User:Toploftical/Workpage 6

James Clunie
Born	(1946-11-24) November 24, 1946 (age 78)
Nationality	American
Alma mater	University of Wisconsin–Madison
Known for	Works on Langlands program
Awards	AMS Distinguished Public Service Award (2014)
Scientific career
Fields	Mathematics
Institutions	University of Iowa
Doctoral advisor	Donald McQuillan

James Clunie (born November 24, 1946) is a prominent American mathematician recognized for his contributions to ^[a] This is more text.^[1]

James Clunie studied mathematics at the City College of New York, earning a BS degree in 1967. Then at the University of Wisconsin–Madison he got an MS in 1968 and a PhD in 1972, under the supervision of Donald McQuillan for his thesis "The Characters of Binary-Modular Congruence Groups."

In 1980, Kutzko proved the local Langlands conjectures

• 2014 AMS Distinguished Public Service Award (2014)

• Toploftical/Workpage 6 at the Mathematics Genealogy Project
• Website at the University of Iowa

MrMathGuy
Born	(1946-11-24) November 24, 1946 (age 78)
Nationality	American
Alma mater	University of Wisconsin–Madison
Known for	Works on Langlands program
Awards	AMS Distinguished Public Service Award (2014)
Scientific career
Fields	Mathematics
Institutions	University of Iowa
Doctoral advisor	Donald McQuillan

MrMathGuy (born November 24, 1946) is a prominent American mathematician recognized for his contributions to ^[a] This is more text.^[1]

MrMathGuy studied mathematics at the City College of New York, earning a BS degree in 1967. Then at the University of Wisconsin–Madison he got an MS in 1968 and a PhD in 1972, under the supervision of Donald McQuillan for his thesis "The Characters of Binary-Modular Congruence Groups."

In 1980, Kutzko proved the local Langlands conjectures

• 2014 AMS Distinguished Public Service Award (2014)

• Toploftical/Workpage 6 at the Mathematics Genealogy Project
• Website at the University of Iowa

Jacqueline Akinpelu (born 1953) Jacqueline Akinpelu grew up in Winston Salem, North Carolina in the 1960s. S

After her graduate studies, Akinpelu was hired by AT&T’s Bell Laboratories. During her more than 25-year career there, she held various positions, eventually overseeing a team of over 200 people and a budget of up to $36 million. During this time, she modeled the behavior of a new methodology for planning and managing telephone network call capacity under non-engineered traffic conditions. She also worked with a team to develop strategies for maintaining the network’s stability under all network conditions. This work was vital to the evolution of AT&T’s long-distance network. She also had a great influence on improving the workplace environment at AT&T and shaped their minority recruitment program.

In 2006, Akinpelu joined the Johns Hopkins University Applied Physics Laboratory (JHUAPL) as an intelligence systems engineer. She built an outreach program between JHUAPL and Morgan State University in order to prepare their students for professional careers. In 2009, she received the Women of Color Technology Award for Career Achievement in Government. Over her industrial career, Akinpelu used algebra, operations research, probability and statistics, and stochastic models for her various projects.

Click here for a video interview with Meet a Mathematician!

She got a BA in mathematics from Duke University in 1975, graduating magna cum laude. She received her PhD in Mathematical Sciences in 1980 from Johns Hopkins University, where she wrote her thesis on a topic in inventory systems management.

• 2019 Honoree Black History Month^[1]
• 2017 Heritage Award^[2]
• 2009 Women of Color Award Winner^[3]

Jacqueline (Jackie) Akinpelu is featured for her contributions to research mathematics; mathematics in business, industry, and government; to establishing, cultivating, and sustaining mathematical communities; and to increasing the participation of women and underrepresented groups.

• Mathematicians of the African Diaspora

Jacqueline Akinpelu Assistant Branch Supervisor

Johns Hopkins University Applied Physics Laboratory

I grew up in 1960’s in Winston Salem, NC. in a low-income, single parent household. At the time, the schools in Winston-Salem were segregated but, due primarily to the dedication of my teachers and my own motivation, I received a very strong public school education. For as long as I can remember, even before I started school, I had a love for mathematics. I think there was something about both the logic of math and the fact that in math there was a “right answer” that appealed to me (clearly before I knew about stochastic mathematics). For a long time, I wanted to be a math teacher, but in high school I started to think about working in jobs where I could “apply” mathematics (though I only had a vague idea of what that meant).

at the Johns Hopkins University that I got my first real exposure to “applied mathematics,” and I completed a doctoral thesis on a topic in inventory systems management.

In 1980 I joined AT&T Bell Laboratories in Holmdel, NJ. Eventually I had a 25- year career at Bell Laboratories and, after the breakup of the Bell System, AT&T Laboratories. Two projects during this time stand out for me as highlights of my career in the mathematical sciences. My first project at Bell Laboratories was to model the behavior of a new methodology for planning and managing telephone network call capacity under non-engineered traffic conditions, and to work with a team to develop strategies for maintaining the network’s stability under all network conditions. This was one of my first opportunities to apply my mathematics expertise to solve a real-world problem – and I learned a lot about how to tackle an ill-defined problem and achieve tangible results. I also learned a lot about working in a team and effectively communicating technical information. The second project was to model the performance of a proposed signaling protocol for voice switched networks. This was another opportunity to use my expertise in mathematical sciences, this time to develop effective message flow control mechanisms, but it also gave me the opportunity to work in a team on the international level through participation in standards body deliberations. Building on my technical successes, I went on to become a manager, leading organizations responsible for providing technology for planning, engineering, provisioning and maintenance of the AT&T long distance network.

During my time at AT&T I learned the importance of mentoring. I have mentored hundreds of people over my career, first at AT&T and, more recently, at the Johns Hopkins University Applied Physics Laboratory (JHUAPL), where I continued my career after leaving AT&T. I'm proud of the outreach that I built at JHUAPL to Morgan State University, which includes mentoring students to prepare them for professional careers and developing research partnerships with the university. I have also worked to improve the work environment for all employees, both at AT&T and JHUAPL. I sincerely believe that we have an obligation to create work environments where those coming behind us can be successful, and to return to our communities to share what we have learned.

• 2020: Modeling Dynamical Systems for 3D Printing (with Stephen Lucas & Evelyn Sander), Notices of the American Mathematical Society, Vol. 67, No.11, p. 1692-1705
• 2020: Wallpaper Patterns for Lattice Designs (with Carolyn Yackel), Proceedings of Bridges Aalto, p. 223-230
• 2020: Optimizing Morton’s Tritangentless Knots for Rolling (with Stephen Lucas & Abigail Eget), Proceedings of Bridges Aalto, p. 367-370
• 2019: Opportunity costs in the game of best choice, (with Michael Urbanski, et.al.), Electronic Journal of Combinatorics, Vol. 26, Issue #1

• Personal website

• Toploftical/Workpage 6 at the Mathematics Genealogy Project

Category:Recreational mathematicians

Category:Living people

Category:James Madison University faculty

Category:1996 births

Category:Scientists from Tartu

Category:Academics of the University of Reading

Category:Oak Ridge National Laboratory people

Category:Alumni of Queen's University Belfast

Laura Anne Taalman, also known as mathgrrl, is an American mathematician known for her work on the mathematics of Sudoku and for her mathematical 3D printing models. Her mathematical research concerns knot theory and singular algebraic geometry; she is a professor of mathematics at James Madison University. Wikipedia Education: Duke University, The University of Chicago Research interests: Computational Design, Knot Theory, Games and Puzzles, Singular Algebraic Geometry

• links from Ernst Öpik, Lembit Öpik, Student Society Liivika, Ray Flannery
• Uuno Öpik on Estonian WP

• Professor M. Raymond Flannery

(Martin) Raymond Flannery was the son of James and Bridget (née Lohan) Flannery of Tubbercurry and Roscommon respectively. His parents were schoolteachers at a two teacher school at Athnahoney, near Claudy, and had seven children. The family moved to Derry City in 1945.

He has presented over 44 invited papers at national and international scientific conferences and many invited colloquia at Universities. He delivered the Commencement Addresses at Graduation '95 of Georgia Institute of Technology and at Graduation '98 of Queen's University of Belfast. He served (1978-85) on the Editorial Board of the International Journal of Quantum Chemistry, served (1981-3, 1986-88) on the Executive Board of the Gaseous Electronics Conference and was appointed (1994-2000) a Divisional Associate Editor of The Physical Review Letters. He is currently a member of the Editorial Board of the Atomic and Molecular Physics Handbook (Springer Press) and an Editor of the Springer Book Series on Atomic, Optical and Plasma Physics.

He was awarded various Prizes from the Georgia Tech Chapter of Sigma-Xi, "for best paper" in 1974, "for best Ph. D thesis advisor and outstanding research" in 1975 and in 2001, and "for sustained research" in 1992. He received the Distinguished Professor Award from Georgia Institute of Technology in 1995 "in recognition of his sustained scholarship, leadership, achievement and excellence in teaching, research and service."

He was elected in 1997 an Honorary Member of the Royal Irish Academy, one of thirty honorary members worldwide in the Section of Science, in recognition of his distinguished services in the Section of Science. He is the recipient of the 1998 Allis Prize, awarded by the American Physical Society for advancing the understanding of recombination processes; in particular for developing a microscopic theory of three-body ionic recombination; and for his novel applications of classical and quantum mechanical methods to the dynamics of atomic, molecular and ionic systems." The Queen's University of Belfast awarded him in 1998, the degree of Doctor of Science, D.Sc. degree (honoris causa) for "his distinction as a scientist." He is the recipient of the 2001 award of "Alumnus Illustrissimus" of St. Columb’s College, Derry. He is the recipient of the 2002 Sir David Bates Prize awarded by the UK Institute of Physics (Division of Atomic, Molecular, Optical and Plasma Physics), London, for “ his distinguished contributions to the field of theoretical atomic physics and, in particular, for his studies of recombination processes with applications to astrophysics and plasma physics.” He is also the recipient of the 2002 Jesse W. Beams Award of the Southeastern Section of the American Physical Society " for his pioneering, seminal, influential and enduring contributions to Atomic and Molecular Collision Physics."

His research focuses on recombination processes. In other words, he studies how electrons, ions and atoms move about, collide, and then combine to form new atoms and molecules. These are essential to understanding the ozone layer as well as planetary and stellar atmospheres. Recombination theory is also important in advanced technologies such as microelectronic circuitry and plasma processing of materials. Currently, Ray is working on a recombination process that he hopes will produce anti-matter at cryogenic temperatures (4 degrees Kelvin). Besides shedding light on origins of the universe and its subsequent evolution, this research might produce a future source of rocket fuel required for interplanetary travel.

• Mathematicians of EvenQuads Deck 1
• Jacqueline Akinpelu (b. 1953)
• Sylvia Celedón-Pattichis (PhD in 1998)
• Rosemary Guzman (PhD in 2011)
• Guadalupe Inés Lozano Guada Lozano (b. 1971)
• Nora G. Ramirez (2000)
• Ivelisse Rubio (b. 1962)

• Mathematicians of EvenQuads Deck 2
• Julia Maria Aguirre (b. 1966) $
• Sandra Crespo (b. 1966) $
• María Angélica Cueto (b. 1981)
• Valeria Espinosa (b. 1980s) $
• Ruth Gonzalez (b. mid 1950s)
• Ilana Seidel Horn (b. 1971)
• Shirley Ann Mathis McBay (1935–2021)
• Veena Mendiratta (b. 1948)
• Perla Myers (b. 1968)
• Aisha Nájera (b. 1981)
• Annie Raymond (b. 1986)
• Angela Robinson (b. 1971) wrong Angela Robinson
• Laurie Rubel (b. 1970s)
• Suzanne Sindi (b. 1970s)
• Shelby Wilson (b. 1985) wrong Shelby Wilson
• Lucía Zapata Cardona (b. 1970s) $
• María del Rosario Zavala (b. 1980s)

The Einstein problem is a mathematical problem in discrete geometry. A geometric form is sought that can be joined together in rotated, shifted and/or mirrored copies without overlapping, so that the entire plane is completely covered (tiled) with it. In addition, this form should have the property that no tiling with a periodically recurring pattern - as on wallpaper - can be produced. The problem was considered unresolved for decades; In 2023, two solutions were proposed for the first time. The name of the problem is a humorous allusion to Albert Einstein and states that only one shape ("one stone") should tile the plane.[1]

In mathematical terms, the Einstein problem is about whether there exists a single tile (prototile) that can tile the Euclidean plane with no additional rules to follow when assembling, but only in a non-periodic way. A prototile with this property is called "aperiodic". "Periodic" in this sense would be a tiling that repeats itself analogously to a wallpaper pattern (according to a crystallographic group), i.e. that can be shifted in two different (more precisely: linearly independent) directions in a straight line in such a way that the entire structure thereby is mapped to itself (translational symmetry). In a non-periodic tiling there are no two independent translational symmetries.

David Smith, Joseph Samuel Myers, Craig S. Kaplan and Chaim Goodman-Strauss were able to present such prototiles and the necessary evidence for the first time in March and May 2023. Some of these require computer support, and a peer review is pending.[2][3] While the tile presented in March must also be used mirrored for tiling, the tile presented in May solves the problem even under the stricter requirement that only plane rotations and translations are allowed.

The German term “Einstein” has become established in English for an aperiodic monotile. This pun on the words "a" and "stone", representing "a (single) tile", is attributed to the German mathematician Ludwig Danzer; there is no actual connection to Einstein's research.[4]

The problem can also be viewed as a natural extension of the second part of Hilbert's eighteenth problem, which asks for a single polyhedron that fills three-dimensional Euclidean space without gaps, but no space-filling through that polyhedron is isohedral.[5] Such anisohedral polyhedra were first presented by Karl Reinhardt in 1928.[6] In 1932, Heinrich Heesch found such a solution for the plain.

For the discovery of the so-called quasicrystals, which led to a Nobel Prize in chemistry in 2011, it was essential that important results on aperiodic prototiles had already been found in the 1970s (more on this in the following section.)

The best-known example of aperiodic prototiles in the plane until March 2023 was the so-called Penrose tiling (1974), which, however, requires a set of two different prototiles. From this point on, the search for the aperiodic monotile began, which lasted almost 50 years.

In 2023, two solutions to the Einstein problem were found by Smith et al. suggested. Before it was unclear what such a tile could look like. The best approximations to the problem up until then either required additional tiling rules such as decorations, were incoherent, or had to accept overlaps or gaps in the tessellation. The Smith et al. The solutions found, on the other hand, are coherent, seamless and do not require additional tiling rules. In order to seamlessly tile the level with copies of the hat tile, an infinite number of mirrored (flipped) tiles must also be used. At the same time, the approach implies the existence of a family of slightly differently shaped monotiles with the same properties. This is visualized by an animation in the first article by M. Bischoff given under “Weblinks”. The authors around David Smith obtained their second solution to the Einstein problem from precisely this approach to further forms, an irregular non-convex 14-sided polygon from which the so-called. Specter tile obtained.

In 1988, Peter Schmitt discovered a polyhedron for the non-periodic, gapless tiling of the three-dimensional Euclidean space. While none of these space-fillings allow translation as a symmetry, some exhibit skew symmetry, which is defined as a combination of translation and rotation through an irrational multiple of circle number

PIIIIIIpi (Pi) can be understood such that no number of repeated operations ever result in a pure parallel shift. This construction was later extended by John Horton Conway and Ludwig Danzer to a convex aperiodic space filler, the Schmitt-Conway-Danzer tile (see figure). The presence of the skew symmetry led to a reassessment of the non-periodicity requirements.[7] Chaim Goodman-Strauss proposed to call a tiling strongly aperiodic if it does not admit an infinite cyclic group of Euclidean transformations as symmetries, and only call tiling sets that enforce strong aperiodicity strongly aperiodic, while other sets too weakly aperiodic are designated.[8]

In 1996, Petra Gummelt constructed a decorated decagonal prototile and showed that it can necessarily nonperiodically tile the plane if two types of overlaps between tile pairs are allowed (see figure).[9] Because of the invalid overlap rules, the Gummelt tile does not solve the problem.

Another approach from 2010 comes from Joshua Socolar and Joan Taylor.[10] The tiling of the Euclidean plane with the Socolar-Taylor tile requires merging rules that constrain the relative orientation of two tiles and refer to drawn decorations of the tiles. These rules apply to pairs of non-adjacent tiles. Alternatively, an undecorated but disjointed tile can be created with no merging rules (see figure). This variant of the Socolar-Taylor tile is composed of various prototiles in a fixed arrangement (19 in total) and is therefore no longer a closed topological disk by definition. This construction can in turn be extended to a space-filling, connected polyhedron without assembly rules. However, the space fillings that are possible with this are periodic in one direction, which is why the three-dimensional Socolar-Taylor tile is only weakly aperiodic.

• Manon Bischoff: Hobby-Mathematiker findet die lang ersehnte Einstein-Kachel, spektrum.de, 29. März 2023
• Manon Bischoff: Vampir-Kachel löst den »Einstein« ab, spektrum.de, 31. Mai 2023
• Spezielle Website zu "A chiral aperiodic monotile", Mai 2023
• Blog von David Smith, 24. April 2016 until today

LEAD: Section of a tessellation with the so-called Specter tile, which was presented for the first time in May 2023. Specter means ghost in English. Ausschnitt einer Parkettierung mit der sogenannten Spectre-Kachel, welche im Mai 2023 erstmals vorgestellt wurde. Spectre bedeutet im Englischen Gespenst. File:Spectre aperiodic monotile small patch.svg

Section of a tiling with the hat tile, presented in March 2023. The blue tiles all have the same shape, the yellow ones are mirror images of it. Ausschnitt einer Parkettierung mit der Hut-Kachel, vorgestellt im März 2023. Die blauen Kacheln haben alle die gleiche Form, die gelben sind dazu spiegelbildlich. File:Aperiodic monotile smith 2023.svg

A Specter tile (right) is obtained by edge-modifying a 14-sided polygon tile (left). The tile shape on the right excludes solutions that contain mirrored tiles. In the case of the polygon (left), reflections would have to be explicitly forbidden, as they could occur. Eine Spectre-Kachel (rechts) erhält man durch Kantenmodifizierung einer 14-seitigen Polygon-Kachel (links). Die rechte Kachelform schließt Lösungen aus, die gespiegelte Kacheln enthalten. Beim Polygon (links) müsste man Spiegelungen explizit verbieten, da sie auftreten könnten. File:Aperiodische Monokacheln Mai 2023.png

In this variant of the Specter tile, the edges have been shaped slightly differently. There is a certain degree of freedom in their exact shape, provided that all edges - as with puzzle pieces - fit together and do not intersect. Bei dieser Variante der Spectre-Kachel wurden die Kanten etwas anders geformt. Bei deren genauer Form besteht eine gewisse Freiheit, sofern alle Kanten - wie bei Puzzleteilen - zueinander passen und sich nicht schneiden. File:Spectre aperiodic monotile single.svg

The three-dimensional Schmitt-Conway-Danzer tile. Die dreidimensionale Schmitt-Conway-Danzer-Kachel. File:SCD tile.svg

Gummelt's decorated decagonal prototile (left) with decomposition into Penrose tiles (kite and arrow) by dashed lines and possible overlaps (right). Gummelts dekorierte zehneckige Protokachel (links) mit Zerlegung in Penrose-Kacheln (Drachen und Pfeil) durch gestrichelte Linien und mögliche Überlappungen (rechts). File:Gummelt decagon.svg

The disjointed Socolar-Taylor tile solves the Einstein problem only with limitations, but was considered the first good approximation of an aperiodic monotile until 2023. Die unzusammenhängende Socolar-Taylor-Kachel löst das Einstein-Problem nur mit Einschränkungen, galt aber bis 2023 als erste gute Approximation einer aperiodischen Monokachel. File:Socolar-Taylor tile.svg

An aperiodic monotile is a single tile that tiles the plane with the additional property that it does not contain arbitrarily large periodic regions or patches.

An einstein (German: ein Stein, one stone) is an aperiodic tiling that uses only a single shape.

In 2023, David Smith, Joseph Samuel Myers, Craig S. Kaplan, and Chaim Goodman-Strauss posted a preprint proving the existence of a tile which when considered with its mirror image form an aperiodic prototile set. The tile, a "hat" formed from eight copies of a 60°–90°–120°–90° kite, glued edge-to-edge, can be generalized to an infinite family of tiles with the same aperiodic property.^[1]

The existence of a strongly aperiodic tile set for the Euclidean plane consisting of one connected tile without matching rules is an unsolved problem.

Category:Aperiodic tilings

an aperiodic monotile

David Smith, Joseph Samuel Myers, Craig S. Kaplan, Chaim Goodman-Strauss

A longstanding open problem asks for an aperiodic monotile, also known as an "einstein": a shape that admits tilings of the plane, but never periodic tilings. We answer this problem for topological disk tiles by exhibiting a continuum of combinatorially equivalent aperiodic polygons. We first show that a representative example, the "hat" polykite, can form clusters called "metatiles", for which substitution rules can be defined. Because the metatiles admit tilings of the plane, so too does the hat. We then prove that generic members of our continuum of polygons are aperiodic, through a new kind of geometric incommensurability argument. Separately, we give a combinatorial, computer-assisted proof that the hat must form hierarchical -- and hence aperiodic -- tilings.

The "hat" aperiodic monotile resolves the question of whether a single shape can force aperiodicity in the plane. However, all tilings by the hat require reflections; that is, they must incorporate both left- and right-handed hats. Mathematically, this leaves open the question of whether a single shape can force aperiodicity using only translations and rotations. (It also complicates the practical application of the hat in some decorative contexts, where extra work would be needed to manufacture both a shape and its reflection.)

Aperiodic tiling

Penrose tiling

Einstein problem

List of aperiodic sets of tiles

• Two algorithms for randomly generating aperiodic tilings Simon Tatham, 2023-04-10

A 13-sided shape called ‘the hat’ forms a pattern that never repeats^[1]

NYT^[2]

https://www.popularmechanics.com/science/math/a43402074/mathematicians-discover-new-13-sided-shape/ Mathematicians Discovered a New 13-Sided Shape That Can Do Remarkable Things It will tile a plane without ever repeating. Tim NewcombBY TIM NEWCOMBPUBLISHED: MAR 24, 2023 Popular Mechanics

xxxx At Long Last, Mathematicians Have Found a Shape With a Pattern That Never Repeats Experts have searched for decades for a polygon that only makes non-repeating patterns. But no one knew it was possible until now Will Sullivan Smithsonian Magazine March 29, 2023

xxxx A hobbyist in the U.K. has come up with a new 13-sided shape called 'the hat' March 31, 20235:56 AM ET NPR Mornin gEdition