math research project high school

12 Math Project Ideas for Middle and High School Students

By János Perczel

Co-founder of Polygence, PhD from MIT

6 minute read

Mathematics serves as the foundation for most fields of science, such as physics, engineering, computer science, and economics. It equips you with critical problem-solving skills and the ability to break down complex problems into smaller, more manageable parts. It helps you avoid ambiguity and communicate in what is often called “the universal language,” so-called because its principles and concepts are the same worldwide. Beyond the fact that studying math can open up many career opportunities, some mathematicians also simply find beauty in the equations and proofs themselves.

In this post, we’ll give you ideas for different math research and passion projects and talk about how you can showcase your project.

Finding Your Math Passion Project Focus

Because math is so foundational in the sciences, there are many different directions you can take with your math passion project. Decide which topics within mathematics most speak to you. Maybe you’re more interested in how math is used in sports statistics, how you can harness math to solve global problems, or perhaps you’re curious about how math manifests itself in the physical realm. Once you find a topic that interests you, then you can begin to dive deeper. 

Keep in mind that some passion projects may require more technical skills, such as computer programming, whereas others may just explore theoretical concepts. The route you take is totally up to you and what you feel comfortable with, but don’t be afraid to pursue a project if you don’t currently have the technical skills for it. You can view it as an opportunity to learn new skills while also exploring a topic you’re excited about.

Do your own research through polygence

Polygence pairs you with an expert mentor in your area of passion. Together, you work to create a high quality research project that is uniquely your own.

12 Math Research and Passion Project Ideas

1. the mathematical properties of elections.

In recent years, there has been a lot of discussion about which election mechanism is most effective at achieving various goals. Proposed mechanisms in United States elections include majority elections, the electoral college, approval voting, and ranked-choice voting. All of these mechanisms have benefits and drawbacks, and it turns out that no perfect election mechanism exists. Look at the work being done by mathematicians to understand when elections fail, and what can be done to improve them. Choose the strongest mechanism and use evidence to support your claim.

Idea by math research mentor Grayson

2. Knot theory

A knot is simply a closed loop of string. Explore how mathematicians represent knots on a page. Learn how knots can be combined, and how to find knots that can't be created by combining other knots. You can learn techniques for determining whether or not two knots are distinct, in the sense that neither can be deformed to match the other. You can also study related objects, such as links and braids, and research the application of knots in the physical sciences.

Idea by math research mentor Alex

3. Bayesian basketball win prediction system

The Bayes’ Rule is crucial to modern statistics (as well as data science and machine learning). Using a Bayesian model to predict the probability distribution of basketball performance statistics, you can attempt to predict a team’s win and loss rate versus another team by drawing samples from these distributions and computing correlation to win or loss. Your project could be as simple or as complicated as you want. Based on your interest and comfort level, you could use simple normal models, mixture models, Gibbs sampling , and hidden Markov models. You can also learn how to code a fairly simple simulation in R or Python. Then, you’ll need to learn how to interpret the significance of statistical results and adjust results over time based on the success/failure of your model over time.

Idea by math research mentor Ari

4. Finding value in Major League Baseball free agency

Here’s another sports-related project idea. Every offseason, there are hundreds of professional baseball players who become free agents and can be signed by any team. This project involves determining which players might be a good "value" by deciding which statistics are most important to helping a team win relative to how players are generally paid. After deciding which stats are the most important, a ranked list of "value" can be produced based on expected salaries.

Idea by math research mentor Dante

5. Impact of climate change on drought risk

Are you interested in environmental economics, risk analysis, or water resource economics?

You can use historical data on precipitation, temperature, soil moisture, drought indicators, and meteorological models that simulate atmospheric conditions to train a machine-learning model that can assess the likelihood and intensity of droughts in different regions under different climate scenarios. You can also explore your assessments' potential adaptation strategies and policy implications. This project would require some skills in data processing, machine learning, and meteorological modeling.

Idea by math research mentor Jameson

Go beyond crunching numbers

Interested in Math? We'll match you with an expert mentor who will help you explore your next project.

6. Making machines make art 

You can program a computer to create an infinite number of images, music, video game levels, 3D objects, or text using techniques like neural style transfer, genetic algorithms, rejection sampling, Perlin noise , or Voronoi tessellation . Your challenge then is to create a functioning content generator that you could then showcase on a website, research conference, or even in a gallery exhibition.

Idea by math research mentor Sam

7. Measuring income inequality and social mobility

If you’re interested in the intersection of mathematics and public policy, here’s an idea. Use data from the World Bank, the Organization for Economic Co-operation and Development (OECD), and other sources to calculate the Gini coefficient and the intergenerational elasticity of income for different countries and regions over time. Explore the factors that influence these measures and their implications for economic development and social justice. You will need to have some skills in data collection, analysis, and visualization.

8. Rocket (fuel) science

Rockets are mainly made out of fuel. When the fuel burns, it gets heated and expelled out, producing thrust. Fuel is heavy and, for long-range space missions, we need to carry around the fuel for the rest of the mission the whole way. It is important that the fuel gives us the most bang for our buck (i.e., the most acceleration per unit of fuel). Compare the amount of fuel (weight) required to get to various celestial objects and back using current electric and chemical propulsion technologies . Then do a cost analysis and compare how long it would take.

Idea by math research mentor Derek

9. COVID-19 and the global financial crisis

It is shocking how the economic effects of COVID-19 have far outweighed the ones from the Global Financial Crisis in 2007-08 . How much is the difference in terms of employment? Production? Let's go to the data!

Idea by math research mentor Alberto

10. Modeling polarization in social networks

We've all seen or heard about nasty political arguments and echo chambers on social media, but how and why do these happen? To try and find out, construct a mathematical and/or computational model of how people with different opinions interact in a social network. When do people come to a consensus, and when do they become more strongly divided? How can we design social networks with these ideas in mind?

Idea by math research mentor Emily

11. The world of mathematics

The history of mathematics dates all the way back to the very first civilizations and followed throughout history all over the globe. This development leads us to our way of living and thinking today. Rarely taught in math courses, the origins of math can provide clear insight into the necessities of learning math and the broad applications that math has in the world. Conduct research on a chosen time period, location, or figure in mathematics and describe the impacts this innovation or innovator had on the development of math as we know it today.

Idea by math research mentor Shae

12. Simulating the stock market

Here’s an idea for a beginner-to-intermediate statistics and programming project centered around Monte Carlo simulations. Monte Carlo simulations are random methods for modeling the outcome of a complicated process. These methods are used in finance all the time. How could you code a program that uses the Monte Carlo technique to "simulate" the stock market? You will need some familiarity with statistics, basic finance, and basic programming in any language to complete this project.

Idea by math research mentor Sahil

Showcasing Your Math Passion Project

After you’ve done the hard work of completing your mathematics passion project, it’s also equally important to showcase your accomplishments . You can see that in many of the project ideas above, there is a clear topic, but how you want to present the project is open-ended. You could try to publish a research paper , create a podcast or infographic, or even create a visual representation of your concept. You’ll find that although many project ideas can simply be summarized in a paper, projects can also be showcased in other creative ways.

Polygence Scholars Are Also Passionate About

Examples of math passion projects completed by polygence students.

There are several examples of math projects Polygence students have completed through enrolling in our programs; we’ll highlight two here.

Ahmet's mathematical passion project offers detailed breakdowns of the first introduced quantum algorithm Deutsch-Jozsa, and the first quantum algorithm proven to be faster than classical algorithms, Grover’s Algorithm. It also includes a side-by-side comparison of the quantum algorithms and their classical counterparts. He uploaded his paper on Github and plans to submit it to an official publication soon.

Anna’s finance project provides an overview of topics related to personal finance, covering tax and benefits, tax-deferred savings, interest rates, cost of living, investing, insurance, and housing to help young adults manage their savings. To further her understanding of how different areas of finance influence one's life consumption, she created a life consumption plan for a hypothetical person and produced a paper. 

Getting Guidance and Support on Your Math Project

In this post, we covered how to find the right mathematics project for you, shared a dozen ideas for physics passion projects, and discussed how to showcase your project.

If you have a passion for math–or are generally curious about exploring mathematical concepts–and are interested in pursuing a passion project, Polygence’s programs are a great place to start. You’ll be paired with a mathematics research mentor with whom you’ll be able to meet one-on-one. Through these virtual mentorship sessions, your mentor can help you learn new concepts, troubleshoot issues you encounter along the way to bringing your math project to completion, and brainstorm with you on how to showcase your passion project .

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Virtual Math Circle: Research Opportunities for High School Students

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• Paid Mentorships
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Math Circle virtual summer camps bring together rising 9th–12th grade math enthusiasts to:

• learn material not typically taught in a high school curriculum;
• traverse the complex world of college mathematics;
• conduct mathematical research with guidance from university faculty and graduate students;
• present a 45-minute, colloquial-style poster session;
• hone research and communication skills through a capstone project.

Each student project may potentially:

• qualify as a fall science fair project;
• evolve into deeper research experiences with faculty;
• merit financial support towards future travel to conferences, or for publication costs;
• enhance college applications.

Math Circle virtual summer camps are an outreach collaboration between the LSU Department of Mathematics and the LSU Gordon A. Cain Center for STEM Literacy .

Work with a mentor and peers

At the start of the summer camp, research mentors give virtual talks on their area of research and potential research topics. Students in groups of 4 will meet virtually with their mentor, Monday–Friday for 2–3 hours each day, for a duration of 3 weeks. Students will be exposed to a wide variety of topics in each field and will gain a solid foundation in university-level mathematics.

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Contact Isaac Michael <[email protected]> .

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Back to Research-Based Educational Programs

Wolfram High School Summer Research Program

Formerly known as the Wolfram High School Summer Camp

Bentley University , Boston, MA June 25–July 13, 2024

A project-based research opportunity for motivated high-school students to move beyond the cutting edge of computational thinking and artificial intelligence.

The Wolfram High School Summer Research Program is an intensive two-week program designed to advance high-school students' programming and problem-solving skills. Through a curriculum of active-learning activities, hands-on workshops and lectures, students explore the power of modern computation and deep dive into STEM fields while gaining mastery of Wolfram Language, computational thinking and research skills.

Under the guidance of expert mentors, students research and implement solutions to cutting-edge problems selected in collaboration with Stephen Wolfram. Projects are novel contributions to the field and are personalized to the students' interests and skill sets. Each student writes a computational essay and an interactive research paper and publishes their work at the end of the program. Successful projects can be submitted to STEM competitions, turned into academic papers or presented at the Wolfram Technology Conference.

This program was brilliant for research, and I got to meet so many great, qualified people here at Wolfram. From selecting my project topic with Stephen Wolfram to talking with my mentor about technical concepts and my college trajectory, I gained so much knowledge from this program.

Hyunjae Chung

This was not only an academically enriching experience but also an introduction to an incredibly bright community of dedicated, driven and kind people. Perhaps even more important than the practical skills gained and excellent work that each student came away with from their projects, this program was an opportunity to connect like-minded and truly passionate students and experts from around the world and develop lasting connections.

Victor Zhou

I'm so glad I was given this experience. I now know that it's very possible to explore on your own and make your own projects. We were given the opportunity to talk with so many knowledgeable people who answered so many of our questions, no matter how technical or philosophical.

Arianna Cao

After the summer, successful students enter our ecosystem of education opportunities. This may include doing an advanced project at the Wolfram Emerging Leaders Program , joining our teaching team, connecting with professional mentors or engaging with fundamental physics and metamathematics research at the Wolfram Institute . Particularly successful students are invited to complete internships at Wolfram Research.

We are seeking motivated high-school students interested in solutions-driven research and creating innovative technology. As we are committed to enabling ambitious students, regardless of background or resources, we provide needs-based scholarships and offer a pre-programming workshop for students with limited coding experience.

Featured Projects

Generating animated guitar tutorials

My project uses chords or MIDI files as input and creates an animated tutorial video. My implementation finds the pitches that match a chord on the fretboard in a localized area. To account for some commonly used patterns, I use the CAGED system on guitar. This project also includes an implementation of major scale patterns and tab sheet implementation.

Nikhil Mani

Class of 2023

Multiway sequential cellular automata

The study of cellular automata is useful for modeling many evolving systems. In my project, I examine a novel variant of cellular automata that uses sequential updating with multiple sets of rules, resulting in multiway sequential cellular automata. This structure has the potential for modeling many aspects of quantum mechanics, including possibly quantum spin chains. A deeper exploration highlights the impact of specific subsets of multiway circular sequential cellular automata rules on the directionality, behavior, symmetry and causal invariance of the resulting states graphs.

Margaux Wong

Class of 2022

Generate Super Mario Bros. levels

Super Mario Bros. is one of the top-selling video games of all time and is known for its excellently designed platforming levels, which pioneered the platforming video game genre. My project uses a convolutional neural network to help determine whether an array is a Mario level and to generate them using levels from Super Mario Bros. and its sequel Super Mario Bros.: The Lost Levels.

Samion Suwito

Implementing counter machines

The objective of this project was to implement counter machines in Wolfram Language and establish which counter machine was the most unpredictable. I designed a general counter machine function and used this function to demonstrate five types of counter machines. I determined which counter machines were unpredictable and explored complexity by adding more registers.

Samikshaa Natarajan

Class of 2021

Building a graph-based reaction network

When performing syntheses in a lab, it can be challenging to find the shortest path and to avoid exceptions and pitfalls. A computational system for predicting synthesis pathways can help take the burden off of a chemist and can allow for more consistent results. By transcribing common reactions computationally and applying them recursively, a network can be generated to inform decisions in the lab. My project focused on building the groundwork for this in Wolfram Language, providing informative and computationally significant results and paving the way for comprehensive computational synthesis design.

Joseph Stocke

Automatic Metrical Scansion of Latin Poetry in Dactylic Hexameter

Many significant works of Latin poetry follow the format of dactylic hexameter, meaning that each line is composed of some combination of six metrical feet, each of which is either two long syllables or a long syllable followed by two short syllables. Scansion is the process of identifying the pattern of syllable lengths. Through this project, I use machine learning to scan lines of Latin poetry in dactylic hexameter.

Class of 2019

Colorful Fraud: Exposing Vulnerabilities in Neural Networks

In a day and age where many consider deep learning an off-the-shelf solution to any and all classification/prediction problems, it's important that people examine whether their neural network models are vulnerable to targeted attacks. This project implements a framework for generating adversarial examples: input data crafted to cause the neural network to produce unexpected or targeted incorrect behavior.

Projects From the Wolfram Summer Research Program

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Summer 2024 Admissions Open Now. Sign up for upcoming live information sessions here (featuring former and current Admission Officers at Havard and UPenn).

5 Free Virtual Research Opportunities For High School Students

Virtual research opportunities for high school students are programs that provide hands-on experience and research projects in various STEM fields, such as mathematics, computer science, computational biology, physics, neuroscience, and engineering. These programs are designed to deepen students’ understanding of STEM and help them develop the skills needed to succeed in their academic and professional careers. 

Participating in these programs can also help high school students expand their knowledge and skills in their areas of interest and work on exciting, unsolved problems with established researchers from top-tier universities. 

Virtual research opportunities are especially useful for high school students who are unable to attend in-person programs due to distance, cost, or other factors. They offer a flexible and accessible way to gain valuable experience and knowledge from the comfort of their own homes. In this article, we will discuss five free virtual research opportunities available for high school students.

1. MIT Primes  

MIT PRIMES is a free, year-long after-school program that provides research projects and guided reading to high school students in the areas of mathematics, computer science, and computational biology. The program is designed for students living within driving distance from Boston, and it offers four sections: PRIMES, PRIMES-USA, Menezes Challenge PRIMES Circle, and Yulia’s Dream.

PRIMES is a research-focused program in which participants work with MIT researchers to solve exciting, unsolved problems. PRIMES-USA is a distance mentoring math research section for high school juniors and sophomores from across the United States. Menezes Challenge PRIMES Circle is a math enrichment section for underrepresented groups living within commuting distance from Boston. Yulia’s Dream is a math enrichment and research program for exceptional high school students from Ukraine.

In addition to these sections, PRIMES runs two collaborative initiatives: MathROOTS, a two-week summer program for high-potential high school students from underrepresented backgrounds or underserved communities, and CrowdMath, a year-long online collaborative research project open to all high school and college students worldwide.

Finally, PRIMES STEP is a year-long math enrichment program for middle school students from Greater Boston.

Overall, MIT PRIMES aims to provide challenging and engaging opportunities for students with a passion for mathematics and science. Through research projects, guided reading, and collaborative initiatives, PRIMES seeks to foster the intellectual growth and development of high school and middle school students, and to inspire them to pursue their interests in these fields.

MIT PRIMES is a prestigious year-long after-school program that offers research projects and guided reading to high school students interested in mathematics, computer science, and computational biology. 

The admissions for the 2023 cycle are closed, and the admission decisions are made by February 1. However, for the 2024 cycle, new problem sets will be posted on October 1, 2023, and applicants will have until November 30, 2023, to solve the relevant problem set(s). 

To apply for MIT PRIMES, you must be a high school student (or a home-schooled student of high school age) living in the Greater Boston area, able to come to MIT weekly from February to May.

To apply, you need to fill out a questionnaire, ask for two or three letters of recommendation, and submit your solutions of the PRIMES problem set. Applicants to the Math section must solve the Math problem set (at least 70%), and applicants to the Computer Science and Computational Biology sections must solve the Computer Science problem set (100%) and the General part of the Math problem set (at least 70%). Admission decisions are based on all components of your application, and there is no application fee.

MIT PRIMES suggests a list of recommended readings as a preparation for entering the program and as a background for further research. By participating in MIT PRIMES, students can gain hands-on experience working on exciting, unsolved problems with MIT researchers and expand their knowledge and skills in these areas.

The Summer Academy for Math and Science (SAMS) is a program that provides opportunities for underrepresented high school students to explore STEM fields. The program is designed to deepen students’ understanding of STEM through traditional classroom instruction, hands-on projects, and sustained engagement with faculty and staff mentors. 

SAMS Scholars are taught by renowned faculty and staff who are deeply committed to their success. They also have the opportunity to collaborate and develop meaningful relationships with peers from across the country. Through SAMS and other outreach initiatives, the program aims to develop a diverse and supportive community of STEM Scholars interested in attending top-tier universities.

The program consists of two parts: Part one is a virtual jumpstart that will occur prior to the start of the residential program. This will focus on skill-building that will be needed for the in-person program. Part two is a 5-week in-person Pre-College program where students will move into the residence halls and attend full days of courses and meetings. The academic portion of the program will conclude with a symposium, and students will move out of the residence halls at the end of the program. 

SAMS is a fully funded, merit-based program, and there is no cost for scholars to participate. To be eligible for the program, students must be at least 16 years old, a U.S. citizen or permanent resident, and a junior in high school at the time of application submission. Scholars are expected to participate fully for the duration of the program and cannot participate in any other programs if selected for SAMS.

3. University of Illinois – High School Summer Research Program

The High School Summer STEM research program invites current 9th-11th graders from Illinois, Indiana, Kentucky, Missouri, Iowa, or Wisconsin to apply for an authentic six-week STEMM research experience at a world-class research university. Participants will be matched with another student, and in some cases, a teacher from their school. 

The program aims to provide hands-on experience in various STEMM fields, including cancer immunology, neuroscience, artificial intelligence, physics, quantum mechanics, bioengineering, and electrical engineering.

Participants will work with established researchers in engineering, computer science, and medicine and attend weekly seminars on topics such as college admission processes and support available, communicating scientifically, and preparing research posters etc. Students will also interact with faculty, post-doctoral researchers, graduate students, undergraduate students, and local high school teachers.

Participants will showcase their research with a research poster and symposium at the end of the program. They should plan for 30-35 hours per week of research and professional development time, with a majority of activities taking place on the University of Illinois campus. 

The program covers some transportation/parking expenses, meals, and a monetary award.

High school teachers play an essential role in the program, with some research projects requiring a teacher to be a co-researcher, and others having a teacher mentor who checks in weekly with the students to discuss their research progress and address any issues or challenges. 

Teachers and students do not need to come from the same school, and interested individuals should apply regardless of whether they can recruit others from their school to apply.

The program also invites research faculty, staff, and graduate student researchers affiliated with The Grainger College of Engineering and the Carle Illinois College of Medicine to propose a high school research project for consideration. The proposals will be mentored by POETS YS, GEnYuS, or SpHERES research teams, which will guide two high school juniors/seniors from limited understanding to completion of a related project of their own and poster presentation explaining their research.

In summary, the High School Summer STEM research program provides high school students with an opportunity to engage in authentic STEMM research and develop professional and college-ready skills. Participants work with established researchers, attend weekly seminars, and showcase their research at the end of the program. 

The program aims to provide hands-on experience and build confidence in students as scientists and engineers.

4. Simons Summer Research Program

The Simons Summer Research Program is a highly selective program that offers high school students the opportunity to conduct hands-on research with Stony Brook faculty mentors. Founded in 1984, the program attracts applicants from all over the country, with Simons Fellows being paired with a faculty mentor, joining a research group or team, and taking responsibility for a project. Students are encouraged to demonstrate independence, creativity, and an aptitude for hands-on work, with a strong interest in science. The program takes place during the summer before the student’s senior year of high school, with students participating in the program from June 26, 2023 to August 11, 2023.

In addition to working on their research project, Simons Fellows attend weekly faculty research talks, special workshops, tours, and events. At the closing poster symposium, students present their research project through a written research abstract and a research poster. Participants receive a stipend award.

The Simons Summer Research Program is supported by the Simons Foundation and is open to US citizens and/or permanent residents who are at least 16 years of age by the start of the program. The program is an opportunity for high school students interested in science to learn valuable techniques, experience life at a major research university, and develop independence, creativity, and an aptitude for hands-on work. The program aims to give students a glimpse into the world of scientific research and inspire them to pursue careers in science.

5. EnergyMag Internship

EnergyMag is offering virtual internships for high school and college students interested in increasing the share of renewable energy in the world and gaining work experience in the energy storage industry. 

The internships aim to provide students with research and analysis skills that will be valuable for their future professional lives. The virtual internship allows students to complete their internship hours virtually, providing flexibility to fit the experience into their busy personal and professional lives. Additionally, virtual interns enjoy the unique rewards of learning from experts regardless of their geographic location and strengthening their information and computer skills. 

The internships are strong resume boosters for employers, graduate college programs, and undergraduate programs. 

EnergyMag offers half-time and quarter-time virtual internships. Half-time internships are available in the summer for two to eight weeks, with interns expected to work approximately 20 hours per week. Quarter-time internships are available all year round for one to nine months, with interns expected to work approximately eight hours per week. The internships are unpaid, and interns work from home while maintaining daily electronic contact with EnergyMag and their mentor. 

Depending on the student’s graduation date, academic record, and experience, interns will be asked to research and analyze a specific company, technology, or market. The intern will be mentored, briefed, supervised, and assisted in producing a draft analysis report. If the report is publishable, EnergyMag will give the intern an internship Letter of Accomplishment. 

The application process for college and high school internships requires an application explaining why EnergyMag should grant an internship, a Skype or voice interview, and a writing sample upon request. College interns are also required to provide their academic record, and high school interns should have at least one honors science or English class with a GPA above 3.25. 

EnergyMag believes that internships provide the opportunity for students to learn on-the-job skills that are not easy to acquire at school but will make a big difference in their future professional success, such as learning how to research a scientific or business issue, approach strangers with positions of authority in a friendly and professional manner, analyze and synthesize information from multiple sources, and communicate professionally in writing.

The blog highlights five virtual research opportunities for high school students, providing hands-on experience and research projects in various STEM fields such as mathematics, computer science, physics, neuroscience, and engineering. These virtual research opportunities aim to provide students with a deeper understanding of STEM and develop the necessary skills to succeed in academic and professional careers. Furthermore, these programs help expand knowledge and work on unsolved problems with established researchers from top-tier universities.

Virtual research opportunities for high school students provide a flexible and accessible way to gain valuable experience and knowledge from the comfort of their own homes. These programs aim to foster the intellectual growth and development of high school and middle school students, and inspire them to pursue their interests in these fields.

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Math Project Ideas for High School

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Are you tired of hearing, “When will we ever use this type of math?” Explore the world of applied math with these math projects for high school students.

High School Math Project Ideas by Subject

Math projects are an ideal way to increase your students’ enthusiasm for math.

Math is not a dull subject! With these math projects, students will use the skills of research, problem-solving, critical thinking, and creativity.

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Algebra Math Project Ideas

These algebra math project ideas for high school bring algebra into the real world.

Modeling Real-World Situations

Are your students interested in the population of endangered species? Or the growing population of the planet?

Are they curious about investing and seeing their money grow?

Teach them to create mathematical models of real-life situations and use these tools to analyze the data.

Data Analysis and Statistics

Students can collect data on a topic of interest, such as sports, weather patterns, or social media usage, and perform statistical analysis using algebraic techniques.

They can create scatter plots, calculate regression lines, analyze correlation coefficients, and draw conclusions based on their findings.

Fantasy Football Mathematical Modeling

Do you have students who love fantasy football?

Give them an edge by incorporating algebra!

Students can use algebraic concepts to analyze various aspects of the game.

They can explore topics such as scoring trends, player performance evaluation, or game strategies using mathematical models and statistical analysis.

Algebraic Art

On graph paper, students can plot various algebraic functions (linear, quadratic, or exponential).

(You could also use a digital graphing program.)

Where the functions overlap, color the shapes.

Explore symmetry, transformations, and creativity through this combination of math and art!

Financial Literacy Project

Students pick a future career and a hypothetical budget based on that income.

Use algebraic equations to calculate savings, loan payments, and interest.

Explore the concepts of compound interest and debt repayment.

Geometry Math Project Ideas

These geometry math project ideas for high school highlight all that is weird and wonderful about shapes!

Exploring Fractals

Fractals are fascinating! They involve a shape that branches into smaller versions of itself.

They are found in nature (think ferns and snowflakes), have applications to tech, and make for incredible artwork!

Check out some digital art involving fractals.

Students can research and create visual representations of different fractals, such as the Sierpinski Triangle, Koch Snowflake, or Mandelbrot Set.

Investigating Polyhedra

Students can study different types of polyhedra, such as platonic solids or Archimedean solids.

They can construct physical models (straws and pipe cleaners, anyone?).

They can also use software to explore their properties, such as the number of vertices, edges, and faces.

Students can learn about their various patterns of symmetry.

Designing a Geometric City

Students can design a fictional city using geometric principles.

They can create a layout for the city, incorporating different shapes, angles, and proportions.

Make the project cross-curricular by creating a story of life in the fictional city.

Urban Planning

Students can explore how geometric concepts are applied in urban planning and architecture.

Which cities of the world are the most geometric in their design?

Which architectural styles are the most “Euclidean”?

Analyzing Tessellations

Students can investigate tessellations and their properties. This is an excellent jumping-off point to the various types of symmetry.

They can create their own tessellation patterns using regular polygons or explore famous examples of tessellations found in art and nature.

Geometry in Art

Students can explore the relationship between geometry and art.

They can research different artists who incorporate geometric principles in their work, such as Piet Mondrian or M.C. Escher.

(You can even find fractals in Jackson Pollock paintings!)

They can analyze the use of symmetry, proportion, and geometric shapes in these artworks.

Go one step further and have students create their own geometric art pieces.

Calculus Math Project Ideas

Calculus helps us understand our world. Make it come alive with these calculus math project ideas for high school students.

Optimization Problems

How does calculus intersect with the real world? Knowing calculus can save money!

It has implications in product design and even backyard projects!

Students can explore optimization problems by finding functions’ maximum or minimum values in various contexts.

They can explore real-world scenarios, such as maximizing the volume of a box given a fixed amount of material or minimizing the cost of constructing a fence.

The Trouble with Tribbles

(Okay, okay, this is a Star Trek reference no student will likely get.)

You can riff on this episode with fun exponential growth or decay scenarios.

(In fact, Fibonacci himself conceptualized his sequence by imagining a colony of rapidly mating rabbits.)

Students can use calculus to analyze the growth or decay of their imaginary species.

The Shape of Water

Calculus is geometry’s much cooler big brother.

Bring in three-dimensional shapes (like water bottles, bowling pins, etc.) and show students how to find the surface area of these shapes using integral calculus.

They can then try it on their own!

Calculus in Physics

Students can explore the application of calculus in physics problems.

They can choose topics such as motion, forces, or energy and use calculus concepts to analyze these phenomena.

Have them give a demonstration of these applications to the class.

Calculus in Engineering

Students can explore how calculus is used in engineering applications.

They can choose topics such as fluid flow, structural analysis, or electrical circuits and use calculus to model and solve engineering problems.

Calculus in Tech

Explore how technology uses calculus (for example, GPS and image processing).

Analyze algorithms and mathematical models. What are the limitations? How can this technology improve?

High School Math Project Ideas

These math projects for high school will help your students see the purpose (and fun) in math).

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21-st century mathematics

Math Research Program

Program for ambitious high school students

Guided research

Gain expertise in a topic under the mentorship of a PhD student. Stand out for admissions. Make an impact on the world.

Taught by the best in the world

Mentor universities

MIT, Harvard, Stanford, UC Berkeley, and more

Our students go on to be leaders

Student acceptances

MIT, Stanford, UChicago, Cornell, Brown, and more

Hear from our satisfied students

Testimonials

"My mentor opened a door to the world of differential equations for me and provided insights on much more challenging mathematics, driving me to pursue mathematics further." - Daniel "I had a great time working with my Research Mentor – it was incredibly enjoyable and produced a tangible result of a research paper from eight weeks of study together." - Aanya "Learning under my Research Mentor was an absolute pleasure. I would gladly recommend the program to any fellow students looking to deepen their knowledge and enrich their love for mathematics." - Domenic

 10 Best School Project Ideas High School For Every Subject

1. science : create an experiment demonstrating a scientific principle., 2. math : develop a practical application of a mathematical concept., 3. english literature : analyze a classic novel or poem through a modern lens., 4. history : produce a documentary on a significant historical event or figure., 5. art: create a portfolio showcasing different artistic techniques or styles., 6. computer science : design a software application to solve a real-world problem., 7. foreign language : produce a short film or presentation entirely in the target language., 8. physical education : develop a fitness program tailored to specific fitness goals., 9. social studies : organize a debate or simulation on a current global issue., 10. home economics : cook a meal from a different culture, incorporating nutritional analysis., discover more stories.

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Breaking News

Kayaker ok after overturning in the snake river, fort hall high school students working to go ‘back into space’.

Logan Ramsey, EastIdahoNews.com

FORT HALL — The students, faculty and administration at Shoshone-Bannock Jr./Sr. High School are working to advance the STEM program and someday return to space.

For the last three years, students have been doing hands-on projects advancing their knowledge of science and technology as part of a career technical education and job placement program with the Idaho National Laboratory. Their efforts earned them a 2024 STEM Impact Award last month at the fourth annual Idaho EcosySTEM .

The students showcase these projects at a STEM night held twice a year. The last one was held on May 2.

“Technology, it’s all gonna be the future,” said Matt Wilson, principal of Shoshone-Bannock Jr./Sr. High School. “It’s really bringing us up to date with where the future is going.”

The partnership with the INL started in 2021,

But this isn’t the first time Fort Hall students have worked on projects in the field of science and technology. A teacher and students from the school had their research project launched aboard the space shuttle Discovery nearly 30 years ago.

This launch in 1998 was not just the first Native American-created payload sent into orbit, but the first one by high schoolers, according to Dave Archuleta, Chairman of the Shoshone-Bannock School Board.

Students built and designed a system to mix phosphate and water in space to create a fertilizer that could aid future interstellar settlers trying to grow food on another planet. Ed Galindo , a now retired science teacher at the school, helped students submit the project to NASA and get it approved.

When reflecting on this past project, Archuleta thought it was something students could do again.

“I want to get our kids back into space,” Archuleta said.

It turned out plenty of other people wanted that same thing, including INL and school officials. After the school reached out to the laboratory, they worked together to create the career technical education program.

At the forefront of implementation was Mikel Green, the science teacher and STEM coordinator. She said having the students work on their own projects has advanced the student’s education.

“Our students are hands on learners that need to learn tools to be successful both in the community and outside of the community,” Green said. “I just really wanted to get the students engaged and offer more opportunities that allowed them to further careers and more schooling.”

The school offers a host of STEM related programs, from training in and access to welding, 3-D Printers and drones. Students at the school also have the opportunity to take an internship at INL with other students across eastern Idaho.

The school is currently working to receive a STEM accreditation, which would offer students the ability to graduate with a technical diploma.

The school is collecting evidence and documentation of everything they’ve implemented at the school for when it comes time to apply. Wilson said that even after that point, the school won’t stop working to advance its program.

“I think it’s just gonna be something on paper to say, okay, this is official,” Wilson said. “We’re not going to be slowing down anytime soon.”

Jennifer Jackson, the K-12 education programs manager at INL, said the laboratory is already likely to hire some of the students who are participating in the school’s STEM program.

“That is the plan. So we know that if they have gone through our programming that we’ve created and come and been able to work alongside the professionals here, I know they would be prepared for entry level positions,” Jackson said.

Ultimately, the students are still inspired by what Galindo and his students accomplished.

In Green’s physics class, the students build and launch rockets every year.

“If we had the opportunity to make something that goes on a space shuttle again, that would definitely be something up our alley,” Green said.

Archuleta has no doubt the school’s current students could accomplish what Galindo’s students did.

“One of those young people today might have the answer to climate change. One of these young people today might be the next space pioneers. We don’t know. All I know is that it’s our job as a school board to provide them with the tools necessary to be able to accomplish all these great things,” Archuleta said.

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Faculty and Staff Grants From March 2024

University of denver, congratulations to the university of denver faculty and staff members who received grants and awards in march 2024 for the following projects..

Synthetic Protein Mimetics-Based Specific Targeting and Degradation of TDP-43 Aggregation Associated With ALS

• Sunil Kumar and Daniel Linseman , College of Natural Sciences & Mathematics
• Grant from U.S. Department of Defense
• Abstract: There are no effective treatments to cure or halt the progression of ALS disease, which is a common neurodegenerative disease characterized by the loss of motor neuron functions. One of the main causal agents associated with ALS pathology is the clumping of a neuronal protein called TDP-43 into aggregates. Therefore, the modulation of the aggregation of TDP-43 is considered to be a potential therapeutic intervention for ALS disease. We propose a novel two-pronged approach using synthetic protein mimetic molecules to modulate the TDP-43 aggregation. Overall, we believe that the completion of this study will empower the translation of drug-like ligands identified in our lab to potential lead therapeutics for the treatment of ALS.

Collaborative Research: Superinvaders: Testing a General Hypothesis of Forest Invasions by Woody Species Across the Americas

• Patrick Martin , College of Natural Sciences & Mathematics
• Grant from National Science Foundation
• Abstract: The main objective of this project is to better understand the functional constraints that drive adaptive trade-offs among woody species, using systematic observations and experiments across light gradients in temperate, subtropical and tropical forest. Our approach is transformative because it would test a new theory that integrates plant functional physiology and food web dynamics in a whole-plant carbon allocation framework.

Advocates for Recovery Colorado, Peer Recovery Support Services Expansion

• Meredith Silverstein , Graduate School of Social Work
• Grant from Advocates for Recovery Colorado (subaward City and County of Denver)
• Abstract: Advocates for Recovery Colorado (AFRC) is Colorado’s first and oldest recovery community organization. Since 2001, AFRC has provided no-cost peer recovery coaching and peer recovery support services to anyone regardless of stage of recovery or chosen recovery pathway. In alignment with Denver Public Health and Environment’s Treatment/People in Additional Areas Strategy Area, AFRC will achieve two key goals over the three-year funding period: expansion of services in Denver through the relocation of its recovery community center and expansion of services to people of color who are increasingly impacted by opioid misuse and overdose.

CueThinkEF+ - Phase 4 and 5 Partnership

• Stephen Hutt , Ritchie School of Engineering & Computer Science
• Grant from CueThink
• Abstract: The team will develop the EF Training feature during Phase 4, so that they will be ready for incorporation into a Phase 4 evaluation study that will allow for features to be rolled out and tested in an iterative manner.

Understanding Personal, Social Network and Neighborhood Environmental Contributors to Gun Access and Violence Among Young Adults Experiencing Homelessness

• Anthony Fulginiti , Graduate School of Social Work
• Grant from University of North Carolina (subaward Centers for Disease Control & Prevention)
• Abstract: Firearm-involved violence is an urgent public health issue in many major cities across the U.S., and youth experiencing homelessness (YEH) are especially vulnerable to violence, including firearm-involved violence. However, little research has focused on firearm risks among YEH. In fact, virtually nothing is known about individual, social network and neighborhood characteristics that may be associated with YEH's firearm risks. This information will provide a much-needed comprehensive understanding of firearm violence among YEH. This study will also inform interventions to reduce firearm violence among YEH and others who may be impacted by firearm violence among this vulnerable population.

History Colorado 2024 Amache Field School in Historic Archaeology and Museum Studies

• Bonnie Clark , College of Arts, Humanities & Social Sciences
• Grant from History Colorado
• Abstract: The Amache National Historic Site contains remarkably intact evidence of life in a WWII-era Japanese American incarceration camp, with building foundations, scattered surface artifacts and incarceree-created landscaping. In 2024, the University of Denver’s Department of Anthropology will continue its ongoing collaborative field school at the site and associated museum, followed by analysis and presentation of the resulting data. This project provides a rare opportunity for students and stakeholders to work together investigating the past and its meaning in the present at a national historic site.

Beyond the Ethnic Trap: Pathways From Power Sharing

• Timothy Sisk , Josef Korbel School of International Studies
• Grant from United States Institute of Peace (subaward AERDF - Advanced Education Research and Development Fund)
• Abstract: Escaping the Ethnic Trap explores the conditions under which inclusive governance and human rights can be fostered in contexts where prior conflict dynamics have created an ethnic trap in which identity-based politics undermines social cohesion and the inter-group interdependencies that give rise to sustainable peace.

Training System Assessment and Recommendations

• Charmaine Brittain , Graduate School of Social Work
• Grant from Colorado Department of Human Services
• Abstract: The Butler Institute for Families at the University of Denver Graduate School of Social Work (Butler) will partner with the Colorado Department of Human Services, Division of Child Support Services (CDHS-CS) to assess their training system and provide recommendations to strengthen it.

Colorado Universal Preschool RFP Development Process Evaluation

• Whitney Leboeuf, Colorado Evaluation Action Lab
• Grant from Colorado Department of Early Childhood
• Abstract: The Colorado Lab will develop a statement of work and support CDEC’s request for proposals (RFP) process to identify a vendor for a multi-year process evaluation of components of Colorado Universal Preschool. This work will result in a final RFP for CDEC, accompanied by recommended response evaluation criteria and vendor selection criteria.

NAACHO Harm Redux

• Grant from Mile High Council on Alcoholism and Drug Abuse
• Abstract: The Butler Institute for Families at the University of Denver, Graduate School of Social Work (Butler) will provide both evaluation and creative work in support of Mile High Behavioral Healthcare’s project to provide academic detailing for drag artists in Colorado. MHBHC’s academic detailing project will support drag artists to incorporate harm reduction messages into their work in the queer nightlife scene across the state and improve overdose prevention outcomes for LGBTQIA+ Coloradans.

Related Articles

Faculty and Staff Grants From January 2024

Faculty and Staff Grants from December 2023

Faculty and staff grants from november 2023.

Mathematics at MIT is administratively divided into two categories: Pure Mathematics and Applied Mathematics. They comprise the following research areas:

Pure Mathematics

• Algebra & Algebraic Geometry
• Algebraic Topology
• Analysis & PDEs
• Mathematical Logic & Foundations
• Number Theory
• Probability & Statistics
• Representation Theory

Applied Mathematics

In applied mathematics, we look for important connections with other disciplines that may inspire interesting and useful mathematics, and where innovative mathematical reasoning may lead to new insights and applications.

• Combinatorics
• Computational Biology
• Physical Applied Mathematics
• Computational Science & Numerical Analysis
• Theoretical Computer Science
• Mathematics of Data

40 Facts About Elektrostal

Written by Lanette Mayes

Modified & Updated: 10 May 2024

Reviewed by Jessica Corbett

Elektrostal is a vibrant city located in the Moscow Oblast region of Russia. With a rich history, stunning architecture, and a thriving community, Elektrostal is a city that has much to offer. Whether you are a history buff, nature enthusiast, or simply curious about different cultures, Elektrostal is sure to captivate you.

This article will provide you with 40 fascinating facts about Elektrostal, giving you a better understanding of why this city is worth exploring. From its origins as an industrial hub to its modern-day charm, we will delve into the various aspects that make Elektrostal a unique and must-visit destination.

So, join us as we uncover the hidden treasures of Elektrostal and discover what makes this city a true gem in the heart of Russia.

Key Takeaways:

• Elektrostal, known as the “Motor City of Russia,” is a vibrant and growing city with a rich industrial history, offering diverse cultural experiences and a strong commitment to environmental sustainability.
• With its convenient location near Moscow, Elektrostal provides a picturesque landscape, vibrant nightlife, and a range of recreational activities, making it an ideal destination for residents and visitors alike.

Known as the “Motor City of Russia.”

Elektrostal, a city located in the Moscow Oblast region of Russia, earned the nickname “Motor City” due to its significant involvement in the automotive industry.

Home to the Elektrostal Metallurgical Plant.

Elektrostal is renowned for its metallurgical plant, which has been producing high-quality steel and alloys since its establishment in 1916.

Boasts a rich industrial heritage.

Elektrostal has a long history of industrial development, contributing to the growth and progress of the region.

Founded in 1916.

The city of Elektrostal was founded in 1916 as a result of the construction of the Elektrostal Metallurgical Plant.

Located approximately 50 kilometers east of Moscow.

Elektrostal is situated in close proximity to the Russian capital, making it easily accessible for both residents and visitors.

Known for its vibrant cultural scene.

Elektrostal is home to several cultural institutions, including museums, theaters, and art galleries that showcase the city’s rich artistic heritage.

A popular destination for nature lovers.

Surrounded by picturesque landscapes and forests, Elektrostal offers ample opportunities for outdoor activities such as hiking, camping, and birdwatching.

Hosts the annual Elektrostal City Day celebrations.

Every year, Elektrostal organizes festive events and activities to celebrate its founding, bringing together residents and visitors in a spirit of unity and joy.

Has a population of approximately 160,000 people.

Elektrostal is home to a diverse and vibrant community of around 160,000 residents, contributing to its dynamic atmosphere.

Boasts excellent education facilities.

The city is known for its well-established educational institutions, providing quality education to students of all ages.

A center for scientific research and innovation.

Elektrostal serves as an important hub for scientific research, particularly in the fields of metallurgy, materials science, and engineering.

Surrounded by picturesque lakes.

The city is blessed with numerous beautiful lakes, offering scenic views and recreational opportunities for locals and visitors alike.

Well-connected transportation system.

Elektrostal benefits from an efficient transportation network, including highways, railways, and public transportation options, ensuring convenient travel within and beyond the city.

Famous for its traditional Russian cuisine.

Food enthusiasts can indulge in authentic Russian dishes at numerous restaurants and cafes scattered throughout Elektrostal.

Home to notable architectural landmarks.

Elektrostal boasts impressive architecture, including the Church of the Transfiguration of the Lord and the Elektrostal Palace of Culture.

Offers a wide range of recreational facilities.

Residents and visitors can enjoy various recreational activities, such as sports complexes, swimming pools, and fitness centers, enhancing the overall quality of life.

Provides a high standard of healthcare.

Elektrostal is equipped with modern medical facilities, ensuring residents have access to quality healthcare services.

Home to the Elektrostal History Museum.

The Elektrostal History Museum showcases the city’s fascinating past through exhibitions and displays.

A hub for sports enthusiasts.

Elektrostal is passionate about sports, with numerous stadiums, arenas, and sports clubs offering opportunities for athletes and spectators.

Celebrates diverse cultural festivals.

Throughout the year, Elektrostal hosts a variety of cultural festivals, celebrating different ethnicities, traditions, and art forms.

Electric power played a significant role in its early development.

Elektrostal owes its name and initial growth to the establishment of electric power stations and the utilization of electricity in the industrial sector.

Boasts a thriving economy.

The city’s strong industrial base, coupled with its strategic location near Moscow, has contributed to Elektrostal’s prosperous economic status.

Houses the Elektrostal Drama Theater.

The Elektrostal Drama Theater is a cultural centerpiece, attracting theater enthusiasts from far and wide.

Popular destination for winter sports.

Elektrostal’s proximity to ski resorts and winter sport facilities makes it a favorite destination for skiing, snowboarding, and other winter activities.

Promotes environmental sustainability.

Elektrostal prioritizes environmental protection and sustainability, implementing initiatives to reduce pollution and preserve natural resources.

Home to renowned educational institutions.

Elektrostal is known for its prestigious schools and universities, offering a wide range of academic programs to students.

Committed to cultural preservation.

The city values its cultural heritage and takes active steps to preserve and promote traditional customs, crafts, and arts.

Hosts an annual International Film Festival.

The Elektrostal International Film Festival attracts filmmakers and cinema enthusiasts from around the world, showcasing a diverse range of films.

Encourages entrepreneurship and innovation.

Elektrostal supports aspiring entrepreneurs and fosters a culture of innovation, providing opportunities for startups and business development.

Offers a range of housing options.

Elektrostal provides diverse housing options, including apartments, houses, and residential complexes, catering to different lifestyles and budgets.

Home to notable sports teams.

Elektrostal is proud of its sports legacy, with several successful sports teams competing at regional and national levels.

Boasts a vibrant nightlife scene.

Residents and visitors can enjoy a lively nightlife in Elektrostal, with numerous bars, clubs, and entertainment venues.

Promotes cultural exchange and international relations.

Elektrostal actively engages in international partnerships, cultural exchanges, and diplomatic collaborations to foster global connections.

Surrounded by beautiful nature reserves.

Nearby nature reserves, such as the Barybino Forest and Luchinskoye Lake, offer opportunities for nature enthusiasts to explore and appreciate the region’s biodiversity.

Commemorates historical events.

The city pays tribute to significant historical events through memorials, monuments, and exhibitions, ensuring the preservation of collective memory.

Promotes sports and youth development.

Elektrostal invests in sports infrastructure and programs to encourage youth participation, health, and physical fitness.

Hosts annual cultural and artistic festivals.

Throughout the year, Elektrostal celebrates its cultural diversity through festivals dedicated to music, dance, art, and theater.

Provides a picturesque landscape for photography enthusiasts.

The city’s scenic beauty, architectural landmarks, and natural surroundings make it a paradise for photographers.

Connects to Moscow via a direct train line.

The convenient train connection between Elektrostal and Moscow makes commuting between the two cities effortless.

A city with a bright future.

Elektrostal continues to grow and develop, aiming to become a model city in terms of infrastructure, sustainability, and quality of life for its residents.

In conclusion, Elektrostal is a fascinating city with a rich history and a vibrant present. From its origins as a center of steel production to its modern-day status as a hub for education and industry, Elektrostal has plenty to offer both residents and visitors. With its beautiful parks, cultural attractions, and proximity to Moscow, there is no shortage of things to see and do in this dynamic city. Whether you’re interested in exploring its historical landmarks, enjoying outdoor activities, or immersing yourself in the local culture, Elektrostal has something for everyone. So, next time you find yourself in the Moscow region, don’t miss the opportunity to discover the hidden gems of Elektrostal.

Q: What is the population of Elektrostal?

A: As of the latest data, the population of Elektrostal is approximately XXXX.

Q: How far is Elektrostal from Moscow?

A: Elektrostal is located approximately XX kilometers away from Moscow.

Q: Are there any famous landmarks in Elektrostal?

A: Yes, Elektrostal is home to several notable landmarks, including XXXX and XXXX.

Q: What industries are prominent in Elektrostal?

A: Elektrostal is known for its steel production industry and is also a center for engineering and manufacturing.

Q: Are there any universities or educational institutions in Elektrostal?

A: Yes, Elektrostal is home to XXXX University and several other educational institutions.

Q: What are some popular outdoor activities in Elektrostal?

A: Elektrostal offers several outdoor activities, such as hiking, cycling, and picnicking in its beautiful parks.

Q: Is Elektrostal well-connected in terms of transportation?

A: Yes, Elektrostal has good transportation links, including trains and buses, making it easily accessible from nearby cities.

Q: Are there any annual events or festivals in Elektrostal?

A: Yes, Elektrostal hosts various events and festivals throughout the year, including XXXX and XXXX.

Elektrostal's fascinating history, vibrant culture, and promising future make it a city worth exploring. For more captivating facts about cities around the world, discover the unique characteristics that define each city . Uncover the hidden gems of Moscow Oblast through our in-depth look at Kolomna. Lastly, dive into the rich industrial heritage of Teesside, a thriving industrial center with its own story to tell.

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Our commitment to delivering trustworthy and engaging content is at the heart of what we do. Each fact on our site is contributed by real users like you, bringing a wealth of diverse insights and information. To ensure the highest standards of accuracy and reliability, our dedicated editors meticulously review each submission. This process guarantees that the facts we share are not only fascinating but also credible. Trust in our commitment to quality and authenticity as you explore and learn with us.

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635th Anti-Aircraft Missile Regiment

635-й зенитно-ракетный полк

Military Unit: 86646

Activated 1953 in Stepanshchino, Moscow Oblast - initially as the 1945th Anti-Aircraft Artillery Regiment for Special Use and from 1955 as the 635th Anti-Aircraft Missile Regiment for Special Use.

1953 to 1984 equipped with 60 S-25 (SA-1) launchers:

• Launch area: 55 15 43N, 38 32 13E (US designation: Moscow SAM site E14-1)
• Support area: 55 16 50N, 38 32 28E
• Guidance area: 55 16 31N, 38 30 38E

1984 converted to the S-300PT (SA-10) with three independent battalions:

• 1st independent Anti-Aircraft Missile Battalion (Bessonovo, Moscow Oblast) - 55 09 34N, 38 22 26E
• 2nd independent Anti-Aircraft Missile Battalion and HQ (Stepanshchino, Moscow Oblast) - 55 15 31N, 38 32 23E
• 3rd independent Anti-Aircraft Missile Battalion (Shcherbovo, Moscow Oblast) - 55 22 32N, 38 43 33E

Disbanded 1.5.98.

Subordination:

• 1st Special Air Defence Corps , 1953 - 1.6.88
• 86th Air Defence Division , 1.6.88 - 1.10.94
• 86th Air Defence Brigade , 1.10.94 - 1.10.95
• 86th Air Defence Division , 1.10.95 - 1.5.98