{"@context": "http://iiif.io/api/presentation/2/context.json", "attribution": "Art Collection", "sequences": [{"canvases": [{"description": "", "height": 4961, "width": 5953, "@type": "sc:Canvas", "images": [{"on": "https://images.is.ed.ac.uk/luna/servlet/iiif/m/UoEart~1~1~75442~198426/canvas/c1", "motivation": "sc:painting", "resource": {"service": {"profile": "http://iiif.io/api/image/2/level2.json", "@context": "http://iiif.io/api/image/2/context.json", "@id": "https://images.is.ed.ac.uk/luna/servlet/iiif/UoEart~1~1~75442~198426"}, "format": "image/jpeg", "height": 4961, "width": 5953, "@id": "https://images.is.ed.ac.uk/luna/servlet/iiif/UoEart~1~1~75442~198426/full/!1024,1024/0/default.jpg", "@type": "dctypes:Image"}, "@type": "oa:Annotation"}], "label": "The MacDonald Equation - Freeman Dyson", "@id": "https://images.is.ed.ac.uk/luna/servlet/iiif/m/UoEart~1~1~75442~198426/canvas/c1", "thumbnail": {"@id": "https://images.is.ed.ac.uk/MediaManager/srvr?mediafile=/Size0/UoEart~1~1/437/0152467c.jpg"}, "metadata": [{"value": "0152467", "label": "Work Record ID"}, {"value": "EU5467", "label": "ID Number"}, {"value": "01 Sep 2017", "label": "ID Date"}, {"value": "The MacDonald Equation", "label": "Title"}, {"value": "Dyson, Freeman (b.1923)", "label": "Creator"}, {"value": "Artist", "label": "Creator Role"}, {"value": "Concinnitas is a portfolio of 10 aquatints with accompanying statements, one each by the following participants: Michael Atiyah, Enrico Bombieri, Simon K. Donaldson, Freeman Dyson, Murray Gell-Mann, Richard Karp, Peter Lax, David Mumford, Stephen Smale and Steven Weinberg. It has been curated and includes and introduction by Daniel Rockmore. The portfolio has been printed in an edition of 100 copies, numbered 1-100, with 15 additional copies lettered AP 1-15. Each of the 10 aquatints has been prepared and printed on Rives BFK White 300g paper using Gamblin Portland Black ink and editioned at Harlan & Weaver, New York City, New York, under the supervisiion of Felix Harlan, Carol Weaver and Derick Wycherly. The artist statements and signature cards have been printed on Crane's Lettra paper by Jenn Lawrence at Letterpress PDX in Portland, Oregon. Published in 2014 by Parasol Press, Ltd., Portland, Oregon, Yale University Art Gallery, New Haven, Connecticut and in association with Bernard Jacobson Gallery, London, England.", "label": "Production Notes"}, {"value": "Harlan & Weaver, Inc. (estab. 1984)", "label": "Creator"}, {"value": "Printer", "label": "Creator Role"}, {"value": "Parasol Press Ltd.", "label": "Creator"}, {"value": "Publisher", "label": "Creator Role"}, {"value": "Rockmore, Daniel", "label": "Creator"}, {"value": "Collaborator", "label": "Creator Role"}, {"value": "2014", "label": "Date"}, {"value": "The portfolio Concinnitas is the result of a collaboration between Dan Rockmore (Professor of Mathematics, Dartmouth College); ten renowned mathematicians and physicists; the publisher Robert Feldman (who earlier produced seminal Conceptual art print portfolios); and the New York printing house Harlan & Weaver. It takes its title from a term used by the Renaissance artist and architect Leon Battista Alberti (1404\u20131472) to indicate the proportions of beauty. Each print represents a participant\u2019s answer to Rockmore\u2019s prompt to represent the \"most beautiful mathematical expression\" they had encountered in their work or study. Rendered so as to mimic the aesthetics of a handwritten equation, such as those immortalized in photographs of Albert Einstein\u2019s blackboard, Concinnitas also echoes Conceptual artists\u2019 engagement with language and systems. While to the layperson the mathematical content may remain enigmatic or require further research, the prints persist on their own as powerful visual signs communicating the gesture and intentions of their creators. Artist's statement: The MacDonald Equation is the most beautiful thing that I ever discovered. It belongs to the theory of numbers, the most useless and ancient branch of mathematics. My friend Ian MacDonald had the joy of discovering it first, and I had the almost equal joy of discovering it second. Neither of us knew that the other was working on it. We had daughters in the same class at school, so we talked about our daughters and not about mathematics. We discovered an e quation for the \"Tau-function\" (written \u03c4(n) in the equation), an object explored by the Indian genius Srinivasa Ramanujan four years before he died at age thirty-two. Here I wrote down MacDonald's equation for the Tau-function. The MacDonald equation has an amazing five-fold symmetry that Ramanujan missed. You can see the five-fold symmetry in the ten differences multiplied together on the right-hand side of the equation. We are grateful to Ramanujan, not only for the many beautiful things that he discovered, but also for the beautiful things that he left for other people to discover. To explain how the MacDonald equation works, let us look at the first three cases, n=1, 2, 3. The sum is over sets of five integers a, b, c, d, e with sum zero and with the sum of their squares equal to 10n. The \"(mod 5)\" statement means that a is of the form 5j+1, b is of the form 5k+2, and so on up to e of the form 5p+5, where j, k, and p are positive or negative integers. The exclamation marks in the equation mean 1!=1, 2!=1x2=2, 3!=1x2x3=6, 4!=1x2x3x4=24. So when n=1, the only choice for a, b, c, d, e is 1, 2, -2, -1, 0, and we find tau(1)=1. When n=2, the only choice is 1, -3 ,3 ,-1 , 0, and we find tau(2)=-24. When n=3, there are two choices, 1, -3, -2, 4, 0 and -4, 2, 3, -1, 0, which give equal contributions, and we find tau(3)=252. It is easy to check that these three values of tau(n) agree with the values given by Ramanujan's equation. The MacDonald equation is a special case of a much deeper connection that Ian MacDonald discovered between two kinds of symmetry which we call modular and affine. The two kinds of symmetry were originally found in separate parts of science, modular in pure mathematics and affine in physics. Modular symmetry is displayed for everyone to see in the drawings of flying angels and devils by the artist Mauritz Escher. Escher understood the mathematics and got the details right. Affine symmetry is displayed in the peculiar groupings of particles created by physicists with high-energy accelerators. The mathematician Robert Langlands was the first to conjecture a connection between these and other kinds of symmetry. Ian MacDonald took a big step toward making Langlands's dream come true. The equation that I wrote down here is a small piece of MacDonald's big step.", "label": "Description"}, {"value": "aquatint/Etching", "label": "Material"}, {"value": "Art Collection", "label": "Repository"}, {"value": "AP12", "label": "Source"}, {"value": "Modern and Contemporary Art Collection", "label": "Repository"}, {"value": "AP12", "label": "Source"}, {"value": "Mathematics", "label": "Subject Category"}, {"value": "\u00a9 the artist", "label": "Rights Statement"}, {"value": "The MacDonald Equation - Freeman Dyson", "label": "Repro Title"}, {"value": "0152467c.tif", "label": "Repro ID Number"}, {"value": "The MacDonald Equation - Freeman Dyson", "label": "Repro Description"}, {"value": "\u00a9 University of Edinburgh Art Collection", "label": "Repro Rights Statement"}, {"value": "Full public access", "label": "Repro Publication Status"}]}], "viewingHint": "individuals", "@type": "sc:Sequence"}], "logo": "https://images.is.ed.ac.uk/luna/images/LUNAIIIF80.png", "@id": "http://collections.ed.ac.uk/manifests/EU5467.json", "@type": "sc:Manifest", "related": "https://images.is.ed.ac.uk/luna/servlet/iiif/m/UoEart~1~1~75442~198426/manifest", "label": "The MacDonald Equation - Freeman Dyson"}