Softcover ISBN: | 978-1-4704-6916-0 |
Product Code: | PSAPM/79 |
List Price: | $129.00 |
MAA Member Price: | $116.10 |
AMS Member Price: | $103.20 |
eBook ISBN: | 978-1-4704-7491-1 |
Product Code: | PSAPM/79.E |
List Price: | $125.00 |
MAA Member Price: | $112.50 |
AMS Member Price: | $100.00 |
Softcover ISBN: | 978-1-4704-6916-0 |
eBook: ISBN: | 978-1-4704-7491-1 |
Product Code: | PSAPM/79.B |
List Price: | $254.00 $191.50 |
MAA Member Price: | $228.60 $172.35 |
AMS Member Price: | $203.20 $153.20 |
Softcover ISBN: | 978-1-4704-6916-0 |
Product Code: | PSAPM/79 |
List Price: | $129.00 |
MAA Member Price: | $116.10 |
AMS Member Price: | $103.20 |
eBook ISBN: | 978-1-4704-7491-1 |
Product Code: | PSAPM/79.E |
List Price: | $125.00 |
MAA Member Price: | $112.50 |
AMS Member Price: | $100.00 |
Softcover ISBN: | 978-1-4704-6916-0 |
eBook ISBN: | 978-1-4704-7491-1 |
Product Code: | PSAPM/79.B |
List Price: | $254.00 $191.50 |
MAA Member Price: | $228.60 $172.35 |
AMS Member Price: | $203.20 $153.20 |
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Book DetailsProceedings of Symposia in Applied MathematicsVolume: 79; 2023; 228 ppMSC: Primary 00; 97; Secondary 54; 14; 46; 20
This volume is based on lectures delivered at the 2022 AMS Short Course “3D Printing: Challenges and Applications” held virtually from January 3–4, 2022.
Access to 3D printing facilities is quickly becoming ubiquitous across college campuses. However, while equipment training is readily available, the process of taking a mathematical idea and making it into a printable model presents a big hurdle for most mathematicians. Additionally, there are still many open questions around what objects are possible to print, how to design algorithms for doing so, and what kinds of geometries have desired kinematic properties. This volume is focused on the process and applications of 3D printing for mathematical education, research, and visualization, alongside a discussion of the challenges and open mathematical problems that arise in the design and algorithmic aspects of 3D printing.
The articles in this volume are focused on two main topics. The first is to make a bridge between mathematical ideas and 3D visualization. The second is to describe methods and techniques for including 3D printing in mathematical education at different levels— from pedagogy to research and from demonstrations to individual projects. We hope to establish the groundwork for engaged academic discourse on the intersections between mathematics, 3D printing and education.
ReadershipUndergraduate and graduate students and researchers interested in 3D printing technology, art, and mechanical designs.
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Table of Contents
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Articles
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Elisabetta A. Matsumoto and Henry Segerman — A mathematical overview and some applications of gear design
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Daniel M. Anderson, Brandon G. Barreto-Rosa, Joshua D. Calvano, Lujain Nsair and Evelyn Sander — Mathematics of floating\index{floating/flotation} 3D printed objects
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silviana amethyst, Samantha Maurer and William O’Brien — A 3D printed Arduino-powered interactive Barth Sextic
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Gabriel Dorfsman-Hopkins — Deformation spaces and static animations
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Timea Tihanyi — Making and breaking rules with clay and code: iteration, glitch, and mathematical thinking
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Janet Chen, Kelly Delp and Stepan Paul — Manipulative calculus: active learning with 3D models
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Christopher R. H. Hanusa — Encouraging student creativity in mathematics through 3D design and 3D printing
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Ivan Sterling — Teaching 3D printing and mathematics at a small public liberal arts college
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Maria Trnkova and Andrew Yarmola — Some mathematical problems motivated by 3D printing
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Additional Material
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RequestsReview Copy – for publishers of book reviewsAccessibility – to request an alternate format of an AMS title
- Book Details
- Table of Contents
- Additional Material
- Requests
This volume is based on lectures delivered at the 2022 AMS Short Course “3D Printing: Challenges and Applications” held virtually from January 3–4, 2022.
Access to 3D printing facilities is quickly becoming ubiquitous across college campuses. However, while equipment training is readily available, the process of taking a mathematical idea and making it into a printable model presents a big hurdle for most mathematicians. Additionally, there are still many open questions around what objects are possible to print, how to design algorithms for doing so, and what kinds of geometries have desired kinematic properties. This volume is focused on the process and applications of 3D printing for mathematical education, research, and visualization, alongside a discussion of the challenges and open mathematical problems that arise in the design and algorithmic aspects of 3D printing.
The articles in this volume are focused on two main topics. The first is to make a bridge between mathematical ideas and 3D visualization. The second is to describe methods and techniques for including 3D printing in mathematical education at different levels— from pedagogy to research and from demonstrations to individual projects. We hope to establish the groundwork for engaged academic discourse on the intersections between mathematics, 3D printing and education.
Undergraduate and graduate students and researchers interested in 3D printing technology, art, and mechanical designs.
-
Articles
-
Elisabetta A. Matsumoto and Henry Segerman — A mathematical overview and some applications of gear design
-
Daniel M. Anderson, Brandon G. Barreto-Rosa, Joshua D. Calvano, Lujain Nsair and Evelyn Sander — Mathematics of floating\index{floating/flotation} 3D printed objects
-
silviana amethyst, Samantha Maurer and William O’Brien — A 3D printed Arduino-powered interactive Barth Sextic
-
Gabriel Dorfsman-Hopkins — Deformation spaces and static animations
-
Timea Tihanyi — Making and breaking rules with clay and code: iteration, glitch, and mathematical thinking
-
Janet Chen, Kelly Delp and Stepan Paul — Manipulative calculus: active learning with 3D models
-
Christopher R. H. Hanusa — Encouraging student creativity in mathematics through 3D design and 3D printing
-
Ivan Sterling — Teaching 3D printing and mathematics at a small public liberal arts college
-
Maria Trnkova and Andrew Yarmola — Some mathematical problems motivated by 3D printing