What question did this study set out to answer?

This note aims to classify how buffering effectiveness is influenced by relational complexity in finite systems.

April 4, 2026Open Access

Complexity-Growth Regimes Governing Closure Burden in Finite Systems

Key Points

This note aims to classify how buffering effectiveness is influenced by relational complexity in finite systems.
Analyzed scaling relationships between relational complexity and buffer size.
Defined scaling exponent γ for complexity as C(B) ~ B^γ.
Characterized three regimes of closure burden based on the value of γ.
Identified beneficial buffering for γ < 1/2.
Found buffering to be neutral at γ = 1/2.
Determined buffering becomes detrimental for γ > 1/2.

Abstract

This note presents a minimal, regime-classifying result for buffering in finite systems operating under closure constraints. We show that the effectiveness of buffering is not intrinsic to system architecture, but instead depends on how relational complexity scales with buffer size. If complexity admits an effective scaling exponent γ such that C (B) ~ B^γ, then total closure burden scales as B^ (2γ−1), yielding three regimes: buffering is beneficial for γ 1/2. This provides a falsifiable, cross-domain framework applicable to computational, physical, and cognitive systems, and extends prior work on closure dynamics and information-theoretic residue.

Read Full Paperexternally

Bookmark

View Full Paper

Cite This Study

C. James Kruse (Fri,) studied this question.

synapsesocial.com/papers/69d0aff2659487ece0fa61ca https://doi.org/https://doi.org/10.5281/zenodo.19392817

Bookmark

View Full Paper