SIAM Student Chapter Seminar: Difference between revisions

From UW-Math Wiki
Jump to navigation Jump to search
No edit summary
No edit summary
(6 intermediate revisions by the same user not shown)
Line 45: Line 45:
|-
|-
| Oct 25, 4 PM,
| Oct 25, 4 PM,
| Zoom (refreshments and conference call in 307)
| Zoom (refreshments and conference call in 9th floor lounge)
| [https://www.linkedin.com/in/patricktbardsley/ Patrick Bardsley] (Machine Learning Engineer at [https://www.cirrus.com/ Cirrus Logic])
| [https://www.linkedin.com/in/patricktbardsley/ Patrick Bardsley] (Senior Machine Learning Engineer at [https://www.cirrus.com/ Cirrus Logic])
| ''[[#Oct 25, Patrick Bardsley|Job Talk-Machine Learning]]''
|
|-
|-
|-
|-
| Nov 8, 4 PM,  
| Nov 8, 4 PM,  
| Zoom (refreshments and conference call in 307)
| Zoom (refreshments and conference call in 9th floor lounge)
| [https://www.linkedin.com/in/libanmohamed496/ Liban Mohammed] (Machine Learning Engineer at [https://www.mitre.org/ MITRE])
| [https://www.linkedin.com/in/libanmohamed496/ Liban Mohamed] (Machine Learning Engineer at [https://www.mitre.org/ MITRE])
| ''[[#Nov 8, Liban Mohamed|Job Talk-Machine Learning]]''
|
|-
|-
|-
|-
| Nov 15, 4 PM,  
| Nov 15, 4 PM,  
| Zoom (refreshments and conference call in 307)
| Zoom (refreshments and conference call in 9th floor lounge)
| [https://www.linkedin.com/in/kurt-ehlert-320b8397/ Kurt Ehlert] (Trading Strategy Developer at [https://auros.global/about/ Auros])
| [https://www.linkedin.com/in/kurt-ehlert-320b8397/ Kurt Ehlert] (Trading Strategy Developer at [https://auros.global/about/ Auros])
| ''[[#Nov 15, Kurt Ehlert|Job Talk-Cryptocurrency Trading]]''
|
|-
|-
|-
|-
| Nov 29, 4 PM
| Nov 29, 4 PM
| TBA
| 9th floor lounge
| [https://people.math.wisc.edu/~boakley/ Bryan Oakley] (Math)
| [https://people.math.wisc.edu/~boakley/ Bryan Oakley] (Math)
| "[[#Nov 29, Bryan Oakley|Optimal Spatially Dependent Diffusion]]"
| ''[[#Nov 29, Bryan Oakley|Optimal Spatially Dependent Diffusion]]''
|
|
|-
|-
|-
|-
| Dec 6, 4 PM
| Dec 6, 4 PM
| Ingraham 214
| 9th floor lounge
| [https://sites.google.com/view/hongxuchen/ Hongxu Chen] (Math)
| [https://sites.google.com/view/hongxuchen/ Hongxu Chen] (Math)
| ''[[#Dec 6, Hongxu Chen|Boltzmann equation with Cercignani-Lampis boundary]]''
|}
|}


Line 83: Line 90:
=== Oct 4, Anjali Nair ===
=== Oct 4, Anjali Nair ===
The phonon transport equation is used to model heat conduction in solid materials. I will talk about how we use it to solve an inverse problem to reconstruct the thermal reflection coefficient at an interface. This takes the framework of a PDE constrained optimization problem, and I will also mention the stochastic methods used to solve it.
The phonon transport equation is used to model heat conduction in solid materials. I will talk about how we use it to solve an inverse problem to reconstruct the thermal reflection coefficient at an interface. This takes the framework of a PDE constrained optimization problem, and I will also mention the stochastic methods used to solve it.


=== Oct 18, Jason Torchinsky ===
=== Oct 18, Jason Torchinsky ===
A vertical Lagrangian coordinate has been used in global climate models for nearly two decades and has several advantages over other discretizations, including reducing the dimensionality of the physical problem. As the Lagrangian surfaces deform over time, it is necessary to accurately and conservatively remap the vertical Lagrangian coordinate back to a fixed Eulerian coordinate. A popular choice of remapping algorithm is the piecewise parabolic method, a modified version of which is used in the atmospheric component of the Department of Energy's Energy Exascale Earth System Model. However, this version of the remapping algorithm creates unwanted noise at the model top and planetary surface for several standard test cases. We explore four alternative modifications to the algorithm and show that the most accurate of these eliminates this noise.  
A vertical Lagrangian coordinate has been used in global climate models for nearly two decades and has several advantages over other discretizations, including reducing the dimensionality of the physical problem. As the Lagrangian surfaces deform over time, it is necessary to accurately and conservatively remap the vertical Lagrangian coordinate back to a fixed Eulerian coordinate. A popular choice of remapping algorithm is the piecewise parabolic method, a modified version of which is used in the atmospheric component of the Department of Energy's Energy Exascale Earth System Model. However, this version of the remapping algorithm creates unwanted noise at the model top and planetary surface for several standard test cases. We explore four alternative modifications to the algorithm and show that the most accurate of these eliminates this noise.  


=== Nov 29 ===
 
=== Oct 25, Patrick Bardsley ===
During the course of a PhD, students typically enter a proverbial `coal mine’ to extract new information about one or more problems, and in the process become a domain expert in a small niche of the technical and scientific world. Upon leaving the academy, unless one lands a job in their niche domain, much of their problem- and domain-specific knowledge is no longer essential. However, mathematics is broad and general, arguably the most general of all scientific disciplines. This fact alone is a mathematician’s greatest asset and ‘leg-up’ when entering the industrial workforce. In this talk, I will discuss some details of my work, both inside and outside of the academy, with the goal of highlighting the skills and concepts that have been the most general and transferable for me. For example, my academic work on hyperbolic inverse problems helped me learn signal processing concepts I now use daily, while my studies on polycrystalline grain growth pushed me to learn thermodynamics, which translated well to the information theory concepts I now utilize. I will also give you some idea of my current day-to-day responsibilities, and close with my thoughts and suggestions on job searches.
 
 
=== Nov 8, Liban Mohamed ===
I work as a researcher at MITRE, a company that manages R&D contracts (FFRDCs) with federal agencies. I am nominally a machine learning engineer, but my department supports a diverse array of initiatives with the IRS. In this talk I'll give an overview of the FFRDC space, give a sketch of what I work on and how I spend my time, and share my thoughts about navigating the transition from academia to industry.
 
 
=== Nov 15, Kurt Ehlert ===
After graduating from the UW, I ventured into the world of trading. My first job was at Virtu, a high-frequency market-maker, and currently I work at Auros, which is a high-frequency trading firm that focuses on cryptocurrencies. During the talk, I will give an overview of the industry, job market, and interview process from the perspective of a "quant". Then I will describe the day-to-day work and give a high-level description of typical projects.
 
 
=== Nov 29, Bryan Oakley ===
The solution to the diffusion equation is known to converge exponentially to its steady state, and the rate is given by the spectral gap of the elliptic operator. Using variational techniques, we will maximize the spectral gap over choices of spatially dependent diffusion functions. Using this characterization, we can obtain bounds on the optimal rate of convergence.
The solution to the diffusion equation is known to converge exponentially to its steady state, and the rate is given by the spectral gap of the elliptic operator. Using variational techniques, we will maximize the spectral gap over choices of spatially dependent diffusion functions. Using this characterization, we can obtain bounds on the optimal rate of convergence.
=== Dec 6, Hongxu Chen ===
Boltzmann equation is a fundamental kinetic equation that describes the dynamics of dilute gas. In this talk I will focus on the boundary value problem of the Boltzmann equation and introduce the Cercignani-Lampis boundary, which is a physical boundary that describes the intermediate reflection law between diffuse reflection and specular reflection.





Revision as of 22:05, 2 December 2021



Fall 2021

date and time location speaker title
Sept 20, 4 PM Ingraham 214 Julia Lindberg (Electrical and Computer Engineering) Polynomial system solving in applications
Sept 27, 4 PM, Zoom (refreshments and conference call in 307) Wil Cocke (Developer for ARCYBER) Job talk-Software Development/Data Science
Oct 4, 2:45 PM B119 Van Vleck Anjali Nair (Math) Reconstruction of Reflection Coefficients Using the Phonon Transport Equation
Oct 18, 4 PM 6104 Social Sciences Jason Tochinsky (Math) Improving the Vertical Remapping Algorithm in the Department of Energy’s Energy Exascale Earth Systems Model
Oct 25, 4 PM, Zoom (refreshments and conference call in 9th floor lounge) Patrick Bardsley (Senior Machine Learning Engineer at Cirrus Logic) Job Talk-Machine Learning
Nov 8, 4 PM, Zoom (refreshments and conference call in 9th floor lounge) Liban Mohamed (Machine Learning Engineer at MITRE) Job Talk-Machine Learning
Nov 15, 4 PM, Zoom (refreshments and conference call in 9th floor lounge) Kurt Ehlert (Trading Strategy Developer at Auros) Job Talk-Cryptocurrency Trading
Nov 29, 4 PM 9th floor lounge Bryan Oakley (Math) Optimal Spatially Dependent Diffusion
Dec 6, 4 PM 9th floor lounge Hongxu Chen (Math) Boltzmann equation with Cercignani-Lampis boundary

Abstracts

Sept 20, Julia Lindberg

Polynomial systems arise naturally in many applications in engineering and the sciences. This talk will outline classes of homotopy continuation algorithms used to solve them. I will then describe ways in which structures such as irreducibility, symmetry and sparsity can be used to improve computational speed. The efficacy of these algorithms will be demonstrated on systems in power systems engineering, statistics and optimization


Sept 27, Wil Cocke

I mostly work as a software developer with an emphasis on data science projects dealing with various Command specific projects. The data science life-cycle is fairly consistent across industries: collect, clean, explore, model, interpret, and repeat with a goal of providing insight to the organization. During my talk, I will share some lessons learned for mathematicians interested in transitioning to software development/ data science.


Oct 4, Anjali Nair

The phonon transport equation is used to model heat conduction in solid materials. I will talk about how we use it to solve an inverse problem to reconstruct the thermal reflection coefficient at an interface. This takes the framework of a PDE constrained optimization problem, and I will also mention the stochastic methods used to solve it.


Oct 18, Jason Torchinsky

A vertical Lagrangian coordinate has been used in global climate models for nearly two decades and has several advantages over other discretizations, including reducing the dimensionality of the physical problem. As the Lagrangian surfaces deform over time, it is necessary to accurately and conservatively remap the vertical Lagrangian coordinate back to a fixed Eulerian coordinate. A popular choice of remapping algorithm is the piecewise parabolic method, a modified version of which is used in the atmospheric component of the Department of Energy's Energy Exascale Earth System Model. However, this version of the remapping algorithm creates unwanted noise at the model top and planetary surface for several standard test cases. We explore four alternative modifications to the algorithm and show that the most accurate of these eliminates this noise.


Oct 25, Patrick Bardsley

During the course of a PhD, students typically enter a proverbial `coal mine’ to extract new information about one or more problems, and in the process become a domain expert in a small niche of the technical and scientific world. Upon leaving the academy, unless one lands a job in their niche domain, much of their problem- and domain-specific knowledge is no longer essential. However, mathematics is broad and general, arguably the most general of all scientific disciplines. This fact alone is a mathematician’s greatest asset and ‘leg-up’ when entering the industrial workforce. In this talk, I will discuss some details of my work, both inside and outside of the academy, with the goal of highlighting the skills and concepts that have been the most general and transferable for me. For example, my academic work on hyperbolic inverse problems helped me learn signal processing concepts I now use daily, while my studies on polycrystalline grain growth pushed me to learn thermodynamics, which translated well to the information theory concepts I now utilize. I will also give you some idea of my current day-to-day responsibilities, and close with my thoughts and suggestions on job searches.


Nov 8, Liban Mohamed

I work as a researcher at MITRE, a company that manages R&D contracts (FFRDCs) with federal agencies. I am nominally a machine learning engineer, but my department supports a diverse array of initiatives with the IRS. In this talk I'll give an overview of the FFRDC space, give a sketch of what I work on and how I spend my time, and share my thoughts about navigating the transition from academia to industry.


Nov 15, Kurt Ehlert

After graduating from the UW, I ventured into the world of trading. My first job was at Virtu, a high-frequency market-maker, and currently I work at Auros, which is a high-frequency trading firm that focuses on cryptocurrencies. During the talk, I will give an overview of the industry, job market, and interview process from the perspective of a "quant". Then I will describe the day-to-day work and give a high-level description of typical projects.


Nov 29, Bryan Oakley

The solution to the diffusion equation is known to converge exponentially to its steady state, and the rate is given by the spectral gap of the elliptic operator. Using variational techniques, we will maximize the spectral gap over choices of spatially dependent diffusion functions. Using this characterization, we can obtain bounds on the optimal rate of convergence.

Dec 6, Hongxu Chen

Boltzmann equation is a fundamental kinetic equation that describes the dynamics of dilute gas. In this talk I will focus on the boundary value problem of the Boltzmann equation and introduce the Cercignani-Lampis boundary, which is a physical boundary that describes the intermediate reflection law between diffuse reflection and specular reflection.



Past Semesters