Unboundedness of the Coefficients of Higher Powers of a Unimodular Power Series
Pith reviewed 2026-06-30 01:33 UTC · model grok-4.3
The pith
For any power series with all coefficients of modulus one, the coefficients of its m-th power are unbounded when m is at least 2.
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
We show that for each integer m≥2, the coefficient sequence of R(z)^m is unbounded. The proof combines Parseval's identity with Jensen's inequality. As a consequence, Conjecture 3.9 of Gawron, Miska, and Ulas is confirmed.
What carries the argument
The direct application of Parseval's identity together with Jensen's inequality to the formal power series R(z) whose coefficients lie on the unit circle.
Load-bearing premise
That Parseval's identity and Jensen's inequality can be applied directly to the formal power series R(z) with |r_n|=1 for all n to conclude unboundedness of the coefficients of R(z)^m.
What would settle it
An explicit sequence r_n with |r_n|=1 for all n such that the coefficients of R(z)^m remain bounded for some fixed m≥2.
read the original abstract
Let $R(z)=\sum_{n=0}^{\infty} r_n z^n$ be a power series with $|r_n|=1$ for every $n\ge 0$. We show that for each integer $m\ge 2$, the coefficient sequence of $R(z)^m$ is unbounded. The proof combines Parseval's identity with Jensen's inequality. As a consequence, Conjecture~3.9 of Gawron, Miska, and Ulas \cite{gmu} is confirmed.
Editorial analysis
A structured set of objections, weighed in public.
Referee Report
Summary. The manuscript proves that if R(z) = ∑ r_n z^n is a formal power series with |r_n| = 1 for every n ≥ 0, then for each integer m ≥ 2 the coefficient sequence of R(z)^m is unbounded. The argument combines Parseval's identity with Jensen's inequality and thereby confirms Conjecture 3.9 of Gawron, Miska, and Ulas.
Significance. If the central claim holds, the result settles an open conjecture on the growth of coefficients of powers of unimodular series and supplies a uniform obstruction to boundedness that applies to every choice of unimodular coefficients. The combination of two classical analytic tools to obtain a coefficient-wise conclusion is economical and potentially reusable.
major comments (2)
- [Abstract and proof] Abstract (paragraph 1) and the proof section: Parseval's identity is invoked to equate the L² norm on the circle with the sum of squared coefficients of R(z)^m, yet the manuscript does not supply an intermediate limiting argument (Abel summation, Cesàro means, or weak-* convergence) that would justify the identity when the partial sums of R(e^{iθ}) fail to converge in L² for arbitrary phases. Without this step the application to a general formal series with |r_n|=1 remains formally unsupported.
- [Proof] Proof (Jensen step): Jensen's inequality is applied directly to log |R(re^{iθ})| or an analogous quantity; the manuscript must clarify whether this is performed on the formal product before taking r→1 or on a truncated polynomial, and whether the resulting lower bound on the constant term of R^m survives the limit.
minor comments (2)
- [Theorem statement] The statement of the main theorem should explicitly quantify over all sequences with |r_n|=1 rather than leaving the quantifier implicit.
- [Introduction] A short remark on the relation between the formal power-series product and the analytic function on |z|<1 would improve readability.
Simulated Author's Rebuttal
We thank the referee for the careful reading and for identifying points where additional justification is needed to make the analytic arguments fully rigorous for formal power series. We respond to each major comment below.
read point-by-point responses
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Referee: [Abstract and proof] Abstract (paragraph 1) and the proof section: Parseval's identity is invoked to equate the L² norm on the circle with the sum of squared coefficients of R(z)^m, yet the manuscript does not supply an intermediate limiting argument (Abel summation, Cesàro means, or weak-* convergence) that would justify the identity when the partial sums of R(e^{iθ}) fail to converge in L² for arbitrary phases. Without this step the application to a general formal series with |r_n|=1 remains formally unsupported.
Authors: We agree that an explicit limiting argument is required, as the series with |r_n|=1 does not define an L² function on the circle. In the revision we will insert a preliminary step that applies Parseval to the Abel means R(r e^{iθ}) for r<1 (which are holomorphic and hence in L²), obtains the identity for the squared coefficients of the m-th power, and passes to the limit r→1^-. Because the coefficients themselves are independent of r, the resulting lower bound on the ℓ² norm of the coefficient sequence of R^m carries over directly to the formal series. revision: yes
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Referee: [Proof] Proof (Jensen step): Jensen's inequality is applied directly to log |R(re^{iθ})| or an analogous quantity; the manuscript must clarify whether this is performed on the formal product before taking r→1 or on a truncated polynomial, and whether the resulting lower bound on the constant term of R^m survives the limit.
Authors: We will clarify that Jensen's inequality is applied to the Abel means (or to the polynomials obtained by truncating the series) inside the disk |z|=r<1. The resulting lower bound on the integral of log |R(r e^{iθ})|^m is independent of r and therefore persists as r→1^-. We will add a short paragraph spelling out this order of operations and invoking the monotone convergence of the means to justify that the lower bound on the constant term of R^m survives the limit. revision: yes
Circularity Check
No circularity; derivation relies on external standard theorems
full rationale
The paper's central claim is established by combining Parseval's identity and Jensen's inequality, both external mathematical results independent of the present work. No self-citations are load-bearing, no parameters are fitted then renamed as predictions, and no ansatz or uniqueness result is imported from prior author work. The argument is self-contained against external benchmarks and does not reduce any step to its own inputs by construction.
Axiom & Free-Parameter Ledger
axioms (2)
- standard math Parseval's identity applies to the power series on the unit circle
- standard math Jensen's inequality applies to the convex function arising from the coefficient extraction
Reference graph
Works this paper leans on
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[1]
Gawron, P
[1] M. Gawron, P. Miska, M. Ulas,Arithmetic properties of coefficients of power series expansion of ∏∞ n=0(1− x2n )t, with an appendix by A. Schinzel, Monatsh. Math.185(2018), 307–360. School of Mathematics and Statistics, Central South University, Changsha, Hunan, China Email address:sz1021@csu.edu.cn
2018
discussion (0)
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