| 1. Domain | 1.1 Scope of the Domain | Boundaries | The range of phenomena the science includes and excludes. | Studies dividing lines among first-order theories (stable, superstable, simple, NIP, NSOP, o-minimal, etc.); includes ranks, independence relations, and behavior of types. Excludes empirical classification or semantic categories outside model-theoretic structure. |
| | Scale | The spatial, temporal, or organizational level at which the science operates (e.g., quantum, cellular, social, cosmic). | Operates at the theory–model–type scale: formulas, types over sets, ranks, independence relations, and saturation levels. |
| 1.2 Ontological Commitments | Entities | The kinds of things assumed to exist within the domain (particles, organisms, agents, fields, etc.). | Theories, models, types, formulas, definable sets, ranks (Morley rank, U-rank), forking/dividing relations, independence relations, saturated models. |
| | Properties | The fundamental attributes these entities possess (mass, charge, genotype, preference, etc.). | Stability, simplicity, NIP/SOP status, rank values, definability of types, canonicity of independence, saturation degrees, homogeneity patterns. |
| | Categories | The basic ontological types used to classify domain elements (substances, processes, relations, structures). | Stable theories, superstable theories, ω-stable theories, simple theories, NIP theories, NSOP theories, classifiable theories, o-minimal theories. |
| 1.3 State-Variables | Variables | The measurable or definable properties that describe system conditions. | Types over parameters, independence configurations, rank assignments, forking patterns, definability patterns, saturation cardinalities. |
| | Parameterization | How variables encode and represent the system’s state. | State encoded by chosen base sets, realized/omitted types, rank values (e.g., RM, U), forking diagrams, and cardinalities used to define saturation. |
| 1.4 Admissible Idealizations | Simplifications | Conceptual reductions used to make the domain tractable (point masses, rational agents, perfect gases). | Assume saturated “monster model,” clean independence relations, well-behaved forking symmetry, definable types, and availability of prime or limit models. |
| | Validity Conditions | The limits and contexts in which idealizations hold or break down. | Failures occur in unstable theories (SOP, TP), non-elementary classes, insufficient saturation, or when independence is non-symmetric or not well-defined. |
| 1.5 Domain Assumptions | Structural Assumptions | Background ontological stances such as determinism, continuity, randomness, discreteness. | Assumes first-order logic, compactness, existence of saturations, robust type spaces, elementary embeddings, and classical model-theoretic independence frameworks. |
| | Implicit Commitments | Unstated but necessary assumptions that shape the field’s conceptual structure. | Assumes ranks track structural tameness; forking reflects genuine independence; definability aligns with stability; type spaces accurately represent model-theoretic geometry. |
| 1.6 Internal Coherence Requirements | Consistency | The demand that domain concepts do not contradict one another. | Requires non-contradictory interaction among ranks, independence relations, definability, and saturation; dividing lines must be logically compatible. |
| | Compatibility | The requirement that entities, variables, and assumptions fit together into a unified descriptive framework. | Requires alignment between types, ranks, independence relations, definability criteria, saturation, and classification-theoretic dividing lines across all models. |
| 2. Evidence Layer | 2.1 Observable Phenomena | Observables | The aspects of the domain that can produce detectable signals accessible to measurement. | Stability behavior, forking/dividing patterns, type multiplicities, rank values (Morley rank, U-rank), independence configurations, saturation behavior, classification dividing lines. |
| | Detection Limits | The boundaries of what can be resolved or sensed by current instruments or methods. | Limits arising from expressiveness of first-order logic: inability to detect unstable patterns via low-rank formulas, limits in distinguishing theories with similar type spectra, compactness constraints, cardinality barriers in saturation detection. |
| 2.2 Measurement Systems | Units | Standardized quantifications (meters, seconds, volts, decibels, dollars, etc.) necessary for consistent comparison. | Rank values (RM, U), cardinalities measuring saturation, multiplicity of types, forking depth, dividing chains, independence dimensions, definability degrees. |
| | Instruments | Devices and tools (microscopes, spectrometers, sensors, surveys, detectors) used to produce measurements. | Forking/dividing tests, rank computations, Morley sequences, indiscernible sequences, type-space topology, EF-game–like independence diagnostics, saturation checks, prime-model constructions. |
| 2.3 Operational Definitions | Definitions | Terms defined by specific measurement procedures, ensuring empirical clarity. | Formal definitions of stability, simplicity, NIP, forking, dividing, rank definitions (e.g., RM, U), definability of types, indiscernibility criteria, independence axioms. |
| | Procedures | The explicit steps required to perform a measurement in a reproducible way. | Calculating ranks, checking forking/dividing behavior, building Morley sequences, constructing indiscernibles, testing NIP via VC-dimension analogues, verifying existence of NF (non-forking) extensions. |
| 2.4 Data Acquisition | Protocols | Formal processes for gathering data under controlled or standardized conditions. | Building saturated models, forming type spaces S(A), generating independence configurations, constructing indiscernible sequences, computing rank spectra across models. |
| | Sampling | Rules determining which subset of the domain is measured and how representative it is. | Selecting representative types, choosing base sets for forking tests, sampling indiscernible sequences, examining definable families, isolating key formulas causing instability. |
| 2.5 Data Character & Format | Data Types | The form raw evidence takes (time series, spectra, images, counts, qualitative records). | Types, rank distributions, forking diagrams, indiscernible sequences, Morley sequences, dividing chains, independence trees, saturation profiles. |
| | Resolution | The granularity or precision with which data is captured. | Fineness of rank discrimination, granularity of type-space distinctions, cardinality resolution in saturation, precision of dividing/forking detection, sensitivity to instability patterns. |
| 2.6 Reliability & Calibration | Calibration | Adjustment procedures ensuring instruments produce accurate results. | Ensuring ranks computed consistently; verifying independence properties; checking that forking matches dividing; calibrating stability results across different models and cardinalities. |
| | Error Characterization | Identification and quantification of noise, uncertainty, bias, and measurement error. | Miscalculated ranks, misclassified stability/simplicity status, false identifications of forking or dividing, incorrect independence assumptions, saturation errors, type miscounting. |
| 3. Structural Layer | 3.1 Patterns & Regularities | Laws / Relations | Stable, repeatable patterns governing how observables behave across conditions. | Stability criteria, dividing/forking relations, rank monotonicity, type regularity, existence of Morley sequences, symmetry/transitivity properties of independence, tameness dividing lines. |
| | Invariants | Quantities or properties that remain constant under transformations (symmetries, conservation laws). | Rank invariants (Morley rank, U-rank), type invariants, saturation levels, independence invariants, definability of types, behavior of indiscernible sequences under automorphisms. |
| 3.2 Causal Architecture | Mechanisms | Underlying processes or structures that produce the observed regularities. | Mechanisms by which forking/dividing detect instability; independence generating tree-like structures; rank computation mechanisms; embeddings producing or eliminating instability; indiscernible collapse mechanisms. |
| | Pathways | Organized sequences of interactions forming a causal chain or network. | Forking/dividing chains, Morley sequence construction, indiscernible generation pathways, saturation-building chains, rank-refinement sequences, extension pathways for types. |
| 3.3 Theoretical Vocabulary | Concepts | Core terms that encode the domain’s structure (force, gene, equilibrium, field). | Stability, simplicity, NIP, NSOP, rank (RM, U), forking, dividing, indiscernibles, saturation, types, Morley sequences, independence relations, tameness, Shelah’s dividing lines. |
| | Classifications | Taxonomies, categories, or typologies that organize entities and relations. | Stable vs. unstable, superstable vs. stable, ω-stable vs. superstable, simple vs. non-simple, NIP vs. IP, NSOP vs. SOP, o-minimal vs. unstable expansions. |
| 3.4 Formal Representations | Equations | Mathematical constructs expressing laws, relations, or mechanisms. | Rank inequalities (e.g., RM(a/A) ≥ RM(a/AB)), forking equivalences, dividing formulas, independence axioms, characterization statements for stability/simplicity/NIP. |
| | Models | Structured representations—mathematical, computational, or conceptual—used to predict and explain phenomena. | Saturated models, homogeneous models, prime models, limit models, models witnessing stability/simplicity, Morley sequence structures, independence trees. |
| 3.5 Idealized Structures | Simplified Models | Purposeful abstractions that capture essential dynamics while omitting irrelevant detail. | Monster model (ℭ), pure-indiscernible arrays, stable fragments of unstable theories, simplified rank-1 theories, clean independence frameworks. |
| | Limit Conditions | Regimes where specific models or approximations hold (classical vs. quantum, linear vs. nonlinear). | Instability (SOP, TP), absence of non-forking extensions, rank divergence, failure of saturation at certain cardinals, non-definability of types, breakdown in non-first-order contexts. |
| 3.6 Integrative Frameworks | Unifying Theories | Higher-order structures that connect disparate laws or mechanisms under a coherent whole. | Shelah’s classification theory, stability theory, simplicity theory, NIP theory, geometric stability theory, o-minimality, model-theoretic tameness frameworks. |
| | Interdisciplinary Links | Points where the theory connects to adjacent sciences or larger explanatory systems. | Links to algebraic geometry (Zariski geometries), real analysis (o-minimal structures), combinatorics (VC-dimension, indiscernibles), group theory (definable groups), and topology (type-space topologies). |
| 4. Method Layer | 4.1 Inquiry Design | Experimental Design | Structured plans for manipulating variables to test causal claims. | Manipulating base sets, cardinalities, or model constructions to evaluate stability, simplicity, NIP/NIP, and rank behavior; altering formulas to test forking/dividing response. |
| | Observational Design | Systematic approaches for gathering non-manipulated data (surveys, field studies, natural experiments). | Observing forking, dividing, and independence behavior in existing models; studying type-space topology; monitoring rank changes without altering the language or theory. |
| 4.2 Testing & Validation | Hypothesis Testing | Procedures for evaluating whether evidence supports or contradicts specific claims. | Testing whether a theory is stable, simple, NIP, or NSOP; verifying symmetry/transitivity of independence; checking whether rank assignments behave predictably; identifying dividing formulas. |
| | Replication | The requirement that results be independently reproducible under similar conditions. | Repeating rank computations across saturated and unsaturated models; reproducing forking/dividing results with different parameter sets; re-testing independence relations across embeddings. |
| 4.3 Inference & Evaluation | Statistical Inference | Rules for drawing conclusions from noisy or incomplete data. | Logical analogues: evaluating distribution of types, comparing rank spectra, analyzing frequency of forking, measuring complexity of dividing chains, identifying extremal type configurations. |
| | Model Comparison | Criteria (fit, simplicity, predictive accuracy, robustness) used to evaluate competing models. | Comparing theories by their stability class, rank complexity, independence behavior, saturation profiles, definability of types, and robustness under model constructions. |
| 4.4 Error Management | Error Analysis | Identification and quantification of random and systematic errors. | Identifying miscalculated ranks, incorrectly classified stability/simplicity/NIP status, mistaken forking/dividing diagnoses, saturation errors, and false independence assumptions. |
| | Bias Control | Methods for minimizing subjective, instrumental, or procedural biases. | Avoiding biased selection of models or base sets; preventing rank overfitting through artificially enriched languages; ensuring neutrality in choice of witnessing types and indiscernible sequences. |
| 4.5 Adjudication & Revision | Peer Scrutiny | Collective evaluation of claims through critique, review, and debate. | Reviewing independence proofs, rank computations, dividing analyses, and classification claims; cross-checking with alternative constructions or canonical witnesses. |
| | Theory Revision | Procedures for modifying, replacing, or discarding models based on new evidence. | Adjusting axioms, modifying languages, refining independence frameworks, recalibrating rank definitions, altering type-space assumptions in response to new counterexamples. |
| 4.6 Integrity Conditions | Transparency | Requirements to disclose methods, data, assumptions, and limitations. | Full disclosure of rank calculations, forking/dividing criteria, independence assumptions, saturation parameters, and model-building methods. |
| | Ethical Standards | Norms ensuring responsible conduct in experimentation, data handling, and publication. | Honest representation of instability or complexity; avoidance of hidden assumptions in independence claims; precise attribution of dividing lines and classification theorems. |