Eric van Fossen Conrad
Department of Mathematics
The Ohio State University

One must always generalize. (Man muß immer generalisieren)
-- Carl Jacobi quoted in P. Davis and R. Hersh The Mathematical Experience, Boston: Birkhäuser, 1981. (Thanks: David Marjanovic of Austria for notes on orthography and translation.)

Practical application is found by not looking for it, and one can say that the whole progress of civilization rests on that principle.
-- Jacques Hadamard quoted in H. Eves Mathematical Circles Squared, Boston: Prindle, Weber and Schmidt, 1972.

Some of My Mathematical Work

• The Fermat cubic, elliptic functions, continued fractions, and a combinatorial excursion. Eric Conrad and Philippe Flajolet.  In: Séminaire Lotharingien de Combinatoire (SLC) volume 54 (2006), 44 pages. http://www.emis.de/journals/SLC/wpapers/s54conflaj.html.  Preprint version of March 25, 2006.  Preprint at http://arxiv.org/pdf/math.CO/0507268. 

  Certain elliptic functions, considered in an 1890 paper by Alfred Cardew Dixon and related to Fermat's cubic equation (x³+y³=1), lead to a new set of continued fraction expansions with sextic numerators and cubic denominators.  The functions and the continued fractions are pregnant with interesting combinatorics, including a special Pólya urn, a continuous-time branching process, as well as permutations satisfying constraints that involve either parity of levels of elements or a repetitive pattern of order three.

  Trivia:  Because of this paper (and thanks to Philippe Flajolet), my Erdös number is 3.  See http://algo.inria.fr/flajolet/numbers.html.

• Some Continued Fraction Expansions of Laplace Transforms of Elliptic Functions. Eric van Fossen Conrad. PhD. Dissertation. Ohio State University, Mathematics, 2002.  PDF copy.  http://rave.ohiolink.edu/etdc/view?acc_num=osu1029248229.
  

  In a 1907 paper, L. Rogers used two methods to obtain continued fractions for certain Laplace transforms of Jacobi elliptic functions.  His first method employed repeated integration by parts, while his second method recalled an 1889 technique of T. Stieltjes.  In 1996, S. Milne used these expansions and others obtained by modular transformations to derive results about sums of squares and triangular numbers.  Working independently in the 1820's, C. Jacobi and N. Abel both introduced elliptic functions to advance the study of elliptic integrals.  In 1981, D. Dumont introduced symmetric variants of the elliptic functions of Jacobi and Abel to facilitate the study of certain combinatorial problems related to coefficients in Maclaurin expansions of Jacobi elliptic functions.  In this thesis, we use Dumont's elliptic functions to rederive the continued fraction expansions of Rogers.  In the classical approach used by Rogers and Milne, four families of continued fractions are obtained.  In our approach, members of the same four families are derived directly by specializing parameters instead of employing modular transformations.  To these four families, we add a new set of continued fractions based on certain elliptic functions that were studied in an 1890 paper by A. Dixon.  These new continued fractions were discovered in 1999 in the course of work with D. Dumont.

Personal hobbies

• Contradancing.
• Columbus (Ohio) Sacred Harp Singers.  (Shape note singing in Ohio).
• Rusalka Slavic Folk Chorus.
• Latin.  (My Latin grammar notes are here.)
  
• 9 Chickweed Lane.
• Primitive Pythagorean triples. Links: A C++ program which makes use of Euclid's gcd algorithm to produce them. Program output of a program run (p=100) sorted by the smallest entry in the triple.

Mathematical links

• My advisor is Dr. Stephen Milne.
• My advisor and others have encouraged me to read the classics. Of late, I have been reading quite a bit from Carl Jacobi, in particular from his Fundamenta Nova. I have included a few sample translations from Jacobi's works in my Jacobi pages.
• Christian Krattenthaler, a combinatorialist who has written Mathematica programs HYP and HYPQ for manipulating hypergeometric and basic hypergeometric series.
• Mathematical trivia.

Potpourri

• Internet Web Archive  http://web.archive.org.  (When curiosity calls and when it's time to say "Oops!")
• Rogerian therapy?  In need of a Rogerian therapist but strapped for cash? You might sample the services of Dr. Eliza, an amusing computer simulation that dates back to the middle 1960's. A sample dialog:

     Eliza: Hello. I am ELIZA. How can I help you?
        Me: By eating porridge.
     Eliza: Please go on.
        Me: I hate porridge and watching you eat porridge would be fun. 
     Eliza: Do you wish to hate porridge and watching me?
        Me: No. I hate porridge but I would like to watch you eat porridge! 
     Eliza: You are being a bit negative.
        Me: I am not being negative. 
     Eliza: How long have you been not being negative?
        Me: How long have you been ungrammatical? 
     Eliza: Does that question interest you?
        Me: Doesn't it interest you? 
     Eliza: Oh, I []
  

  At this point the cybertherapist became unintelligible.

MATHEMATICAL TRIVIA

1. Eric Weisstein's World of Mathematics. (Now: Wolfram's MathWorld.  Formerly: "Treasure Trove of Mathematics")
2. Favorite Mathematical Constants.
3. Mathematical Quotation Server.
4. Biographies such as the inspiring story of Girolamo Cardano, credited with solving the cubic because he published first, and the quartic because he got a student to do the work.
5. The state of Indiana and the value of pi

OTHER FAVORITES

1. Mathematicians
   • Bruce Berndt.
   • Philippe Flajolet.
   • Christian Krattenthaler.
   • Dominique Foata.
     
   • Herbert Wilf.
   • Doron Zeilberger.
2. Bureaucracies and bureaucrats
   • MathSciNet Home Page
   • e-MATH Home Page
3. TeX Users Group Home Page.
4. American Mathematical Society TeX freebies.