Dr. Cristian-Silviu Radu

Research Area

Computer mathematics

Office

Schloss Hagenberg
A-4232 Hagenberg im Mühlkreis

Room: 0.2-5

Postal Address

Research Institute for Symbolic Computation
Johannes Kepler University
Altenberger Straße 69
A-4040 Linz, Austria

Phone

+43 732 2468 9981

eMail

sradu@risc.jku.at

Software

math4ti2

A Mathematica Interface to 4ti2

math4ti2.m is an interface package, allowing the execution of zsolve of the package 4ti2 from within Mathematica notebooks. The package is written by Ralf Hemmecke and Silviu Radu. Licence This program is free software: you can redistribute it and/or ...

Authors: Ralf Hemmecke, Cristian-Silviu Radu

More Software Website

Publications

2023

[Radu]

Error bounds for the asymptotic expansion of the partition function

Koustav Banerjee, Peter Paule, Cristian-Silviu Radu, Carsten Schneider

Rocky Mt J Math to appear, pp. ?-?. 2023. ISSN: 357596. arXiv:2209.07887 [math.NT]. [doi]

[bib]

@article{RISC6710,
author = {Koustav Banerjee and Peter Paule and Cristian-Silviu Radu and Carsten Schneider},
title = {{Error bounds for the asymptotic expansion of the partition function}},
language = {english},
abstract = {Asymptotic study on the partition function $p(n)$ began with the work of Hardy and Ramanujan. Later Rademacher obtained a convergent series for $p(n)$ and an error bound was given by Lehmer. Despite having this, a full asymptotic expansion for $p(n)$ with an explicit error bound is not known. Recently O'Sullivan studied the asymptotic expansion of $p^{k}(n)$-partitions into $k$th powers, initiated by Wright, and consequently obtained an asymptotic expansion for $p(n)$ along with a concise description of the coefficients involved in the expansion but without any estimation of the error term. Here we consider a detailed and comprehensive analysis on an estimation of the error term obtained by truncating the asymptotic expansion for $p(n)$ at any positive integer $n$. This gives rise to an infinite family of inequalities for $p(n)$ which finally answers to a question proposed by Chen. Our error term estimation predominantly relies on applications of algorithmic methods from symbolic summation. },
journal = {Rocky Mt J Math },
volume = {to appear},
pages = {?--?},
isbn_issn = {ISSN: 357596},
year = {2023},
note = {arXiv:2209.07887 [math.NT]},
refereed = {yes},
keywords = {partition function, asymptotic expansion, error bounds, symbolic summation},
length = {43},
url = {https://doi.org/10.35011/risc.22-13}
}

2022

[Radu]

New inequalities for p(n) and log p(n)

K. Banerjee, P. Paule, C. S. Radu, W. H. Zeng

Research Institute for Symbolic Computation, JKU, Linz. Technical report no. RISC6607, 2022. To appear in the Ramanujan Journal. [pdf]

[bib]

@techreport{RISC6607,
author = {K. Banerjee and P. Paule and C. S. Radu and W. H. Zeng},
title = {{New inequalities for p(n) and log p(n)}},
language = {english},
number = {RISC6607},
year = {2022},
institution = {Research Institute for Symbolic Computation, JKU, Linz},
length = {37},
type = {To appear in the Ramanujan Journal}
}

2021

[Radu]

A method of verifying partition congruences by symbolic computation

Nicolas Allen Smoot, Cristian-Silviu Radu

Journal of Symbolic Computation 104, pp. 105-133. 2021. 0747-7171. [doi] [pdf]

[bib]

@article{RISC6106,
author = {Nicolas Allen Smoot and Cristian-Silviu Radu},
title = {{A method of verifying partition congruences by symbolic computation}},
language = {english},
abstract = {Conjectures involving infinite families of restricted partition congruences can be difficult to verify for a number of individual cases, even with a computer. We demonstrate how the machinery of Radu's algorithm may be modified and employed to efficiently check a very large number of cases of such conjectures. This allows substantial evidence to be collected for a given conjecture, before a complete proof is attempted.},
journal = {Journal of Symbolic Computation},
volume = {104},
pages = {105--133},
isbn_issn = {0747-7171},
year = {2021},
refereed = {yes},
length = {29},
url = {https://doi.org/10.1016/j.jsc.2020.04.008}
}

[Radu]

Holonomic relations for modular functions and forms: First guess, then prove

Peter Paule, Cristian-Silviu Radu

International Journal of Number Theory 17(3), pp. 713-759. 2021. World Scientific, 1793-0421. [doi]

[bib]

@article{RISC6279,
author = {Peter Paule and Cristian-Silviu Radu},
title = {{Holonomic relations for modular functions and forms: First guess, then prove}},
language = {english},
journal = {International Journal of Number Theory},
volume = {17},
number = {3},
pages = {713--759},
publisher = {World Scientific},
isbn_issn = {1793-0421},
year = {2021},
refereed = {yes},
length = {47},
url = {https://doi.org/10.1142/S1793042120400278}
}

[Radu]

Construction of modular function bases for $Gamma_0(121)$ related to $p(11n+6)$

Ralf Hemmecke, Peter Paule, Silviu Radu

Integral Transforms and Special Functions 32(5-8), pp. 512-527. 2021. Taylor & Francis, 1065-2469. [doi]

[bib]

@article{RISC6342,
author = {Ralf Hemmecke and Peter Paule and Silviu Radu},
title = {{Construction of modular function bases for $Gamma_0(121)$ related to $p(11n+6)$}},
language = {english},
abstract = {Motivated by arithmetic properties of partitionnumbers $p(n)$, our goal is to find algorithmicallya Ramanujan type identity of the form$sum_{n=0}^{infty}p(11n+6)q^n=R$, where $R$ is apolynomial in products of the form$e_alpha:=prod_{n=1}^{infty}(1-q^{11^alpha n})$with $alpha=0,1,2$. To this end we multiply theleft side by an appropriate factor such the resultis a modular function for $Gamma_0(121)$ havingonly poles at infinity. It turns out thatpolynomials in the $e_alpha$ do not generate thefull space of such functions, so we were led tomodify our goal. More concretely, we give threedifferent ways to construct the space of modularfunctions for $Gamma_0(121)$ having only poles atinfinity. This in turn leads to three differentrepresentations of $R$ not solely in terms of the$e_alpha$ but, for example, by using as generatorsalso other functions like the modular invariant $j$.},
journal = {Integral Transforms and Special Functions},
volume = {32},
number = {5-8},
pages = {512--527},
publisher = {Taylor & Francis},
isbn_issn = {1065-2469},
year = {2021},
refereed = {yes},
keywords = {Ramanujan identities, bases for modular functions, integral bases},
sponsor = {FWF (SFB F50-06)},
length = {16},
url = {https://doi.org/10.1080/10652469.2020.1806261}
}

[Radu]

An algorithm to prove holonomic differential equations for modular forms

Peter Paule, Cristian-Silviu Radu

In: Transcendence in Algebra, Combinatorics, Geometry and Number Theory. TRANS 2019., Bostan A., Raschel K. (ed.), Springer Proceedings in Mathematics & Statistics 373, pp. 367-420. 2021. Springer, Cham, 978-3-030-84303-8. [doi]

[bib]

@incollection{RISC6395,
author = {Peter Paule and Cristian-Silviu Radu},
title = {{An algorithm to prove holonomic differential equations for modular forms}},
booktitle = {{Transcendence in Algebra, Combinatorics, Geometry and Number Theory. TRANS 2019.}},
language = {english},
abstract = {Express a modular form $g$ of positive weight locally in terms of a modular function $h$ as$y(h)$, say. Then $y(h)$ as a function in $h$ satisfiesa holonomic differential equation; i.e., one which islinear with coefficients being polynomials in $h$.This fact traces back to Gau{ss} and has beenpopularized prominently by Zagier. Using holonomicprocedures, computationally it is often straightforwardto derive such differential equations as conjectures.In the spirit of the ``first guess, then prove'' paradigm,we present a new algorithm to prove such conjectures.},
series = {Springer Proceedings in Mathematics & Statistics},
volume = {373},
pages = {367--420},
publisher = {Springer, Cham},
isbn_issn = {978-3-030-84303-8},
year = {2021},
editor = {Bostan A. and Raschel K. },
refereed = {yes},
keywords = {modular functions, modular forms, holonomic differential equations, holonomic functions and sequences, Fricke-Klein relations, $q$-series, partition congruences},
sponsor = {FWF SFB F50},
length = {54},
url = {https://doi.org/10.1007/978-3-030-84304-5_16}
}

[Radu]

Computing an order complete basis for M∞(N) and applications

Mark van Hoeij and Cristian-Silviu Radu

In: Transcendence in Algebra, Combinatorics, Geometry and Number Theory. TRANS 2019, Bostan A., Raschel K. (ed.), Springer Proceedings in Mathematics & Statistics 373, pp. 355-366. 2021. Springer, Cham, 978-3-030-84303-8. [doi]

[bib]

@incollection{RISC6396,
author = {Mark van Hoeij and Cristian-Silviu Radu },
title = {{Computing an order complete basis for M∞(N) and applications}},
booktitle = {{Transcendence in Algebra, Combinatorics, Geometry and Number Theory. TRANS 2019}},
language = {english},
series = {Springer Proceedings in Mathematics & Statistics},
volume = {373},
pages = {355--366},
publisher = {Springer, Cham},
isbn_issn = {978-3-030-84303-8},
year = {2021},
editor = {Bostan A. and Raschel K.},
refereed = {no},
length = {12},
url = {https://doi.org/10.1007/978-3-030-84304-5_15}
}

[Radu]

Infinite product formulae for generating functions for sequences of squares

Christian Krattenthaler, Mircea Merca, Cristian-Silviu Radu

In: Transcendence in Algebra, Combinatorics, Geometry and Number Theory. TRANS 2019, Bostan A., Raschel K. (ed.), Springer Proceedings in Mathematics & Statistics 373, pp. 193-236. 2021. Springer, Cham, 978-3-030-84303-8. [doi]

[bib]

@incollection{RISC6397,
author = {Christian Krattenthaler and Mircea Merca and Cristian-Silviu Radu},
title = {{Infinite product formulae for generating functions for sequences of squares}},
booktitle = {{Transcendence in Algebra, Combinatorics, Geometry and Number Theory. TRANS 2019}},
language = {english},
series = {Springer Proceedings in Mathematics & Statistics},
volume = {373},
pages = {193--236},
publisher = {Springer, Cham},
isbn_issn = {978-3-030-84303-8},
year = {2021},
editor = {Bostan A. and Raschel K.},
refereed = {yes},
length = {44},
url = {https://doi.org/10.1007/978-3-030-84304-5_8}
}

2020

[Radu]

An algorithm to prove holonomic differential equations for modular forms

Peter Paule, Cristian-Silviu Radu

Technical report no. 20-05 in RISC Report Series, Research Institute for Symbolic Computation (RISC), Johannes Kepler University Linz, Austria. ISSN 2791-4267 (online). May 2020. A final version appeared in: Transcendence in Algebra, Combinatorics, Geometry and Number Theory. TRANS 2029, eds.: A. Bostan and K. Raschel, Springer, 2021. Licensed under CC BY 4.0 International. [pdf]

[bib]

@techreport{RISC6108,
author = {Peter Paule and Cristian-Silviu Radu},
title = {{An algorithm to prove holonomic differential equations for modular forms}},
language = {english},
abstract = {Express a modular form $g$ of positive weight locally in terms of a modular function $h$ as$y(h)$, say. Then $y(h)$ as a function in $h$ satisfiesa holonomic differential equation; i.e., one which islinear with coefficients being polynomials in $h$.This fact traces back to Gau{ss} and has beenpopularized prominently by Zagier. Using holonomicprocedures, computationally it is often straightforwardto derive such differential equations as conjectures.In the spirit of the ``first guess, then prove'' paradigm,we present a new algorithm to prove such conjectures.},
number = {20-05},
year = {2020},
month = {May},
note = {A final version appeared in: Transcendence in Algebra, Combinatorics, Geometry and Number Theory. TRANS 2029, eds.: A. Bostan and K. Raschel, Springer, 2021},
keywords = {modular functions, modular forms, holonomic differential equations, holonomic functions and sequences, Fricke-Klein relations, $q$-series, partition congruences},
sponsor = {FWF SFB F50},
length = {48},
license = {CC BY 4.0 International},
type = {RISC Report Series},
institution = {Research Institute for Symbolic Computation (RISC), Johannes Kepler University Linz},
address = {Altenberger Straße 69, 4040 Linz, Austria},
issn = {2791-4267 (online)}
}

[Radu]

A reduction theorem of certain relations modulo p involving modular forms

Radu, Cristian-Silviu

In: Algorithmic Combinatorics: Enumerative Combinatorics, Special Functions and Computer Algebra, in Honour of Peter Paule on his 60th Birthday, V. Pillwein, C. Schneider (ed.), pp. 317-337. 2020. Springer, 978-3-030-44558-4. [doi] [pdf]

[bib]

@incollection{RISC6110,
author = {Radu and Cristian-Silviu},
title = {{A reduction theorem of certain relations modulo p involving modular forms}},
booktitle = {{Algorithmic Combinatorics: Enumerative Combinatorics, Special Functions and Computer Algebra, in Honour of Peter Paule on his 60th Birthday}},
language = {english},
pages = {317--337},
publisher = {Springer},
isbn_issn = {978-3-030-44558-4},
year = {2020},
editor = {V. Pillwein and C. Schneider},
refereed = {yes},
length = {21},
url = {https://doi.org/10.1007/978-3-030-44559-1_16}
}

2019

[Radu]

Construction of all Polynomial Relations among Dedekind Eta Functions of Level $N$

Ralf Hemmecke, Silviu Radu

Journal of Symbolic Compuation 95, pp. 39-52. 2019. ISSN 0747-7171. Also available as RISC Report 18-03 http://www.risc.jku.at/publications/download/risc_5561/etarelations.pdf. [doi]

[bib]

@article{RISC5703,
author = {Ralf Hemmecke and Silviu Radu},
title = {{Construction of all Polynomial Relations among Dedekind Eta Functions of Level $N$}},
language = {english},
abstract = {We describe an algorithm that, given a positive integer $N$,computes a Gr\"obner basis of the ideal of polynomial relations among Dedekind$\eta$-functions of level $N$, i.e., among the elements of$\{\eta(\delta_1\tau),\ldots,\eta(\delta_n\tau)\}$ where$1=\delta_1<\delta_2\dots<\delta_n=N$ are the positive divisors of$N$.More precisely, we find a finite generating set (which is also aGr\"obner basis of the ideal $\ker\phi$ where\begin{gather*} \phi:Q[E_1,\ldots,E_n] \to Q[\eta(\delta_1\tau),\ldots,\eta(\delta_n\tau)], \quad E_k\mapsto \eta(\delta_k\tau), \quad k=1,\ldots,n.\end{gather*}},
journal = {Journal of Symbolic Compuation},
volume = {95},
pages = {39--52},
isbn_issn = {ISSN 0747-7171},
year = {2019},
note = {Also available as RISC Report 18-03 http://www.risc.jku.at/publications/download/risc_5561/etarelations.pdf},
refereed = {yes},
keywords = {Dedekind $\eta$ function, modular functions, modular equations, ideal of relations, Groebner basis},
length = {14},
url = {https://doi.org/10.1016/j.jsc.2018.10.001}
}

[Radu]

The Generators of all Polynomial Relations among Jacobi Theta Functions

Ralf Hemmecke, Silviu Radu, Liangjie Ye

In: Elliptic Integrals, Elliptic Functions and Modular Forms in Quantum Field Theory, Johannes Blümlein and Carsten Schneider and Peter Paule (ed.), Texts & Monographs in Symbolic Computation 18-09, pp. 259-268. 2019. Springer International Publishing, Cham, 978-3-030-04479-4. Also available as RISC Report 18-09 http://www.risc.jku.at/publications/download/risc_5719/thetarelations.pdf. [doi]

[bib]

@incollection{RISC5913,
author = {Ralf Hemmecke and Silviu Radu and Liangjie Ye},
title = {{The Generators of all Polynomial Relations among Jacobi Theta Functions}},
booktitle = {{Elliptic Integrals, Elliptic Functions and Modular Forms in Quantum Field Theory}},
language = {english},
abstract = {In this article, we consider the classical Jacobi theta functions$\theta_i(z)$, $i=1,2,3,4$ and show that the ideal of all polynomialrelations among them with coefficients in$K :=\setQ(\theta_2(0|\tau),\theta_3(0|\tau),\theta_4(0|\tau))$ isgenerated by just two polynomials, that correspond to well knownidentities among Jacobi theta functions.},
series = {Texts & Monographs in Symbolic Computation},
number = {18-09},
pages = {259--268},
publisher = {Springer International Publishing},
address = {Cham},
isbn_issn = {978-3-030-04479-4},
year = {2019},
note = {Also available as RISC Report 18-09 http://www.risc.jku.at/publications/download/risc_5719/thetarelations.pdf},
editor = {Johannes Blümlein and Carsten Schneider and Peter Paule},
refereed = {yes},
length = {9},
url = {https://doi.org/10.1007/978-3-030-04480-0_11}
}

[Radu]

A UNIFIED ALGORITHMIC FRAMEWORK FOR RAMANUJAN'S CONGRUENCES MODULO POWERS OF 5, 7, AND 11

Peter Paule, Silviu Radu

Technical report no. 19-09 in RISC Report Series, Research Institute for Symbolic Computation (RISC), Johannes Kepler University Linz, Austria. ISSN 2791-4267 (online). submitted, 2019. [pdf]

[bib]

@techreport{RISC5979,
author = {Peter Paule and Silviu Radu},
title = {{A UNIFIED ALGORITHMIC FRAMEWORK FOR RAMANUJAN'S CONGRUENCES MODULO POWERS OF 5, 7, AND 11}},
language = {english},
number = {19-09},
year = {2019},
howpublished = {submitted},
length = {49},
type = {RISC Report Series},
institution = {Research Institute for Symbolic Computation (RISC), Johannes Kepler University Linz},
address = {Altenberger Straße 69, 4040 Linz, Austria},
issn = {2791-4267 (online)}
}

[Radu]

A proof of the Weierstrass gap theorem not using the Riemann-Roch formula

Peter Paule, Silviu Radu

Annals of Combinatorics 23(19-02), pp. 963-1007. May 2019. Springer, 0218-0006. [doi]

[bib]

@article{RISC6076,
author = {Peter Paule and Silviu Radu},
title = {{A proof of the Weierstrass gap theorem not using the Riemann-Roch formula}},
language = {english},
abstract = {https://doi.org/10.1007/s00026-019-00459-2},
journal = {Annals of Combinatorics},
volume = {23},
number = {19-02},
pages = {963--1007},
publisher = {Springer},
isbn_issn = {0218-0006},
year = {2019},
month = {May},
refereed = {yes},
length = {47},
url = {https://doi.org/10.1007/s00026-019-00459-2}
}

2018

[Radu]

An algorithm to prove algebraic relations involving eta quotients

Cristian-Silviu Radu

Annals of Combinatorics 22, pp. 377-391. 2018. Springer, 0219-3094. [doi] [pdf]

[bib]

@article{RISC5312,
author = {Cristian-Silviu Radu},
title = {{An algorithm to prove algebraic relations involving eta quotients}},
language = {english},
journal = {Annals of Combinatorics},
volume = {22},
pages = {377--391},
publisher = {Springer},
isbn_issn = {0219-3094},
year = {2018},
refereed = {yes},
length = {15},
url = {https://doi.org/10.1007/s00026-018-0388-y}
}

[Radu]

Iterative and Iterative-Noniterative Integral Solutions in 3-Loop Massive QCD Calculations

J. Ablinger, A. Behring, J. Blümlein, A. De Freitas, E. Imamoglu, M. van Hoeij A. von Manteuffel, C.G. Raab, C.-S. Radu, C. Schneider

In: Proc. of the 13th International Symposium on Radiative Corrections (Applications of Quantum Field Theory to Phenomenology), A. Hoang, C. Schneider (ed.)PoS (RADCOR2017) 069, pp. 1-13. 2018. ISSN 1824-8039. arXiv:1711.09742 [hep-ph]. [doi]

[bib]

@inproceedings{RISC5350,
author = {J. Ablinger and A. Behring and J. Blümlein and A. De Freitas and E. Imamoglu and M. van Hoeij A. von Manteuffel and C.G. Raab and C.-S. Radu and C. Schneider},
title = {{Iterative and Iterative-Noniterative Integral Solutions in 3-Loop Massive QCD Calculations}},
booktitle = {{Proc. of the 13th International Symposium on Radiative Corrections (Applications of Quantum Field Theory to Phenomenology)}},
language = {english},
volume = {PoS (RADCOR2017) 069},
pages = {1--13},
isbn_issn = {ISSN 1824-8039},
year = {2018},
note = {arXiv:1711.09742 [hep-ph]},
editor = {A. Hoang and C. Schneider},
refereed = {no},
length = {13},
url = {https://doi.org/10.22323/1.290.0069 }
}

[Radu]

Iterated Elliptic and Hypergeometric Integrals for Feynman Diagrams

J. Ablinger, J. Blümlein, A. De Freitas, M. van Hoeij, E. Imamoglu, C.G. Raab, C.-S. Radu, C. Schneider

J. Math. Phys. 59(062305), pp. 1-55. 2018. ISSN 0022-2488. arXiv:1706.01299 [hep-th]. [doi] [pdf]

[bib]

@article{RISC5456,
author = {J. Ablinger and J. Blümlein and A. De Freitas and M. van Hoeij and E. Imamoglu and C.G. Raab and C.-S. Radu and C. Schneider},
title = {{Iterated Elliptic and Hypergeometric Integrals for Feynman Diagrams}},
language = {english},
journal = {J. Math. Phys.},
volume = {59},
number = {062305},
pages = {1--55},
isbn_issn = {ISSN 0022-2488},
year = {2018},
note = {arXiv:1706.01299 [hep-th]},
refereed = {yes},
length = {55},
url = {https://www.doi.org/10.1063/1.4986417}
}

[Radu]

Rogers-Ramanujan functions, modular functions, and computer algebra

Peter Paule, Cristian-Silviu Radu

In: Advances in Computer Algebra - In Honour of Sergei Abramov's 70th Birthday, C. Schneider, E. Zima. (ed.), Springer Proceedings in Mathematics & Statistics 226, pp. 229-280. 2018. Springer, Cham, 978-3-319-73231-2. [doi] [pdf]

[bib]

@incollection{RISC5475,
author = {Peter Paule and Cristian-Silviu Radu},
title = {{Rogers-Ramanujan functions, modular functions, and computer algebra}},
booktitle = {{Advances in Computer Algebra - In Honour of Sergei Abramov's 70th Birthday}},
language = {english},
series = { Springer Proceedings in Mathematics & Statistics},
volume = {226},
pages = {229--280},
publisher = {Springer, Cham},
isbn_issn = {978-3-319-73231-2},
year = {2018},
editor = {C. Schneider and E. Zima.},
refereed = {yes},
length = {52},
url = {https://doi.org/10.1007/978-3-319-73232-9_10}
}

2016

[Radu]

A new witness identity for $11|p(11n+6)$

Peter Paule, Cristian-Silviu Radu

In: Analytic Number Theory, Modular Forms and q-Hypergeometric Series, George E. Andrews, Frank Garvan (ed.), pp. 625-640. 2016. Springer, 2194-1009. [pdf]

[bib]

@inproceedings{RISC5329,
author = {Peter Paule and Cristian-Silviu Radu},
title = {{A new witness identity for $11|p(11n+6)$}},
booktitle = {{Analytic Number Theory, Modular Forms and q-Hypergeometric Series}},
language = {english},
pages = {625--640},
publisher = {Springer},
isbn_issn = { 2194-1009},
year = {2016},
editor = { George E. Andrews and Frank Garvan},
refereed = {yes},
length = {16}
}

[Radu]

Inverse inequality estimates with symbolic computation

Christoph Koutschan and Martin Neumüller and Cristian-Silviu Radu

Advances in Applied Mathematics 80, pp. 1-23. 2016. 0196-8858. [doi] [pdf]

[bib]

@article{RISC5454,
author = {Christoph Koutschan and Martin Neumüller and Cristian-Silviu Radu},
title = {{Inverse inequality estimates with symbolic computation}},
language = {english},
journal = {Advances in Applied Mathematics},
volume = {80},
pages = {1--23},
isbn_issn = {0196-8858},
year = {2016},
refereed = {yes},
length = {23},
url = {https://doi.org/10.1016/j.aam.2016.04.005}
}