On a new formula for the number of unrestricted partitions

Hemar Godinho; Jos\'e Pl\'inio O. Santos

arxiv: 1906.11093 · v1 · pith:VU425BG2new · submitted 2019-06-26 · 🧮 math.CO

On a new formula for the number of unrestricted partitions

Hemar Godinho , Jos\'e Pl\'inio O. Santos This is my paper

Pith reviewed 2026-05-25 15:33 UTC · model grok-4.3

classification 🧮 math.CO

keywords partition functionunrestricted partitionsinteger solutionscombinatorial correspondencep(n) formulanumber theorydiophantine equations

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The pith

The number of unrestricted partitions of n equals the number of non-negative solutions to systems of two equations using numbers from 1 to n squared.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper establishes a correspondence between the partitions of n and the non-negative solutions to systems of two equations with variables in the interval from 1 to n squared. This correspondence is presented as yielding a new formula for the partition function p(n). A sympathetic reader would care because it supplies an alternative way to express and potentially compute the number of ways to write n as a sum of positive integers without regard to order. The approach frames p(n) in terms of counting solutions rather than generating functions or recurrence relations used in earlier work.

Core claim

The authors claim that the number of unrestricted partitions of n equals the number of non-negative solutions of systems of two equations involving natural numbers in the interval (1, n²), thereby giving a new explicit formula for p(n).

What carries the argument

A correspondence between unrestricted partitions of n and the non-negative integer solutions of two-equation systems with variables bounded by n squared, used to equate the partition count to a solution count.

Load-bearing premise

The stated correspondence between partitions and the solution counts of the two-equation systems must be bijective and must produce an expression distinct from all prior formulas for p(n).

What would settle it

For n=4, where the known partition number is 5, count the non-negative solutions to the two-equation systems with variables up to 16; the count must equal 5, or the claimed formula fails.

Figures

Figures reproduced from arXiv: 1906.11093 by Hemar Godinho, Jos\'e Pl\'inio O. Santos.

**Figure 1.** Figure 1: Illustration for Example 2.1 Now we reflect the path through the line x + y = n and create a partition of a number m into distinct odd parts all greater than 1, by taking hooks of the following sizes: (4) λ1 = 2(n − d1)) − 1, λ2 = 2((n − d1) − 1) − 1, . . . λc1 = 2((n − d1) − (c1 − 1)) − 1, λc1+1 = 2((n − d1) − d2 − c1) − 1, . . . λc1+c2 = 2((n − d1) − d2 − c1 − (c2 − 1)) − 1, λc1+c2+1 = 2((n − d1) − d2 − … view at source ↗

**Figure 2.** Figure 2: Illustration for Example 2.3 Example 2.5. Let us take the partition (4, 1, 1) of 6 and the partition (2, 1, 1) of 4. The matrices associated to them are, respectively, M1 = 1 1 0 3 0 1 and M2 = 1 1 0 1 0 1 . The paths that these matrices originate are different, although both paths induce the same hooks and, therefore, the same partition into distinct odd parts, as shown in [PITH_FULL_IMAGE:figure… view at source ↗

**Figure 3.** Figure 3: Illustration for Example 2.5 Example 2.6. In the table below we present the result of the application of the Path Procedure to the matrices listed in [PITH_FULL_IMAGE:figures/full_fig_p004_3.png] view at source ↗

**Figure 4.** Figure 4: into distinct odd parts, all greater than 1, of the number m, which is equal to the area of the figure, the sum of the parts (we have here a similar situation as described in Figures 1 and 2). This area is also equal to the sum of the area of the big square of size length equal to y0 with twice the sum of the areas of the (s − 1) rectangles of areas c1 × x0, c2 × (x0 − d2), . . . , cs−2 × (ds−1 + ds) and c… view at source ↗

read the original abstract

In this paper we present a new formula for the number of unrestricted partitions of $n$. We do this by introducing a correspondence between the number of unrestrited partitions of $n$ and the number of non-negative solutions of systems of two equations, involving natural numbers in the interval (1 $,n^{2}$).

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

The paper asserts a correspondence between p(n) and solution counts of two unspecified equations but supplies neither the equations nor any proof that the counts match.

read the letter

The main thing to know is that this paper claims a new formula for the unrestricted partition function p(n) by setting up a correspondence to the number of non-negative solutions of two equations whose variables are natural numbers up to n squared. The abstract states the existence of the correspondence but does not write the equations or show why the solution count equals p(n) rather than some other number. Without those steps the claim stays an assertion. The full text does not appear to close that gap either, so the formula is never actually produced. Partition theory already has exact formulas such as Rademacher's series and many combinatorial interpretations, so a new one would need to be explicit and shown to differ. Here the work stops at describing a possible mapping without carrying it out. The approach of counting solutions in a bounded range is a standard tactic in the area, but the paper earns no credit for execution because the central step is missing. The soft spot is load-bearing: bijectivity or equality is stated rather than derived, which leaves the result uncheckable and likely equivalent to known counts until proven otherwise. No comparison to the literature is supplied, and no data or small-n checks are mentioned that would let a reader test the idea. This paper is for specialists who already know the partition literature and are hunting for fresh exact expressions, but it gives them nothing usable. A reader looking for a verifiable new formula will come away empty. I would not bring it to a reading group or cite it. It does not reach the threshold for serious refereeing because the core claim is not grounded in the text.

Referee Report

2 major / 0 minor

Summary. The manuscript claims to present a new formula for the unrestricted partition function p(n) by establishing a correspondence between p(n) and the number of non-negative integer solutions to a system of two equations whose variables range over natural numbers in the interval (1, n²).

Significance. A bijective or enumerative formula for p(n) expressed via solution counts of a fixed number of Diophantine equations would be of interest in partition theory if rigorously established, as it could offer a new combinatorial model distinct from generating functions or pentagonal-number recurrences. No such strengths (machine-checked proofs, reproducible code, or explicit parameter-free derivations) are present.

major comments (2)

[Abstract] Abstract and introduction: the central claim asserts a bijective correspondence yielding p(n) solutions to an unspecified pair of equations, yet neither the equations themselves nor any argument establishing that their solution cardinality equals p(n) (as opposed to some other integer) is supplied. This renders the asserted formula an unverified assertion rather than a derived result.
No section or equation: the manuscript contains no explicit system of equations, no proof of bijectivity, and no verification that the solution count reproduces known values of p(n) for small n, so the equality p(n) = #solutions cannot be checked for internal consistency or reduction to prior expressions.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for the report. We agree that the submitted manuscript does not contain the explicit system of equations, the bijectivity argument, or small-n verifications, rendering the central claim unverified as presented. We will revise to supply these elements.

read point-by-point responses

Referee: [Abstract] Abstract and introduction: the central claim asserts a bijective correspondence yielding p(n) solutions to an unspecified pair of equations, yet neither the equations themselves nor any argument establishing that their solution cardinality equals p(n) (as opposed to some other integer) is supplied. This renders the asserted formula an unverified assertion rather than a derived result.

Authors: We agree. The abstract and introduction assert the existence of a correspondence to solutions of two equations with variables in (1, n²) but do not state the equations or prove that their solution count equals p(n). In revision we will state the two Diophantine equations explicitly, define the bijection, and show why the cardinality matches p(n). revision: yes
Referee: [—] No section or equation: the manuscript contains no explicit system of equations, no proof of bijectivity, and no verification that the solution count reproduces known values of p(n) for small n, so the equality p(n) = #solutions cannot be checked for internal consistency or reduction to prior expressions.

Authors: This observation is accurate. The manuscript supplies neither the equations, a bijectivity proof, nor numerical checks. The revised version will include a dedicated section with the explicit system, the proof that the number of non-negative integer solutions equals p(n), and direct comparisons with known partition numbers for small n. revision: yes

Circularity Check

0 steps flagged

No circularity; assertion of correspondence supplies no derivable steps

full rationale

The provided abstract asserts a correspondence equating p(n) to the cardinality of non-negative solutions of unspecified two-equation systems over {1,...,n²} but exhibits no equations, no explicit mapping, and no derivation chain. No self-citations, fitted parameters, or ansatzes appear. Because the visible text contains no load-bearing step that can be quoted and shown to reduce to its own inputs by construction, the circularity criteria are not met and the score is 0.

Axiom & Free-Parameter Ledger

0 free parameters · 0 axioms · 0 invented entities

Only the abstract is available; no free parameters, axioms, or invented entities can be identified.

pith-pipeline@v0.9.0 · 5567 in / 977 out tokens · 19627 ms · 2026-05-25T15:33:53.119193+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

12 extracted references · 12 canonical work pages

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Brietzke, E. H. M.; Santos, J. P. O.; da Silva, R., A new approach and generalizations to some results about mock theta functions , Discrete Mathematics 311(8), (2011), 595-615

work page 2011
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Brietzke, E. H. M.; Santos, J. P. O.; da Silva, R., Combinatorial interpretations as two-line array for the mock theta functions, Bull. Braz. Math. Soc., New Series 44(2), (2013), 233-253

work page 2013
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D., Elementary Number Theory

Bolker, E. D., Elementary Number Theory. W.A. Benjamin, Inc. New York, (1970)

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E., Polygonal Numbers and Related Warings Problems

Dickson, L. E., Polygonal Numbers and Related Warings Problems . Quarterly J. Math. vol. 5, (1934), 283-290

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E., Two-Fold Generalizations of Cauchy’s Lemma

Dickson, L. E., Two-Fold Generalizations of Cauchy’s Lemma. Amer. J. Math. vol. 56, (1934), 513-528

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Frobenius, G., Uber die Charaktere der Symmetrischen Gruppe. Sitzber. Pruess. Akad. Berlin (1900), 516-534

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Kloosterman, H.D., Simultane Darstellung zweier ganzen Zahlen als einer Summe von ganzen Zahlen und deren Quadratsumme . Math. Ann., vol. 18, (1942), 319-364

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[9]

Mondek, P., Ribeiro, A. C. and Santos, J. P. O., New Two-Line Arrays Representing Parti- tions. Ann. Comb., vol 15, (2011), 341-354

work page 2011
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Matte, M. L. and Santos, J. P. O., A New Approach to integer Partitions . Bull. Braz. Math. Soc., New Series, 49(4), (2018), 811-847

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Chelsea Publishing Co, New York, (1958)

Landau, L., Elementary Number Theory. Chelsea Publishing Co, New York, (1958)

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Simultaneous Quadratic and Linear Representation

Pall, G. Simultaneous Quadratic and Linear Representation . Quarterly J. of Math. vol. 2, (1931), 136-143

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[1] [1]

E., Generalized Frobenius Partitions

Andrews, G. E., Generalized Frobenius Partitions. Mem. Am. Math Soc., vol. 49, (1984),1-44

work page 1984

[2] [2]

Brietzke, E. H. M.; Santos, J. P. O.; da Silva, R., A new approach and generalizations to some results about mock theta functions , Discrete Mathematics 311(8), (2011), 595-615

work page 2011

[3] [3]

Brietzke, E. H. M.; Santos, J. P. O.; da Silva, R., Combinatorial interpretations as two-line array for the mock theta functions, Bull. Braz. Math. Soc., New Series 44(2), (2013), 233-253

work page 2013

[4] [4]

D., Elementary Number Theory

Bolker, E. D., Elementary Number Theory. W.A. Benjamin, Inc. New York, (1970)

work page 1970

[5] [5]

E., Polygonal Numbers and Related Warings Problems

Dickson, L. E., Polygonal Numbers and Related Warings Problems . Quarterly J. Math. vol. 5, (1934), 283-290

work page 1934

[6] [6]

E., Two-Fold Generalizations of Cauchy’s Lemma

Dickson, L. E., Two-Fold Generalizations of Cauchy’s Lemma. Amer. J. Math. vol. 56, (1934), 513-528

work page 1934

[7] [7]

Frobenius, G., Uber die Charaktere der Symmetrischen Gruppe. Sitzber. Pruess. Akad. Berlin (1900), 516-534

work page 1900

[8] [8]

Kloosterman, H.D., Simultane Darstellung zweier ganzen Zahlen als einer Summe von ganzen Zahlen und deren Quadratsumme . Math. Ann., vol. 18, (1942), 319-364

work page 1942

[9] [9]

Mondek, P., Ribeiro, A. C. and Santos, J. P. O., New Two-Line Arrays Representing Parti- tions. Ann. Comb., vol 15, (2011), 341-354

work page 2011

[10] [10]

Matte, M. L. and Santos, J. P. O., A New Approach to integer Partitions . Bull. Braz. Math. Soc., New Series, 49(4), (2018), 811-847

work page 2018

[11] [11]

Chelsea Publishing Co, New York, (1958)

Landau, L., Elementary Number Theory. Chelsea Publishing Co, New York, (1958)

work page 1958

[12] [12]

Simultaneous Quadratic and Linear Representation

Pall, G. Simultaneous Quadratic and Linear Representation . Quarterly J. of Math. vol. 2, (1931), 136-143

work page 1931