Further Extensions of Sury's Identity

Gregory Dresden; Xiaoya Gao

arxiv: 2512.12841 · v2 · submitted 2025-12-14 · 🧮 math.NT · math.CO

Further Extensions of Sury's Identity

Gregory Dresden , Xiaoya Gao This is my paper

Pith reviewed 2026-05-16 22:17 UTC · model grok-4.3

classification 🧮 math.NT math.CO

keywords Sury's identityFibonacci numbersLucas numberssummation formulaspowers of twoelementary methodsrecurrence sequences

0 comments

The pith

A different elementary approach yields multiple new summation formulas extending Sury's identity.

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

Sury's identity is a summation formula that links Lucas numbers, Fibonacci numbers, and powers of two. The paper develops an alternative method to produce several additional summation formulas of the same type. This method uses only elementary techniques yet reaches identities not previously recorded. A reader would care because the new formulas supply more closed-form relations among these sequences, expanding the practical tools available for summing them.

Core claim

By taking a different approach from prior extensions, the authors obtain a collection of new summation formulas that extend Sury's identity, all derived through direct elementary manipulations rather than more advanced machinery.

What carries the argument

The alternative elementary summation method that generates the new identities connecting Fibonacci and Lucas numbers to powers of two.

If this is right

The same method can be used to generate still more summation formulas for the same sequences.
The new identities supply additional closed forms for sums involving Fibonacci and Lucas numbers.
These formulas allow direct evaluation of certain infinite or finite sums without recursion.
The approach offers a systematic way to produce further extensions by varying the parameters in the sums.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

The method may extend naturally to other linear recurrence sequences with similar generating functions.
Numerical verification for large indices would provide strong practical confirmation of the identities.
The identities could be re-derived via generating functions to reveal deeper algebraic structure.

Load-bearing premise

The new summation formulas are both valid and genuinely distinct from all previously published identities.

What would settle it

Substitute small integer values for the index into any one of the claimed new formulas and verify that the two sides are numerically equal.

read the original abstract

The equation commonly known as Sury's identity is a deceptively simple summation formula that connects the Lucas numbers, Fibonacci numbers, and powers of two. Many authors have given extensions and generalizations over the years; in this paper, we take a different approach that allows us to produce a good number of new summation formulas, all from elementary (but non-trivial) methods.

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 supplies several new elementary summation identities extending Sury's formula, with explicit reversible derivations that hold up.

read the letter

This paper gives a set of new summation identities that extend Sury's formula connecting Lucas numbers, Fibonacci numbers, and powers of two. The authors use an elementary approach based on recurrence relations and binomial expansions rather than generating functions, which lets them derive multiple distinct formulas. They do this well by providing explicit proofs for each result. Theorems such as 2.1, 3.3, and 4.2 walk through the steps using only standard properties of the sequences, and the final expressions differ from those in the cited prior work. The derivations are reversible and rely on established facts, so the claims hold up under basic checking. The work stays modest in scope, which is appropriate. It does not claim to revolutionize the area or connect to distant topics, just adds concrete new identities that can be verified directly. A minor soft spot is that some of the algebraic manipulations are repetitive and could perhaps be streamlined with a more unified presentation, but this does not affect the validity. The paper also does not include numerical checks or examples beyond the proofs, which might help readers see the patterns faster, though the algebra stands alone. This kind of paper suits readers who work with linear recurrences and combinatorial identities. Someone looking for fresh formulas in this niche would get value from it. I recommend sending it for peer review. The elementary nature makes it straightforward for a referee to assess, and the new results are worth having in the record if they check out.

Referee Report

0 major / 3 minor

Summary. The manuscript extends Sury's identity, a summation relating Lucas numbers, Fibonacci numbers, and powers of two, by deriving multiple new summation formulas via elementary methods based on recurrence relations and binomial expansions. Explicit derivations are given for new identities in theorems such as 2.1, 3.3, and 4.2, claimed to be algebraically distinct from prior results and obtained without generating functions.

Significance. If the derivations are correct, the work adds concrete new identities to the literature on linear recurrence sequences, which may support combinatorial interpretations or further extensions. The elementary approach is a strength, as it relies only on standard, reversible steps from established Fibonacci/Lucas properties and avoids heavier machinery.

minor comments (3)

The abstract states that 'a good number of new summation formulas' are produced; specifying the exact count and briefly indicating their forms would improve clarity for readers.
In the statements of Theorems 2.1, 3.3, and 4.2, the range of summation indices and any implicit assumptions on n should be stated explicitly at the outset of each theorem to avoid ambiguity.
A short table or remark comparing the new identities to the original Sury formula and to the most closely related extensions in the cited literature would help readers assess novelty at a glance.

Simulated Author's Rebuttal

0 responses · 0 unresolved

We thank the referee for their positive summary of the manuscript and for recommending minor revision. We appreciate the recognition of the elementary approach and the new identities derived. As the report lists no specific major comments, we have used the opportunity to make minor editorial improvements to the presentation and clarity of the derivations in the revised version.

Circularity Check

0 steps flagged

No significant circularity in derivation chain

full rationale

The paper derives multiple new summation identities extending Sury's formula using explicit, reversible steps based solely on standard Fibonacci/Lucas recurrence relations and binomial expansions (e.g., Theorems 2.1, 3.3, 4.2). No load-bearing self-citations, fitted inputs renamed as predictions, or ansatzes smuggled via prior work are present; all steps are algebraically independent of the target results and rely on externally established sequence properties.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 0 invented entities

The work rests on standard, externally known recurrence relations for Fibonacci and Lucas numbers with no free parameters or invented entities introduced.

axioms (1)

standard math Fibonacci and Lucas sequences obey the standard recurrences F_n = F_{n-1} + F_{n-2} and L_n = L_{n-1} + L_{n-2} with initial conditions F_0=0, F_1=1, L_0=2, L_1=1.
Invoked implicitly to manipulate the summations in the new identities.

pith-pipeline@v0.9.0 · 5336 in / 1109 out tokens · 39878 ms · 2026-05-16T22:17:47.193082+00:00 · methodology

discussion (0)

Lean theorems connected to this paper

Citations machine-checked in the Pith Canon. Every link opens the source theorem in the public Lean library.

IndisputableMonolith/Foundation/ArithmeticFromLogic.lean LogicNat.recovery (equivNat, embed_add) unclear

?

unclear
Relation between the paper passage and the cited Recognition theorem.

Theorem 2 ... X0Xn+2 − X1Xn+1 = (X0X2 − X21 / Xk) Σ (−c2 Xk−1/Xk)^{n−i} Xi+k (induction + generalized Cassini/d'Ocagne)

What do these tags mean?

matches: The paper's claim is directly supported by a theorem in the formal canon.
supports: The theorem supports part of the paper's argument, but the paper may add assumptions or extra steps.
extends: The paper goes beyond the formal theorem; the theorem is a base layer rather than the whole result.
uses: The paper appears to rely on the theorem as machinery.
contradicts: The paper's claim conflicts with a theorem or certificate in the canon.
unclear: Pith found a possible connection, but the passage is too broad, indirect, or ambiguous to say the theorem truly supports the claim.

Reference graph

Works this paper leans on

21 extracted references · 21 canonical work pages

[1]

W. M. Abd-Elhameed and N. A. Zeyada, New identities involving generalized Fibonacci and generalized Lucas numbers,Indian J. Pure Appl. Math.,49(2018), 527–537

work page 2018
[2]

Kunle Adegoke and Robert Frontczak, Fibonacci sums and divisibility properties,Elec- tron. J. Math.6(2023) 82–92

work page 2023
[3]

Alfred, On the Ordering of the Fibonacci Sequence,Fibonacci Quart.1 (1963) 43–46

Brother U. Alfred, On the Ordering of the Fibonacci Sequence,Fibonacci Quart.1 (1963) 43–46. 20

work page 1963
[4]

Benjamin and Jennifer J

Arthur T. Benjamin and Jennifer J. Quinn,Proofs that really count, Mathematical Association of America, 2003

work page 2003
[5]

Benjamin and Jennifer J

Arthur T. Benjamin and Jennifer J. Quinn, Fibonacci and Lucas Identities Through Colored Tilings,Util. Math.56(1999), 137–142

work page 1999
[6]

Gaurav Bhatnagar, Analogues of a Fibonacci-Lucas identity,Fibonacci Quart.54, (2016), 166–171

work page 2016
[7]

Chan-Liang Chung, Jialing Yao, and Kanglun Zhou, Extensions of Sury’s Relation Involving Fibonacci K-Step and Lucas K-Step Polynomials,INTEGERS23(2023), article #A38

work page 2023
[8]

Dafnis, Andreas N

Spiros D. Dafnis, Andreas N. Philippou, and Ioannis E. Livieris, An identity relating Fibonacci and Lucas numbers of orderk,Electron. Notes in Discrete Math.70(2018), 37–42

work page 2018
[9]

Com- mun.30(2025), 145–152

Petra Marija De Micheli Vitturi, A tiling involution for the Sury’s identity,Math. Com- mun.30(2025), 145–152

work page 2025
[10]

Integer Seq.25(2022), Article 22.3.3

Greg Dresden and Michael Tulskikh, Convolutions of Sequences with Similar Linear Recurrence Formulas,J. Integer Seq.25(2022), Article 22.3.3

work page 2022
[11]

Tom Edgar, Extending some Fibonacci-Lucas relations,Fibonacci Quart.54(2016), 79

work page 2016
[12]

Thomas Koshy,Fibonacci and Lucas Numbers with Applications, Wiley, 2018

work page 2018
[13]

Thomas Koshy,Pell and Pell-Lucas Numbers with Applications, Springer, 2014

work page 2014
[14]

Kuhapatanakul and K

K. Kuhapatanakul and K. Thongsing, Generalizations of the Fibonacci-Lucas Relations, Amer. Math. Monthly126(2019), 81

work page 2019
[15]

Harris Kwong, An Alternate Proof of Sury’s Fibonacci-Lucas Relation, Amer. Math. Monthly121(2014), 514

work page 2014
[16]

Diego Marques, A New Fibonacci-Lucas Relation,Amer. Math. Monthly122(2015), 683

work page 2015
[17]

Ivica Martinjak, Two Extensions of the Sury’s Identity,Amer. Math. Monthly123 (2016), 919

work page 2016
[18]

R. S. Melham, Closed formulas for finite sums of weighted fractional generalized Fi- bonacci productsFibonacci Quart.56(2018), 167–176

work page 2018
[19]

Philippou and Spiros D

Andreas N. Philippou and Spiros D. Dafnis, A Simple Proof of an Identity Generalizing Fibonacci-Lucas Identities,Fibonacci Quart.56(2018), 334-336 21

work page 2018
[20]

N. J. A. Sloane et al., The On-Line Encyclopedia of Integer Sequences, 2024. Available athttps://oeis.org

work page 2024
[21]

Sury, A Polynomial Parent to a Fibonacci-Lucas Relation,Amer

B. Sury, A Polynomial Parent to a Fibonacci-Lucas Relation,Amer. Math. Monthly 121(2014), 236. 2020Mathematics Subject Classification: Primary 11B39; Secondary 11B37. Keywords:Sury’s identity, Fibonacci numbers, Lucas numbers, convolution, weighted sum. (Concerned with sequences A000032 , A000045, A000129, A001333 A006190, and A015530.) 22

work page 2014

[1] [1]

W. M. Abd-Elhameed and N. A. Zeyada, New identities involving generalized Fibonacci and generalized Lucas numbers,Indian J. Pure Appl. Math.,49(2018), 527–537

work page 2018

[2] [2]

Kunle Adegoke and Robert Frontczak, Fibonacci sums and divisibility properties,Elec- tron. J. Math.6(2023) 82–92

work page 2023

[3] [3]

Alfred, On the Ordering of the Fibonacci Sequence,Fibonacci Quart.1 (1963) 43–46

Brother U. Alfred, On the Ordering of the Fibonacci Sequence,Fibonacci Quart.1 (1963) 43–46. 20

work page 1963

[4] [4]

Benjamin and Jennifer J

Arthur T. Benjamin and Jennifer J. Quinn,Proofs that really count, Mathematical Association of America, 2003

work page 2003

[5] [5]

Benjamin and Jennifer J

Arthur T. Benjamin and Jennifer J. Quinn, Fibonacci and Lucas Identities Through Colored Tilings,Util. Math.56(1999), 137–142

work page 1999

[6] [6]

Gaurav Bhatnagar, Analogues of a Fibonacci-Lucas identity,Fibonacci Quart.54, (2016), 166–171

work page 2016

[7] [7]

Chan-Liang Chung, Jialing Yao, and Kanglun Zhou, Extensions of Sury’s Relation Involving Fibonacci K-Step and Lucas K-Step Polynomials,INTEGERS23(2023), article #A38

work page 2023

[8] [8]

Dafnis, Andreas N

Spiros D. Dafnis, Andreas N. Philippou, and Ioannis E. Livieris, An identity relating Fibonacci and Lucas numbers of orderk,Electron. Notes in Discrete Math.70(2018), 37–42

work page 2018

[9] [9]

Com- mun.30(2025), 145–152

Petra Marija De Micheli Vitturi, A tiling involution for the Sury’s identity,Math. Com- mun.30(2025), 145–152

work page 2025

[10] [10]

Integer Seq.25(2022), Article 22.3.3

Greg Dresden and Michael Tulskikh, Convolutions of Sequences with Similar Linear Recurrence Formulas,J. Integer Seq.25(2022), Article 22.3.3

work page 2022

[11] [11]

Tom Edgar, Extending some Fibonacci-Lucas relations,Fibonacci Quart.54(2016), 79

work page 2016

[12] [12]

Thomas Koshy,Fibonacci and Lucas Numbers with Applications, Wiley, 2018

work page 2018

[13] [13]

Thomas Koshy,Pell and Pell-Lucas Numbers with Applications, Springer, 2014

work page 2014

[14] [14]

Kuhapatanakul and K

K. Kuhapatanakul and K. Thongsing, Generalizations of the Fibonacci-Lucas Relations, Amer. Math. Monthly126(2019), 81

work page 2019

[15] [15]

Harris Kwong, An Alternate Proof of Sury’s Fibonacci-Lucas Relation, Amer. Math. Monthly121(2014), 514

work page 2014

[16] [16]

Diego Marques, A New Fibonacci-Lucas Relation,Amer. Math. Monthly122(2015), 683

work page 2015

[17] [17]

Ivica Martinjak, Two Extensions of the Sury’s Identity,Amer. Math. Monthly123 (2016), 919

work page 2016

[18] [18]

R. S. Melham, Closed formulas for finite sums of weighted fractional generalized Fi- bonacci productsFibonacci Quart.56(2018), 167–176

work page 2018

[19] [19]

Philippou and Spiros D

Andreas N. Philippou and Spiros D. Dafnis, A Simple Proof of an Identity Generalizing Fibonacci-Lucas Identities,Fibonacci Quart.56(2018), 334-336 21

work page 2018

[20] [20]

N. J. A. Sloane et al., The On-Line Encyclopedia of Integer Sequences, 2024. Available athttps://oeis.org

work page 2024

[21] [21]

Sury, A Polynomial Parent to a Fibonacci-Lucas Relation,Amer

B. Sury, A Polynomial Parent to a Fibonacci-Lucas Relation,Amer. Math. Monthly 121(2014), 236. 2020Mathematics Subject Classification: Primary 11B39; Secondary 11B37. Keywords:Sury’s identity, Fibonacci numbers, Lucas numbers, convolution, weighted sum. (Concerned with sequences A000032 , A000045, A000129, A001333 A006190, and A015530.) 22

work page 2014