Lindström–Gessel–Viennot lemma

In mathematics, the Lindström–Gessel–Viennot lemma provides a way to count the number of tuples of non-intersecting lattice paths, or, more generally, paths on a directed graph. It was proved by Gessel–Viennot in 1985, based on previous work of Lindström published in 1973.

Statement

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Let G be a locally finite directed acyclic graph. This means that each vertex has finite degree, and that G contains no directed cycles. Consider base vertices   and destination vertices  , and also assign a weight   to each directed edge e. These edge weights are assumed to belong to some commutative ring. For each directed path P between two vertices, let   be the product of the weights of the edges of the path. For any two vertices a and b, write e(a,b) for the sum   over all paths from a to b. This is well-defined if between any two points there are only finitely many paths; but even in the general case, this can be well-defined under some circumstances (such as all edge weights being pairwise distinct formal indeterminates, and   being regarded as a formal power series). If one assigns the weight 1 to each edge, then e(a,b) counts the number of paths from a to b.

With this setup, write

 .

An n-tuple of non-intersecting paths from A to B means an n-tuple (P1, ..., Pn) of paths in G with the following properties:

  • There exists a permutation   of   such that, for every i, the path Pi is a path from   to  .
  • Whenever  , the paths Pi and Pj have no two vertices in common (not even endpoints).

Given such an n-tuple (P1, ..., Pn), we denote by   the permutation of   from the first condition.

The Lindström–Gessel–Viennot lemma then states that the determinant of M is the signed sum over all n-tuples P = (P1, ..., Pn) of non-intersecting paths from A to B:

 

That is, the determinant of M counts the weights of all n-tuples of non-intersecting paths starting at A and ending at B, each affected with the sign of the corresponding permutation of  , given by   taking   to  .

In particular, if the only permutation possible is the identity (i.e., every n-tuple of non-intersecting paths from A to B takes ai to bi for each i) and we take the weights to be 1, then det(M) is exactly the number of non-intersecting n-tuples of paths starting at A and ending at B.

Proof

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To prove the Lindström–Gessel–Viennot lemma, we first introduce some notation.

An n-path from an n-tuple   of vertices of G to an n-tuple   of vertices of G will mean an n-tuple   of paths in G, with each   leading from   to  . This n-path will be called non-intersecting just in case the paths Pi and Pj have no two vertices in common (including endpoints) whenever  . Otherwise, it will be called entangled.

Given an n-path  , the weight   of this n-path is defined as the product  .

A twisted n-path from an n-tuple   of vertices of G to an n-tuple   of vertices of G will mean an n-path from   to   for some permutation   in the symmetric group  . This permutation   will be called the twist of this twisted n-path, and denoted by   (where P is the n-path). This, of course, generalises the notation   introduced before.

Recalling the definition of M, we can expand det M as a signed sum of permutations; thus we obtain

 

It remains to show that the sum of   over all entangled twisted n-paths vanishes. Let   denote the set of entangled twisted n-paths. To establish this, we shall construct an involution  with the properties   and   for all  . Given such an involution, the rest-term

 

in the above sum reduces to 0, since its addends cancel each other out (namely, the addend corresponding to each   cancels the addend corresponding to  ).

Construction of the involution: The idea behind the definition of the involution   is to take choose two intersecting paths within an entangled path, and switch their tails after their point of intersection. There are in general several pairs of intersecting paths, which can also intersect several times; hence, a careful choice needs to be made. Let   be any entangled twisted n-path. Then   is defined as follows. We call a vertex crowded if it belongs to at least two of the paths  . The fact that the graph is acyclic implies that this is equivalent to "appearing at least twice in all the paths".[1] Since P is entangled, there is at least one crowded vertex. We pick the smallest   such that   contains a crowded vertex. Then, we pick the first crowded vertex v on   ("first" in sense of "encountered first when travelling along  "), and we pick the largest j such that v belongs to  . The crowdedness of v implies j > i. Write the two paths   and   as

 

where  , and where   and   are chosen such that v is the  -th vertex along   and the  -th vertex along   (that is,  ). We set   and   and   and  . Now define the twisted n-path   to coincide with   except for components   and  , which are replaced by

 

It is immediately clear that   is an entangled twisted n-path. Going through the steps of the construction, it is easy to see that  ,   and furthermore that   and  , so that applying   again to   involves swapping back the tails of   and leaving the other components intact. Hence  . Thus   is an involution. It remains to demonstrate the desired antisymmetry properties:

From the construction one can see that   coincides with   except that it swaps   and  , thus yielding  . To show that   we first compute, appealing to the tail-swap

 

Hence  .

Thus we have found an involution with the desired properties and completed the proof of the Lindström–Gessel–Viennot lemma.

Remark. Arguments similar to the one above appear in several sources, with variations regarding the choice of which tails to switch. A version with j smallest (unequal to i) rather than largest appears in the Gessel-Viennot 1989 reference (proof of Theorem 1).

Applications

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Schur polynomials

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The Lindström–Gessel–Viennot lemma can be used to prove the equivalence of the following two different definitions of Schur polynomials. Given a partition   of n, the Schur polynomial   can be defined as:

  •  

where the sum is over all semistandard Young tableaux T of shape λ, and the weight of a tableau T is defined as the monomial obtained by taking the product of the xi indexed by the entries i of T. For instance, the weight of the tableau   is  .

  •  

where hi are the complete homogeneous symmetric polynomials (with hi understood to be 0 if i is negative). For instance, for the partition (3,2,2,1), the corresponding determinant is

 

To prove the equivalence, given any partition λ as above, one considers the r starting points   and the r ending points  , as points in the lattice  , which acquires the structure of a directed graph by asserting that the only allowed directions are going one to the right or one up; the weight associated to any horizontal edge at height i is xi, and the weight associated to a vertical edge is 1. With this definition, r-tuples of paths from A to B are exactly semistandard Young tableaux of shape λ, and the weight of such an r-tuple is the corresponding summand in the first definition of the Schur polynomials. For instance, with the tableau  , one gets the corresponding 4-tuple

 

On the other hand, the matrix M is exactly the matrix written above for D. This shows the required equivalence. (See also §4.5 in Sagan's book, or the First Proof of Theorem 7.16.1 in Stanley's EC2, or §3.3 in Fulmek's arXiv preprint, or §9.13 in Martin's lecture notes, for slight variations on this argument.)

The Cauchy–Binet formula

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One can also use the Lindström–Gessel–Viennot lemma to prove the Cauchy–Binet formula, and in particular the multiplicativity of the determinant.

Generalizations

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Talaska's formula

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The acyclicity of G is an essential assumption in the Lindström–Gessel–Viennot lemma; it guarantees (in reasonable situations) that the sums   are well-defined, and it advects into the proof (if G is not acyclic, then f might transform a self-intersection of a path into an intersection of two distinct paths, which breaks the argument that f is an involution). Nevertheless, Kelli Talaska's 2012 paper establishes a formula generalizing the lemma to arbitrary digraphs. The sums   are replaced by formal power series, and the sum over nonintersecting path tuples now becomes a sum over collections of nonintersecting and non-self-intersecting paths and cycles, divided by a sum over collections of nonintersecting cycles. The reader is referred to Talaska's paper for details.

See also

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References

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  1. ^ If the graph was not acyclic, the "crowdedness" might change after applying   ; this proof would not work, and the lemma would actually become totally false.
  • Gessel, Ira M.; Viennot, Xavier G. (1989), Determinants, Paths and Plane Partitions (PDF), archived from the original (PDF) on 2017-04-17
  • Lindström, Bernt (1973), On the vector representations of induced matroids, doi:10.1112/blms/5.1.8 (inactive 1 November 2024){{citation}}: CS1 maint: DOI inactive as of November 2024 (link)
  • Sagan, Bruce E. (2001), The symmetric group, Springer
  • Stanley, Richard P. (1999), Enumerative Combinatorics, volume 2, CUP
  • Talaska, Kelli (2012), Determinants of weighted path matrices, arXiv:1202.3128v1
  • Martin, Jeremy (2012), Lecture Notes on Algebraic Combinatorics (PDF)
  • Fulmek, Markus (2010), Viewing determinants as nonintersecting lattice paths yields classical determinantal identities bijectively, arXiv:1010.3860v1