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For the site in Spanish, visit [[Math Circle de Madison]]
For the site in Spanish, visit [[Math Circle de Madison]]
=COVID-19 Update=
We will moving back to in-person talks for the remainder of the semester.
As is the university's policy, all participants must wear masks. We will make every effort to maintain social distancing where possible.
=What is a Math Circle?=
=What is a Math Circle?=
The Madison Math Circle is a weekly series of mathematically based activities aimed at interested middle school and high school students. It is an outreach program organized by the UW Math Department.  Our goal is to provide a taste of exciting ideas in math and science. In the past we've had talks about plasma and weather in outer space, video game graphics, and encryption.  In the sessions, students (and parents) are often asked to explore problems on their own, with the presenter facilitating a discussion.  The talks are independent of one another, so new students are welcome at any point.
The Madison Math Circle is a weekly series of mathematically based activities aimed at interested middle school and high school students. It is an outreach program organized by the UW Math Department.  Our goal is to provide a taste of exciting ideas in math and science. In the past we've had talks about plasma and weather in outer space, video game graphics, and encryption.  In the sessions, students (and parents) are often asked to explore problems on their own, with the presenter facilitating a discussion.  The talks are independent of one another, so new students are welcome at any point.
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=All right, I want to come!=
=All right, I want to come!=


Our in person talks will be at, <b>Monday at 6pm in 3255 Helen C White Library</b>, during the school year, and the link for our virtual talks will be available through our mailing list and on the schedule below. New students are welcome at any point!  There is no fee and the talks are independent of one another, so you can just show up any week, but we ask all participants to take a moment to register by following the link below:
Our in person talks will be at, <b>Monday at 6pm in 3255 Helen C White Library</b>, during the school year. New students are welcome at any point!  There is no fee and the talks are independent of one another. You can just show up any week, but we ask all participants to take a moment to register by following the link below:


  [https://docs.google.com/forms/d/e/1FAIpQLSe_cKMfdjMQlmJc9uZg5bZ-sjKZ2q5SV9wLb1gSddrvB1Tk1A/viewform '''Math Circle Registration Form''']
  [https://forms.gle/5QRTkHngWf43nmCC9 '''Math Circle Registration Form''']


All of your information is kept private, and is only used by the Madison Math Circle organizer to help run the Circle.  
All of your information is kept private, and is only used by the Madison Math Circle organizer to help run the Circle.  


If you are a student, we hope you will tell other interested students about these talks, and speak with your parents or with your teacher about organizing a car pool to the UW campus. If you are a parent or a teacher, we hope you'll tell your students about these talks and organize a car pool to the UW (all talks take place in 3255 Helen C White Library, on the UW-Madison campus, right next to the Memorial Union).
If you are a student, we hope you will tell other interested students about these talks, and speak with your parents or with your teacher about organizing a car pool to the UW campus. If you are a parent or a teacher, we hope you'll tell your students about these talks and organize a car pool to the UW (all talks take place in 3255 Helen C White Library, on the UW-Madison campus, right next to the Memorial Union).
==Spring Enhancement Workshop==
Our aim is to offer an opportunity for students to not only explore various fields of math through our weekly talks, but also give them the opportunity to hone the various skills involved in higher mathematics. To this end, starting this spring, we are beginning a first in a semesterly series of workshops aimed at developing these skills for middle school students. The workshop, titled the Math Circle Spring Enhancement Workshop (SEP) will be held in May, on every Monday from 6:00pm - 7:00pm from May 2nd to May 30th at the UW-Madison campus. Please see our schedule below for details. 
The topics for this workshop will cover an introduction to constructing mathematical arguments and proofs, understanding how to generalise simple mathematical ideas, and learn how to discover math for one's self. We will build these skills through collaborative problem solving sessions while learning about graph theory, game theory, and other cool areas of mathematics.
The 2022 SEP is being organised by the Math Circle team in collaboration with Dr. Peter Juhasz, an instructor at the Budapest Semester in Math Education, a world renowned program in training talented students in math education from across the globe. Peter will be the main speaker and facilitator for the spring and has extensive experience teaching mathematics to secondary students and is the chief organizer of various mathematics camps in Hungary. He also directs the Joy of Thinking Foundation, whose aim is to promote mathematics education of gifted students in Hungary.
We want to invite any middle school students curious about math to join! If you are interested, please register using the form below. As always, this workshop is free and only requires your curiosity and participation!
  [https://forms.gle/ZwcTcMrAAc6UfjnP9 '''Math Circle SEP Registration Form''']
All your information is kept private, and is only used by the Madison Math Circle organiser to help run the Circle.




We hope to see you there!


== Fall Schedule ==
<center>
<center>


{| style="color:black; font-size:120%" border="1" cellpadding="14" cellspacing="0"
{| style="color:black; font-size:120%" border="1" cellpadding="14" cellspacing="0"
|-
|-
! colspan="4" style="background: #e8b2b2;" align="center" | SEP Schedule
! colspan="4" style="background: #e8b2b2;" align="center" | Fall Schedule
|-
! Date !! Location and Room || Speaker || Title
|-
| Oct 7 || 3255 College Library || Caitlin Davis || How to Cut a Cake (Fairly)
|-
| Oct 14 || 3255 College Library || Uri Andrews || Math, Philosophy, Psychology, and Artificial Intelligence
|-
| Oct 21 || 3255 College Library || Sam Craig || Fractal geometry and the problem of measuring coastlines
|-
| Oct 28 || 3255 College Library || Cancelled || Cancelled
|-
| Nov 4 || 3255 College Library || Sam Craig || Proofs of the Pythagorean theorem, new and old.
|-
| Nov 11 || 3255 College Library || Chenxi Wu || Heron’s method for approximating square roots
|-
|-
! Date !! Location and Room
| Nov 18 || 3255 College Library || Diego Rojas || Non-Transitive Dice: The Math That Doesn’t Play Fair
|-
|-
| May 2nd || 3255 Helen C White Library  
| Nov 25 || 3255 College Library || Kaiyi Huang || A geometric investigation into a space shuttle failure
|-
|-
| May 9th || 3255 Helen C White Library  
| Dec 2 || 3255 College Library || TBA || TBA
|-
|-
| May 16th || TBA  
| Dec 9 || 3255 College Library || TBA || TBA
|-
|-
| May 23rd || 3255 Helen C. White Library  
| Dec 16 || 3255 College Library || TBA || TBA
|-
|-
| May 30th || TBA
|}
|}


</center>
</center>


= Fall Abstracts =


 
=== Abstract 10/7 ===
 
 
 
==Meetings for Spring 2022==
 
 
<center>
<center>
 
{| style="color:black; font-size:100%" table border="2" cellpadding="10" width="700" cellspacing="20"
{| style="color:black; font-size:120%" border="1" cellpadding="14" cellspacing="0"
|-
|-
! colspan="4" style="background: #e8b2b2;" align="center" | Spring 2022
| bgcolor="#e8b2b2" align="center" style="font-size:125%" | '''Caitlin Davis'''
|-
|-
! Date !! Speaker !! Topic
| bgcolor="#BDBDBD"  align="center" | '''Title: How to Cut a Cake (Fairly)'''
|-
|-
| February 7th || Aleksandra Cecylia Sobieska || <strong>Mathematical Auction</strong>
| bgcolor="#BDBDBD"  |  
We will play a game called “Mathematical Auction,” where teams have the opportunity to solve and steal problems for points by presenting solutions that build on one another.
Imagine you and a friend are sharing a cupcake.  How can you cut the cupcake so that each of you gets your fair share?  If you've ever shared a cupcake (or some other treat) with a friend, you might have an answer!  Now what if you're sharing a cake with several friends?  Can we use the same strategy to cut the cake fairly? We'll talk about how math can be used to study questions like this.
|}                                                                       
</center>


=== Abstract 10/14 ===
<center>
{| style="color:black; font-size:100%" table border="2" cellpadding="10" width="700" cellspacing="20"
|-
| bgcolor="#e8b2b2" align="center" style="font-size:125%" | '''Uri Andrews'''
|-
| bgcolor="#BDBDBD"  align="center" | '''Title: Math, Philosophy, Psychology, and Artificial Intelligence'''
|-
|-
| February 14th || Jake Fiedler || <strong>Fractals in Math and Nature</strong>
| bgcolor="#BDBDBD"  |  
People come to understand the truth via a process of arguing. This could be a philosophical debate. This could be an internal dialogue. This could be in a courtroom. This could be deciding with your family where to go for dinner. These are all different forms of argumentation, with different rules for when you are convinced. In a courtroom, you have to be convinced beyond a reasonable doubt, whereas when deciding where to go for dinner, you might just have to look hungriest to win. These processes can be mathematically modeled. Moreover, this is important for the modern goal of teaching a computer how to think and how to understand human reasoning (Artificial Intelligence).
|}                                                                       
</center>


If you've ever had to clean up branches after a storm, you may notice that the branches look surprisingly like the whole tree they fell from, just at a smaller scale. Similarly, lightning bolts during that storm probably had numerous "arms", each appearing similar to the entire bolt. In this talk, we'll investigate this behavior more closely through objects called fractals. We'll see how fractals are made, where they appear in the real world, and then you'll get a chance to build your own.
|-
| February 21st || Mikhail Ivanov || <strong>Elevator with just 2 buttons.</strong>
There are two buttons inside an elevator in a building with twenty floors. The elevator goes 7 floors up when the first button is pressed, and 9 floors down when the second one is pressed (a button will not function if there are not enough floors to go up or down).


Can we use such elevator? We'll play with this elevator found math behind it.
=== Abstract 10/21 ===
<center>
{| style="color:black; font-size:100%" table border="2" cellpadding="10" width="700" cellspacing="20"
|-
|-
| February 28th || Michael Jesurum || <strong>Bubbling Cauldrons</strong>
| bgcolor="#e8b2b2" align="center" style="font-size:125%" | '''Sam Craig'''
Place our numbers into the cauldrons in ascending order – you can choose which cauldron each one goes in. However, if two numbers in one cauldron add up to a third number in that same cauldron, they bubble up and cause an explosion! This means that all the numbers leave the cauldrons, and you must start all over again. Our goal is to find the largest number we can place in our cauldrons without them exploding… do you think you’re up for this daunting task?
|-
|-
| March 7th || Erika Pirnes || <strong>Reconstructing Graphs</strong>
| bgcolor="#BDBDBD"  align="center" | '''Title: Fractal geometry and the problem of measuring coastlines'''
A graph is a "picture" with dots (called vertices) and lines (called edges). From a graph, we can extract information called the deck. In this talk, we will explore the connection between a graph and its deck, and how we can move from one to the other. We will do a lot of examples! There is a famous conjecture (unproven result) that stays that a graph can always be reconstructed (recovered) from its deck. This is called the reconstruction conjecture. (There are some small restrictions on what the graph can be)
|-
|-
| March 14th || SPRING BREAK || <strong>NA</strong>
| bgcolor="#BDBDBD"  |  
NA
A fractal is a shape which looks about the same when you look closely as when you look far away. I will show some examples of fractals that arise in math (like the Sierpinski triangle) and in nature (like the coastline of an island) and discuss the difficulties in determining what the length of a fractal means.
|-
|}                                                                       
| March 21st || Ian Seong || <strong>Center of a triangle? But which center?</strong>
</center>
It is easy to locate the center of a circle, or regular polygons. How do we define the center for an arbitrary triangle?


In fact, for each triangle, there are many points that can be entitled the "center". We will investigate a few of them (classic examples are circumcenter and incenter) and learn how they are constructed.
=== Abstract 11/4 ===
|-
<center>
| March 28th || Caitlin Davis || <strong>Math and voting: Can math help us make decisions more fairly?</strong>
{| style="color:black; font-size:100%" border="2" cellpadding="10" width="700" cellspacing="20" table
We are often faced with decisions we must make as a group.  For example, a city might need to decide on a new mayor, or you and your friends might need to decide on a movie to watch or a type of pizza to share.  We often use voting to try to make a fair choice.  The voting method which you’re probably used to is called “plurality,” but it turns out there are many other possible voting methods.  Could one of them be more fair than plurality?  We’ll talk about how math can be used to study questions like this.
|-
| April 4th || BREAK || <strong>NA</strong>
|-
|-
| April 11th || Aleksander Skenderi || <strong>Happy Numbers</strong>
| bgcolor="#e8b2b2" align="center" style="font-size:125%" | '''Sam Craig'''
In many areas of mathematics, we look for patterns to describe or model a particular problem. However, sometimes these patterns occur in some late stage of some process, and sometimes not at all! For instance, if a particle of gas is moving around in a container, it may be that, after some time, the gas particle follows an easily described trajectory. It may also be, depending on the initial trajectory, that the gas particle moves totally randomly. In this talk, we'll describe a class of numbers called "happy numbers," and explore some of their properties and patterns.
|-
|-
| April 18th || John Cobb || <strong>Chip-Firing Games on Graphs</strong>
| bgcolor="#BDBDBD" align="center" | '''Title: Proofs of the Pythagorean theorem, new and old.'''
We will play a game called the dollar game, where we will try to clear out debt among a group of people in a funny way. Then, we’ll investigate ways to see when this is possible and how to do it, leading to some unexpected conclusions and a look into a very active area of math called tropical geometry.
|-
|-
| April 25th || Chengxi Wu || <strong>Non integer bases and Paths on colored graphs</strong>
| bgcolor="#BDBDBD" |
We can count in base 10 (decimals) or base 2 (binary), but how about counting in base 5/3, or the golden ratio? We will investigate that via the question of finding possible paths on a graph with colored vertices, and also look at some of the interesting self similar patterns we can get from it!
The Pythagorean theorem has been known for thousands of years and over that time, people have found a number of different ways to prove the theorem. We will talk about a proof given by Pythagoras, a proof by US President Andrew Garfield, and a very recent proof (that you might have heard of in the news) by Calcea Johnson and Ne'Kiya Jackson.
 
|}
|}
</center>
</center>


==Meetings for Fall 2021==
=== Abstract 11/11 ===
 
 
<center>
<center>
 
{| style="color:black; font-size:100%" border="2" cellpadding="10" width="700" cellspacing="20" table
{| style="color:black; font-size:120%" border="1" cellpadding="14" cellspacing="0"
|-
|-
! colspan="3" style="background: #e8b2b2;" align="center" | Fall 2021
| bgcolor="#e8b2b2" align="center" style="font-size:125%" | '''Chenxi Wu'''
|-
|-
! Date !! Speaker !! Topic
| bgcolor="#BDBDBD" align="center" | '''Title:Heron’s method for approximating square roots.'''
|-
|-
| September 20th || Daniel Erman || <strong>Number Games</strong>
| bgcolor="#BDBDBD" |
We will talk about Heron's method for approximating square roots. This will lead us on a journey through approximation methods including Newton's method, through algebraic concepts like the p-adic numbers, and Hensel's Lemma.
|}
</center>


We’ll play some math-based games and then try to understand some of the patterns we observe.
=== Abstract 11/18 ===
<center>
{| style="color:black; font-size:100%" border="2" cellpadding="10" width="700" cellspacing="20" table
|-
|-
| September 27th || Evan Sorensen || <strong> The fastest way to travel between two points </strong>
| bgcolor="#e8b2b2" align="center" style="font-size:125%" | '''Diego Rojas'''
Given two points, we know the shortest distance between the points is a straight line. But is that always true? We will talk about how to build the best track for a toy car to travel between two points.  We’ll start by trying a few different options together and having a race. We’ll then talk about how two brothers thought about how to solve this problem using interesting examples from physics.
|-
|-
| October 4th || Yandi Wu || <strong> Do you wanna build a donut?  </strong>
| bgcolor="#BDBDBD" align="center" | '''Title:Non-Transitive Dice: The Math That Doesn’t Play Fair.'''
Topology is a field of math that deals with studying spaces. This math circle talk is an introduction to a concept in topology called “cut-and-paste” topology, which is named that way because we will build spaces out of cutting and gluing pieces of paper.
|-
|-
| October 11th || Ivan Aidun || <strong> Words, Words, Words </strong>
| bgcolor="#BDBDBD" |
We'll play a game where you have to guess a secret word that I choose.  We'll figure out how to use logic to improve our guesses.  Then, we'll explore some questions like: is there a best way to guess? or, what happens when I change the rules slightly?
What if I told you there’s a set of dice where winning doesn’t follow the rules you expect? In this talk, we’ll explore the strange and surprising world of non-transitive dice, where the usual logic of “if A is better than B, and B is better than C, then A must be better than C” simply falls apart. Using math, probability, and a little imagination, we’ll uncover why these dice defy intuition and how they challenge our understanding of competition and strategy. Get ready to think about games—and math—in a whole new way!
|-
|}
| October 18th || Allison Byars || <strong> Sheep and Wolves </strong>
</center>
In this math circle talk, we'll look at placing sheep and wolves on a grid so that none of the sheep get eaten. We'll find different arrangements and try to figure out the maximum number which can be placed on a board of given size and generalize it for an arbitrary board. We will also discuss how this relates to a field of mathematics called combinatorics.
 
|-
 
| October 25th || Jacob C Denson || <strong>Proofs in Three Bits or Less</strong>
=== Abstract 11/25 ===
How many questions does it take to beat someone at Guess Who? How long should it take for you to figure out how to get to this math talk from your house? How many questions do you have to ask your classmate before you know they're telling the truth to you? Let's eat some pizza, and talk about how mathematicians might reason about these problems.
<center>
|-
{| style="color:black; font-size:100%" border="2" cellpadding="10" width="700" cellspacing="20" table
| November 1st || Qin Li || <strong> How do we describe the world? </strong>
The physical world consists of everything from small systems of a few atoms to large systems of billions of billions of molecules. Mathematicians use different languages and equations to describe large and small systems. Question is: How does mother nature use different languages for different systems and scales? Let us see what these languages look like, talk about their connections and differences, and see how they are reflected in our day-to-day life.
|-
|-
| November 8th || John Yin ||  <strong> River Crossings </strong>
| bgcolor="#e8b2b2" align="center" style="font-size:125%" | '''Kaiyi Huang'''
Here's a classic puzzle: A farmer needs to move a wolf, a sheep, and a box of cabbages across a river. He has a boat that can fit only one object other than himself. However, when left alone, the wolf will eat the sheep, and the sheep will eat the cabbages. How can the farmer move the wolf, the sheep, and the box of cabbages across the river without anything being eaten? I will discuss this problem by connecting it to graph theory, then give a generalization.
|-
|-
| November 15th || Erik Bates || <strong> How big is a cartographer’s crayon box? </strong>
| bgcolor="#BDBDBD" align="center" | '''Title:A geometric investigation into a space shuttle failure'''
Have a look at a world map.  If you are looking at one with borders and colors, notice that no border has the same color on both sides.  That is, no neighboring countries are colored the same.  So how many different colors are needed to make this possible?  Does the answer change for a map of the U.S., when we try to color its fifty states?  What about a map of Wisconsin with its 72 counties?  We will explore these questions---and uncover some very deep mathematics---by doing the simplest and most soothing activity: coloring.
|-
|-
| November 22nd || Robert Walker || <strong>Lagrange's Four Square Sum Theorem</strong>
| bgcolor="#BDBDBD" |
How many perfect squares are needed to represent each nonnegative integer n as a sum of perfect squares? This talk will answer that precise question -- students will get to the bottom of this.
We know that a circle has the same width in every direction, but is it the only object that has this property? NASA engineers assumed so, which, together with a string of other mistakes, might have led to the tragic failure of their space shuttle launch. Let’s look further into this problem so that we won’t make the same mistake again!
|}
|}
</center>
</center>


Line 198: Line 180:
The Madison Math Circle is organized by a group of professors and graduate students from the [http://www.math.wisc.edu Department of Mathematics] at the UW-Madison. If you have any questions, suggestions for topics, or so on, just email the '''organizers''' [mailto:mathcircleorganizers@g-groups.wisc.edu here]. We are always interested in feedback!
The Madison Math Circle is organized by a group of professors and graduate students from the [http://www.math.wisc.edu Department of Mathematics] at the UW-Madison. If you have any questions, suggestions for topics, or so on, just email the '''organizers''' [mailto:mathcircleorganizers@g-groups.wisc.edu here]. We are always interested in feedback!
<center>
<center>
<gallery widths=500px heights=300px mode="packed">
<gallery widths="500" heights="300" mode="packed">
<!--File:de.jpg|[https://www.math.wisc.edu/~derman/ Prof. Daniel Erman]-->
<!--File:Betsy.jpg|[http://www.math.wisc.edu/~stovall/ Prof. Betsy Stovall]-->
File:Uri.jpg|[https://www.math.wisc.edu/~andrews/ Prof. Uri Andrews]
File:Uri.jpg|[https://www.math.wisc.edu/~andrews/ Prof. Uri Andrews]
File: Omer.jpg|[https://www.math.wisc.edu/~omer/ Dr. Omer Mermelstein]
</gallery>
</gallery>


 
<gallery widths="500" heights="250" mode="packed">
 
<gallery widths=500px heights=250px mode="packed">
File: Karan.jpeg|[https://karansrivastava.com/ Karan Srivastava]
File: Colin.jpg|[https://sites.google.com/view/colincrowley/home Colin Crowley]
File: Allison.jpg|[https://sites.google.com/wisc.edu/allisonbyars/ Allison Byars]
</gallery>
</gallery>
</center>
</center>
and [https://math.wisc.edu/graduate-students/ Caitlin Davis] and  [https://math.wisc.edu/graduate-students/ Ivan Aidun].


==Donations==
==Donations==
Line 237: Line 209:


=Useful Resources=
=Useful Resources=
<!--==Annual Reports==
 
[https://www.math.wisc.edu/wiki/images/Math_Circle_Newsletter.pdf  2013-2014 Annual Report]-->
 


== Archived Abstracts ==
== Archived Abstracts ==
[https://www.math.wisc.edu/wiki/index.php/Madison_Math_Circle_Abstracts_2023-2024 2023 - 2024 Abstracts]
[https://www.math.wisc.edu/wiki/index.php/Madison_Math_Circle_Abstracts_2022-2023 2022 - 2023 Abstracts]
[https://www.math.wisc.edu/wiki/index.php/Madison_Math_Circle_Abstracts_2021-2022 2021 - 2022 Abstracts]


[https://www.math.wisc.edu/wiki/index.php/Madison_Math_Circle_Abstracts_2020-2021 2020 - 2021 Abstracts]
[https://www.math.wisc.edu/wiki/index.php/Madison_Math_Circle_Abstracts_2020-2021 2020 - 2021 Abstracts]

Latest revision as of 15:58, 25 November 2024

Logo.png

For the site in Spanish, visit Math Circle de Madison

What is a Math Circle?

The Madison Math Circle is a weekly series of mathematically based activities aimed at interested middle school and high school students. It is an outreach program organized by the UW Math Department. Our goal is to provide a taste of exciting ideas in math and science. In the past we've had talks about plasma and weather in outer space, video game graphics, and encryption. In the sessions, students (and parents) are often asked to explore problems on their own, with the presenter facilitating a discussion. The talks are independent of one another, so new students are welcome at any point.

The level of the audience varies quite widely, including a mix of middle school and high school students, and the speakers generally address this by considering subjects that will be interesting for a wide range of students.


MathCircle 2.jpg MathCircle 4.jpg


After each talk we'll have pizza provided by the Mathematics Department, and students will have an opportunity to mingle and chat with the speaker and with other participants, to ask questions about some of the topics that have been discussed, and also about college, careers in science, etc.

The Madison Math Circle was featured in Wisconsin State Journal: check it out!

All right, I want to come!

Our in person talks will be at, Monday at 6pm in 3255 Helen C White Library, during the school year. New students are welcome at any point! There is no fee and the talks are independent of one another. You can just show up any week, but we ask all participants to take a moment to register by following the link below:

Math Circle Registration Form

All of your information is kept private, and is only used by the Madison Math Circle organizer to help run the Circle.

If you are a student, we hope you will tell other interested students about these talks, and speak with your parents or with your teacher about organizing a car pool to the UW campus. If you are a parent or a teacher, we hope you'll tell your students about these talks and organize a car pool to the UW (all talks take place in 3255 Helen C White Library, on the UW-Madison campus, right next to the Memorial Union).


Fall Schedule

Fall Schedule
Date Location and Room Speaker Title
Oct 7 3255 College Library Caitlin Davis How to Cut a Cake (Fairly)
Oct 14 3255 College Library Uri Andrews Math, Philosophy, Psychology, and Artificial Intelligence
Oct 21 3255 College Library Sam Craig Fractal geometry and the problem of measuring coastlines
Oct 28 3255 College Library Cancelled Cancelled
Nov 4 3255 College Library Sam Craig Proofs of the Pythagorean theorem, new and old.
Nov 11 3255 College Library Chenxi Wu Heron’s method for approximating square roots
Nov 18 3255 College Library Diego Rojas Non-Transitive Dice: The Math That Doesn’t Play Fair
Nov 25 3255 College Library Kaiyi Huang A geometric investigation into a space shuttle failure
Dec 2 3255 College Library TBA TBA
Dec 9 3255 College Library TBA TBA
Dec 16 3255 College Library TBA TBA

Fall Abstracts

Abstract 10/7

Caitlin Davis
Title: How to Cut a Cake (Fairly)

Imagine you and a friend are sharing a cupcake. How can you cut the cupcake so that each of you gets your fair share? If you've ever shared a cupcake (or some other treat) with a friend, you might have an answer! Now what if you're sharing a cake with several friends? Can we use the same strategy to cut the cake fairly? We'll talk about how math can be used to study questions like this.

Abstract 10/14

Uri Andrews
Title: Math, Philosophy, Psychology, and Artificial Intelligence

People come to understand the truth via a process of arguing. This could be a philosophical debate. This could be an internal dialogue. This could be in a courtroom. This could be deciding with your family where to go for dinner. These are all different forms of argumentation, with different rules for when you are convinced. In a courtroom, you have to be convinced beyond a reasonable doubt, whereas when deciding where to go for dinner, you might just have to look hungriest to win. These processes can be mathematically modeled. Moreover, this is important for the modern goal of teaching a computer how to think and how to understand human reasoning (Artificial Intelligence).


Abstract 10/21

Sam Craig
Title: Fractal geometry and the problem of measuring coastlines

A fractal is a shape which looks about the same when you look closely as when you look far away. I will show some examples of fractals that arise in math (like the Sierpinski triangle) and in nature (like the coastline of an island) and discuss the difficulties in determining what the length of a fractal means.

Abstract 11/4

Sam Craig
Title: Proofs of the Pythagorean theorem, new and old.

The Pythagorean theorem has been known for thousands of years and over that time, people have found a number of different ways to prove the theorem. We will talk about a proof given by Pythagoras, a proof by US President Andrew Garfield, and a very recent proof (that you might have heard of in the news) by Calcea Johnson and Ne'Kiya Jackson.

Abstract 11/11

Chenxi Wu
Title:Heron’s method for approximating square roots.

We will talk about Heron's method for approximating square roots. This will lead us on a journey through approximation methods including Newton's method, through algebraic concepts like the p-adic numbers, and Hensel's Lemma.

Abstract 11/18

Diego Rojas
Title:Non-Transitive Dice: The Math That Doesn’t Play Fair.

What if I told you there’s a set of dice where winning doesn’t follow the rules you expect? In this talk, we’ll explore the strange and surprising world of non-transitive dice, where the usual logic of “if A is better than B, and B is better than C, then A must be better than C” simply falls apart. Using math, probability, and a little imagination, we’ll uncover why these dice defy intuition and how they challenge our understanding of competition and strategy. Get ready to think about games—and math—in a whole new way!


Abstract 11/25

Kaiyi Huang
Title:A geometric investigation into a space shuttle failure

We know that a circle has the same width in every direction, but is it the only object that has this property? NASA engineers assumed so, which, together with a string of other mistakes, might have led to the tragic failure of their space shuttle launch. Let’s look further into this problem so that we won’t make the same mistake again!

Directions and parking

Our meetings are held on the 3rd floor of Helen C. White Hall in room 3255.

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Parking. Parking on campus is rather limited. Here is as list of some options:

Email list

The best way to keep up to date with the what is going is by signing up for our email list. Please add your email in the form: Join Email List

Contact the organizers

The Madison Math Circle is organized by a group of professors and graduate students from the Department of Mathematics at the UW-Madison. If you have any questions, suggestions for topics, or so on, just email the organizers here. We are always interested in feedback!

Donations

Please consider donating to the Madison Math Circle. Our main costs consist of pizza and occasional supplies for the speakers. So far our costs have been covered by donations from the UW Mathematics Department as well as a generous gifts from private donors. The easiest way to donate is to go to the link:

Online Donation Link

There are instructions on that page for donating to the Math Department. Be sure and add a Gift Note saying that the donation is intended for the "Madison Math Circle"! The money goes into the Mathematics Department Annual Fund and is routed through the University of Wisconsin Foundation, which is convenient for record-keeping, etc.

Alternately, you can bring a check to one of the Math Circle Meetings. If you write a check, be sure to make it payable to the "WFAA" and add the note "Math Circle Donation" on the check.

Or you can make donations in cash, and we'll give you a receipt.

Help us grow!

If you like Math Circle, please help us continue to grow! Students, parents, and teachers can help by:

  • Like our Facebook Page and share our events with others!
  • Posting our flyer at schools or anywhere that might have interested students.
  • Discussing the Math Circle with students, parents, teachers, administrators, and others.
  • Making an announcement about Math Circle at PTO meetings.
  • Donating to Math Circle.

Contact the organizers if you have questions or your own ideas about how to help out.

Useful Resources

Archived Abstracts

2023 - 2024 Abstracts

2022 - 2023 Abstracts

2021 - 2022 Abstracts

2020 - 2021 Abstracts

2019 - 2020 Abstracts

2016 - 2017 Math Circle Page

2016 - 2017 Abstracts

2015 - 2016 Math Circle Page

2015 - 2016 Math Circle Page (Spanish)

2015 - 2015 Abstracts

The way-back archives

Link for presenters (in progress)

Advice For Math Circle Presenters

Sample Talk Ideas/Problems from Tom Davis

Sample Talks from the National Association of Math Circles

"Circle in a Box"