A Proof of a Conjecture for the Number of Ramified Coverings of the Sphere by the Torus

Similar documents
An Optimal Bound for Sum of Square Roots of Special Type of Integers

Applied Mathematics Letters

Finite Fields and Their Applications

On Pfaff s solution of the Pfaff problem

The Parity of the Number of Irreducible Factors for Some Pentanomials

On an identity for the cycle indices of rooted tree automorphism groups

Denote the function derivatives f(x) in given points. x a b. Using relationships (1.2), polynomials (1.1) are written in the form

Least Squares Fitting of Data

= z 20 z n. (k 20) + 4 z k = 4

Special Relativity and Riemannian Geometry. Department of Mathematical Sciences

System in Weibull Distribution

LECTURE 8-9: THE BAKER-CAMPBELL-HAUSDORFF FORMULA

PARTITIONS WITH PARTS IN A FINITE SET

Quantum Particle Motion in Physical Space

Canonical transformations

,..., k N. , k 2. ,..., k i. The derivative with respect to temperature T is calculated by using the chain rule: & ( (5) dj j dt = "J j. k i.

THE ADJACENCY-PELL-HURWITZ NUMBERS. Josh Hiller Department of Mathematics and Computer Science, Adelpi University, New York

Inner Product. Euclidean Space. Orthonormal Basis. Orthogonal

What is LP? LP is an optimization technique that allocates limited resources among competing activities in the best possible manner.

n α j x j = 0 j=1 has a nontrivial solution. Here A is the n k matrix whose jth column is the vector for all t j=0

Preference and Demand Examples

More metrics on cartesian products

ON THE NUMBER OF PRIMITIVE PYTHAGOREAN QUINTUPLES

COS 511: Theoretical Machine Learning

AN ANALYSIS OF A FRACTAL KINETICS CURVE OF SAVAGEAU

International Journal of Mathematical Archive-9(3), 2018, Available online through ISSN

Chapter One Mixture of Ideal Gases

Least Squares Fitting of Data

General viscosity iterative method for a sequence of quasi-nonexpansive mappings

FORMULAS FOR BINOMIAL SUMS INCLUDING POWERS OF FIBONACCI AND LUCAS NUMBERS

APPENDIX A Some Linear Algebra

Integral Transforms and Dual Integral Equations to Solve Heat Equation with Mixed Conditions

Difference Equations

Numerical Heat and Mass Transfer

arxiv: v1 [math.ho] 18 May 2008

Ballot Paths Avoiding Depth Zero Patterns

FACTORIZATION IN KRULL MONOIDS WITH INFINITE CLASS GROUP

The internal structure of natural numbers and one method for the definition of large prime numbers

Fermi-Dirac statistics

PHYS 705: Classical Mechanics. Canonical Transformation II

Bernoulli Numbers and Polynomials

Slobodan Lakić. Communicated by R. Van Keer

Chapter 1. Theory of Gravitation

Expected Value and Variance

DUE: WEDS FEB 21ST 2018

On the Calderón-Zygmund lemma for Sobolev functions

One-sided finite-difference approximations suitable for use with Richardson extrapolation

EXACT TRAVELLING WAVE SOLUTIONS FOR THREE NONLINEAR EVOLUTION EQUATIONS BY A BERNOULLI SUB-ODE METHOD

Xiangwen Li. March 8th and March 13th, 2001

Chapter 12 Lyes KADEM [Thermodynamics II] 2007

NUMERICAL DIFFERENTIATION

1 Generating functions, continued

A Hybrid Variational Iteration Method for Blasius Equation

3.1 Expectation of Functions of Several Random Variables. )' be a k-dimensional discrete or continuous random vector, with joint PMF p (, E X E X1 E X

1 Definition of Rademacher Complexity

Chapter 12. Ordinary Differential Equation Boundary Value (BV) Problems

FINITELY-GENERATED MODULES OVER A PRINCIPAL IDEAL DOMAIN

Lectures - Week 4 Matrix norms, Conditioning, Vector Spaces, Linear Independence, Spanning sets and Basis, Null space and Range of a Matrix

The Feynman path integral

Binomial transforms of the modified k-fibonacci-like sequence

Multiplicative Functions and Möbius Inversion Formula

= m 1. sin π( ai z ) )

Our focus will be on linear systems. A system is linear if it obeys the principle of superposition and homogenity, i.e.

A new Approach for Solving Linear Ordinary Differential Equations

BOUNDEDNESS OF THE RIESZ TRANSFORM WITH MATRIX A 2 WEIGHTS

Foundations of Arithmetic

Convexity preserving interpolation by splines of arbitrary degree

Georgia Tech PHYS 6124 Mathematical Methods of Physics I

Econ107 Applied Econometrics Topic 3: Classical Model (Studenmund, Chapter 4)

COMPARISON OF SOME RELIABILITY CHARACTERISTICS BETWEEN REDUNDANT SYSTEMS REQUIRING SUPPORTING UNITS FOR THEIR OPERATIONS

e companion ONLY AVAILABLE IN ELECTRONIC FORM

XII.3 The EM (Expectation-Maximization) Algorithm

Approximate Technique for Solving Class of Fractional Variational Problems

Global Sensitivity. Tuesday 20 th February, 2018

PHYS 705: Classical Mechanics. Calculus of Variations II

Computational and Statistical Learning theory Assignment 4

Chapter 5. Solution of System of Linear Equations. Module No. 6. Solution of Inconsistent and Ill Conditioned Systems

Solutions for Euler and Navier-Stokes Equations in Powers of Time

Appendix B. Criterion of Riemann-Stieltjes Integrability

Excess Error, Approximation Error, and Estimation Error

Determinants Containing Powers of Generalized Fibonacci Numbers

An explicit solution to polynomial matrix right coprime factorization with application in eigenstructure assignment

Short running title: A generating function approach A GENERATING FUNCTION APPROACH TO COUNTING THEOREMS FOR SQUARE-FREE POLYNOMIALS AND MAXIMAL TORI

Supplementary Notes for Chapter 9 Mixture Thermodynamics

Modified parallel multisplitting iterative methods for non-hermitian positive definite systems

Finite Vector Space Representations Ross Bannister Data Assimilation Research Centre, Reading, UK Last updated: 2nd August 2003

Lecture 13 APPROXIMATION OF SECOMD ORDER DERIVATIVES

arxiv: v2 [math.co] 3 Sep 2017

Formulas for the Determinant

Solutions to the 71st William Lowell Putnam Mathematical Competition Saturday, December 4, 2010

Dirichlet s Theorem In Arithmetic Progressions

The binomial transforms of the generalized (s, t )-Jacobsthal matrix sequence

The Order Relation and Trace Inequalities for. Hermitian Operators

Implicit scaling of linear least squares problems

EEE 241: Linear Systems

ONE EXPRESSION FOR THE SOLUTIONS OF SECOND ORDER DIFFERENCE EQUATIONS JERZY POPENDA

Graph Reconstruction by Permutations

arxiv: v1 [math.co] 12 Sep 2014

Maximizing the number of nonnegative subsets

A summation on Bernoulli numbers

Transcription:

Journal of Cobnatoral Theory, Seres A 88, 4658 (999) Artcle ID jcta99999, avalable onlne at httpwwwdealbraryco on A Proof of a Conjecture for the Nuber of Rafed Coverngs of the Sphere by the Torus I P Goulden and D M Jackson Departent of Cobnatorcs and Optzaton, Unversty of Waterloo, Waterloo, Ontaro, Canada Councated by the Managng Edtors Receved Deceber 8, 998 An explct expresson s obtaned for the generatng seres for the nuber of rafed coverngs of the sphere by the torus, wth eleentary branch ponts and prescrbed rafcaton type over nfnty Ths proves a conjecture of Goulden, Jackson, and Vanshten for the explct nuber of such coverngs 999 Acadec Press INTRODUCTION Let X be a copact connected Reann surface of genus g0 A rafed coverng of S of degree n by X s a non-constant eroorphc functon f X S such that f & (q) =n for all but a fnte nuber of ponts q # S, whch are called branch ponts Two rafed coverngs f and f of S by X are sad to be equvalent f there s a hoeoorphs? X X such that f = f b? A rafed coverng f s sad to be sple f f & (q) =n& for each branch pont of f, and s alost sple f f & (q) =n& for each branch pont wth the possble excepton of a sngle pont, that s denoted by The preages of are the poles of f If,, are the orders of the poles of f, where }}}, then =(,, ) s a partton of n and s called the rafcaton type of f Let + (g) () be the nuber of alost sple rafed coverngs of S by X wth rafcaton type The proble of deternng an (explct) expresson for + (g) () s called the Hurwtz Enueraton Proble The purpose of ths paper s to prove the followng result for the torus, gvng an explct expresson for + () () for an arbtrary partton =(,, ) Theore was prevously conjectured by Goulden et al n [4] where t was proved for all parttons wth 6, and for the partcular partton ( ), for any Let C be the conjugacy class of the syetrc group S n on n sybols ndexed by the partton of n 0097-36599 3000 Copyrght 999 by Acadec Press All rghts of reproducton n any for reserved 46

RAMIFIED COVERINGS BY THE TORUS 47 Theore + () ()= C 4 n! (n+)! \ ` = ( &)!+\ n &n & & = (&)! e n &+ where e s the th eleentary syetrc functon n,, and e = +}}}+ =n Prevously Hurwtz [5] had stated that, for the sphere, + (0) ()= C (n+&)! n &3 n! \ ` = ( &)!+ () A proof was of ths sketched by Hurwtz [5] It was frst proved by Goulden and Jackson [] (see also Strehl [6]) The approach developed by Hurwtz s outlned n the next secton Very recently Vakl [7] has gven an ndependent proof of Theore He develops, by technques n algebrac geoetry, and solves a recurrence equaton that s copletely dfferent n character fro the one obtaned fro the dfferental equaton n ths paper HURWITZ'S COMBINATORIALIZATION OF RAMIFIED COVERINGS Hurwtz's approach was to represent a rafed coverng f of S, wth rafcaton type, by a cobnatoral datu (_,, _ r ) consstng of transpostons n S n, whose product? s n C, such that (_,, _ r ) acts transtvely on the set [,, n] of sheet labels and that r=n++ (g&), where =l(), the length of The latter condton s a consequence of the Reann-Hurwtz forula Under ths cobnatoralzaton he showed that + (g) ()= C n! c g(), where c g () s the nuber of such factorzatons of an arbtrary but fxed? # C He studed the effect of ultplcaton by _ r on _ }}}_ r& to derve a recurrence equaton for c g () The dffculty wth Hurwtz's approach s that the recurrence equatons for c g () are ntractable n all but a sall nuber of specal cases It appears that hs approach can be ade ore tractable by the ntroducton of cut operators and jon operators that have been developed for cobnatoral purposes by Goulden [], Goulden and Jackson [], and

48 GOULDEN AND JACKSON Goulden et al [4] These are partal dfferental operators n ndeternates p, p, that take account of the enueratve consequences of the ultplcaton by _ r on \=_ }}}_ r&, when sued over all such ordered transtve factorzatons There are two cases The acton of _ r on \ s ether to jon an -cycle and a j-cycle of \ to produce an + j-cycle, or to cut an + j-cycle of \ to produce an -cycle and a j-cycle In the frst case the operators are the jon operators p + j and p + p p j j\ p +\ p j+, and n the second case the operator s the cut operator p p j p + j A ``cut-and-jon'' analyss of the acton of _ r on \ therefore leads to a nonhoogeneous partal dfferental equaton n a countably nfnte nuber of varables (ndeternates) for the generatng seres 8 for c g () The type of 8 s deterned by the cobnatoral propertes of the cut-and-jon analyss The advantage of ths approach to the Hurwtz Enueraton Proble s that t facltates the transforaton of the dfferental equaton for 8 by an plct change of varables The seres that s nvolved wth ths transforaton s denoted by s=s(x, p) throughout, where p=(p, p, ), and appears to be fundaental to the proble 3 THE DIFFERENTIAL EQUATION Let p = p }}}p where =(,, ) Let 8(u, x, z, p)= n, g0 &n l()= C c g () u n++(g&) x n (n++(g&))! n! z g p, () the generatng seres for c g (), where &n sgnfes that s a partton of n It was shown n [4] that f =8(u,,z, p) satsfes the partal dfferental equaton f u =, j\ jp + jz f p p j +jp +j f f +(+j) p p j p p j f p +j+ (3)

RAMIFIED COVERINGS BY THE TORUS 49 By replacng p by x p for t s readly seen that f =8(u, x, z, p) satsfes (3) But 8(u, x, z, p)#q[u, z, p][[x]], and t s also readly seen that (3) has a unque soluton n ths rng Let F (x, p)=[z ] 8(, x, z, p) for =0,, where [z ] f denotes the coeffcent of z n the foral power seres f Then F 0 s the generatng seres for the nubers c 0 (), whch have been deterned by Hurwtz, so F 0 s known F s the generatng seres for c () The next result gves the lnear frst order partal dfferental equaton for F that s nduced by restrctng (3) above to ters of degree at ost one n z Lea 3 The seres f =F satsfes the partal dfferental equaton T 0 f &T =0, (4) where T 0 =x x + p T =, j F 0 & jp + j p p, j jp + j F 0 p p j Proof Clearly, fro (3), & p j (+j) p p j, j u u [z] 8=[z] \ x x + p p + 8 p +j, The result follows by applyng [z] to(3) K We now turn our attenton to solvng ths partal dfferental equaton Let G (x, p)= 4 n, &n l()= C \ ` = ( &)!+ _ &n & & \n = (&)! e n + & xn n! p (5) Snce (3) has a unque soluton n Q[u, z, p] [[x]], then (4) has a unque soluton n Q[p] [[x]] To establsh Theore t therefore suffces to show that f =G satsfes (4) (note that G has a constant ter of 0, so the ntal condton s satsfed)

50 GOULDEN AND JACKSON 4 THE GENERATING SERIES G To obtan a convenent for for G the followng lea s requred that expresses the eleentary syetrc functon e k (*) as the coeffcent n a foral power seres For a partton =(,, r ) let denote the nuber of occurrences of n, and we ay therefore wrte =( }}}r r) Let ()=> r =! Let P denote the set of all parttons wth the null partton adjoned Lea 4 For any nonnegatve nteger k and partton *, e k (*)= (*) k! [ p * ]( p + p +}}}) k # P p () Proof Frst # P p () =,, 0 p! p! }}} and ( p + p +}}}) k =,, 0 + +}}}=k If *=( j j ), then (*)= j j! j j! }}} so (*) k! [ p * ]( p + p +}}}) k # P p () = k! p p }}}!!}}},,,, 0\ j + +}}}=k + \ j + }}}, where the su s further constraned by + = j, + = j, Then (*) k! [ p * ]( p + p +}}}) k # P p () =[tk ](+t) j (+t) j (+3t) j 3 }}} =e k (( j j }}})) and the result follows Let K (x, p)= r r & a r p r x r, (6)

RAMIFIED COVERINGS BY THE TORUS 5 where s an nteger and a r =r r (r&)!, for r Let s#s(x, p) be the unque soluton of the functonal equaton s=xe 0 (s, p) (7) n the rng Q[p] [[x]] An explct seres expanson of s can be obtaned by Lagrange's Iplct Functon Theore (see [3, Sect ], for exaple) Let denote (s, p) The next result gves an expresson for G explctly n ters of s, and ndcates the fundaental portance of the seres s to the soluton of the partal dfferental equaton gven n (3) Theore 4 G (x, p)= 4 log(& ) & & 4 0 Proof For a partton =(,, ), let a =a }}}a and g(x, p)= n &n l()= n & () a p x n, a consttuent of the seres G gven n (5), snce ()=n! C It s easly shown that x g x = x n [t n ] e n 0 (t, p) n so, by Lagrange's Iplct Functon Theore, But, fro (7), and fro (6), x g x = & x s x = s (8) & s = s + Then x(g& 0 )x=0 and, snce g(0, p)=0, t follows that g(x, p)= 0

5 GOULDEN AND JACKSON Next we consder the ters of G n (5) that are not ncluded n g(x, p) Frst, note that % # P p % (%) =exp p, so, replacng p by ntp a for n Lea 4, we have () k! where =l() Then [ p t n ](e 0 (t, p) ) n k (t, p)=n&k a e k (), a n & k (k&)! n &k a e k () =()[ p t n ] \& k =()[ p x n ] & \ k(k&) k (t, p) + (e 0 (t, p) ) n & k k(k&) + k by Lagrange's Iplct Functon Theore, for n Then a n & k (k&)! n &k a e k ()=()[p x n ](+log(& ) & ) The result follows by cobnng the two expressons that have been obtaned and by usng the fact that G (0, p)=0 K 5 THE PROOF OF THEOREM The reanng porton of the paper s concerned wth the proof of Theore Proof Our strategy s to show that the expresson for G gven n Theore 4 satsfes the partal dfferental equaton gven n (4) We begn by consderng the dervatves that are requred n the deternaton of T 0 G &T Fro the functonal equaton (7) s = a k s k+ (9) p k k &

RAMIFIED COVERINGS BY THE TORUS 53 Then, for k, j =k j& a k s k + a k j+ s k (0) p k k & The only dervatves of F 0 that are needed are F 0 = a k p k k 3 sk & a k k s k+r a r p r r k+r, () fro Proposton 3 of [] and, fro (9) and (), s + j F 0 = a a j p p j j + j, () for, j For copleteness we note that, fro Proposton 3 of [], \ x x+ F 0 = 0 The dervatves of G that are needed are, fro (9), and, fro (0), for k, G = p k 4 a k 4\ x G x = s k & + 4 (& ) & & + (3) a k k sk \ (& ) & & + (4) Then fro Lea 3 and expressons (), (), (3), and (4) t follows that 4(& ) (T 0 G &T )= (+ 0 )& 0 (& )&(& ) A where A=, j a a j + j p + js + j, &(& ) B+(& ) C&( + &) D +( + &) E, (5) B=, j a a j j p + j s + j,

54 GOULDEN AND JACKSON C=, j, a a j a j( j+) p + jp s + j+ &, j (+ j) a + j p p j s + j, D=, j a a j j p + j s + j, E=, j, a a j a j( j+) p + jp s + j+ &, j a + j p p j s + j When the expresson (5) s transfored by replacng p s by q, for, t s edately seen to be a polynoal n q, q, of degree 3 wth ratonal coeffcents If U denotes the degree part of the expresson, for =,, 3, the transfored expresson can be wrtten n the for where 4(& ) (T 0 G &T )=U +U +U 3, U = & 0 &A&B+D, U = 0 ( + )+4 A+ B+C&( + ) D&E, U 3 =& A& C+( + ) E Then U # H [q, q, ], the set of hoogeneous polynoals of degree n q, q, Let,, H [q, q, ] [ Q[x, x, ] be the syetrzaton operaton defned by,, (q }}}q )= x?() }}}x,?()? # S extended lnearly to H [q, q, ] Then,, f =0 ples that f =0 for f # H [q, q, ] We therefore prove that U =0 by provng that,, U =0, for =,, 3 To deterne the acton of the syetrzaton operator on A,, E t s convenent to ntroduce the seres w=w(x) as the unque soluton of the functonal equaton w=xe w (6) n the rng Q[[x]] By Lagrange's Iplct Functon Theore we have w= n n n& n! x n

RAMIFIED COVERINGS BY THE TORUS 55 Now let w =w(x )andw ( j) =(x x ) j w Then, fro (6), w () = w &w, w () = w (&w ) 3, w(3) = w +w (&w ) (7) 5 The acton of the syetrzng operator on A,, E and ther products wth can be deterned n ters of these as follows It s readly seen that For (A), usng (7), we have ( )=w (+), & (A)= k x k k [xk ](w () ) = x 0 (w () ) dx x = w 0 w (&w ) 5 dw so, by rearrangeent Trvally, (A)= ((&w ) w (3) +w w () &w() ) (B)=w (3) w Next,, (C) s the syetrzaton of, j, wth respect to x and x Now a a j a j( j+) x+ j x & (+ j) a + j x x j, j, j, a a j a j( j+) x+ j x =w(3) a x j =w (3) a x But, fro (7), and ntegratng by parts, we obtan x a j j x 0 x j j+ w () x& dx x 0 w () x& dx = w 0 w e&w dw = a \ &x = & (&)! &x w +

56 GOULDEN AND JACKSON Thus, j, a a j a j( j+) x+ j x =w (3) \ =w (3) \ =w (3) \ x x &x & x x &x & x = x [t ] e t & (&)! x & w &w () x &x w &w &w w &w () + \\ & t & w + & +&w() + by the Lagrange Iplct Functon Theore Moreover, t s easly seen that, j + (+ j) a + j x x j =x w (3) &x w (3) x &x Thus, by syetrzng the ndcated lnear cobnaton of these sus, we have Trvally,, (C)=&w (3) w () &w () w (3) & w(3) w() &w() w(3) w &w (D)=w () w Fnally,, (E ) s obtaned n a fashon slar to, (C) The expresson s &w(), (E )=&w () w() &w() w() w() &w() w() w &w These results ay be cobned to gve expressons for the syetrzatons of U, U, U 3 as follows For the ter of degree one, (U )=w (3) &w() &((&w ) w (3) +w w () &w() )&w(3) w +w () w

RAMIFIED COVERINGS BY THE TORUS 57 For the ter of degree two, after rearrangeent,, (U )=(w () w(3) +w(3) w() )(&w &w )+w () w() (w +w ) & w(3) w() &w() w &w w(3) + w() w() &w() w() w &w When ultpled by w &w and a sutable power of (&w ) & and (&w ) & ths becoes a polynoal n w and w that s dentcally zero For the ter of degree three, after rearrangeent,,, 3 (U 3 )= w &w 3 (w () (w(3) w() 3 &w() w(3) 3 ) &(w () +w(3) )(w() w() 3 &w () w() 3 )) + (w () w &w (w(3) w () 3 &w() w(3) ) 3 3 &(w () +w(3) )(w() w() 3 &w () w() 3 )) + (w () 3 w &w (w(3) w () &w() w(3) ) &(w () 3 +w(3) 3 )(w() w() &w () w() )) &w () w() w(3) (&w 3 3)&w () w() 3 w(3) (&w ) &w () w() 3 w(3) (&w )&w () w() w() (w 3 +w +w 3 ) When ultpled by (w &w )(w &w 3 )(w &w 3 ) and a sutable power of (&w ) &,(&w ) & and (&w 3 ) & ths becoes a polynoal n w, w and w 3 that s dentcally zero It s quckly seen that (U ) s zero For both, (U )and,, 3 (U 3 ), however, the polynoal expressons were suffcently large that t was convenent to use Maple to carry out the routne splfcaton of ths stage Thus the syetrzaton of 4(& ) (T 0 G &T )=0 so T 0 G & T =0 It follows fro Lea 3 that F =G and ths copletes the proof of Theore K ACKNOWLEDGEMENTS Ths work was supported by grants ndvdually to IPG and DMJ fro the Natural Scences and Engneerng Research Councl of Canada

58 GOULDEN AND JACKSON REFERENCES I P Goulden, A dfferental operator for syetrc functons and the cobnatorcs of ultplyng transpostons, Trans Aer Math Soc 344 (994), 4440 I P Goulden and D M Jackson, Transtve factorzatons nto transpostons and holoorphc appngs on the sphere, Proc Aer Math Soc 5 (997), 560 3 I P Goulden and D M Jackson, ``Cobnatoral Enueraton,'' Wley, New York, 983 4 I P Goulden, D M Jackson, and A Vanshten, The nuber of rafed coverngs of the sphere by the torus and surfaces of hgher genera, Ann of Cobn, to appear, athag9905 5 A Hurwtz, Ueber Reann'sche Fla chen t gegebenen Verzwegungspunkten, Math Ann 39 (89), 60 6 V Strehl, Mnal transtve products of transpostonsthe reconstructon of a proof by A Hurwtz, Se Lothar Cobn 37 (996), Art S37c 7 R Vakl, Recursons, forulas, and graph-theoretc nterpretatons of rafed coverngs of the sphere by surfaces of genus 0 and, athco9805

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback