A graph G is called a sum graph if there exists a labelling of the vertices of G by distinct positive integers such that the vertices labelled u and v are adjacent if and only if there exists a vertex labelled u + v. If G is not a sum graph, adding a finite number of isolated vertices to it will always yield a sum graph, and the sum number oe(G) of G is the smallest number of isolated vertices that will achieve this result. A labelling that realizes G + K oe(G) as a sum graph is said to be optimal. In this paper we consider G = H m;n , the complete n-partite graph on n 2 sets of m 2 nonadjacent vertices. We give an optimal labelling to show that oe(H 2;n ) = 4n \Gamma 5, and in the general case we give constructive proofs that oe(H m;n ) 2 \Omega\Gamma mn) and oe(H m;n ) 2 O(mn 2 ). We conjecture that oe(H m;n ) is asymptotically greater than mn, the cardinality of the vertex set; if so, then H m;n is the first known graph with this property. We also provide for the first time an optimal labelling of the complete bipatite graph Kmn whose smallest label is 1

Miller, M.

Ryan, J.F.

Smyth, W.F.

English

Research Repository

  MURDOCH RESEARCH REPOSITORY  Authors Version     Miller, M., Ryan, J.F. and Smyth, W.F. (1998) The sum number of the cocktail party graph. Bulletin of the Institute of Combinatorics and its Applications, 22 . pp. 79-90.    http://researchrepository.murdoch.edu.au/27559/          Copyright: © 1998 The Institute of Combinatorics and its Applications It is posted here for your personal use. No further distribution is permitted.            The Sum Number of the Cocktail Party GraphMirka MILLERDepartment of Computer ScienceThe University of Newcastle NSW  Australiaemail mirka	csnewcastleeduauJoseph F RYANDepartment of MathematicsThe University of Newcastle NSW  Australiaemail joe	freynewcastleeduauW F SMYTHDepartment of Computer Science and SystemsMcMaster University Hamilton Ontario CanadaSchool of ComputingCurtin University Perth WA  Australiaemail smyth	mcmastercaAbstractA graph G is called a sum graph if there exists a labelling of the vertices of G bydistinct positive integers such that the vertices labelled u and v are adjacent if andonly if there exists a vertex labelled u v If G is not a sum graph adding a nitenumber of isolated vertices to it will always yield a sum graph and the sum numberG of G is the smallest number of isolated vertices that will achieve this resultA labelling that realizes G K G as a sum graph is said to be optimal In thispaper we consider G  Hmn the complete n	partite graph on n    sets of m   nonadjacent vertices We give an optimal labelling to show that Hn  n and in the general case we give constructive proofs that Hmn  mn andHmn  Omn We conjecture that Hmn is asymptotically greater thanmn the cardinality of the vertex set if so then Hmn is the rst known graph withthis property We also provide for the rst time an optimal labelling of the completebipartite graph Kmn whose smallest label is  IntroductionSince the introduction of sum graphs by Harary  a number of easilystated but tantalizingly di	cult problems have emerged Do there exist graphs G  VE such that G   jV j This question wasanswered in the a	rmative by Gould  Rodl  but their methods provide nomeans of constructing such graphs In fact the only known class of graphs G thateven achieves as much as G   jEj is the class of wheels Wn with n spokes asshown in  and Wn  n   for n even n for n oddWith the possible exception of the graphs considered in this paper no graphs areknown whose sum number exceeds jV j in an asymptotic sense Eorts to nd graphs of large sum number have of course led to a consideration ofgraphs with many edges for example complete graphs Kn and complete bipartitegraphs Kmn But for these graphs it turns out that G   jV j Bergstrand etal showed  that for n   Kn  n  while Hartseld and Smyth showed that for n  m   Kmn  dm  n e Attention has also been directed toward graphs of small sum number in particulartoward unit graphs graphs G such that G   Ellingham showed  that forevery forest F  F    and Smyth showed  that for all integers n   andm   nbnc there exists a unit graph with n vertices and m edges Furthereorts to characterize unit graphs have so far been unsuccessful In a labelling of a sum graph vertices whose label corresponds to an edge u v aresaid to be working vertices It has been realized that certain graphs can only belabelled in such a way that all the working vertices are also isolates such graphsare called exclusive Exclusive graphs are of interest for two reasons they may beeasier to label optimally and they may be more likely to have a large sum numberIt turns out that Kn and Wn are exclusive while F and Kmn are not We show inthis paper that Hmn also is exclusive but the characterization of exclusive graphsremains an open problem Optimal labellings that include  as the least label are called minimal labellings Itis not known whether or not every graph G has at least one minimal labelling Thelabellings presented in this paper for Hmn and Kmn are either minimal or haveequivalent minimal labellings The number of dierent edges u v to which a vertex label corresponds is called themultiplicity  of the vertex Thus nonworking vertices have zero multiplicity Forcertain graphs  notably Kn and Kmn  the multiplicity pattern of the verticesis the same for every optimal labelling Thus nding a means of specifying themultiplicity pattern for these kinds of graphs would eliminate the need to exhibita specic labelling No general results for identifying multiplicity patterns have sofar been discovered though the concept is useful in this paper as in others forestablishing other properties of sum graphsIn his original paper  Harary mentions the curious case of the cycle Cn n   forn   Cn   while C   In a recent paper  Sharary nds C also to bean anomaly for integral sum graphs In this paper we describe a minimal labelling forHn sometimes called the cocktail party graph that achieves Hn  n n  Since H is isomorphic to C and H   it appears that as a component of a sumgraph C is more naturally regarded as a cocktail party graph than as a cycle Moregenerally we give a lower bound for Hmn and show also that Hmn   Omn Finallywe extend our discussion of bipartite graphs by exhibiting for the rst time a minimallabelling for Kmn The Working VerticesThroughout this paper we refer to vertices by their labels usually of the form vi If twovertices are not adjacent we say that they are independent For Hmn we use the symbolfig to denote the independent set fvi vi     vimg that is the set of all vertices thatare independent of a specied vertex vi Note that this set includes vi itself The vertexvivj is said to correspond to the edge vi vj and we write vifjg to denote the set ofdistinct vertices corresponding to the edges joining vi to fjgTheorem  Hmn is exclusiveProof Let Hmn  VE Assume that Hmn is not exclusive and let vk  vivj denotethe largest working vertex in V  Without loss of generality suppose that vi  vj  vkThis leads to two cases vk is adjacent to both vi and vj vk is adjacent to exactly one of vivj assumed without loss of generality to be viCase  vk   fig  fjgIn this case the vertices vkvj      vkvmj all exist Then since for every h   mvk  vjh  vivjh  vjit follows that all the vertices vifjg   V  Similarly vjfig   V  Setting V   vjfig  vifjg we see that m  jV  j  m If jV  j  m there is at least one vertex in V   not contained in fkg which means that atleast one of the vertices in V   must be adjacent to vk Then either there exists p   msuch that vivjp vk   E or there exists q   m such that vjviq vk   E Thisimplies that either vivk   V or vjvk   V  contradicting the original assumption thatvk is the largest working nonisolate We conclude that jV j  m hence that V    fkgLet vi  vj  and vk   vk denote the smallest vertices in fig fjg and fkg respectivelyThenvk   vivj   vi vjand it is clear that vi   vi and vj    vj Now consider the edge vk   vj   to which thevertexvk vj   vi vj   vjcorresponds This tells us that vi vj  is a working vertex in V that is however not infkg Hence vkvi vj   is a working vertex so that vkvi  vj     E and vkvi    V Since vkvi   vk this contradicts the assumption that vk is the largest working vertexin V  and so we conclude that Case  is impossibleCase  vk   fjgSuppose there exists q   m such that viqvj   fjg But since viqvk  viqvj  vimust exist it follows that viqvj   V  Hence viqvj vk is an edge so that viqvk vjis a vertex revealing viqvk as a working nonisolate greater than vk a contradictionWe conclude then that viqvj   fjg for all q   m That is each element of vjfigis contained in fjg But since there are m elements in each set it therefore followsthat vjfig  fjg an impossibility since vj   vjfig Thus Case  is also impossiblecompleting the proof  For n   note that Hm  Kmm The complete bipartite graph is not generallyexclusive  but the symmetric complete bipartite graph Kmm is exclusive suggestingthat for the purposes of sum graphs it more naturally resides in Hmn than in Kmn The Sum Number of Hmn  Lower  Upper Bounds for   HmnTheorem  Hmn  mn m Proof Let v  and v denote the smallest and largest labels in V  respectively under somelabelling of Hmn Consider the sets of verticesV    fv vi  v  vi   EgV   fviv  vi v   EgObserve that jV  j  jV j  mnm Observe also that if v  v   E then v v is boththe greatest element in V   and the least element in V  otherwise V    V    Thusmn m  jV    V j  mn m from which the result follows  Theorem Hmn  mn n  n even mn   mn    n oddProof We exhibit labellings of Hmn that yield the sum numbers speciedFor even n  l number the vertices of pairs H i of independent sets as followsH i  fk  i  f      m gg  fk  i  f      mgg   i  l  where i  m  i   and k is chosen su	ciently large to avoid any accidentaladditional edges say k  lFor the isolates let Ii be the set of isolates arising from edges between the two independentsets in H i and let Iij be the set of isolates arising from edges between Hi and Hj i  jThenIi  fk  i  f      m gg and Iij  fk  i  j  f      mggSimple counting yields jIij  m  and jIijj  m  If we further letI  iIi and I  ijIijand denote the set of isolates by I thenI  I  Iand jIj  jIj jIj  jI  Ij lm  lm  jI  IjIt remains to calculate jI  IjBy virtue of the numbering we have maxIi  minIi i        l   along withminI  maxI accounting for l repetitions Further repetitions stem from noting thatthe two greatest terms in Ii are duplicated as are the two least terms in Ii accountingfor two repetitions from each of l   sets Totalling gives jI  Ij  l   so we havejIj  lm  lm  l   lml  l  For n  l   label the rst independent set J ask  f      mgand the remaining l sets in a way similar to the even caseH i  fk  i  f      m gg  fk  i  f      mgg   i  l  where i  im   i  m  and k  lThis time the set of isolates are considered as a union of three setsIi accounting for edges between vertices in HiIJi accounting for edges between J and HiIij accounting for edges between Hi and Hj i  jwhereIi  fk  i  f      m ggIJi  fk  i  f      mggIij  fk  i  j  f      mggLetI  iIi I  iIJi I  ijIijand similar to the case of even n we have I  I  I  I In this case jIij m  jIJij  m  and jIijj  m  and as beforejIj  jIj jIj jIj  jI  Ij  jI  Ij  jI  Ij jI  I  Ij jIj jIj jIj  j duplicates j lm   lm  lm  j duplicates jwhere as above it remains to calculate the duplicatesIn a similar manner to the even case we have maxIi  minIJi i        l  along with minI  maxIJ accounting for l repetitions ie jI Ij  l Again the twogreatest terms in IJi are duplicated as are the two least terms in Ii accounting for tworepetitions in each of l  sets jI Ij  l  Since jI Ij  jI I Ij   totalling gives the number of repetitions as l   so we havejIj  lm   lm  lm  l   lm ml l  l  Expressing l in terms of n and doing some manipulation yields the forms given in thestatement of the theorem  We conjecture that in fact Hmn   mn in general even though as the nextsection shows a better result holds for m    The Sum Number of H nSubstituting m   into Theorem  yields Hn  n We now present a labellingof the vertices of Hn that achieves Hn  n This labelling is also based on the labelling for the complete graph Kn as presentedin  Note thatHn  n  n   Kn We construct Hn by considering Kn and removing n independent edges with just twoisolates By labelling Kn according tovi    i  i       nwe induce a labelling on the isolates according tovj    i  i       n To apply this labelling to Hn	 When n is even remove the smallest and largest isolates with multiplicity n andthe corresponding edges from the graph	 For n odd remove the smallest isolate with multiplicity n   and the largestisolate with multiplicity n  Remove the corresponding edgesIn both cases we have removed  isolates from the sum graph for Kn and n correspondingnonadjacent edges A Minimal Labelling for KmnAs stated in the Introduction a minimal labelling is an optimal sum graph labelling inwhich the smallest label is  In  Hartseld and Smyth gave a labelling for Kmn whichin most cases was not minimal We present a minimal labelling for all complete bipartitegraphsThroughout we assume m  n and label the partite sets Vm and Vn of cardinality mand n respectively In keeping with the manner of  we rst consider the case wherem  n is odd and denote Vn as the non intersecting union of two sets of vertices Q andQ with cardinalities respectively q and q n q R refers to the set of isolates Thelabelling is as followsNumber Vm   ix i         m  x  maxm q qNumber Q y  jx j         q   q nmNumber Q y  kx   k         n q   x   y  x Number R y  lx   l         Kmn Selecting y in the interval x  x  removes the possibility of vertices in Vm and Vnhaving the same labelThe following lemma shows that we have accounted for all edgesLemma  Suppose that a   Vm Theni for b   Q a  b   Qii for b   Q a b   RProof ia    ix i         m b  y  jx j         q  a b  y  i  jx  i j         m   q  Note that m   q    mnm   nm n q   Sofa b  a   Vm b   Qg  Qiia    ix i         m b  y  kx   k         n q  a b  y  k  ix  k  i         m   n q  where m   n q    m   nnm   mn   Kmn  Sofa b  a   Vm b   Qg  R As in  the case m n even follows by labelling Kmn as above and removing onevertex and incident edges from Q leaving a labelling for KmnAcknowledgementsThe work of the third author was supported in part by Grant No A of the NaturalSciences  Engineering Research Council of Canada and by Grant No GO of theMedical Research Council of CanadaReferences D Bergstrand F Harary K Hodges G Jennings L Kuklinski  J Wiener Thesum number of a complete graph Bull Malaysian Math Soc    Mark N Ellingham Sum graphs from trees Ars Combinatoria 	   R Gould  V Rodl Bounds on the number of isolated vertices in sumgraphs Graph Theory Combinatorics and Applications edited by Y Alevi GChartrand O R Oellermann  A J Schwenk John Wiley  Sons   F Harary Sum graphs and dierence graphs Congressus Numerantium      Nora Hartseld W F Smyth The sum number of complete bipartite graphsGraphs and Matrices edited by Rolf Rees Marcel Dekker     Nora Hartseld  W F Smyth A family of sparse graphs of large sum num	ber Discrete Math    Mirka Miller Joseph F Ryan Slamin  W F Smyth Labelling wheels for min	imum sum number submitted for publication  Ahmad Sharary Integral sum graphs from complete graphs cycles andwheels Arab Gulf J Sci Res    W F Smyth Sum graphs of small sum number Colloq Math Soc Janos Bolyai  

The sum number of the cocktail party graph

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The sum number of the cocktail party graph

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