The list of figures inventories the figure callouts harvested from chapter prose. Each entry pairs the figure number and caption with a wikilink to the source figure module.

Chapter 2 — Literature Review and Theoretical Framework

• Figure 2.1 — Housing as a person-environment fit problem — view
• Figure 2.2 — Person-environment fit: competence-press dynamics — view
• Figure 2.3 — Lawton-Nahemow zone model: competence-press space with blocked adjustment — view
• Figure 2.4 — Supply-side architecture of change — view
• Figure 2.5 — Separation of concerns: monolithic vs layered systems — view
• Figure 2.6 — Shearing layers of the built environment (layer lifetimes) — view
• Figure 2.7 — Bounded optionality design problem — view
• Figure 2.8 — Nominal to effective optionality funnel — view
• Figure 2.9 — Modularity as bounded interdependence — view
• Figure 2.10 — Six conditions for manageable change — view
• Figure 2.11 — Representational governance as design problem — view
• Figure 2.12 — Chapter 2 argument map — view
• Figure 2.13 — Gregor-Hevner knowledge contribution framework — view
• Figure 2.14 — Hevner’s DSR three-cycle view — view
• Figure 2.15 — Meta-requirements traceability network — view
• Figure 2.16 — Near-decomposability: block-diagonal interaction structure — view
• Figure 2.17 — Containing vs transmitting interface behaviour — view
• Figure 2.18 — Life-course trajectory divergence — view
• Figure 2.19 — Permutation explosion: independent vs coupled decision variables — view
• Figure 2.20 — Three interface types in housing adaptation — view
• Figure 2.21 — Burden accumulation across interface sequence — view

Chapter 3 — Theory: Modularity and Complexity

• Figure 3.1 — Chapter 3 theory map — view
• Figure 3.2 — CAS feedback loops in the housing adaptation domain — view
• Figure 3.3 — Modularity constructs: interface-governed interaction density — view
• Figure 3.4 — Schematic Model of a Module — view
• Figure 3.5 — Platform architecture: from requirements to verification — view
• Figure 3.6 — Design-theory scaffold (after Gregor and Jones 2007) — view

Chapter 4 — Methodology

• Figure 4.1 — DSR cycle architecture — view
• Figure 4.2 — Four-layer data pipeline architecture — view
• Figure 4.3 — Evaluation traceability map — view
• Figure 4.4 — Thesis alignment with Hevner’s three-cycle DSR framework — view
• Figure 4.5 — Validity threat matrix — view

Chapter 5 — A Queryable Schema for Accessibility Standards

• Figure 5.2 — Five-layer standardisation schema architecture — view
• Figure 5.3 — Five-stage serialisation pipeline — view
• Figure 5.4 — Resolution rate resolution profile by dimension — view
• Figure 5.5 — Resolution rate by clause class — view
• Figure 5.6 — Progressive schema layer contribution — view
• Figure 5.7 — External benchmarking coverage — view
• Figure 5.8 — Primitive ablation information loss — view
• Figure 5.9 — Threshold sensitivity: polysemy ratio across frequency cutpoints — view
• Figure 5.10 — Cross-channel fragmentation: text–figure normative coverage overlap — view
• Figure 5.11 — Design Science Research iteration history for the standardisation schema — view
• Figure 5.12 — Deontic force decomposition: three-path honest reframing — view
• Figure 5.13 — Permutation test: significant primitive co-occurrence pairs — view
• Figure 5.14 — Literature positioning: four-stream intersection of the standardisation schema — view
• Figure 5.15 — SDA foundational primitive taxonomy — view
• Figure 5.18 — Artefact suite dependency chain with handoff contracts — view

Chapter 6 — A Governed Kernel Architecture for Housing

• Figure 6.1 — The Governed Kernel Architecture: three layers and the governed instance library — view
• Figure 6.2 — The stratified vocabulary: seven primitives, seven composites, ten operators — view
• Figure 6.3 — Twelve-pair boundary network with interaction differential heatmap — view
• Figure 6.4 — Verification sequence DAG — view

Chapter 7 — A Formal Notation for Floor Plans

• Figure 7.1 — Two-layer notation architecture — view
• Figure 7.2 — Cell taxonomy by free-edge count — view
• Figure 7.3 — Three-plane stratification with entity types and verb families — view
• Figure 7.4 — Local and global grids across Shape, Form, and Instance — view
• Figure 7.5 — RecPol EBNF production rules and LL(1) decision points — view
• Figure 7.6 — RecPol syntax by example: coordinates, joints, and free-edge counts — view
• Figure 7.7 — Raw and canonical form with the canonicalisation operator — view
• Figure 7.8a — Composite shape construction (worked example, S1) — view
• Figure 7.8b — Composite construction (abstract concept) — view
• Figure 7.9 — Lateral attachment of two distinct shapes via edge selection — view
• Figure 7.10 — Reflective self-attachment with the canonicalisation operator — view
• Figure 7.11 — Lanes and permeability flags as receptacle-prefix components — view
• Figure 7.12 — Permeability matrix: conditions in which two receptacles may overlap — view
• Figure 7.13 — Object exclusivity cases: disjoint, adjacent, and overlapping configurations — view
• Figure 7.14a — Instance placement walk-through (faithful worked example, RecPol syntax) — view
• Figure 7.14b — Instance placement (clean conceptual: Place, Mirror, Rotate) — view
• Figure 7.15 — PlaniSyn three-layer architecture with tag types and interaction mapping — view
• Figure 7.16 — Verification sequence constraint encoding (HC-6C) — view

Chapter 8 — Evidence from a Census of Australian Floor Plans

• Figure 8.1 — Geographic and market coverage of the census’s two strata (August and October) — view
• Figure 8.2 — Corpus construction data flow — view
• Figure 8.3 — Dimension frequency distribution with Gaussian-mixture-model components — view
• Figure 8.4 — 4D composite-coverage curve for module candidate selection — view
• Figure 8.5 — Soft and hard coverage profiles across module candidate range — view
• Figure 8.8 — Coincidence family network at the 25 mm module — view
• Figure 8.9 — Space-category connectivity frequency heatmap — view
• Figure 8.10 — Space-category adjacency coupling network — view
• Figure 8.11 — Hard- and soft-constraint adjacency segregation subgraph — view
• Figure 8.12 — Generator constraint funnel: from all polyominoes to feasible packings — view
• Figure 8.13 — D4 symmetry group and canonical form for polyomino deduplication — view
• Figure 8.14 — Representative arrangement permutations from the generator — view
• Figure 8.15 — Representative packing permutations showing port and attachment semantics — view
• Figure 8.16 — Micro-to-meso module LCM staircase hierarchy — view
• Figure 8.17 — the empirical substrate to the generator handoff contracts — view

Chapter 9 — Generating Documented Dwelling Variants

• Figure 9.1 — Procedural generation pipeline stages — view
• Figure 9.2 — the generator prototype: end-to-end run flow — view

Chapter 10 — Demonstration and Evaluation

• Figure 10.1 — Trajectory tree (S0 → S4 → {S5a, S5b}) — view
• Figure 10.2 — State progression — footprints (S0 to S4) — view
• Figure 10.3 — Fork path comparison (S5a vs S5b) — view
• Figure 10.4 — Standards-interpretability per-state profile — view
• Figure 10.5 — Modular fit (Module-Inheritance Ratio) per-state metrics — view
• Figure 10.6 — Per-event workflow burden across the trajectory — view
• Figure 10.7 — Evaluation surface (cross-state EM-09-01..04 composite, 2×2 panel grid) — view

Appendices

The appendix-data and supplementary-context appendices contain illustrative figures that are not numbered into the main-text figure sequence. See the appendix data index for the full appendix inventory. Appendix figures (when numbered) follow the “Appendix Figure A.N” convention to distinguish them from main-text figures.

• Appendix Figure: Cross-chapter figure-traceability matrix — view