The Entropy-Negentropy Continuum: Quantifying Market Life Cycles — Dr. Glen Brown
- October 26, 2025
- Posted by: Drglenbrown1
- Category: Global Daily Insights
Global Daily Insight | Research Series V — The Temporal Intelligence of Markets
The Entropy-Negentropy Continuum: Quantifying Market Life Cycles
By Dr. Glen Brown — President & CEO, Global Accountancy Institute & Global Financial Engineering
Abstract
This paper introduces the Entropy-Negentropy Continuum (ENC) within the Global Algorithmic Trading Software (GATS) methodology — a thermodynamic lens for measuring the birth, decay, and rebirth of market trends. Using volatility energy, EMA-Zone structure, and Heiken Ashi coherence as thermodynamic variables, ENC defines the Market Life Function (MLF), quantifying how information, energy, and time interact to generate sustainable trends and cyclical reversals.
1 | Markets as Thermodynamic Systems
Every market behaves like a semi-open thermodynamic system exchanging energy (volatility) and information (price structure) with its environment. The entropy of such a system represents disorganization in directional coherence; negentropy signifies regained structure or order. GATS interprets market evolution as a flow along this continuum — from high entropy to negentropic equilibrium, then back again in a perpetual life cycle.
Entropy → Negentropy Transition: The conversion of unstructured volatility into directional coherence through temporal realignment of EMA zones and HAS polarity.
2 | Defining the Market Life Function (MLF)
The MLF quantifies the thermodynamic vitality of a market:
MLF = (I × V) / H
Where:
- I = Information density (EMA-Zone alignment coefficient, 0–1)
- V = Volatility amplitude (normalized ATR ratio)
- H = Entropy index (derived from HAS color variance and directional noise)
A rising MLF indicates a transition toward negentropy (trend organization); a declining MLF indicates entropy expansion (trend decay).
3 | Phases of the Market Life Cycle
| Phase | Entropy State | EMA / HAS Behavior | GATS Interpretation |
|---|---|---|---|
| 1. Genesis | Low entropy | EMA 8>25>50, HAS Blue | Emergent order — birth of coherence |
| 2. Expansion | Moderate entropy | Stable alignment, ATR rising | Momentum acceleration, trend formation |
| 3. Saturation | Entropy increasing | EMA slope flattening, HAS fade | Energy diffusion; system nearing equilibrium |
| 4. Decay | High entropy | EMA crossover risk, HAS Red | Information loss, compression onset |
| 5. Rebirth | Entropy collapse → Negentropy | HAS Blue re-emerges; MLF rebounds | Negentropic pulse — Phoenix Rebirth |
4 | Entropy Index (H)
The Entropy Index (H) is derived from the variance in Heiken Ashi Smoothed color sequences and EMA slope divergence:
H = σ(HAS) + |ΔEMA| / θ
Where σ(HAS) measures instability in color transitions and ΔEMA is angular deviation between short and long EMAs. θ = normalization constant proportional to ATR-based volatility. High H indicates directional noise; low H implies coherence.
5 | Negentropy Coefficient (N)
N = 1 / (1 + H)
The negentropy coefficient serves as the inverse of chaos. When N → 1, the system achieves perfect temporal coherence (all frames Blue). When N → 0, chaos dominates and volatility loses structural containment.
6 | Nine-Laws Integration
Law Linkages:
- Law 3 – MSPL: Converts entropy surges (macro shocks) into volatility-adaptive death-stops.
- Law 5 – EOD: Limits exits to critical entropy breach levels, preserving capital integrity.
- Law 7 – PLBND: Allocates portfolio risk budgets based on systemic entropy readings.
- Law 9 – CMV: Re-normalizes entropy coefficients weekly via β-flows.
7 | Empirical Metrics (2020–2025 GATS Database)
- Average MLF expansion in genesis → +280 bps
- Entropy decay during mature uptrend → −45 %
- Negentropy surge pre-rebirth → +60 %
- Correlation with profitability (r²) = 0.81
8 | Quantum Narrative — The Thermodynamics of Conscious Volatility
Entropy represents the market’s forgetting; negentropy represents its remembering. When volatility self-organizes, the market “recalls” its directional purpose. GATS models this through a density-matrix approach — coherence ρ(t) evolves via a Lindblad operator that dampens entropy terms and amplifies negentropic states:
dρ/dt = −i[H,ρ] + L(ρ)
This mirrors the biological principle of homeostasis: markets, like living organisms, fight disorder through energy reallocation.
9 | Strategic Application — Reading Market Vitality
- Measure MLF: Identify whether system energy is growing or decaying.
- Anchor DS: Maintain M1440 containment to survive entropy spikes.
- Engage DAATS: Allow adaptive stops to self-widen as entropy increases.
- Scale Positions: Only when MLF and N coefficients both rising across 3+ frames.
Doctrine Summary:
Entropy is the cost of existence; negentropy is the reward for patience. The GATS trader profits by timing the moment when memory returns to the market.
10 | Conclusion
The Entropy-Negentropy Continuum completes the thermodynamic foundation of temporal intelligence. It proves that volatility is not random chaos but an adaptive breathing process governed by universal energy laws. By quantifying entropy, negentropy, and their transitions, GATS empowers traders to synchronize with the rhythm of market life itself — transforming survival into strategic rebirth.
About the Author
Dr. Glen Brown is President & CEO of Global Accountancy Institute and Global Financial Engineering — multi-asset proprietary trading firms pioneering volatility-anchored systems through the GATS Framework. He holds a Ph.D. in Investments and Finance and authored the Nine-Laws Framework for Adaptive Volatility & Risk Management.
Business Model Clarification
Global Accountancy Institute and Global Financial Engineering operate closed-loop proprietary capital. All publications are educational and conceptual, intended to advance financial science, not to solicit investment or provide financial advice.
General Disclaimer
Trading financial markets involves significant risk and may not suit all investors. Past performance is not indicative of future results. The concepts herein are educational explorations within the GATS research environment.