This whitepaper introduces Strategy Knowledge Science (SKS) as a formal framework for representing strategic environments as computable state-spaces. It presents the OS2x2 architecture as a strategic computing system for positioning, feasibility analysis, trajectory computation, verified strategic decision-making, continuous strategic memory, and strategic learning over time. The paper defines the core layers of strategic computation — Strategic Geometry, Strategic Algebra, Strategic Mechanics, Strategic Topology, Strategic Field Theory, and Strategic Information Theory — and shows how they are translated into an applied computational architecture for deployment, runtime computation, graph-based strategic memory, and validation. It also introduces the Strategy Knowledge Model (SKM) as a new class of strategic-native artificial intelligence aligned with strategic state-spaces, constraints, and trajectories rather than linguistic plausibility alone, and extends the framework into financial markets through Trading Strategy Knowledge (TSK). The paper introduces Strategy Knowledge Reality (SKR) as the protocol by which real-world domains are projected into strategically legible form. Under SKR, domains are no longer treated as unconstrained narrative topics, but as structured environments of coordinates, regimes, field gradients, friction, and transition logic. This same logic extends into user-facing access through Ask Strategy Knowledge (ASK), the unified service layer through which users can query strategically encoded domains, receive structured answers, and, when needed, continue into persistent strategic navigation. It is further extended through Expert Strategy Knowledge (ESK), the expert analytic layer for security audit, structural review, architectural diagnosis, and optimization of complex agentic and strategic systems. The paper also introduces the Principle of Strategy Knowledge Invariance, which explains why Strategy Knowledge Science can operate across domains, scales, and representational frames. While strategic reality may differ in semantics, institutions, and local appearance, core relations such as position, regime, transition, force, friction, field-conditioning, dissipation, and feasibility remain sufficiently stable to support a common science of strategic computation. Invariance therefore complements Strategy Knowledge Relativity: relativity explains why strategic reality appears differently across frames, while invariance explains why those differing views can still belong to one coherent computable structure. The paper extends SKS into the affective dimension through Emotional Strategy Knowledge, which treats emotional states, affective fields, and relational emotional dynamics as structured modifiers of strategic motion rather than as narrative residue. In this formulation, emotion alters force, friction, inertia, field sensitivity, memory persistence, coordination thresholds, and regime stability. This allows strategic systems to model not only rational structure, but also affective distortion, trust collapse, burnout, emotional hysteresis, collective trauma, and other hidden variables that shape the real feasibility of motion across human, institutional, and human-agent environments. The architecture is further extended through the Strategic Memory Layer (SML), the persistence layer in which encoded states, transitions, constraints, regime histories, and recurring strategic patterns become reusable computable strategic memory. In this form, organizational knowledge is no longer preserved only as documents, repositories, or static taxonomies, but as strategically encoded state available for inference, validation, navigation, and adaptive learning. The Strategy Knowledge Graph (SKG) functions as the canonical graph-structured realization of this memory, transforming Knowledge Management (KM) from artifact preservation into strategic state persistence and inference. The paper is further extended by introducing Reasoning Strategy Knowledge (RSK) as a new general domain of Strategy Knowledge Science concerned with structured reasoning as a navigable, dynamic, and strategically regulable process. Developed primarily through the first major realization of Mathematical Strategy Knowledge (MSK), this extension models reasoning in terms of Resolution Space, Reasoning Regimes, Hidden Axes, False Attractors, Structural Friction, Reasoning Heat, and Phase Transitions of Insight, while also showing how these dynamics can support next-generation AI learning systems, closed-loop tutoring, strategic learner modeling, and reasoning-state intervention. In parallel, the paper strengthens its epistemic and operational architecture through the introduction of Strategic Core Calibration (SCC), the continuous calibration process through which axes, regimes, observables, and mechanical, field, and dissipative parameters are selected, refined, and recalibrated so that strategic computation remains valid under evolving domain conditions. This document serves as the theoretical and architectural foundation of the OS2x2 platform and the broader category of computed strategy What’s new in v4.0 LLM Integration: This PDF is optimized to function as a structural grounding layer for Large Language Models. By uploading this document as a reference context into an LLM interface (such as ChatGPT, Claude, or Gemini), users can enable LLMs to apply Strategy Knowledge Science for deterministic strategic analysis, effectively transforming the AI into a Strategy Knowledge Model (SKM). Introduced Strategic Markov Chains (SMC) to model stochastic transitions between discrete regime states under SKS. Developed Field-Conditioned Transition Mechanics, integrating friction, force coherence, strategic temperature, residual anomalies (ε), and hysteresis to detect hidden axes and guide Regime Escape protocols. Website: https://os2x2.com
Igor Binom (Sun,) studied this question.