimization, collision detection, and skeleton extraction. We present experimental timings, comparisons with previous approaches, and provide a reference implementation in the supplemental material, which can be found on the Computer Society Digital Library at http://doi.ieeecomputersociety.org/10.1109/TVCG.2019.2945961. [ABSTRACT FROM AUTHOR]

Published

2020

18. DHFSlicer: double height-field slicing for milling fixed-height materials.

Author

Yang, Jinfan, Araujo, Chrystiano, Vining, Nicholas, Ferguson, Zachary, Rosales, Enrique, Panozzo, Daniele, Lefevbre, Sylvain, Cignoni, Paolo, and Sheffer, Alla

Subjects

WOOD, WASTE products, DECOMPOSITION method, MEDIUM density fiberboard, MATERIALS

Abstract

3-axis milling enables cheap and precise fabrication of target objects from precut slabs of materials such as wood or stone. However, the space of directly millable shapes is limited since a 3-axis mill can only carve a height-field (HF) surface during each milling and their size is bounded by the slab dimensions, one of which, the height, is typically significantly smaller than the other two for many typical materials. Extending 3-axis milling of precut slabs to general arbitrarily-sized shapes requires decomposing them into bounded-height 3-axis millable parts, or slices, which can be individually milled and then assembled to form the target object. We present DHFSlicer, a novel decomposition method that satisfies the above constraints and significantly reduces both milling time and material waste compared to alternative approaches. We satisfy the fabrication constraints by partitioning target objects into double height-field (DHF) slices, which can be fabricated using two milling passes: the HF surface accessible from one side is milled first, the slice is then flipped using appropriate fixtures, and then the second, remaining, HF surface is milled. DHFSlicer uses an efficient coarse-to-fine decomposition process: It first partitions the inputs into maximally coarse blocks that satisfy a local DHF criterion with respect to per-block milling axes, and then cuts each block into well-sized DHF slices. It minimizes milling time and material waste by keeping the slice count small, and maximizing slice height. We validate our method by embedding it within an end-to-end DHF milling pipeline and fabricating objects from slabs of foam, wood, and MDF; demonstrate that using the obtained slices reduces milling time and material waste by 42% on average compared to existing automatic alternatives; and highlight the benefits of DHFSlicer via extensive ablation studies. [ABSTRACT FROM AUTHOR]

Published

2020

19. Bijective projection in a shell.

Author

Jiang, Zhongshi, Schneider, Teseo, Zorin, Denis, and Panozzo, Daniele

Subjects

MAP projection, ALGORITHMS, TRIANGLES

Abstract

We introduce an algorithm to convert a self-intersection free, orientable, and manifold triangle mesh T into a generalized prismatic shell equipped with a bijective projection operator to map T to a class of discrete surfaces contained within the shell whose normals satisfy a simple local condition. Properties can be robustly and efficiently transferred between these surfaces using the prismatic layer as a common parametrization domain. The combination of the prismatic shell construction and corresponding projection operator is a robust building block readily usable in many downstream applications, including the solution of PDEs, displacement maps synthesis, Boolean operations, tetrahedral meshing, geometric textures, and nested cages. [ABSTRACT FROM AUTHOR]

Published

2020

20. EGGS: Sparsity‐Specific Code Generation.

Author

Tang, Xuan, Schneider, Teseo, Kamil, Shoaib, Panda, Aurojit, Li, Jinyang, and Panozzo, Daniele

Subjects

SPARSE matrices, MATRIX multiplications, LINEAR algebra, ALGORITHMS, GRAPH algorithms

Abstract

Sparse matrix computations are among the most important computational patterns, commonly used in geometry processing, physical simulation, graph algorithms, and other situations where sparse data arises. In many cases, the structure of a sparse matrix is known a priori, but the values may change or depend on inputs to the algorithm. We propose a new methodology for compile‐time specialization of algorithms relying on mixing sparse and dense linear algebra operations, using an extension to the widely‐used open source Eigen package. In contrast to library approaches optimizing individual building blocks of a computation (such as sparse matrix product), we generate reusable sparsity‐specific implementations for a given algorithm, utilizing vector intrinsics and reducing unnecessary scanning through matrix structures. We demonstrate the effectiveness of our technique on a benchmark of artificial expressions to quantitatively evaluate the benefit of our approach over the state‐of‐the‐art library Intel MKL. To further demonstrate the practical applicability of our technique we show that our technique can improve performance, with minimal code changes, for mesh smoothing, mesh parametrization, volumetric deformation, optical flow, and computation of the Laplace operator. [ABSTRACT FROM AUTHOR]

Published

2020

21. Reading News with Maps by Exploiting Spatial Synonyms.

Author

SAMET, HANAN, SANKARANARAYANAN, JAGAN, LIEBERMAN, MICHAEL D., ADELFIO, MARCO D., FRUIN, BRENDAN C., LOTKOWSKI, JACK M., PANOZZO, DANIELE, SPERLING, JON, and TEITLER, BENJAMIN E.

Subjects

WEB-based user interfaces, JOURNALISM, COMPUTER software

Abstract

The article offers brief information on the NewStand map query web application.

Published

2014

22. Feature Preserving Octree‐Based Hexahedral Meshing.

Author

Gao, Xifeng, Shen, Hanxiao, and Panozzo, Daniele

Subjects

BATCH processing, CANNING & preserving, CELL membranes

Abstract

We propose an octree‐based algorithm to tessellate the interior of a closed surface with hexahedral cells. The generated hexahedral mesh (1) explicitly preserves sharp features of the original input, (2) has a maximal, user‐controlled distance deviation from the input surface, (3) is composed of elements with only positive scaled jacobians (measured by the eight corners of a hex [SEK*07]), and (4) does not have self‐intersections. We attempt to achieve these goals by proposing a novel pipeline to create an initial pure hexahedral mesh from an octree structure, taking advantage of recent developments in the generation of locally injective 3D parametrizations to warp the octree boundary to conform to the input surface. Sharp features in the input are bijectively mapped to poly‐lines in the output and preserved by the deformation, which takes advantage of a scaffold mesh to prevent local and global intersections. The robustness of our technique is experimentally validated by batch processing a large collection of organic and CAD models, without any manual cleanup or parameter tuning. All results including mesh data and statistics in the paper are provided in the additional material. The open‐source implementation will be made available online to foster further research in this direction. [ABSTRACT FROM AUTHOR]

Published

2019

23. CurviSlicer: slightly curved slicing for 3-axis printers.

Author

Etienne, Jimmy, Ray, Nicolas, Panozzo, Daniele, Hornus, Samuel, Wang, Charlie C. L., Martínez, Jonàs, McMains, Sara, Alexa, Marc, Wyvill, Brian, and Lefebvre, Sylvain

Subjects

MANUFACTURED products, PLANAR motion, FABRICATION (Manufacturing), SAMPLING (Process), PLANAR antennas

Abstract

Most additive manufacturing processes fabricate objects by stacking planar layers of solidified material. As a result, produced parts exhibit a so-called staircase effect, which results from sampling slanted surfaces with parallel planes. Using thinner slices reduces this effect, but it always remains visible where layers almost align with the input surfaces. In this research we exploit the ability of some additive manufacturing processes to deposit material slightly out of plane to dramatically reduce these artifacts. We focus in particular on the widespread Fused Filament Fabrication (FFF) technology, since most printers in this category can deposit along slightly curved paths, under deposition slope and thickness constraints. Our algorithm curves the layers, making them either follow the natural slope of the input surface or on the contrary, make them intersect the surfaces at a steeper angle thereby improving the sampling quality. Rather than directly computing curved layers, our algorithm optimizes for a deformation of the model which is then sliced with a standard planar approach. We demonstrate that this approach enables us to encode all fabrication constraints, including the guarantee of generating collision-free toolpaths, in a convex optimization that can be solved using a QP solver. We produce a variety of models and compare print quality between curved deposition and planar slicing. [ABSTRACT FROM AUTHOR]

Published

2019

24. TriWild: robust triangulation with curve constraints.

Author

Hu, Yixin, Schneider, Teseo, Gao, Xifeng, Zhou, Qingnan, Jacobson, Alec, Zorin, Denis, and Panozzo, Daniele

Subjects

ROBUST statistics, CURVES, ERROR, ALGORITHMS, GEOMETRY

Abstract

We propose a robust 2D meshing algorithm, TriWild, to generate curved triangles reproducing smooth feature curves, leading to coarse meshes designed to match the simulation requirements necessary by applications and avoiding the geometrical errors introduced by linear meshes. The robustness and effectiveness of our technique are demonstrated by batch processing an SVG collection of 20k images, and by comparing our results against state of the art linear and curvilinear meshing algorithms. We demonstrate for our algorithm the practical utility of computing diffusion curves, fluid simulations, elastic deformations, and shape inflation on complex 2D geometries. [ABSTRACT FROM AUTHOR]

Published

2019

25. Progressive embedding.

Author

Shen, Hanxiao, Jiang, Zhongshi, Zorin, Denis, and Panozzo, Daniele

Subjects

EMBEDDING theorems, GEOMETRY, BLOCKS (Building materials), ROBUST statistics, TOPOLOGY

Abstract

Tutte embedding is one of the most common building blocks in geometry processing algorithms due to its simplicity and provable guarantees. Although provably correct in infinite precision arithmetic, it fails in challenging cases when implemented using floating point arithmetic, largely due to the induced exponential area changes. We propose Progressive Embedding, with similar theoretical guarantees to Tutte embedding, but more resilient to the rounding error of floating point arithmetic. Inspired by progressive meshes, we collapse edges on an invalid embedding to a valid, simplified mesh, then insert points back while maintaining validity. We demonstrate the robustness of our method by computing embeddings for a large collection of disk topology meshes. By combining our robust embedding with a variant of the matchmaker algorithm, we propose a general algorithm for the problem of mapping multiply connected domains with arbitrary hard constraints to the plane, with applications in texture mapping and remeshing. [ABSTRACT FROM AUTHOR]

Published

2019

26. Interactive hand pose estimation using a stretch-sensing soft glove.

Author

Glauser, Oliver, Wu, Shihao, Panozzo, Daniele, Hilliges, Otmar, and Sorkine-Hornung, Olga

Subjects

CAPACITIVE sensors, ACCURACY, FABRICATION (Manufacturing), TOOLS, CALIBRATION

Abstract

We propose a stretch-sensing soft glove to interactively capture hand poses with high accuracy and without requiring an external optical setup. We demonstrate how our device can be fabricated and calibrated at low cost, using simple tools available in most fabrication labs. To reconstruct the pose from the capacitive sensors embedded in the glove, we propose a deep network architecture that exploits the spatial layout of the sensor itself. The network is trained only once, using an inexpensive off-the-shelf hand pose reconstruction system to gather the training data. The per-user calibration is then performed on-the-fly using only the glove. The glove's capabilities are demonstrated in a series of ablative experiments, exploring different models and calibration methods. Comparing against commercial data gloves, we achieve a 35% improvement in reconstruction accuracy. [ABSTRACT FROM AUTHOR]

Published

2019

27. Poly-Spline Finite-Element Method.

Author

Schneider, Teseo, Dumas, Jérémie, Gao, Xifeng, Botsch, Mario, Panozzo, Daniele, and Zorin, Denis

Subjects

POLYHEDRAL functions, FINITE element method, PARTIAL differential equations, POISSON'S equation, PROBLEM solving

Abstract

We introduce an integrated meshing and finite-element method pipeline enabling solution of partial differential equations in the volume enclosed by a boundary representation. We construct a hybrid hexahedral-dominant mesh, which contains a small number of star-shaped polyhedra, and build a set of high-order bases on its elements, combining triquadratic B-splines, triquadratic hexahedra, and harmonic elements. We demonstrate that our approach converges cubically under refinement, while requiring around 50% of the degrees of freedom than a similarly dense hexahedral mesh composed of triquadratic hexahedra. We validate our approach solving Poisson's equation on a large collection of models, which are automatically processed by our algorithm, only requiring the user to provide boundary conditions on their surface. [ABSTRACT FROM AUTHOR]

Published

2019

28. Decoupling simulation accuracy from mesh quality.

Author

Schneider, Teseo, Hu, Yixin, Dumas, Jérémie, Gao, Xifeng, Panozzo, Daniele, and Zorin, Denis

Subjects

COMPUTER simulation, IMAGE processing, FINITE element method, PARTIAL differential equations, ALGORITHMS

Abstract

For a given PDE problem, three main factors affect the accuracy of FEM solutions: basis order, mesh resolution, and mesh element quality. The first two factors are easy to control, while controlling element shape quality is a challenge, with fundamental limitations on what can be achieved. We propose to use p-refinement (increasing element degree) to decouple the approximation error of the finite element method from the domain mesh quality for elliptic PDEs. Our technique produces an accurate solution even on meshes with badly shaped elements, with a slightly higher running time due to the higher cost of high-order elements. We demonstrate that it is able to automatically adapt the basis to badly shaped elements, ensuring an error consistent with high-quality meshing, without any per-mesh parameter tuning. Our construction reduces to traditional fixed-degree FEM methods on high-quality meshes with identical performance. Our construction decreases the burden on meshing algorithms, reducing the need for often expensive mesh optimization and automatically compensates for badly shaped elements, which are present due to boundary constraints or limitations of current meshing methods. By tackling mesh generation and finite element simulation jointly, we obtain a pipeline that is both more efficient and more robust than combinations of existing state of the art meshing and FEM algorithms. [ABSTRACT FROM AUTHOR]

Published

2018

29. Generalized motorcycle graphs for imperfect quad-dominant meshes.

Author

Schertler, Nico, Panozzo, Daniele, Gumhold, Stefan, and Tarini, Marco

Subjects

MOTORCYCLES, TEXTURE mapping, MATHEMATICAL singularities, PARAMETERIZATION, GRAPH theory

Abstract

We introduce a practical pipeline to create UV T-layouts for real-world quad dominant semi-regular meshes. Our algorithm creates large rectangular patches by relaxing the notion of motorcycle graphs and making it insensitive to local irregularities in the mesh structure such as non-quad elements, redundant irregular vertices, T-junctions, and others. Each surface patch, which can contain multiple singularities and/or polygonal elements, is mapped to an axis-aligned rectangle, leading to a simple and efficient UV layout, which is ideal for texture mapping (allowing for mipmapping and artifact-free bilinear interpolation). We demonstrate that our algorithm is an ideal solution for both recent semi-regular, quad-dominant meshing methods, and for the low-poly meshes typically used in games and movies. [ABSTRACT FROM AUTHOR]

Published

2018

30. Stitch meshing.

Author

Wu, Kui, Gao, Xifeng, Ferguson, Zachary, Panozzo, Daniele, and Yuksel, Cem

Subjects

THREE-dimensional imaging, COMPUTER simulation, RAPID prototyping, COMPUTER algorithms, COMPUTED tomography

Abstract

We introduce the first fully automatic pipeline to convert arbitrary 3D shapes into knit models. Our pipeline is based on a global parametrization remeshing pipeline to produce an isotropic quad-dominant mesh aligned with a 2-RoSy field. The knitting directions over the surface are determined using a set of custom topological operations and a two-step global optimization that minimizes the number of irregularities. The resulting mesh is converted into a valid stitch mesh that represents the knit model. The yarn curves are generated from the stitch mesh and the final yarn geometry is computed using a yarn-level relaxation process. Thus, we produce topologically valid models that can be used with a yarn-level simulation. We validate our algorithm by automatically generating knit models from complex 3D shapes and processing over a hundred models with various shapes without any user input or parameter tuning. We also demonstrate applications of our approach for custom knit model generation using fabrication via 3D printing. [ABSTRACT FROM AUTHOR]

Published

2018

31. Tetrahedral meshing in the wild.

Author

Hu, Yixin, Zhou, Qingnan, Gao, Xifeng, Jacobson, Alec, Zorin, Denis, and Panozzo, Daniele

Subjects

MESH networks, ITERATIVE methods (Mathematics), GEOMETRIC modeling, IMAGE processing, ROBUST statistics

Abstract

We propose a novel tetrahedral meshing technique that is unconditionally robust, requires no user interaction, and can directly convert a triangle soup into an analysis-ready volumetric mesh. The approach is based on several core principles: (1) initial mesh construction based on a fully robust, yet efficient, filtered exact computation (2) explicit (automatic or user-defined) tolerancing of the mesh relative to the surface input (3) iterative mesh improvement with guarantees, at every step, of the output validity. The quality of the resulting mesh is a direct function of the target mesh size and allowed tolerance: increasing allowed deviation from the initial mesh and decreasing the target edge length both lead to higher mesh quality. Our approach enables "black-box" analysis, i.e. it allows to automatically solve partial differential equations on geometrical models available in the wild, offering a robustness and reliability comparable to, e.g., image processing algorithms, opening the door to automatic, large scale processing of real-world geometric data. [ABSTRACT FROM AUTHOR]

Published

2018

32. Digitally reconstructing the Great Parchment Book: 3D recovery of fire-damaged historical documents.

Author

Pal, Kazim, Avery, Nicola, Boston, Pete, Campagnolo, Alberto, De Stefani, Caroline, Matheson-Pollock, Helen, Panozzo, Daniele, Payne, Matthew, Schüller, Christian, Sanderson, Chris, Scott, Chris, Smith, Philippa, Smither, Rachael, Sorkine-Hornung, Olga, Stewart, Ann, Stewart, Emma, Stewart, Patricia, Terras, Melissa, Walsh, Bernadette, and Ward, Laurence

Subjects

ESTATES (Social orders), HISTORICAL source material, DIGITAL humanities, PRESERVATION of antiquities

Abstract

The Great Parchment Book of the Honourable the Irish Society is a major surviving historical record of the estates of the county of Londonderry (in modern day Northern Ireland). It contains key data about landholding and population in the Irish province of Ulster and the city of Londonderry and its environs in the mid-17th century, at a time of social, religious, and political upheaval. Compiled in 1639, it was severely damaged in a fire in 1786, and due to the fragile state of the parchment, its contents have been mostly inaccessible since. We describe here a long-term, interdisciplinary, international partnership involving conservators, archivists, computer scientists, and digital humanists that developed a low-cost pipeline for conserving, digitizing, 3D-reconstructing, and virtually flattening the fire-damaged, buckled parchment, enabling new readings and understanding of the text to be created. For the first time, this article presents a complete overview of the project, detailing the conservation, digital acquisition, and digital reconstruction methods used, resulting in a new transcription and digital edition of the text in time for the 400th anniversary celebrations of the building of Londonderry's city walls in 2013. We concentrate on the digital reconstruction pipeline that will be of interest to custodians of similarly fire-damaged historical parchment, whilst highlighting how working together on this project has produced an online resource that has focussed community reflection upon an important, but previously inaccessible, historical text. [ABSTRACT FROM AUTHOR]

Published

2017

33. Fabrication-Aware Geometry Processing.

Author

Panozzo, Daniele

Published

2016

34. T-junctions in Spline Surfaces.

Author

Karčiauskas, Kȩstutis, Panozzo, Daniele, and Peters, Jörg

Subjects

SPLINE theory, GEOMETRIC surfaces, DISTRIBUTION (Probability theory), PARAMETERIZATION, POLYNOMIALS

Abstract

T-junctions occur where surface strips start or terminate. This paper develops a new way to create smooth piecewise polynomial free-form spline surfaces from quad-meshes that include T-junctions. All mesh nodes are interpreted as control points of GT-splines, that is, geometrically smoothly joined piecewise polynomials. GT-splines are akin to and compatible with B-splines and cover simple T-junctions by two polynomial pieces of degree bi-4 and more complex ones by four such patches. They complement multi-sided surface constructions in generating free-form surfaces with adaptive layout. Since GT-splines do not require a global coordination of knot intervals, GT-constructions are easy to deploy and can provide smooth surfaces with T-junctions where T-splines cannot have a smooth parameterization. GT-constructions display a uniform highlight linedistribution on input meshes where alternatives, such as Catmull-Clark subdivision, exhibit oscillations. [ABSTRACT FROM AUTHOR]

Published

2017

35. Robust hex-dominant mesh generation using field-guided polyhedral agglomeration.

Author

Gao, Xifeng, Jakob, Wenzel, Tarini, Marco, and Panozzo, Daniele

Subjects

POLYHEDRA, COMPUTER algorithms, COMPUTER graphics, DIGITAL image processing, POLYGONS, GEOMETRIC shapes

Abstract

We propose a robust and efficient field-aligned volumetric meshing algorithm that produces hex-dominant meshes, i.e. meshes that are predominantly composed of hexahedral elements while containing a small number of irregular polyhedra. The latter are placed according to the singularities of two optimized guiding fields, which allow our method to generate meshes with an exceptionally high amount of isotropy. The field design phase of our method relies on a compact quaternionic representation of volumetric octa-fields and a corresponding optimization that explicitly models the discrete matchings between neighboring elements. This optimization naturally supports alignment constraints and scales to very large datasets. We also propose a novel extraction technique that uses field-guided mesh simplification to convert the optimized fields into a hexdominant output mesh. Each simplification operation maintains topological validity as an invariant, ensuring manifold output. These steps easily generalize to other dimensions or representations, and we show how they can be an asset in existing 2D surface meshing techniques. Our method can automatically and robustly convert any tetrahedral mesh into an isotropic hex-dominant mesh and (with minor modifications) can also convert any triangle mesh into a corresponding isotropic quad-dominant mesh, preserving its genus, number of holes, and manifoldness. We demonstrate the benefits of our algorithm on a large collection of shapes provided in the supplemental material along with all generated results. [ABSTRACT FROM AUTHOR]

Published

2017

36. Field-aligned online surface reconstruction.

Author

Schertler, Nico, Tarini, Marco, Jakob, Wenzel, Kazhdan, Misha, Gumhold, Stefan, and Panozzo, Daniele

Subjects

THREE-dimensional imaging, SCANNING systems, OPTICAL scanners, IMAGING systems, THREE-dimensional display systems, IMAGE reconstruction

Abstract

Today's 3D scanning pipelines can be classified into two overarching categories: offline, high accuracy methods that rely on global optimization to reconstruct complex scenes with hundreds of millions of samples, and online methods that produce real-time but low-quality output, usually from structure-from-motion or depth sensors. The method proposed in this paper is the first to combine the benefits of both approaches, supporting online reconstruction of scenes with hundreds of millions of samples from high-resolution sensing modalities such as structured light or laser scanners. The key property of our algorithm is that it sidesteps the signed-distance computation of classical reconstruction techniques in favor of direct filtering, parametrization, and mesh and texture extraction. All of these steps can be realized using only weak notions of spatial neighborhoods, which allows for an implementation that scales approximately linearly with the size of each dataset that is integrated into a partial reconstruction. Combined, these algorithmic differences enable a drastically more efficient output-driven interactive scanning and reconstruction workflow, where the user is able to see the final quality field-aligned textured mesh during the entirety of the scanning procedure. Holes or parts with registration problems are displayed in real-time to the user and can be easily resolved by adding further localized scans, or by adjusting the input point cloud using our interactive editing tools with immediate visual feedback on the output mesh. We demonstrate the effectiveness of our algorithm in conjunction with a state-of-the-art structured light scanner and optical tracking system and test it on a large variety of challenging models. [ABSTRACT FROM AUTHOR]

Published

2017

37. Rig animation with a tangible and modular input device.

Author

Glauser, Oliver, Ma, Wan-Chun, Panozzo, Daniele, Jacobson, Alec, Hilliges, Otmar, and Sorkine-Hornung, Olga

Subjects

ANIMATION (Cinematography), CONFIGURATIONS (Geometry), ALGORITHMS, SPARSE approximations, MOTION

Abstract

We propose a novel approach to digital character animation, combining the benefits of tangible input devices and sophisticated rig animation algorithms. A symbiotic software and hardware approach facilitates the animation process for novice and expert users alike. We overcome limitations inherent to all previous tangible devices by allowing users to directly control complex rigs using only a small set (5-10) of physical controls. This avoids oversimplification of the pose space and excessively bulky device configurations. Our algorithm derives a small device configuration from complex character rigs, often containing hundreds of degrees of freedom, and a set of sparse sample poses. Importantly, only the most influential degrees of freedom are controlled directly, yet detailed motion is preserved based on a pose interpolation technique. We designed a modular collection of joints and splitters, which can be assembled to represent a wide variety of skeletons. Each joint piece combines a universal joint and two twisting elements, allowing to accurately sense its configuration. The mechanical design provides a smooth inverse kinematics-like user experience and is not prone to gimbal locking. We integrate our method with the professional 3D software Autodesk Maya® and discuss a variety of results created with characters available online. Comparative user experiments show significant improvements over the closest state-of-the-art in terms of accuracy and time in a keyframe posing task. [ABSTRACT FROM AUTHOR]

Published

2016

38. Computational thermoforming.

Author

Schüller, Christian, Panozzo, Daniele, Grundhöfer, Anselm, Zimmer, Henning, Sorkine, Evgeni, and Sorkine-Hornung, Olga

Subjects

GEOMETRIC shapes, GEOMETRIC surfaces, ALGORITHMS, MATHEMATICAL programming, COMPUTER programming

Abstract

We propose a method to fabricate textured 3D models using thermoforming. Differently from industrial techniques, which target mass production of a specific shape, we propose a combined hardware and software solution to manufacture customized, unique objects. Our method simulates the forming process and converts the texture of a given digital 3D model into a pre-distorted image that we transfer onto a plastic sheet. During thermoforming, the sheet deforms to create a faithful physical replica of the digital model. Our hardware setup uses off-the-shelf components and can be calibrated with an automatic algorithm that extracts the simulation parameters from a single calibration object produced by the same process. [ABSTRACT FROM AUTHOR]

Published

2016

39. Directional Field Synthesis, Design, and Processing.

Author

Vaxman, Amir, Campen, Marcel, Diamanti, Olga, Panozzo, Daniele, Bommes, David, Hildebrandt, Klaus, and Ben‐Chen, Mirela

Subjects

COMPUTER graphics research, COMPUTER art, DIGITAL image processing, COMPUTATIONAL geometry, COMPUTER science

Abstract

Direction fields and vector fields play an increasingly important role in computer graphics and geometry processing. The synthesis of directional fields on surfaces, or other spatial domains, is a fundamental step in numerous applications, such as mesh generation, deformation, texture mapping, and many more. The wide range of applications resulted in definitions for many types of directional fields: from vector and tensor fields, over line and cross fields, to frame and vector-set fields. Depending on the application at hand, researchers have used various notions of objectives and constraints to synthesize such fields. These notions are defined in terms of fairness, feature alignment, symmetry, or field topology, to mention just a few. To facilitate these objectives, various representations, discretizations, and optimization strategies have been developed. These choices come with varying strengths and weaknesses. This report provides a systematic overview of directional field synthesis for graphics applications, the challenges it poses, and the methods developed in recent years to address these challenges. [ABSTRACT FROM AUTHOR]

Published

2016

40. Instant field-aligned meshes.

Author

Jakob, Wenzel, Tarini, Marco, Panozzo, Daniele, and Sorkine-Hornung, Olga

Subjects

ISOTROPY subgroups, MATHEMATICAL optimization, GEOMETRIC vertices, NUMERICAL grid generation (Numerical analysis), CLOUDS

Abstract

We present a novel approach to remesh a surface into an isotropic triangular or quad-dominant mesh using a unified local smoothing operator that optimizes both the edge orientations and vertex positions in the output mesh. Our algorithm produces meshes with high isotropy while naturally aligning and snapping edges to sharp features. The method is simple to implement and parallelize, and it can process a variety of input surface representations, such as point clouds, range scans and triangle meshes. Our full pipeline executes instantly (less than a second) on meshes with hundreds of thousands of faces, enabling new types of interactive workflows. Since our algorithm avoids any global optimization, and its key steps scale linearly with input size, we are able to process extremely large meshes and point clouds, with sizes exceeding several hundred million elements. To demonstrate the robustness and effectiveness of our method, we apply it to hundreds of models of varying complexity and provide our cross-platform reference implementation in the supplemental material. [ABSTRACT FROM AUTHOR]

Published

2015

41. Data-driven interactive quadrangulation.

Author

Marcias, Giorgio, Takayama, Kenshi, Pietroni, Nico, Panozzo, Daniele, Sorkine-Hornung, Olga, Puppo, Enrico, and Cignoni, Paolo

Subjects

QUERYING (Computer science), PATTERN recognition systems, TESSELLATIONS (Mathematics), MATHEMATICAL singularities, ALGORITHM research, PATTERNS (Mathematics)

Abstract

We propose an interactive quadrangulation method based on a large collection of patterns that are learned from models manually designed by artists. The patterns are distilled into compact quadrangulation rules and stored in a database. At run-time, the user draws strokes to define patches and desired edge flows, and the system queries the database to extract fitting patterns to tessellate the sketches' interiors. The quadrangulation patterns are general and can be applied to tessellate large regions while controlling the positions of the singularities and the edge flow. We demonstrate the effectiveness of our algorithm through a series of live retopology sessions and an informal user study with three professional artists. [ABSTRACT FROM AUTHOR]

Published

2015

42. Integrable PolyVector fields.

Author

Diamanti, Olga, Vaxman, Amir, Panozzo, Daniele, and Sorkine-Hornung, Olga

Subjects

VECTOR fields, GEOMETRIC surfaces, MATHEMATICAL functions, MATHEMATICAL optimization, MATCHING theory, PARAMETERIZATION

Abstract

We present a framework for designing curl-free tangent vector fields on discrete surfaces. Such vector fields are gradients of locally-defined scalar functions, and this property is beneficial for creating surface parameterizations, since the gradients of the parameterization coordinate functions are then exactly aligned with the designed fields. We introduce a novel definition for discrete curl between unordered sets of vectors (PolyVectors), and devise a curl-eliminating continuous optimization that is independent of the matchings between them. Our algorithm naturally places the singularities required to satisfy the user-provided alignment constraints, and our fields are the gradients of an inversion-free parameterization by design. [ABSTRACT FROM AUTHOR]

Published

2015

43. Texture Mapping Real-World Objects with Hydrographics.

Author

Panozzo, Daniele, Diamanti, Olga, Paris, Sylvain, Tarini, Marco, Sorkine, Evgeni, and Sorkine‐Hornung, Olga

Subjects

TEXTURE mapping, HYDROGRAPHY, THREE-dimensional imaging, PARAMETERIZATION, COLOR image processing

Abstract

In the digital world, assigning arbitrary colors to an object is a simple operation thanks to texture mapping. However, in the real world, the same basic function of applying colors onto an object is far from trivial. One can specify colors during the fabrication process using a color 3D printer, but this does not apply to already existing objects. Paint and decals can be used during post-fabrication, but they are challenging to apply on complex shapes. In this paper, we develop a method to enable texture mapping of physical objects, that is, we allow one to map an arbitrary color image onto a three-dimensional object. Our approach builds upon hydrographics, a technique to transfer pigments printed on a sheet of polymer onto curved surfaces. We first describe a setup that makes the traditional water transfer printing process more accurate and consistent across prints. We then simulate the transfer process using a specialized parameterization to estimate the mapping between the planar color map and the object surface. We demonstrate that our approach enables the application of detailed color maps onto complex shapes such as 3D models of faces and anatomical casts. [ABSTRACT FROM AUTHOR]

Published

2015

44. Demystifying Quadrilateral Remeshing.

Author

Panozzo, Daniele

Subjects

ALGORITHMS, RAPID prototyping, MANUFACTURING processes, SOFTWARE libraries (Computer programming), COMPUTER software development

Abstract

Quadrilateral meshes are ubiquitously used as a control grid for subdivision and parametric surfaces. The process of converting a triangular mesh into a quadrilateral is called retopology, or quadrilateral meshing, and it is an essential step for the creation of 3D models used in games, movies, and special effects. This article introduces the problem, highlights the major differences between triangular and quadrilateral meshes, and provides an overview of several new automatic and semiautomatic solutions. The pros and cons of each algorithm are discussed as well as interesting directions for future work in this area. [ABSTRACT FROM PUBLISHER]

Published

2015

45. Animation-aware quadrangulation.

Author

Marcias, Giorgio, Pietroni, Nico, Panozzo, Daniele, Puppo, Enrico, and Sorkine-Hornung, Olga

Published

2013

46. Consistent volumetric discretizations inside self-intersecting surfaces.

Author

Sacht, Leonardo, Jacobson, Alec, Panozzo, Daniele, Schüller, Christian, and Sorkine-Hornung, Olga

Published

2013

47. Locally injective mappings.

Author

Schüller, Christian, Kavan, Ladislav, Panozzo, Daniele, and Sorkine-Hornung, Olga

Published

2013

48. Patchwork Terrains: Multi-resolution Representation from Arbitrary Overlapping Grids with Dynamic Update.

Author

Rocca, Luigi, Panozzo, Daniele, and Puppo, Enrico

Published

2013

49. Simple quad domains for field aligned mesh parametrization.

Author

Tarini, Marco, Puppo, Enrico, Panozzo, Daniele, Pietroni, Nico, and Cignoni, Paolo

Published

2011

50. Interference-aware geometric modeling.

Author

Harmon, David, Panozzo, Daniele, Sorkine, Olga, and Zorin, Denis

Published

2011