Lines Matching +full:test +full:- +full:experimental
1 ---
3 ---
11 May 20-21, 2025, 101 Davis Hall, University of Buffalo, NY, USA ([105 White Rd, Amherst, NY 14260](https://maps.app.goo.gl/B38RsNe41Zd93rvX7))
15 - Monday, May 19 - Tutorial (tutorials begin at 9am)
16 - Tuesday, May 20 - Meeting (begin at 9am)
17 - Wednesday, May 21 - Meeting (ends around 5pm)
28 | -------- | ---------------------------------------------------------------------------------------------------------------------------- | ----------------------- |
39 | -------- | ---------------------------------------------------------------------------------------------------------------------------- | ----------------------- |
42 | 9:30 am | Dense Broyden-Fletcher-Goldfarb-Shanno (BFGS) | [Hansol Suh](https://www.youtube.com/watch?v=efOjxXJeEXU&list=PLgFMPm27S9JrnzQmEZq54TGe5Iv8P6V_V&index=10&pp=iAQB) |
43 | 10:00 am | IBAMR: Immersed-Boundary Adaptive Mesh Refinement | [David Wells](https://www.youtube.com/watch?v=-TYu8x8hkcU&list=PLgFMPm27S9JrnzQmEZq54TGe5Iv8P6V_V&index=9&pp=iAQB) |
44 | 10:30 am | TaoTerm | [Toby Isaac](https://www.youtube.com/watch?v=XwEZ6-VqEt8&list=PLgFMPm27S9JrnzQmEZq54TGe5Iv8P6V_V&index=18&pp=iAQB) |
50 | 1:30 pm | Exploring Quantum Phases of Interacting Lattice Models via Exact Diagonalization | [Cheng-Chien Chen](https://www.youtube.com/watch?v=MDYmajrhLsw&list=PLgFMPm27S9JrnzQmEZq54TGe5Iv8P6V_V&index=3&pp=iAQB) |
52 | 2:30 pm | Application of CutFEM and SCIFEM to the modeling of coastal processes through vegetation | [Chris Kees](https://www.youtube.com/watch?v=l-z2Hj9pGtY&list=PLgFMPm27S9JrnzQmEZq54TGe5Iv8P6V_V&index=4&pp=iAQB) |
62 | -------- | ---------------------------------------------------------------------------------------------------------------------------- | ----------------------- |
63 | 9:00 am | Mesh Transformations | [Matt Knepley](https://www.youtube.com/watch?v=s-83i-asJVQ&list=PLgFMPm27S9JrnzQmEZq54TGe5Iv8P6V_V&index=16&pp=iAQB) |
64 | 9:30 am | Automatic Generation of Matrix-Free Routines for PDE Solvers with Devito via PETSc | [Zoe Leibowitz](https://www.youtube.com/watch?v=FAiuTPkowM0&list=PLgFMPm27S9JrnzQmEZq54TGe5Iv8P6V_V&index=19&pp=iAQB) |
81 (alexander-hoover)=
88 Metachronal waves are ubiquitous in propulsive and fluid transport systems across many different scales and morphologies in the biological world. Gossamer worms, or tomopterids, are a soft-bodied, holopelagic worm that use metachrony with their flexible, gelatinous parapodia to deftly navigate the midwater ocean column that they inhabit. In the following study, we develop a three-dimensional, fluid-structure interaction model, using the IBAMR and libmesh frameworks, of a tomopterid parapodium to explore the emergent metachronal waves formed from the interplay of passive body elasticity, active muscular tension, and hydrodynamic forces. After introducing our model, we examine the effects that varying material properties have on the stroke of an individual parapodium as well as the resulting fluid dynamics. We then explore the temporal dynamics when multiple parapodia are placed sequentially and how differences in the phase can alter the collective kinematics and resulting flow field. Finally, we examine the role of phase differences in a freely-swimming model.
91 (mark-adams)=
98 Particle discretizations of partial differential equations are advantageous for high-dimensional kinetic models in phase space due to their better scalability than continuum approaches with respect to dimension. Complex processes collectively referred to as particle noise hamper long time simulations with particle methods. One approach to address this problem is particle mesh adaptivity or remapping, known as particle resampling. This talk introduces a resampling method that projects particles to and from a (finite element) function space. The method is simple; using standard sparse linear algebra and finite element techniques, it can adapt to almost any set of new particle locations and preserves all moments up to the order of polynomial represented exactly by the continuum function space.
100 This work is motivated by the Vlasov-Maxwell-Landau model of magnetized plasmas with up to six dimensions, 3X in physical space and 3V in velocity space, and is developed in the context of a 1X + 1V Vlasov-Poisson model of Landau damping with logically regular particle and continuum phase space grids. Stable long time dynamics are demonstrated up to T=500 and reproducibility artifacts and data with stable dynamics up to T=1000 are publicly available.
103 (hansol-suh)=
105 :::{topic} **Dense Broyden-Fletcher-Goldfarb-Shanno (BFGS)**
110 We will present a new dense formulation of BFGS specialize for the Limited Memory-Variable Metric (KSPLMVM) linear solver in PETSc, and illustrate its use for optimization problems.
113 (david-wells)=
115 :::{topic} **IBAMR: Immersed-Boundary Adaptive Mesh Refinement**
120 IBAMR is a parallel implementation of the immersed boundary method and other relevant numerics, such as Navier-Stokes and multiphase flow solvers. This presentation showcases some applications built on IBAMR and describes how they are fundamentally powered by PETSc.
123 (joseph-pusztay)=
133 (cheng-chien-chen)=
136 **Cheng-Chien Chen**
140 Fermionic particles cannot occupy the same quantum state due to the Pauli exclusion principle. Therefore, solving the quantum many-body Schrödinger equation for electrons on finite-size lattices is equivalent to solving a finite-dimensional eigenvalue problem, where the matrix dimension grows exponentially with the lattice size. Here, I will discuss the exact diagonalization technique for finding the low-energy eigenstates of interacting fermionic models on two-dimensional lattices. These interacting models are shown to host a variety of emergent quantum phases, such as superconductivity and antiferromagnetism. For a sparse matrix with 34 billion basis states, the underlying code based on PETSc/SLEPc achieves a strong scaling performance of 85% linear scaling on more than 100,000 CPUs. The presentation will conclude with a brief discussion of potential future research directions, including ultra-large-scale matrix diagonalization based on matrix-free algorithms and/or quantum circuit simulations.
143 (boyce-griffith)=
150 Cardiac fluid dynamics fundamentally involves interactions between complex blood flows and the structural deformations of the muscular heart walls and the thin, flexible valve leaflets. I will initially focus on models of an in vitro pulse-duplicator system that is commonly used in the development and regulation of prosthetic heart valves. These models enable detailed comparisons between experimental data and computational model predictions but use highly simplified descriptions of cardiac anatomy and physiology. I will also present recent in vitro models, focusing on a new comprehensive model of the human heart. This heart model includes fully three-dimensional descriptions of all major cardiac structures along with biomechanics models that are parameterized using experimental tensile test data obtained exclusively from human tissue specimens. Simulation results demonstrate that the model generates physiological stroke volumes, pressure-volume loops, and valvular pressure-flow relationships, thereby illustrating is its potential for predicting cardiac function in both health and disease. Time permitting, I will end the talk by describing extensions of this model to incorporate a comprehensive description of cardiac electrophysiology and electro-mechanical coupling.
153 (chris-kees)=
160 Understanding the effects of sea level rise on coastal ecosystems involves complex solid materials, such as mixed sediments and vegetation. Physical flume and basin studies have long been used in coastal engineering to understand wave and current dynamics around such structures. Numerical flumes based on computational fluid dynamics and fluid-structure interaction have recently begun to augment physical models for design studies, particularly for engineered structures where established Arbitrary Lagrangian-Eulerian (ALE) methods based on boundary-conforming meshes and isoparametric or isogeoemtric finite element methods are effective. The rapid growth of lidar and photogrammetrytechniques at large scales and computed tomography at small scales has introduced the possibility of constructing numerical experiments for the complex natural materials in coastal ecosystems. These methods tend to produce low-order geometric representations with uneven resolution, which are typically not appropriate for conforming mesh generation. To address this challenge, recent work extended an existing ALE method to include embedded solid dynamics using a piecewise linear CutFEM approach. The implementation is based on equivalent polynomials. The approach retains the convergence properties of the CutFEM method while having a simple implementation within the existing twophase RANS model, which has been used frequently for numerical flume studies. This presentation will consider application and performance of the method for two critical coastal processes: wave interaction with vegetation and sediment dynamics.
163 (matt-knepley)=
170 Computational meshes, as a way to partition space, form the basis of much of PDE simulation technology, for instance for the finite element and finite volume discretization methods. In complex simulations, we are often driven to modify an input mesh. For example, to refine, coarsen, extrude, change cell types, or filter it. This code can be voluminous, error-prone, spread over many special cases, and hard to understand and maintain by subsequent developers. We present a simple, table-driven paradigm for mesh transformation which can execute a large variety of transformations in a performant, parallel manner, along with experiments in the open source library PETSc which can be run by the reader.
173 (zoe-leibowitz)=
175 :::{topic} **Automatic Generation of Matrix-Free Routines for PDE Solvers with Devito via PETSc**
180 Traditional numerical solvers are often optimized for specific hardware architectures, making their adaptation to new computing environments challenging. The rapid evolution of hardware increases the complexity of rewriting and re-optimizing these solvers. By combining domain-specific languages (DSLs) with automated code generation, the level of abstraction is raised, enabling the generation of high-performance code across diverse hardware architectures. Moreover, providing users with a high-level problem specification facilitates the development of complex PDE solvers in a form closer to continuous mathematics, reducing code complexity and maximizing reuse.
182 Devito, a DSL and compiler for finite-difference solvers, has been extended to integrate iterative solver functionality through an interface with PETSc, enabling the generation of solvers for various computational fluid dynamics (CFD) problems. As an industry-standard framework, Devito automates the generation of highly optimized explicit finite-difference kernels and stencil computations and has been extensively used in large-scale seismic inversion and medical imaging applications. The new developments introduce automatic generation of matrix-free routines in Devito, allowing interaction with PETSc’s suite of solvers. Key enhancements include support for iterative solvers, implicit time-stepping, coupled solvers, and matrix-free preconditioning. These features are fully integrated into Devito’s symbolic API while maintaining compatibility with staggered grids, subdomains, and custom stencils.
184 This work expands Devito’s capabilities, enabling it to address a broader range of high-performance computing challenges, including incompressible flow problems in CFD. The new framework is demonstrated through benchmark simulations, including the backward-facing step and flow around a cylinder.
187 (david-salac)=
194 This talk will outline recent efforts to include finite difference operations in PETSc through the addition of PetscFD. We begin by formally exploring the concept of stencil composition, showing that resulting stencil will have an accuracy equal to the lower of the two stencils being composed. The basic outline of PetscFD is then provided, in addition to several high-level functions that return matrices for arbitrary derivatives. Finally, the usage of PetscFD is demonstrated via several canonical examples.
197 (margarete-jadamec)=
204 Plate tectonic theory provides a self-consistent, first order explanation of the distribution of earthquakes, volcanoes, and mountain belts on Earth, thus forming a comprehensive framework for interpreting how internal processes are expressed at the Earth’s surface. Inherent in the tenet of plate tectonics is that the plates are internally rigid with deformation concentrated at the boundaries. However, adequately capturing the relevant physics that allows for both strong plate interiors and weak boundaries, and then numerically implementing the complex rheologies in software to model the time-dependent evolution of plate motion and subduction remains a challenge. A series of (a) two-dimensional models of generalized subduction and (b) three-dimensional, data-driven models of natural subduction are presented that examine how the subducting plate geometry, coupling along the subduction interface, and a non-linear mantle rheology control surface plate motion, viscous flow in the asthenosphere, and length-scales of decoupling between the plates and asthenosphere at convergent plate boundaries. The non-linear, visco-plastic rheology and complex subducted plate geometries require high-performance computing and optimized numerical solvers to resolve the flow dynamics. Results show the incorporation of a strain-rate dependent rheology allows for dynamic decoupling between the lithosphere and asthenosphere at subduction zones facilitating self-sustaining plate tectonics. In addition, the three-dimensional models produce dynamic upwelling off-axis from the subducted slab edge, suggesting a new mechanism to explain anomalous volcanism observed at lateral subduction zone terminations.
207 (conor-ward)=
214 pyop3 is a new domain-specific language that automates the application of local computational kernels over a mesh, termed 'unstructured mesh stencil calculations’. Such operations are ubiquitous across simulation methods including the finite element method and finite volume method, as well as preconditioners, slope limiters, and more. Written in Python, pyop3 takes advantage of some novel abstractions for describing mesh data (think generalised `PetscSection`) to describe complex mesh loops in a concise way that is agnostic to the underlying data layout. Having described the computation to be performed, pyop3 then uses just-in-time compilation to generate high-performance C code (CUDA/HIP coming soon) and coordinates its execution in parallel using MPI.
221 (darsh-nathawani)=
228 Proteus is a python package to solve PDEs using traditional and state-of-the-art numerical models. Proteus uses several C, C++ and Fortran libraries either as an external package or a part of Proteus. PETSc is a vital part of the development of Proteus. The objective of this talk is to introduce Proteus, explain how to get it and use it, and some initial performance tests using the Poisson problem and provide comparison with PETSc. This scaling analysis is a crucial part for a guidance to better design efficient algorithms.
231 (tim-steinhoff)=
233 :::{topic} **Using PETSc in a Multi-application Environment**
236 Gesellschaft für Anlagen- und Reaktorsicherheit (GRS) gGmbH
238 In this talk we provide an overview of the use of PETSc in the context of the code family AC<sup>2</sup> which is developed and distributed by GRS. AC<sup>2</sup> consists of multiple codes and is used to simulate the behavior of nuclear reactors during operation, transients, design basis and beyond design basis accidents up to radioactive releases to the environment. Access to PETSc is controlled by the self-developed wrapper NuT (Numerical Toolkit). We present a brief rundown of historical developments introducing NuT and therefore PETSc to handle certain numerical subtasks in AC<sup>2</sup>. This is accompanied by a deeper look into our latest development and the challenges that come with it in order to support the time evolution of nuclide inventories in burnup and decay calculations.
244 - [Blaise Bourdin](https://math.mcmaster.ca/~bourdinb/)
245 - [Danny Finn](https://scholar.google.com/citations?user=l09jI6wAAAAJ&hl=en)
246 - [Toby Isaac](https://tisaac.gitlab.io/triquadtethex/)
247 - [Lois McInnes](https://wordpress.cels.anl.gov/curfman/)
248 - [Louis Moresi](https://www.moresi.info/)
249 - [Darsh Nathawani](https://darshnathawani.com/)
250 - [Barry Smith](https://barrysmith.github.io/)
251 - [Junchao Zhang](https://www.anl.gov/profile/junchao-zhang)
254 - [Margarete Jadamec](https://geovizlab.geology.buffalo.edu/)
255 - [Matt Jones](https://www.buffalo.edu/ccr/about-us/people/staff/jones.html)
256 - [Matt Knepley](https://cse.buffalo.edu/~knepley/)
257 - [Joseph Pusztay](https://www.linkedin.com/in/joseph-pusztay-174183129/)
258 - [David Salac](https://engineering.buffalo.edu/mechanical-aerospace/people/faculty/d-salac.html)
261 ```{image} https://petsc.gitlab.io/annual-meetings/2025/Center-for-Computational-Research.png
264 ```{image} https://petsc.gitlab.io/annual-meetings/2025/Institute-for-Artificial-Intelligence-and-Data-Science-color.png
275 All meeting attendees are expected to follow the PETSc/NumFocus Code of Conduct. The local committee will serve as the code of conduct response team, https://numfocus.org/code-of-conduct#response-team. Should any concerns arise during the meeting, please contact any response team member.
280 Please [register](https://ti.to/nf-projects/petsc-annual-meeting) to save your seat.
285 [Submit an abstract](https://docs.google.com/forms/d/126KwzajoQvcqU_q7btNsYxFqbe7rJ_vASC-tejZfXDQ) to be included in the schedule.
288 - contributions to PETSc
289 - use of PETSc in applications or libraries
290 - development of libraries and packages [called from PETSc](https://petsc.org/release/install/external_software/)
291 - just curious about using PETSc in applications
300 - Hotels Near UB North
302 - [Motel 6 Amherst, NY](https://www.motel6.com/en/home/property/buffalo-amherst.html) 4400 Maple Rd, Amherst, NY 14226, (716) 834-2231
303 - [Hampton Inn Buffalo - Amherst](https://www.hilton.com/en/hotels/bufcphx-hampton-buffalo-amherst/) 1601 Amherst Manor Dr, Amherst, NY 14221, (716) 559-7010
304 - [Candlewood Suites Buffalo Amherst](https://www.ihg.com/candlewood/hotels/us/en/amherst/bufcw/hoteldetail?cm_mmc=GoogleMaps-_-CW-_-US-_-BUFCW) 20 Flint Rd, Amherst, NY 14226, (716) 688-2100
305 - [DoubleTree by Hilton Hotel Buffalo-Amherst](https://www.hilton.com/en/hotels/buffldt-doubletree-buffalo-amherst/) 10 Flint Rd, Amherst, NY 14226, (716) 689-4414
306 - [Comfort Inn University](https://www.choicehotels.com/new-york/amherst/comfort-inn-hotels/ny293?mc=llgoxxpx) 1 Flint Rd, Amherst, NY 14226, (716) 415-1132
307 - [Fairfield Inn & Suites Buffalo Amherst/University](https://www.marriott.com/en-us/hotels/buffn-fairfield-inn-and-suites-buffalo-amherst-university/overview/?scid=f2ae0541-1279-4f24-b197-a979c79310b0) 3880 Rensch Rd, Amherst, NY 14228, (716) 204-8936
308 - [Staybridge Suites Buffalo-Amherst by IHG](https://www.ihg.com/staybridge/hotels/us/en/amherst/bufrr/hoteldetail?cm_mmc=GoogleMaps-_-SB-_-US-_-BUFRR}) 1290 Sweet Home Rd, Amherst, NY 14228, (716) 276-8750
311 - Hotels in Downtown Buffalo
313 - [Holiday In Express & Suites Buffalo Downtown-Medical Ctr by IHG](https://www.ihg.com/holidayinnexpress/hotels/us/en/buffalo/bufms/hoteldetail?cm_mmc=GoogleMaps-_-EX-_-US-_-BUFMS) 601 Main St, Buffalo, NY 14203, (716) 854-5500, Located near a subway station
314 - [Hilton Garden Inn Buffalo Downtown](https://www.hilton.com/en/hotels/bufmsgi-hilton-garden-inn-buffalo-downtown/?SEO_id=GMB-AMER-GI-BUFMSGI&y_source=1_MjA4MTcyMy03MTUtbG9jYXRpb24ud2Vic2l0ZQ%3D%3D) 10 Lafayette Square, Buffalo, NY 14203, (716) 848-1000, Located near a subway station
315 - [Hampton Inn & Suites Buffalo Downtown](https://www.hilton.com/en/hotels/bufdthx-hampton-suites-buffalo-downtown/?SEO_id=GMB-AMER-HX-BUFDTHX&y_source=1_MjA4MzA5Ny03MTUtbG9jYXRpb24ud2Vic2l0ZQ%3D%3D) 220 Delaware Ave, Buffalo, NY 14202, (716) 855-2223, Located near Chippewa St/Nightlife
316 - [Embassy Suites by Hilton Buffalo](https://www.hilton.com/en/hotels/bufeses-embassy-suites-buffalo/?SEO_id=GMB-AMER-ES-BUFESES&y_source=1_MTEwOTkxNC03MTUtbG9jYXRpb24ud2Vic2l0ZQ%3D%3D) 200 Delaware Ave, Buffalo, NY 14202, (716) 842-1000, Located near Chippewa St/Nightlife
317 - [Curtiss Hotel](https://curtisshotel.com/) 210 Franklin St, Buffalo, NY 14202, (716) 954-4900, Located near Chippewa St/Nightlife