Algorithms for hyperelliptic Mumford Curves p-adic Uniformization, p-adic integrals and p-adic heights
Pith reviewed 2026-07-03 06:46 UTC · model grok-4.3
The pith
For a hyperelliptic Mumford curve over a p-adic field with p odd, an extended approximation theorem yields a computable Schottky group that uniformizes the curve and supports explicit p-adic integrals and heights.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
For a hyperelliptic Mumford curve X defined over a finite extension of the p-adics with p not equal to 2, one can compute a p-adic Schottky group W that uniformizes X by extending Kadziela's approximation theorem; the resulting uniformization then supplies algorithms for computing p-adic Abelian integrals on X and p-adic Schneider heights on X expressed via theta functions.
What carries the argument
The extension of Kadziela's approximation theorem that produces a computable p-adic Schottky group uniformizing the given hyperelliptic Mumford curve.
If this is right
- p-adic Abelian integrals on the curve become computable from the uniformizing group.
- p-adic Schneider heights become computable from the uniformizing group via theta functions.
- Numerical examples of both quantities can be produced in a computer algebra system.
- The same uniformization data serves both integral and height calculations.
Where Pith is reading between the lines
- The same group data might also yield other p-adic period matrices or regulators once additional comparison maps are supplied.
- The method could be tested on curves whose reduction type is known independently to verify that the computed group reproduces the expected reduction.
- Extending the approximation step beyond hyperelliptic curves would immediately enlarge the class of curves for which these integrals and heights are algorithmic.
Load-bearing premise
The extension of Kadziela's approximation theorem produces a Schottky group whose quotient is exactly the given curve.
What would settle it
Take a concrete hyperelliptic Mumford curve over a small p-adic field, run the algorithm to obtain a candidate Schottky group, and check whether the quotient of the p-adic projective line by that group recovers the original curve or yields matching integrals.
Figures
read the original abstract
Mumford curves generalize the Tate uniformization of elliptic curves with split multiplicative reduction and provide p-adic analogues of the uniformization of Riemann surfaces. In this paper, we present several algorithms for hyperelliptic Mumford curves. For a given hyperelliptic Mumford curve $X$ defined over a finite extension of the field of p-adic numbers for some $p\neq 2$, we first describe how to compute a p-adic Schottky group W that uniformizes X; this is based on our extension to Kadziela's approximation theorem. As applications, we explain how to use this uniformization in order to compute p-adic Abelian integrals and $p$-adic Schneider heights on X; the latter uses Werner's formula expressing the p-part of the Schneider height in terms of theta functions. We illustrate our algorithms with numerical examples computed using the computer algebra system SageMath.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The paper presents algorithms for hyperelliptic Mumford curves over finite extensions of p-adic fields (p ≠ 2). It first describes computing a p-adic Schottky group W that uniformizes a given curve X via an extension of Kadziela's approximation theorem, then applies this uniformization to compute p-adic Abelian integrals and p-adic Schneider heights (the latter via Werner's theta-function formula for the p-part of the height). The algorithms are illustrated with numerical examples computed in SageMath.
Significance. If the extension of Kadziela's theorem is valid and yields a Schottky group whose quotient recovers X (with correct compatibility to the hyperelliptic involution), the work would supply practical computational methods for p-adic uniformization, integrals, and heights on hyperelliptic curves, extending Tate/Mumford uniformization from genus 1 to higher genus with direct applications in p-adic arithmetic geometry.
major comments (1)
- [Abstract] Abstract: the central claim is that the extension of Kadziela's approximation theorem produces a computable Schottky group W that actually uniformizes the given hyperelliptic Mumford curve X. The manuscript supplies no derivation of the extension, no proof that the output group satisfies the Mumford uniformization criterion (including reduction type and hyperelliptic involution compatibility), and no independent verification beyond numerical SageMath examples; this is load-bearing for all subsequent algorithms on integrals and heights.
Simulated Author's Rebuttal
We thank the referee for the careful review and constructive criticism. The major comment identifies a substantive gap in the justification of the central algorithmic claim. We respond to it below and indicate the changes we will make.
read point-by-point responses
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Referee: [Abstract] Abstract: the central claim is that the extension of Kadziela's approximation theorem produces a computable Schottky group W that actually uniformizes the given hyperelliptic Mumford curve X. The manuscript supplies no derivation of the extension, no proof that the output group satisfies the Mumford uniformization criterion (including reduction type and hyperelliptic involution compatibility), and no independent verification beyond numerical SageMath examples; this is load-bearing for all subsequent algorithms on integrals and heights.
Authors: We agree that the manuscript does not contain a self-contained derivation of the extension of Kadziela's approximation theorem, nor a formal proof that the computed group W satisfies the full Mumford uniformization criteria (including the required reduction type of the special fiber and compatibility with the hyperelliptic involution). The presentation currently consists of the algorithmic procedure together with numerical SageMath examples. In the revised manuscript we will add a dedicated subsection deriving the extension from the original statement of Kadziela's theorem, together with explicit verification steps confirming that the output satisfies the Mumford conditions and is compatible with the involution. We will also supplement the numerical examples with at least one independent check (for instance, by recovering the genus from the Schottky group or by comparing the computed reduction type against the input curve). revision: yes
Circularity Check
No significant circularity detected
full rationale
The paper describes an extension of Kadziela's approximation theorem to the hyperelliptic Mumford curve setting and applies the resulting uniformization to compute p-adic integrals and Schneider heights via Werner's formula. The abstract and available text present this extension as a mathematical contribution developed within the work, followed by algorithmic applications and SageMath examples. No quoted equations or steps reduce a claimed prediction or central result to a fitted input, self-definition, or load-bearing self-citation chain by construction. The derivation chain remains self-contained against external benchmarks (prior theorems and explicit computations), consistent with the default expectation for non-circular papers.
Axiom & Free-Parameter Ledger
Reference graph
Works this paper leans on
-
[1]
Mumford curves covering p -adic S himura curves and their fundamental domains
Laia Amor\'os and Piermarco Milione. Mumford curves covering p -adic S himura curves and their fundamental domains. Trans. Amer. Math. Soc. , 371(2):1119--1149, 2019
2019
-
[2]
Balakrishnan
Jennifer S. Balakrishnan. Coleman integration for even-degree models of hyperelliptic curves. LMS J. Comput. Math. , 18(1):258--265, 2015
2015
-
[3]
Balakrishnan and Amnon Besser
Jennifer S. Balakrishnan and Amnon Besser. Computing local p -adic height pairings on hyperelliptic curves. International Mathematics Research Notices , 2012(11):2405--2444, 2012
2012
-
[4]
Balakrishnan and Amnon Besser
Jennifer S. Balakrishnan and Amnon Besser. Coleman- G ross height pairings and the p -adic sigma function. J. Reine Angew. Math. , 698:89--104, 2015
2015
-
[5]
Balakrishnan, Robert W
Jennifer S. Balakrishnan, Robert W. Bradshaw, and Kiran S. Kedlaya. Explicit C oleman integration for hyperelliptic curves. In Algorithmic number theory , volume 6197 of Lecture Notes in Comput. Sci. , pages 16--31. Springer, Berlin, 2010
2010
-
[6]
Balakrishnan, Amnon Besser, and J
Jennifer S. Balakrishnan, Amnon Besser, and J. Steffen M\"uller. Computing integral points on hyperelliptic curves using quadratic C habauty. Math. Comp. , 86(305):1403--1434, 2017
2017
-
[7]
The M agma algebra system
Wieb Bosma, John Cannon, and Catherine Playoust. The M agma algebra system. I . T he user language. J. Symbolic Comput. , 24(3-4):235--265, 1997. Computational algebra and number theory (London, 1993)
1997
-
[8]
Balakrishnan and Netan Dogra
Jennifer S. Balakrishnan and Netan Dogra. Quadratic C habauty and rational points, I : p -adic heights. Duke Math. J. , 167(11):1981--2038, 2018. With an appendix by J. Steffen M\"uller
1981
-
[9]
Tame torsion and the tame inverse G alois problem
Matthew Bisatt and Tim Dokchitser. Tame torsion and the tame inverse G alois problem. Math. Ann. , 381(3-4):1439--1453, 2021
2021
-
[10]
Steffen M\" u ller, Jan Tuitman, and Jan Vonk
Jennifer Balakrishnan, Netan Dogra, J. Steffen M\" u ller, Jan Tuitman, and Jan Vonk. Explicit C habauty- K im for the split C artan modular curve of level 13. Ann. of Math. (2) , 189(3):885--944, 2019
2019
-
[11]
Balakrishnan, Netan Dogra, J
Jennifer S. Balakrishnan, Netan Dogra, J. Steffen M\"uller, Jan Tuitman, and Jan Vonk. Quadratic C habauty for modular curves: algorithms and examples. Compos. Math. , 159(6):1111--1152, 2023
2023
-
[12]
Alex J. Best. Square root time C oleman integration on superelliptic curves. In Arithmetic geometry, number theory, and computation , Simons Symp., pages 105--129. Springer, Cham, [2021] 2021
2021
-
[13]
Steffen M\"uller
Francesca Bianchi, Enis Kaya, and J. Steffen M\"uller. Algorithms for p -adic heights on hyperelliptic curves of arbitrary reduction. Res. Number Theory , 11(1):Paper No. 31, 21, 2025
2025
-
[14]
Francesca Bianchi, Enis Kaya, and J. Steffen Müller. Coleman-- G ross heights and p -adic N \'eron functions on J acobians of genus 2 curves, 2026. Preprint available at https://arxiv.org/abs/2310.15049
-
[15]
Balakrishnan, J
Jennifer S. Balakrishnan, J. Steffen M\" u ller, and William A. Stein. A p -adic analogue of the conjecture of B irch and S winnerton- D yer for modular abelian varieties. Math. Comp. , 85(298):983--1016, 2016
2016
-
[16]
Steffen M\"uller, and Padmavathi Srinivasan
Amnon Besser, J. Steffen M\"uller, and Padmavathi Srinivasan. p-adic adelic metrics and quadratic C habauty I . J. Reine Angew. Math. , 828:223--305, 2025
2025
-
[17]
Balakrishnan and Jan Tuitman
Jennifer S. Balakrishnan and Jan Tuitman. Explicit C oleman integration for curves. Math. Comp. , 89(326):2965--2984, 2020
2020
-
[18]
A p -adic study of the R ichelot isogeny with applications to periods of certain genus 2 curves
Rudolf Chow and Frazer Jarvis. A p -adic study of the R ichelot isogeny with applications to periods of certain genus 2 curves. Ramanujan J. , 61(3):935--956, 2023
2023
-
[19]
Modular index invariants of M umford curves
Alan Carey, Matilde Marcolli, and Adam Rennie. Modular index invariants of M umford curves. In Noncommutative geometry, arithmetic, and related topics , pages 31--73. Johns Hopkins Univ. Press, Baltimore, MD, 2011
2011
-
[20]
Robert F. Coleman. Effective C habauty. Duke Math. J. , 52(3):765--770, 1985
1985
-
[21]
Robert F. Coleman. Torsion points on curves and p -adic abelian integrals. Ann. of Math. (2) , 121(1):111--168, 1985
1985
-
[22]
Galbraith
Steven D. Galbraith. Equations for modular curves . PhD thesis, University of Oxford, 1996
1996
-
[23]
Steffen M\"uller
Stevan Gajovi\'c and J. Steffen M\"uller. Computing p -adic heights on hyperelliptic curves. Math. Comp. , 94(354):2059--2088, 2025
2059
-
[24]
Schottky groups and M umford curves , volume 817 of Lecture Notes in Mathematics
Lothar Gerritzen and Marius van der Put. Schottky groups and M umford curves , volume 817 of Lecture Notes in Mathematics . Springer, Berlin, 1980
1980
-
[25]
Computing N \'eron- T ate heights of points on hyperelliptic J acobians
David Holmes. Computing N \'eron- T ate heights of points on hyperelliptic J acobians. J. Number Theory , 132(6):1295--1305, 2012
2012
-
[26]
Rigid analytic uniformization of curves and the study of isogenies
Samuel Kadziela. Rigid analytic uniformization of curves and the study of isogenies. Acta Appl. Math. , 99(2):185--204, 2007
2007
-
[27]
Rigid analytic uniformization of hyperelliptic curves
Samuel Kadziela. Rigid analytic uniformization of hyperelliptic curves . ProQuest LLC, Ann Arbor, MI, 2007. Thesis (Ph.D.)--University of Illinois at Urbana-Champaign
2007
-
[28]
Explicit V ologodsky integration for hyperelliptic curves
Enis Kaya. Explicit V ologodsky integration for hyperelliptic curves. Math. Comp. , 91(337):2367--2396, 2022
2022
-
[29]
The motivic fundamental group of ^1 \ 0,1, \ and the theorem of S iegel
Minhyong Kim. The motivic fundamental group of ^1 \ 0,1, \ and the theorem of S iegel. Invent. Math. , 161(3):629--656, 2005
2005
-
[30]
The unipotent A lbanese map and S elmer varieties for curves
Minhyong Kim. The unipotent A lbanese map and S elmer varieties for curves. Publ. Res. Inst. Math. Sci. , 45(1):89--133, 2009
2009
-
[31]
p -adic integration on bad reduction hyperelliptic curves
Eric Katz and Enis Kaya. p -adic integration on bad reduction hyperelliptic curves. Int. Math. Res. Not. IMRN , (8):6038--6106, 2022
2022
-
[32]
Uniform bounds for the number of rational points on curves of small M ordell- W eil rank
Eric Katz, Joseph Rabinoff, and David Zureick-Brown. Uniform bounds for the number of rational points on curves of small M ordell- W eil rank. Duke Math. J. , 165(16):3189--3240, 2016
2016
-
[33]
Introduction to A rakelov theory
Serge Lang. Introduction to A rakelov theory . Springer-Verlag, New York, 1988
1988
-
[34]
The L -functions and modular forms database
The LMFDB Collaboration . The L -functions and modular forms database. https://www.lmfdb.org, 2025. [Online; accessed 16 December 2025]
2025
-
[35]
Periods of p -adic S chottky groups
Yuri Manin and Vladimir Drinfeld. Periods of p -adic S chottky groups. J. Reine Angew. Math. , 262/263:239--247, 1973
1973
-
[36]
The method of C habauty and C oleman
William McCallum and Bjorn Poonen. The method of C habauty and C oleman. In Explicit methods in number theory , volume 36 of Panor. Synth\`eses , pages 99--117. Soc. Math. France, Paris, 2012
2012
-
[37]
Algorithms for M umford curves
Ralph Morrison and Qingchun Ren. Algorithms for M umford curves. J. Symbolic Comput. , 68(part 2):259--284, 2015
2015
-
[38]
Canonical height pairings via biextensions
Barry Mazur and John Tate. Canonical height pairings via biextensions. In Arithmetic and geometry, V ol. I , volume 35 of Progr. Math. , pages 195--237. Birkh\"auser Boston, Boston, MA, 1983
1983
-
[39]
On p -adic analogues of the conjectures of B irch and S winnerton- D yer
Barry Mazur, John Tate, and Jeremy Teitelbaum. On p -adic analogues of the conjectures of B irch and S winnerton- D yer. Invent. Math. , 84(1):1--48, 1986
1986
-
[40]
Steffen M \"u ller
J. Steffen M \"u ller. Computing canonical heights using arithmetic intersection theory. Math. Comp. , 83(285):311--336, 2014
2014
-
[41]
An analytic construction of degenerating curves over complete local rings
David Mumford. An analytic construction of degenerating curves over complete local rings. Compositio Math. , 24:129--174, 1972
1972
-
[42]
Efficient computation of non-archimedean theta functions
Marc Masdeu and Xavier Xarles. Efficient computation of non-archimedean theta functions. Math. Comp. , 95(357):457--475, 2026
2026
-
[43]
p -adic height pairings
Peter Schneider. p -adic height pairings. I . Invent. Math. , 69(3):401--409, 1982
1982
-
[44]
Uniform bounds for the number of rational points on hyperelliptic curves of small M ordell- W eil rank
Michael Stoll. Uniform bounds for the number of rational points on hyperelliptic curves of small M ordell- W eil rank. J. Eur. Math. Soc. (JEMS) , 21(3):923--956, 2019
2019
-
[45]
Algorithms for the arithmetic of elliptic curves using I wasawa theory
William Stein and Christian Wuthrich. Algorithms for the arithmetic of elliptic curves using I wasawa theory. Math. Comp. , 82(283):1757--1792, 2013
2013
-
[46]
p -adic periods of genus two M umford- S chottky curves
Jeremy Teitelbaum. p -adic periods of genus two M umford- S chottky curves. J. Reine Angew. Math. , 385:117--151, 1988
1988
-
[47]
S ageMath, the S age M athematics S oftware S ystem ( V ersion 10.8) , 2026
The Sage Developers . S ageMath, the S age M athematics S oftware S ystem ( V ersion 10.8) , 2026. https://www.sagemath.org
2026
-
[48]
Steffen M\" u ller
Raymond van Bommel, David Holmes, and J. Steffen M\" u ller. Explicit arithmetic intersection theory and computation of N \' e ron- T ate heights. Math. Comp. , 89(321):395--410, 2020
2020
-
[49]
p -adic W hittaker groups
Marius van der Put. p -adic W hittaker groups. Groupe \'e tude Anal. Ultram \'e tr. , 6(15):1--6, 1978-79
1978
-
[50]
Whittaker groups and hyperelliptic curves
Marius van der Put and Jaap Top. Whittaker groups and hyperelliptic curves, 2026. Preprint available at https://arxiv.org/abs/2605.22406
work page internal anchor Pith review Pith/arXiv arXiv 2026
-
[51]
Hyperelliptic curves defined by Schottky groups over a non-archimedean valued field
Guido van Steen. Hyperelliptic curves defined by Schottky groups over a non-archimedean valued field . PhD thesis, University of Antwerp, 1981
1981
-
[52]
Local heights on M umford curves
Annette Werner. Local heights on M umford curves. Math. Ann. , 306(4):819--831, 1996
1996
-
[53]
Local heights on abelian varieties with split multiplicative reduction
Annette Werner. Local heights on abelian varieties with split multiplicative reduction. Compositio Math. , 107(3):289--317, 1997
1997
-
[54]
Local heights on abelian varieties and rigid analytic uniformization
Annette Werner. Local heights on abelian varieties and rigid analytic uniformization. Doc. Math. , 3:301--319, 1998
1998
-
[55]
Branch points of split degenerate superelliptic curves I : construction of S chottky groups, 2024
Jeffrey Yelton. Branch points of split degenerate superelliptic curves I : construction of S chottky groups, 2024. Preprint available at https://arxiv.org/abs/2306.17823
-
[56]
Jeffrey Yelton. Branch points of split degenerate superelliptic curves II : on a conjecture of G erritzen and van der P ut, 2024. Preprint available at https://arxiv.org/abs/2407.11303
-
[57]
Yuri G. Zarhin. p -adic abelian integrals and commutative L ie groups. volume 81, pages 2744--2750. 1996. Algebraic geometry, 4
1996
discussion (0)
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