Front Matter

• Title Page
• Abstract
• Statement of Originality
• Acknowledgements
• Table of Contents
• List of Figures
• List of Tables
• List of Abbreviations
• Glossary
• Writing Philosophy and Principles Commitment

Background

• Background Context
• Thesis Structure Overview

Main Body

• Chapter 1: Introduction
  • 1.1 Introduction
  • 1.2 Research Problem
  • 1.3 Research Gap
  • 1.4 Aim, Objectives, and Research Questions
  • 1.5 Contributions
  • 1.6 Scope, Delimitations, and Thesis Structure
• Chapter 2: Literature Review and Theoretical Framework
  • 2.0 Chapter Roadmap
  • 2.1 Housing Need as Dynamic Person-Environment Fit
  • 2.2 Why Misfit Persists: Stock Inertia, Non-Convex Costs, and Lumpy Adjustment
  • 2.3 From Persistence to Stickiness: Path Dependence, Lock-In, Hysteresis, Divergence
  • 2.4 Supply-Side Architecture of Local Optionality
  • 2.5 Interface Discipline and Adoption Logic
  • 2.6 Bounded Optionality: Nominal vs Effective, Bounded Rationality, Permutation Explosion
  • 2.7 Dimensionality Reduction and Bounded Optionality as Enabling Constraint
  • 2.8 Modularity, Interfaces, and Manageable Change
  • 2.9 Four Critical Properties
  • 2.10 The Representational-Governance Problem Class
  • 2.11 Meta-Requirements and Research Questions
• Chapter 3: Theory — Modularity and Complexity
  • 3.1 Introduction: Why Modularity and Complexity Form the Lens
  • 3.2 Wickedness Emerges from Complex Adaptive Dynamics
  • 3.3 Modularity Theory and the Representational Substrate
  • 3.4 Platform Architecture Makes Modularity Actionable at System Scale
  • 3.5 The Design-Theory Contract
  • 3.6 Conclusion: Theoretical Commitments and Chapter Transition
• Chapter 4: Methodology
  • 4.1 Introduction: From Theory Contract to Method Contract
  • 4.2 Research Paradigm and the Inheritance from Theory
  • 4.3 Design Cycles, the Data Pipeline, and the Census Basis of Evidence
  • 4.4 Evaluation Questions and Measures
  • 4.5 Adjudication, Thresholds, and the P5 Composite Criterion
  • 4.6 Validity and Reliability
  • 4.7 Ethical Considerations and the Handoff Contract
• Chapter 5: A Queryable Schema for Accessibility Standards
  • 5.1 Introduction
  • 5.2 Artefact-Specific Literature: Standards Formalisation and Lexical Ambiguity
  • 5.3 Schema Design Theory, the SDA Domain, and Contribution Positioning
  • 5.4 Artefact Objectives, Corpus, and Analytical Methods
  • 5.5 Schema Objectives
  • 5.6 Corpus and Source Material
  • 5.7 Analytical Methods
  • 5.8 Evaluation Framework, Success Criteria, and DSR Iteration Evidence
  • 5.9 Success Criteria and Rejection Logic
  • 5.10 Design Science Research Iteration Evidence
  • 5.11 Empirical Baseline: Ambiguity and Fragmentation
  • 5.12 Schema Design: Principles and the Five-Layer Contract
  • 5.13 The Clause-Representation Contract, Inventories, and Residual Governance
  • 5.14 Implementation: The Five-Stage Serialisation Pipeline
  • 5.15 Pipeline Architecture
  • 5.16 Identity Generation and Clause Classification
  • 5.17 Term-Level Analysis and Polysemy Protocol
  • 5.18 Foundational Mapping and Fallback Governance
  • 5.19 Row Assembly, Validation, and Reproducibility Controls
  • 5.20 Evaluation Results: Resolution Rate, Deontic Force, and Schema Comparison
  • 5.21 Resolution Rate: Overall Results
  • 5.22 Resolution Rate by Clause Class
  • 5.23 Deontic Force: Honest Reframing
  • 5.24 Null-Model and Reduced-Schema Comparison
  • 5.25 Robustness, Integrated Assessment, Contributions, and Handoff to Chapter 6
  • 5.26 Threshold Sensitivity
  • 5.27 Integrated Assessment Against Success Criteria
  • 5.28 Contribution
  • 5.29 Limitations
  • 5.30 Handoff Contracts to Chapter 6
  • 5.31 Future Work
• Chapter 6: A Governed Kernel Architecture for Housing
  • 6.1 Introduction, the Governed Kernel Architecture, and Layer 1 — The Generative Grammar
  • 6.2 Layer 2 — The Modular Contract System: Taxonomy and Constituents
  • 6.3 Layer 2 — The Modular Contract System: Interaction Rules and the Modularity Admission Test
  • 6.4 Layer 3 — The Governed Instance Library and System Validation
  • 6.5 Contributions, Limitations, and Handoff to Chapter 7
• Chapter 7: A Formal Notation for Floor Plans
  • 7.1 Introduction and the Need for Formal Notation
  • 7.2 Notation Architecture and the Wrapping Functor
  • 7.3 RecPol: The Formal Core
  • 7.4 Design axioms and their consistency
  • 7.5 World model and coordinate systems
  • 7.6 Entity type system and plane projection
  • 7.7 The complete EBNF
  • 7.8 Canonical orthography
  • 7.9 Three-plane verb systems
  • 7.10 Version semantics
  • 7.11 Generative constraints
  • 7.12 Goodman compliance
  • 7.13 PlaniSyn: The Applied Layer
  • 7.14 Three-layer architecture
  • 7.15 Tag grammar and object model
  • 7.16 Spatial primitives
  • 7.17 Interaction types and interface expressibility
  • 7.18 Hierarchical nesting and the verification sequence
  • 7.19 Constraint preservation
  • 7.20 Encoding, Validation, and Contributions
  • 7.21 The encoding pipeline
  • 7.22 A worked example: an L-shaped living–kitchen with a coupled service lane
  • 7.23 Round-trip fidelity
  • 7.24 Requirements traceability
  • 7.25 Five demonstrated properties
  • 7.26 Contributions
  • 7.27 Limitations
  • 7.28 Handoff contracts to Chapter 9
  • 7.29 Forward to Chapter 9
• Chapter 8: Evidence from a Census of Australian Floor Plans
  • 8.1 Introduction
  • 8.2 The problem: bridging theoretical commitment and empirical grounding
  • 8.3 What the substrate establishes: one compound claim, ten instantiations
  • 8.4 The research question and its four-pipeline answer
  • 8.5 The Empirical Turn: Why a Substrate Chapter Is Necessary
  • 8.6 Why theoretical specification is not enough
  • 8.7 What an empirical substrate is, and what it contributes
  • 8.8 Four questions, four pipelines: the triangulation strategy
  • 8.9 The substrate’s position in the study’s arc
  • 8.10 Corpus Construction: Method and Calibration
  • 8.11 Why a corpus, and why this one
  • 8.12 The methodology pivot: agent-manual over API extraction
  • 8.13 The ten-principle calibration ruleset
  • 8.14 Corpus Pipeline, Merge, and Sealing
  • 8.15 The five-stage extraction pipeline
  • 8.16 The August-plus-October merge
  • 8.17 Sealing and provenance
  • 8.18 Residual scope-limit declarations
  • 8.19 Dimensional Evidence
  • 8.20 The dimensional question: ISO 2848 and the Australian market
  • 8.21 The coverage sweep and the 25 mm result
  • 8.22 Robustness of the selection, and the conditional lower bound
  • 8.23 Coincidence families: cross-category robustness
  • 8.24 The meso tier: a calibration check on the corpus
  • 8.25 Handoff to the frequency question
  • 8.26 Occurrence Evidence
  • 8.27 What the occurrence pipeline measures
  • 8.28 The 72-category frequency distribution
  • 8.29 Opening types and the topological aggregate
  • 8.30 The frequency-threshold derivation
  • 8.31 Stability of the threshold partition
  • 8.32 The meso-tier module synthesis
  • 8.33 Topological Evidence
  • 8.34 The topological question: access graphs and coupling
  • 8.35 The circulation hallway as organising hub
  • 8.36 The coupling partition: required and preferred adjacencies
  • 8.37 Threshold sensitivity and the census read directly
  • 8.38 Are the dispreferences regulated? The NCC sweep (CL-8-05)
  • 8.39 The Census Coupling Structure
  • 8.40 The census coupling structure and sensitivity finding S5-3
  • 8.41 Handoff to the configurational pipeline
  • 8.42 Configurational Evidence
  • 8.43 The configurational question: polyomino grammar and enumeration
  • 8.44 The feasibility rules and the symmetry group
  • 8.45 Arrangements, packings, and the deduplication result
  • 8.46 The three geometric indices
  • 8.47 The Partial Grammar and the Superset-Language Framing
  • 8.48 The partial grammar and the superset-language framing (CL-8-06)
  • 8.49 Handoff to integration (HC-8D)
  • 8.50 Integration
  • 8.51 The integration stance: triangulation, not redundancy
  • 8.52 Cross-pipeline coherence: the six probes
  • 8.53 The ten claims as facets of one substrate
  • 8.54 The four handoff contracts
  • 8.55 The merged-corpus coupling matrix
  • 8.56 Scope limits and the forward to Chapter 9
  • 8.57 Validation
  • 8.58 Why three validation dimensions
  • 8.59 Reproducibility: two of four pipelines verified
  • 8.60 Stability: dimensional stable, topological secure on the interior
  • 8.61 Coverage and the single-author limit
  • 8.62 The verdict-loop record and the anti-fabrication posture
  • 8.63 Limitations and External Validity
  • 8.64 The function of declared limitations
  • 8.65 External validity: what the substrate licenses
  • 8.66 Conclusion
  • 8.67 What the chapter constructed
  • 8.68 The ten claims and their final status
  • 8.69 The four handoff contracts and the open pathways
  • 8.70 The chapter’s position in the study
• Chapter 9: Generating Documented Dwelling Variants
  • 9.1 Introduction
  • 9.2 The Documentation Bottleneck
  • 9.3 An empirical anchor: documentation resists naive automation
  • 9.4 Four families of existing approach
  • 9.5 The gap the generator fills
  • 9.6 The Procedural-Generation Pipeline: Four-Stage Architecture
  • 9.7 Four-stage transformation: ingest, validate, transform, emit
  • 9.8 Architectural position: a thin executable layer over a thick specification stack
  • 9.9 Three design decisions
  • 9.10 Inter-stage contracts and independent testability
  • 9.11 The specification and its existence proof
  • 9.12 The Pre-Vetted Library: Definition and Distinction
  • 9.13 What the pre-vetted library is
  • 9.14 Distinction from naive component libraries
  • 9.15 Theoretical Warrant: Three Converging Literatures
  • 9.16 Current population state
  • 9.17 Curation discipline
  • 9.18 Position against future work
  • 9.19 Prototype: Runtime and the Documentation-Packet Contract
  • 9.20 Architecture and runtime stack
  • 9.21 The documentation-packet contract
  • 9.22 PlaniSyn predicate parsing and the Unparsed-line discipline
  • 9.23 The end-to-end run
  • 9.24 Spot-checks: ENT-FA-01 and KIT-FA-01
  • 9.25 Why this is the minimum DSR instantiation depth
  • 9.26 Reproducibility and the procedural round-trip
  • 9.27 Conclusion and Handoff to Chapter 10
• Chapter 10: Demonstration and Evaluation
  • 10.1 Introduction: A Single Dwelling Traced Across Its Life-Cycle
  • 10.2 Demonstration Case 1: The Trajectory Site (Baseline and Canonical Trunk)
  • 10.3 Demonstration Case 2: The Fork at S4 (Typical Aging vs SDA-Overlay-with-Secondary)
  • 10.4 Results: Standards Interpretability
  • 10.5 Operational definition
  • 10.6 Per-state interpretability profile
  • 10.7 The interface-obligation limitation
  • 10.8 Diagnostic locality and cross-event traceability
  • 10.9 Verdict against the threshold
  • 10.10 Results: Modular Fit and the Composition-Boundary-Stability Index
  • 10.11 Operational definition and the module-inheritance ratio
  • 10.12 Per-state modular-fit profile
  • 10.13 Per-state module-inheritance ratio
  • 10.14 Stable anchors
  • 10.15 Variant introduction and its structured-field limitation
  • 10.16 Hard-constraint cases and the verdicts
  • 10.17 Results: Workflow Efficiency and Discussion of Results
  • 10.18 Per-event workflow burden
  • 10.19 Synthesis matrix
  • 10.20 Aggregate verdict against the four properties
  • 10.21 Disconfirming and boundary outcomes
  • 10.22 Cross-chapter integration, limitations, and what the trajectory does not exercise
  • 10.23 Conclusion
• Chapter 11: Discussion
  • 11.1 Introduction
  • 11.2 Synthesis of Contributions
  • 11.3 Theoretical Implications
  • 11.4 Practical Implications
  • 11.5 Limitations
  • 11.6 Single-rater calibration scope (Ch5-CW-04)
  • 11.7 Cross-corpus generalisation (Ch6-AW-04)
  • 11.8 Independent third-party Goodman verification (Ch7-CW-10ER)
  • 11.9 UD/MOD/RB/LV baseline-library scope-limit
  • 11.10 SDA-Robust governed-kernel scope-limit
  • 11.11 Single-dwelling demonstration trajectory
  • 11.12 Synthetic-dwelling positioning
  • 11.13 Parser interface-obligations limitation
  • 11.14 Production-grade tooling
  • 11.15 Proposition 3 manipulability evidence borrowing
  • 11.16 Proposition 5 burden practitioner-field evaluation
  • 11.17 HLP/OFC/DIN/LNK module-class taxonomy
  • 11.18 Vocabulary divergence between Chapter 10 Section 10.8 and Section 10.9
  • 11.19 Future Work
  • 11.20 External multi-rater inter-rater-reliability validation
  • 11.21 Cross-corpus generalisation study
  • 11.22 Independent Goodman verification
  • 11.23 Full UD/MOD/RB/LV baseline-library expansion
  • 11.24 Multi-dwelling cohort study
  • 11.25 Parser interface-obligations field surfacing
  • 11.26 Production-grade generator tooling
  • 11.27 Non-specialist practitioner usability evaluation
  • 11.28 Practitioner-burden field study
  • 11.29 HLP/OFC/DIN/LNK formal taxonomy amendment
  • 11.30 LLM-assisted authoring layer
  • 11.31 Cross-jurisdictional SDA-equivalent regimes
  • 11.32 Conclusion
• Chapter 12: Conclusion
  • 12.1 Summary of Thesis
  • 12.2 Summary of Contributions
  • 12.3 Final Recommendations
  • 12.4 Concluding Remarks ## Appendices
• Appendices Index
  • Type A: Data and Materials (Appendix Data Index)
    • the Artefact Suite Evolution appendix
    • Appendix: Artefact Suite Handoff Contracts
    • Appendix: Standing Research Commitments
    • the Biological Degeneracy Analogues appendix
    • Chapter 5 Cross-Channel Validation Results
    • appendix-data-ch5-figures-ambiguity-scorecard
    • appendix-data-ch5-predicate-coverage-deontic-force
    • the Chapter 5 Reference Tables appendix
    • Chapter 5 Data Pipeline and Reproducibility
    • Appendix: Contribution and Design Rules
    • the Data Dictionaries appendix
    • appendix-data-environmental-grounding-dossier
    • Chapter 4w Evaluation Workbench
    • Chapter 5 Foundational Primitive Mapping Coverage
    • appendix-data-modularity-definition-corpus-profile
    • appendix-data-planisyn-grammar
    • Chapter 5 Polysemy Burden Assessment
    • appendix-data-recpol-specification
    • appendix-data-requirements-design-evaluation-traceability-matrix
    • appendix-data-requirements-register
    • Chapter 5 SDA Corpus Integrity Metrics
    • Chapter 5 Evaluation Results and Data Package
    • the Space Category Taxonomy appendix
    • Appendix: Standards Serialisation Schema Specification
    • appendix-data-text-floorplan-representations-evidence-profile
    • Chapter 5 Trigram and Part-of-Speech Structural Metrics
    • Appendix Figure: Cross-Chapter Figure Traceability
  • Type B: Supplementary Context Essays (Supplementary Index)
    • Text as Building Medium: Non-Graphic Construction Knowledge in Historical Practice
    • Ch8 supplementary context — dimensional modularity and ISO 2848 grounding for the 25 mm empirical finding
    • Ch8 supplementary context — packing efficiency metrics: CEI, EEI, BEI and their isoperimetric and spatial-efficiency literature analogues
    • Ch8 supplementary context — polyomino combinatorics, dihedral symmetry groups, and grammar-based spatial generation
    • supp-context-ch8–topological-coupling

Bibliography

The thesis uses inline footnote citations throughout the prose; full reference entries are aggregated at the end of the manuscript and cross-referenced from each footnote callout.