A tropical approach to rigidity: Counting realisations of frameworks

Oliver Clarke; Sean Dewar; Daniel Green Tripp; James Maxwell; Anthony Nixon; Yue Ren; Ben Smith

doi:10.1112/jlms.70438

A tropical approach to rigidity: Counting realisations of frameworks

Oliver Clarke, Sean Dewar^*, Daniel Green Tripp, James Maxwell, Anthony Nixon, Yue Ren, Ben Smith

^*Corresponding author for this work

Research output: Contribution to journal › Article (Academic Journal) › peer-review

Abstract

A realisation of a graph in the plane as a bar‐joint framework is rigid if there are finitely many other realisations, up to isometries, with the same edge lengths. Each of these finitely many realisations can be seen as a solution to a system of quadratic equations prescribing the distances between pairs of points. For generic realisations, the size of the solution set depends only on the underlying graph so long as we allow for complex solutions. We provide a characterisation of the realisation number — that is the cardinality of this complex solution set — of a minimally rigid graph. Our characterisation uses tropical geometry to express the realisation number as an intersection of Bergman fans of the graphic matroid. As a consequence, we derive a combinatorial upper bound on the realisation number involving the Tutte polynomial. Moreover, we provide computational evidence that our upper bound is usually an improvement on the mixed volume bound.

Original language	English
Article number	e70438
Number of pages	42
Journal	Journal of the London Mathematical Society
Volume	113
Issue number	2
DOIs	https://doi.org/10.1112/jlms.70438
Publication status	Published - 23 Feb 2026

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© 2026 The Author(s).

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title = "A tropical approach to rigidity: Counting realisations of frameworks",

abstract = "A realisation of a graph in the plane as a bar‐joint framework is rigid if there are finitely many other realisations, up to isometries, with the same edge lengths. Each of these finitely many realisations can be seen as a solution to a system of quadratic equations prescribing the distances between pairs of points. For generic realisations, the size of the solution set depends only on the underlying graph so long as we allow for complex solutions. We provide a characterisation of the realisation number — that is the cardinality of this complex solution set — of a minimally rigid graph. Our characterisation uses tropical geometry to express the realisation number as an intersection of Bergman fans of the graphic matroid. As a consequence, we derive a combinatorial upper bound on the realisation number involving the Tutte polynomial. Moreover, we provide computational evidence that our upper bound is usually an improvement on the mixed volume bound.",

author = "Oliver Clarke and Sean Dewar and Tripp, \{Daniel Green\} and James Maxwell and Anthony Nixon and Yue Ren and Ben Smith",

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AU - Clarke, Oliver

AU - Dewar, Sean

AU - Tripp, Daniel Green

AU - Maxwell, James

AU - Nixon, Anthony

AU - Ren, Yue

AU - Smith, Ben

PY - 2026/2/23

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N2 - A realisation of a graph in the plane as a bar‐joint framework is rigid if there are finitely many other realisations, up to isometries, with the same edge lengths. Each of these finitely many realisations can be seen as a solution to a system of quadratic equations prescribing the distances between pairs of points. For generic realisations, the size of the solution set depends only on the underlying graph so long as we allow for complex solutions. We provide a characterisation of the realisation number — that is the cardinality of this complex solution set — of a minimally rigid graph. Our characterisation uses tropical geometry to express the realisation number as an intersection of Bergman fans of the graphic matroid. As a consequence, we derive a combinatorial upper bound on the realisation number involving the Tutte polynomial. Moreover, we provide computational evidence that our upper bound is usually an improvement on the mixed volume bound.

AB - A realisation of a graph in the plane as a bar‐joint framework is rigid if there are finitely many other realisations, up to isometries, with the same edge lengths. Each of these finitely many realisations can be seen as a solution to a system of quadratic equations prescribing the distances between pairs of points. For generic realisations, the size of the solution set depends only on the underlying graph so long as we allow for complex solutions. We provide a characterisation of the realisation number — that is the cardinality of this complex solution set — of a minimally rigid graph. Our characterisation uses tropical geometry to express the realisation number as an intersection of Bergman fans of the graphic matroid. As a consequence, we derive a combinatorial upper bound on the realisation number involving the Tutte polynomial. Moreover, we provide computational evidence that our upper bound is usually an improvement on the mixed volume bound.

U2 - 10.1112/jlms.70438

DO - 10.1112/jlms.70438

M3 - Article (Academic Journal)

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JO - Journal of the London Mathematical Society

JF - Journal of the London Mathematical Society

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M1 - e70438

ER -

A tropical approach to rigidity: Counting realisations of frameworks

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