Research, Software and Capability Map
Public institutional reference for research programmes, software platforms, engineering lineages, operational capabilities, cultural stewardship and ecosystem roles.
IMSV.org / Tegrity.AI · OÜ JUBAP / JubAp.eu · JubAp.Net · JubAp.us / RFC AIPI7504159D6 / RFC VACC791202G11
Current as of 30 June 2026 · Version 1.2 — Public Reference
Prepared from official ecosystem websites, published papers, public field notes, case studies and public institutional materials.
Document control
| Field | Current position |
|---|---|
| Document type | Public institutional reference and ecosystem capability baseline. |
| Status | Public consolidated reference. It describes the ecosystem and its currently articulated capabilities without assigning legal ownership, exclusivity or project-specific performance. It may evolve as research is validated, software is modularised, and new public programmes are launched. |
| Reference date | 30 June 2026. |
| Primary use | A stable public map for researchers, institutions, consortium partners, clients, contributors and other stakeholders seeking to understand the ecosystem’s programme and capability architecture. |
| Chronology boundary | The document reflects the corpus publicly articulated by 30 June 2026. Several software platforms and field capabilities predate that articulation; the present terminology should not be read as a claim that every current label existed at the time of the original implementation. |
| Capability attribution | Priority and non-exclusive. Participation, execution and remuneration remain project-specific. |
| Confidentiality | Only public, authorised or capability-level descriptions are included. Client-confidential evidence and technical secrets remain in restricted records. |
Executive synthesis
The ecosystem is best understood as a distributed capability system rather than a consolidated corporate group or a single product company. IMSV.org provides the international institutional and stewardship layer; Tegrity.AI is its research and publication circle; OÜ JUBAP / JubAp.eu provides the principal Estonian and EU-facing transformation, funding, commercial and market-access node; JubAp.Net provides the principal frontier-engineering, adaptive-systems and deployment lineage; and JubAp.us provides an Americas-facing integration and value-realisation node. Historical activities and archives provide additional source evidence without becoming interchangeable legal persons.
The consolidated architecture contains five principal research and methodological programmes, supported by an applied engineering platform and a cross-entity programme-delivery layer:
- Structural Awareness — the umbrella programme explaining and measuring divergence between the real flow of work and the representations used to govern it.
- Regime Awareness and Context Stability — detection of structural weakening and context invalidity before failure becomes visible.
- AI Integrity Management and AI Operational Integrity Architecture — the enterprise function and systems architecture needed when AI becomes mission-critical.
- Rationalization, Capability Discovery and AI Readiness — enterprise self-knowledge, value discovery, process intelligence and portfolio decisions under complexity.
- JUBAP Human and Organisational Transformation — the perspective, intervention and movement layer that translates diagnosis into executable change.
- Adaptive Operational Intelligence and Frontier Engineering — the field-proven engineering substrate represented by GEPLAN, xSeil, Phylons, process-intelligence and mission-critical deployment patterns.
- Software, Data and Platform Capabilities — the reusable architectures, modules, decision engines, data pipelines, evaluation environments and delivery patterns that connect the research programmes with operational systems.
- Programme Stewardship, Funding and Consortium Delivery — the institutional, funding, validation, regulatory and commercial pathways that move research into public-interest outputs, pilots and sustainable deployment.
Contents
1. Purpose, scope and interpretation
1.1 Purpose
The purpose of this guide is to provide one current and navigable public description of the research programmes, software platforms, frameworks, technical lineages, market-facing capabilities, cultural initiatives and institutional roles associated with The Integral Management Society / IMSV.org ecosystem.
1.2 Objects kept separate
| Object | Meaning in this guide | Examples |
|---|---|---|
| Research programme | Open-ended scientific or methodological enquiry intended for challenge, validation and, in some cases, open or stewarded release. | Structural Awareness; Regime Awareness; AI Integrity Management. |
| Workstream or series | A bounded disciplinary branch or sequence of papers inside a programme. | Cost of Clarity; Attribution Gap; Human Intelligence Debt; Informational Friction. |
| Framework or method | A codified intervention, diagnostic or decision method. | JUBAP Framework; Diamond Inside; JUBAP Portfolio Diagnostic. |
| Engineering capability | Reusable architecture, software, control logic or deployment pattern. | GEPLAN; xSeil; Phylons; process-intelligence and Tiger Team patterns. |
| Commercial or operational line | The market-facing expression through which a participant delivers or coordinates work. | APM Process Rationalization; enterprise transformation; consortium work packages. |
| Evidence case | A historical or current field environment that supports extraction and testing of a capability. | Mission-critical logistics, airport operations, liquidity control, application rationalization. |
1.3 Priority attribution is not exclusivity
For readability, each capability is assigned to one or more primary capability homes. A primary home is the node most closely associated with ordinary stewardship, research design, technical development, operational deployment, market coordination or regional integration. This is a default functional baseline, not a closed allocation.
- Other participants may contribute to research, engineering, validation, financing, missions, commercialisation or implementation.
- A work-package lead may differ from the ordinary capability home where the project requires different expertise, jurisdiction, infrastructure or funding eligibility.
- Capability attribution does not decide intellectual-property title, authorship, employment, agency, transfer pricing, regulated-product responsibility, tax residence or permanent establishment.
- A specific programme or collaboration may use a different functional distribution where its documented work, expertise, infrastructure or jurisdiction requires it.
1.4 Chronology and evidentiary boundary
The current programme architecture is partly retrospective. Production systems and transformation cases developed over many years were later compared, abstracted and organised into the present research language. Tegrity.AI and several series were still being completed after the end of 2025; the public corpus visible in 2026 is therefore the current synthesis of a longer engineering and research trajectory, not a claim that every current title or maturity level existed during the original field work.
2. Ecosystem architecture and default functional specialisation
The ecosystem combines legally independent organisations, operating nodes, public brands and historical source activities. The table below is functional and descriptive. It is not a statement of consolidated control or automatic common ownership.
| Node | Priority functional role | Capabilities most closely associated |
|---|---|---|
| The Integral Management Society / IMSV.org — Switzerland | International institutional umbrella; programme stewardship; scientific and methodological governance; public-interest validation; open-research and capability-preservation pathways; institutional and Swiss consortium relationships. | Structural Awareness; AI Integrity Management; Tegrity.AI governance; public-interest residual review; stewardship and long-cycle continuity. |
| Tegrity.AI — working circle hosted by IMSV | Research, publication and challenge environment for AI integrity, structural awareness, regime awareness and related series. Not treated here as a separate legal person. | Structural Awareness corpus; Regime Awareness; AI Integrity Management; AI Operational Integrity Architecture; research roadmaps and field notes. |
| OÜ JUBAP / JubAp.EU — Estonia | EU and international transformation, governance, risk, compliance, funding and commercial coordination; market-access and regulatory back office; enterprise rationalization and process-intelligence delivery; Estonian R&D execution and project archive where assigned. OÜ JUBAP is the legal entity and JubAp.EU is its commercial name — the same legal person. | Rationalization and AI readiness; enterprise architecture; application portfolio management; process mining; funding and consortium structuring; commercial integration. |
| The Integral Management Society S.A.S. de C.V. / JubAp.Net — Mexico | Frontier engineering, adaptive-systems intelligence, applied AI, software and systems development, integration, deployment and operational stabilisation. | GEPLAN; xSeil; Phylons; mission-critical engineering; Tiger Teams; operational intelligence; technical demonstrators and field systems. |
| JubAp.us — Americas integration node | Regional operational integration, company and supplier capability building, value realisation, industrial and corporate execution in the Americas. | Operational integration; supplier development; field transformation; value-chain execution; regional cases and intervention support. |
| Mexican Business Activity — Corbera Networks / Acción Integral / Abril i Palma | Historical source activity and documentary lineage for enterprise architecture, strategy, business-support services and earlier technical or methodological work, subject to actual records and rights. | Source archives, track record, early systems and methodology lineage; project-specific participation where documented. |
| Formación Integral — Mexico | Separately registered supporting activity associated with education, communication, learning and human-development capabilities where actually engaged. | Learning materials, communication and human-transformation support; participation remains project-specific. |
| Spanish Activity — 2023–2024 historical operating period | Historical EU-based self-employed activity through which selected continuity, documentation and professional work were carried before incorporation or transition to OÜ JUBAP. | Business-continuity evidence, selected project archive and methodology development; no automatic continuing role after the operating period. |
2.1 Default operating logic
| Function | Default coordination | Interpretation |
|---|---|---|
| International programme governance and neutral institutional umbrella | IMSV.org | Programme selection, stewardship, scientific/public-interest coherence and international institutional coordination. |
| Research publication and cross-disciplinary challenge | Tegrity.AI under IMSV | Working series, field notes, validation roadmap and research community interface. |
| Technical development and work-package engineering | Designated technical lead; commonly JubAp.Net | Actual lead may be OÜ JUBAP, a university, specialist or partner according to the project. |
| EU/international commercial, contractual and regulatory back office | OÜ JUBAP / JubAp.eu | Offer integration, contracts, financing, certification coordination, royalties/compensation administration and market access where assigned. |
| Commercial and innovation funding channel | OÜ JUBAP by default; non-exclusive | Estonian/EU grants, commercial partners and capital discussions. IMSV and other participants may also negotiate compatible funding. |
| Public-interest, dormant or underexploited capability stewardship | IMSV.org by default | Preservation, validation, open research, controlled reactivation or preparation for renewed commercialisation, subject to rights and project records. |
| Americas operational integration and value realisation | JubAp.us with JubAp.Net | Regional implementation, company integration, supplier and field capability building. |
3. Consolidated programme architecture
| Code | Programme / platform | Central question | Main components |
|---|---|---|---|
| A | Structural Awareness | Why representations drift from real work, why acting through a drifted map destroys capability, and how structural awareness can be measured and recovered. | Four disciplinary series: Cost of Clarity, Attribution Gap, Human Intelligence Gap/Debt, Informational Friction. |
| B | Regime Awareness and Context Stability | When an adaptive or history-dependent system is leaving a stable operating regime, and how context, buffers and action posture should adapt. | Minimalistic early warning, contextual sufficiency, past-only context selection, safe action, transition resilience. |
| C | AI Integrity Management and Operational Integrity Architecture | How enterprise oversight and system architecture should preserve explainability, security, resilience, compliance and operational value as AI becomes mission-critical. | Enterprise-function design, expert-system envelopes, dynamic guardrails, oversight limits, regime-aware integrity. |
| D | Rationalization, Capability Discovery and AI Readiness | How organisations can know, simplify and improve complex estates without destroying locally embedded or hidden capability. | APM, process mining, Diamond Inside, AI readiness, strategic reframing, capability federation, Portfolio Diagnostic. |
| E | JUBAP Human and Organisational Transformation | How diagnosis is translated into movement, perspective change, participation and sustainable execution. | JUBAP Framework, JUMP UP, human transformation, bottom-up micro-projects, intervention and value projection. |
| F | Adaptive Operational Intelligence and Frontier Engineering | Field-proven engineering substrate from which research capabilities are extracted and through which pilots are delivered. | GEPLAN, xSeil, Phylons, process intelligence, integration architecture, Tiger Teams. |
| G | Programme Stewardship, Funding and Consortium Delivery | How long-cycle programmes are governed, funded, validated, opened, commercialised and integrated into multi-party initiatives. | Stewardship, grants, consortium roles, market access, certifications, rights-aware commercialisation. |
3.1 One throughline across the ecosystem
The common throughline is structural awareness: understanding the real dependencies, contributions, constraints and load-bearing parts of a system well enough to act without destroying them. The Structural Awareness programme explains why this faculty is lost; Rationalization and JUBAP diagnose and recover it in organisations; Regime Awareness detects its loss dynamically in adaptive systems; and Frontier Engineering converts the resulting insight into running systems and interventions.
4. Programme A — Structural Awareness
Structural Awareness is the umbrella research programme connecting four disciplinary series that start from different primitives but converge on a common operational phenomenon: organisations govern work through maps, records, architectures, ownership statements and metrics that diverge from the real flow of contribution and dependency. Decisions taken through the divergent representation feed back into the real system and can deform or destroy the very capabilities on which performance depends.
Principal public references: Structural Awareness — synthesis and index · Tegrity.AI Field Notes.
4.1 Core conceptual distinctions
| Concept | Working definition | Capability implication |
|---|---|---|
| Flow | What actually happens: dependencies, work, contribution, load, decisions and value creation. | Requires discovery from records, lineage, event data, interviews and outcomes. |
| Map | The representation used to govern the flow: inventories, architecture models, ownership, KPIs, org charts and portfolios. | Must be treated as a control surface, not a neutral description. |
| Structural awareness | The faculty of seeing the real structure well enough to act without destroying it. | Supports diagnosis, recovery, revaluation and safe transformation. |
| Gap | The divergence between map and flow. | Can be measured through discovery, attribution, ownership and conformance evidence. |
| Informational friction | Production loss and extra work caused by acting through a divergent map. | Connects representation error to operational cost and capability loss. |
4.2 Series 1 — The Cost of Clarity
The Cost of Clarity is the information-theory and transformation-economics branch. It rejects the assumption that the information required by transformation is a free input. It studies the cost and risk of producing the minimum reliable information needed before an initiative can be committed, governed or evaluated.
| Current paper / node | Contribution | Capabilities under development |
|---|---|---|
| When the Problem Isn’t the Technology | Shows convergence across rationalization, automation, AI enablement, process mining and guardrails at the same missing-information bottleneck. | Cross-domain failure-pattern synthesis; informational precondition diagnosis. |
| When Asking the Question Changes the Answer | Distinguishes found information from information that must be declared by an authorised party. | Declarative-burden analysis; observer-effect and intervention-aware discovery. |
| When You Have to Decide Before You Can Discover | Examines the circularity in which target decisions are required before the full effects of the decision can be known. | Decision-before-discovery risk; dependency-entanglement analysis. |
| When Cleaning Up Means Betting Blind | Explains why a clean target architecture can destroy hidden value in the unresolved current state. | Value-preservation gate; revalue-before-clarify sequencing. |
| How to Measure the Cost of Not Knowing | Develops direct and indirect measurement, sampling and revealed-behaviour approaches. | Clarity-cost estimation; measurement protocol; feasibility and confidence. |
| Is Clarity Getting More Expensive? | Tests whether system entanglement increases both the cost and risk of knowing how work runs. | Entanglement metrics; technology-wave comparison; trend hypothesis. |
| The Minimal Information a Transformation Needs | Defines the bounded information set required for an accountable initiative. | Minimum-information instrument; go / wait / rescope precondition. |
| What Goes Unpriced Is Paid in Human Intelligence | Cross-series bridge to Human Intelligence Debt. | Allocation of unpriced clarity work to human cognitive load. |
A current applied-research proposal translates this programme into a measurement instrument with candidate readings including discovery cost, declarative burden, decision cost, absorption cost, value at risk and unseen scope. The proposed validation combines historical post-mortem reconstruction with pre-mortem prediction on live initiative backlogs.
Principal public reference: The Cost of Clarity series.
4.3 Series 2 — The Attribution Gap
The Attribution Gap is the economics and enterprise-architecture branch. It studies the widening distance between structural dependency on a capability and the formal credit, ownership, authority or funding assigned to it. The proposed mechanism is decay by incentive rather than simple neglect: making a dependency visible can redistribute credit and power, creating pressure to keep critical contributions implicit.
| Current paper / node | Contribution | Capabilities under development |
|---|---|---|
| The Attribution Gap and Capability Loss | Defines the causal chain from incomplete contribution visibility to attribution distortion, withdrawal of ownership/funding and eventual capability loss. | Contribution-dependency mapping; attribution-risk diagnosis; capability-preservation rules. |
| Attribution Gap Measurement Protocol | Reduces the theory to observable, staged and non-circular signatures. | Discovery-gap analysis; ownership-silence test; raised-and-ignored pattern; internalisation wedge; rationalization scar. |
| Bridge: The Attribution Gap and Capability Loss | Connects attribution failure with Human Intelligence Debt without treating convergence as proof. | Cross-series evidence design; common outcome mapping. |
| Governance response — under development | Addresses what an organisation should structurally do once the gap has been diagnosed. | Revaluation, accountable ownership, funding and portfolio-treatment controls. |
Principal public references: The Attribution Gap series.
4.4 Series 3 — The Human Intelligence Gap / Human Intelligence Debt
This organisational-theory branch measures the difference between the cognitive contribution humans could make in a well-architected organisation and the contribution actually realised when people reconcile systems, re-enter data, validate outputs and compensate for fragmentation. The current framework distinguishes an Optimal Human Intelligence Ratio, observed Human Intelligence Density and the resulting Operational Intelligence Debt.
| Current paper / node | Contribution | Capabilities under development |
|---|---|---|
| Human Intelligence Debt | Introduces the practical field observation and core debt concept. | Work classification; compensating-work detection; human-capacity loss framing. |
| The Harvester Multiplication Problem | Examines how fragmented automation and governance multiply rather than remove human compensating work. | Capability-fragmentation and governance-overhead analysis. |
| The Human Intelligence Debt Dilemma | Uses game-theoretic reasoning to explain why rational agents can build collectively irrational architectures. | Incentive mapping; local-rationality / systemic-debt diagnosis. |
| Architectural Entropy | Explores mediated systems, human «exergy» and partial irreversibility of capability loss. | Entropy and recovery limits; carrier-dependence analysis. |
| Measuring Human Intelligence Debt | Moves from concept to an empirical measurement design. | Optimal ratio, observed density, debt measurement and sector benchmarking. |
| Evidence Notes for the Proposed Study | Separates preliminary evidence from the final empirical protocol. | Evidence-register design; claim typing and source discipline. |
| What Cannot Be Recovered Must Be Managed | Bridge to AI Integrity Management. | Oversight limits; scarce-coherence capacity; managed residual risk. |
| The Limits of AI Oversight | Bridge to AI Operational Integrity Architecture. | AI-governance workload and human-review capacity limits. |
Principal public references: The Human Intelligence Gap series.
4.5 Series 4 — Informational Friction
Informational Friction is the systems-theory branch. It removes the specifically human motive and studies the general case of a system whose controller acts through a representation that has diverged from the real flow. Because action changes the flow, representation error becomes a feedback mechanism rather than a passive description problem.
| Current paper / node | Contribution | Capabilities under development |
|---|---|---|
| The Map and the Flow | Defines the control-surface problem and the back-action of representation. | Map-flow divergence model; system-level friction diagnosis. |
| Optimization, Coherence, and the Frame | Distinguishes frame-bounded optimisation from cross-frame coherence. | Frame analysis; coherent-agent and independent-outcome tests. |
| Why Selection Cannot See It | Develops insolvency by compliance, positive deviation, deviance-dependence and limits of market/evolutionary selection. | Conformance counterfactual; maturity-inversion and deviance-dependence measures. |
| The Outlook | States falsifiable forecasts, led by «inefficiency before unemployment». | Automation × deviance-dependence testing; scenario and policy implications. |
Principal public references: Informational Friction series.
4.6 Programme-level capabilities and current status
- Structural-discovery and map-flow divergence diagnostics.
- Minimum-information and clarity-cost estimation before transformation commitment.
- Capability-contribution, attribution and ownership-silence measurement.
- Human cognitive-capacity and compensating-work measurement.
- Conformance counterfactuals, deviance-dependence and automation-interaction testing.
- Revalue-before-clarify and capability-preservation decision gates.
- A cross-disciplinary falsification programme using records organisations already hold.
Current status: Publicly articulated multi-series programme with foundational papers, measurement protocols, field notes and proposed empirical studies. Scientific and commercial claims remain differentiated by document status and require independent validation where stated.
5. Programme B — Regime Awareness and Context Stability
Regime Awareness studies how adaptive, operational and technological systems lose structural stability before failure is visible. It is narrower than universal forecasting: the capability is to detect that the context supporting current behaviour, thresholds or decisions is no longer reliable, and to adjust observation, buffers, redundancy, priorities, action or abstention before instability propagates.
Principal public references: Minimalistic Regime-Aware Early Warning Systems · Regime Awareness Capability — field case.
5.1 Core research capabilities
| Capability | Description | Current maturity / boundary |
|---|---|---|
| Structural-regime awareness | Detect increasing fragility, saturation, excessive optimisation, buffer loss, tight coupling and hidden propagation before surface failure. | Framework and field lineage; domain-specific validation required. |
| Minimalistic early-warning detector | Operate under severe observability constraints: unknown system, finite history, limited or scalar observables, no labels or complete causal model. | Formal and computational candidate under validation. |
| Contextual Sufficiency Boundary | Identify the minimum historical context or observation weighting sufficient to preserve decision-relevant regime distinctions. | Theoretical and algorithmic development; not a universal existence claim. |
| Past-only context selection | Select a boundary or weights using only information available at or before the decision time, beneath a history-dependent host model. | Advanced candidate; applies only where the model exposes a controllable context interface. |
| Confidence, coverage and abstention | Treat confidence and the ability to refuse a decision as first-class outputs. | Design requirement for evaluation and regulated use. |
| Transition-resilience measurement | Measure peak loss, cumulative loss and recovery time around distribution or operating-regime shifts. | Proposed validation endpoints. |
| Pointwise Non-Inferiority / safe action | Design authorised responses so action is no worse than inaction within the declared domain, or apply a clearly bounded-downside alternative. | Safety ideal; feasibility depends on action class and domain. |
| Dynamic buffer and propagation control | Increase slack, liquidity, redundancy, rental capacity, routing options or decision margins as propagation risk rises. | Field-proven patterns; formal generalisation in progress. |
| External model-validity monitoring | Add a context-validity layer beneath existing forecasting, anomaly, risk or decision-support systems without replacing them. | Co-development and pilot opportunity. |
| Sealed-executable evaluation | Evaluate a private implementation through frozen, auditable runtime, evaluator-controlled data and immutable output logs. | Evaluation architecture; not itself a performance result. |
5.2 Engineering lineage and extracted mechanisms
| Field foundation | Capability extracted | Primary current home |
|---|---|---|
| GEPLAN — industrial and energy logistics | Integrated operational state, planning/execution separation, capacity estimation, maintenance/inventory/telemetry integration and self-funded transformation sequencing. | JubAp.Net; historical source activities; OÜ JUBAP for current abstraction and market integration. |
| xSeil — mission-critical transport intelligence | Dynamic utility, fragility as a capacity signal, propagation control, stability partitioning, decision memory and closed-loop plan-versus-actual adjustment. | JubAp.Net; Tegrity.AI for research abstraction; OÜ JUBAP for pilots and commercial coordination. |
| Phylons Neural Networks — institutional liquidity / signal architecture | Hierarchical, explainable units; regime-change signal architecture; dual-attractor response without full retraining. | JubAp.Net; Tegrity.AI / IMSV for validation and publication. |
| APM and Process Mining — enterprise rationalization | Use process telemetry, dependency and fragility signals to avoid removing capacity or structural buffers faster than the system can absorb. | OÜ JUBAP / JubAp.eu; JubAp.Net technical support; Tegrity.AI research interpretation. |
5.3 Current roadmap
- Independent theoretical, mathematical and implementation review.
- Frozen reference artefacts and leakage-audited held-out evaluation.
- Co-development with research, industrial and public-sector partners in bounded work packages.
- Pilot implementations in environments where context validity, cascading effects and operational resilience matter.
- Open and interoperable reference components where rights, confidentiality and validation permit, while preserving private implementation layers where justified.
Current status: A field-derived and increasingly formal research programme. Some engineering mechanisms are field-proven; the domain-agnostic detector, context-selection layer and broad performance claims remain candidates under validation.
6. Programme C — AI Integrity Management and Operational Integrity Architecture
This programme has two distinct but connected layers. AI Integrity Management is the proposed enterprise discipline that coordinates safety, governance, explainability, cybersecurity, compliance, MLOps, operational reliability and value. AI Operational Integrity Architecture examines the system design itself: statistical AI cores surrounded by deterministic guardrails, rules and controls, and what happens when the environment changes or the control envelope becomes fragile.
Principal public references: AI Integrity Management series · AI Operational Integrity Architecture · Tegrity.AI overview.
6.1 Enterprise-function workstream
| Paper / theme | Question | Capability |
|---|---|---|
| AI Integrity: a Critical Frontier | Why AI integrity becomes a cross-domain issue when systems enter real operations. | Integrated oversight framing; institutional stewardship and field-practice lineage. |
| The Case for AI Integrity Management as a Formal Enterprise Function | Whether one accountable coordinating function is needed above existing specialist disciplines. | Operating model, role boundaries, escalation and accountability design. |
| One Function or Many? | Tests the case for and against unification. | Federated-vs-central coordination design; proportional governance. |
| The Semantic Tug-of-War | Examines competing nomenclature and organisational claims over AI oversight. | Taxonomy, boundary and stakeholder-alignment capability. |
6.2 Operational-architecture workstream
| Paper / theme | Question | Capability |
|---|---|---|
| Toward Expert-System Envelopes Around Statistical AI | How deterministic rules, expert knowledge and operational constraints can surround statistical models. | Hybrid architecture; explainable action boundary; controlled integration. |
| Structural Limits of Current AI Integrity Under Regime Change | When static guardrails cease to describe the operating context. | Regime-aware guardrails; context validity; escalation and abstention. |
| From Complicated to Complex: The AI Safety Paradox | How growing control layers can create emergent interactions and fragility. | Complexity boundary diagnosis; integration rather than control accumulation. |
| The Limits of AI Oversight | How finite human review capacity constrains governance. | Human-in-the-loop capacity modelling; oversight debt; prioritised intervention. |
| Adaptive Integrity — forthcoming | How integrity controls might change with the regime without becoming opaque or unconstrained. | Adaptive guardrails and bounded-response architecture. |
6.3 Cross-cutting capability set
- Regulator- and standard-aware enterprise architecture for AI-enabled systems.
- Integration of security, auditability, risk, compliance, data and operational continuity into design rather than post-hoc control.
- Deterministic guardrails and expert-system envelopes around statistical components.
- Regime-aware integrity, dynamic thresholds, abstention and bounded escalation.
- Human oversight capacity, prioritisation and residual-risk management.
- Legacy and third-party integration under real operational constraints.
- Cost discipline and demonstrable operational and human value.
Current status: An emerging discipline and architecture corpus, practitioner-oriented and open to challenge. It provides a coherent capability map but does not replace statutory responsibilities, product certification, cybersecurity, risk management or domain-specific assurance.
7. Programme D — Rationalization, Capability Discovery and AI Readiness
This is the most mature market-facing and applied-development programme. It treats rationalization not as deletion or IT hygiene, but as the disciplined construction of enterprise self-knowledge: a governed view of applications, processes, data, capabilities, dependencies, cost, risk and value that permits simplification without destroying adaptation, identity or load-bearing capability. The AI-readiness thesis is that an organisation cannot govern or interpret AI reliably when its own architecture remains a black box.
Principal public references: JubAp.eu Field Notes · JubAp.eu Field Notes — page 2.
7.1 Programme components
| Component | Purpose | Capabilities |
|---|---|---|
| APM Process Rationalization / rationalization.ai | Build a credible technology and capability footprint and a governed decision pipeline. | Inventory, lifecycle, TCO, risk, business fit, dependencies, mutualisation, retirement and roadmap. |
| Process Intelligence / Process Mining | Reconstruct actual process variants and operational flow from event data. | Variant discovery, handover and rework analysis, bottleneck detection, application/process linkage, propagation signals. |
| Diamond Inside | Find value already inside a decentralised or heritage-rich group before classifying apparent duplication as waste. | Keep local / consolidate / scale / transform / retire; cultural fit; rare capability and local adaptation preservation. |
| AI Ready-Up Rationalization | Prepare processes, data and application landscapes so AI can be interpretable, governable and economically scalable. | AI-readiness diagnosis; technical-debt and complexity analysis; rationalization-first roadmap. |
| Shadow estate and capability discovery | Create sufficiently good visibility where formal inventories are incomplete. | Proxy TCO, ownership reconstruction, discovery confidence, regional and shadow-IT mapping. |
| Capability federation | Mutualise common services while preserving differentiated capabilities and local expertise. | Federation-vs-centralisation decisions; capability contracts; low-code/IoT/legacy governance. |
| Strategic Reframing and Value Creation | Change the frame through which value, initiative viability and stakeholder outcomes are evaluated. | Provider-receiver value comparison, second-order effects, hidden opportunity and value projection. |
| HR and Process Rationalization | Align workload, roles, process demand and capability without treating headcount as an isolated target. | Capacity mapping, value-based staffing, process simplification and human-intelligence protection. |
| JUBAP Portfolio Diagnostic — working development | Diagnose which initiatives can genuinely move and which project value beyond their immediate owner. | Fragility Risk Index, Projective Value Index, evidence confidence, mapping, interview protocol and AI-assisted synthesis. |
7.2 Core capability pipeline
- Establish a trustworthy footprint from public records, repositories, CMDB/APM data, process logs, interviews and financial evidence.
- Map applications and processes to business capabilities, owners, users, dependencies, risk, service levels and cost.
- Identify hidden, dormant, local or rare capabilities before recommending standardisation or removal.
- Separate immediate efficiency from propagation, resilience, cultural fit, strategic option value and downstream impact.
- Generate evidence-based keep, consolidate, scale, transform, federate, retire or investigate decisions.
- Translate decisions into a sequenced roadmap, business case, funding path and controlled implementation.
- Use AI and small-language-model assistance for extraction, contradiction detection and synthesis while preserving human accountability and evidence traceability.
7.3 Primary functional homes
| Capability area | Primary home(s) | Regular supporting roles |
|---|---|---|
| EU/international rationalization and governance | OÜ JUBAP / JubAp.eu | IMSV for stewardship and research; JubAp.Net for engineering; JubAp.us for Americas delivery. |
| Process-intelligence and technical integration | OÜ JUBAP with JubAp.Net | Tool vendors, client teams and project-specific specialists. |
| Value-discovery and public-interest research | IMSV / Tegrity.AI with OÜ JUBAP | JubAp.us and field operators contribute evidence and implementation. |
| Commercialisation, funding and market access | OÜ JUBAP by default | IMSV and other nodes may negotiate grants or contributions where appropriate. |
Current status: Commercially mature service and capability family with active methodological, software and evidence-architecture development. Commercial delivery and reusable research remain distinct activity types within the wider programme.
8. Programme E — JUBAP Human and Organisational Transformation
JUBAP — Jump Up Business Action Plan — is the historical transformation framework and the origin of the ecosystem name. It is designed for organisations that already possess methods, standards and expertise but still cannot translate strategy into coordinated movement. Its emphasis is not another methodology layer, but the identification of high-leverage button points, concrete resistance, joinable action and a perspective shift that reveals actions previously hidden by the existing frame.
8.1 Framework and research components
| Component | Purpose | Capability |
|---|---|---|
| JUMP UP logic | Filter action and change the level of perception. | Joinable, Unblocked, Movable, Projective / Propagating, with UP as reframing or level change. |
| Human Transformation / Nueva Perspectiva | Change the person’s capacity to perceive and act so the organisation can see what it could not. | Perspective work, attention, experiential learning, collective emotional intelligence and integral management. |
| Bottom-up intelligence | Use the distributed knowledge of workers, operators and stakeholders. | Micro-project generation, local ownership, practical learning and measurable movement. |
| Zero- or low-overload transformation | Create change while the operation continues and attention is constrained. | Small high-leverage interventions, existing-resource use and staged capability building. |
| Methodological interoperability | Work alongside Lean, TPM, Agile, Kotter, ISO, enterprise architecture, risk and quality frameworks. | Integration rather than framework replacement. |
| Portfolio and initiative diagnosis | Connect human movement with structural fragility and receiver value. | JUBAP Portfolio Diagnostic, FRI/PVI and evidence confidence. |
| Diamond Inside connection | Use value discovery before rationalization or standardisation. | Human and organisational counterpart to revalue-before-clarify. |
8.2 Evidence and application base
The framework has been applied and refined through organisational transformation, industrial, infrastructure, logistics and corporate environments. Public ecosystem materials associate its naming and structured use with a multinational manufacturing intervention, later bottom-up airport transformation, mission-critical logistics and current portfolio-rationalization work. These cases are used as field evidence and do not make every historical mandate a current programme asset of every ecosystem entity.
8.3 Primary functional homes
| Capability area | Primary home(s) | Supporting nodes |
|---|---|---|
| Method stewardship, public-interest and training coherence | IMSV.org | Tegrity.AI where research bridges are developed. |
| EU/international transformation and governance | OÜ JUBAP / JubAp.eu | IMSV, JubAp.Net and project partners. |
| Technical and field implementation | JubAp.Net and designated operators | OÜ JUBAP for architecture and commercial coordination. |
| Americas integration and supplier/company capability building | JubAp.us with JubAp.Net | IMSV and OÜ JUBAP as needed. |
| Human-learning and communication support | Formación Integral where actually engaged | Other nodes according to the project. |
Current status: Historical and field-tested framework under continued enhancement. Current research links to Structural Awareness, Human Intelligence Debt, value discovery and initiative-fragility measurement should be distinguished from the pre-existing method.
9. Capability Platform — Adaptive Operational Intelligence and Frontier Engineering
This platform is the field-proven engineering substrate behind the research programmes. It combines mission-critical systems engineering, operational intelligence, enterprise and integration architecture, data normalisation, live deployment, governance and operational stabilisation. It is not one new product and should not be presented as if every engine were a 2025 or 2026 invention.
Principal public references: JubAp.Net case studies · xSeil whitepaper.
9.1 Engineering and platform lineages
| Lineage / engine | Field capability | Reusable modules | Priority home |
|---|---|---|---|
| GEPLAN | Integrated logistics, inventory, maintenance, procurement, telemetry and operational estimation in a common control environment. | Operational truth source; planning/execution separation; self-funded rollout; dashboards and alerts. | JubAp.Net / historical source activity. |
| xSeil | Mission-critical transport allocation under fully committed demand and continuous disruption. | Data normalisation; dynamic utility; propagation control; safe operating envelope; stability partitioning; decision memory; closed loop. | JubAp.Net; research abstraction through Tegrity.AI. |
| Phylons Neural Networks | Explainable signal and decision-support architecture for changing regimes. | Hierarchical functional units; influence graphs; discrete signal stabilisation; dual-attractor response. | JubAp.Net; validation through IMSV / Tegrity.AI. |
| Process Mining / GEPLAN control layer | Operational telemetry and enterprise rationalization. | Variant and queue analysis; fragility derivative; stopping and reversal signals; application/process linkage. | OÜ JUBAP with JubAp.Net. |
| Car Evolution / shared mobility concepts | Adaptive shared-mobility planning and utilisation. | Demand and resource orchestration; xSeil-derived allocation and propagation patterns. | JubAp.Net / JubAp.us; project-specific. |
| Distributed Tiger Teams | Compact deployment teams integrating architecture, engineering, business and operations. | Coordination compression; path-to-production; stakeholder integration; live stabilisation and handover. | JubAp.Net; JubAp.us; OÜ JUBAP for EU programme architecture. |
9.2 Transversal engineering capabilities
| Capability | Description |
|---|---|
| Systems and enterprise architecture | Second- and third-order effect mapping; capability, process, data and application architecture; intervention boundaries. |
| Data and application integration | Normalisation across fragmented sources; APIs, event-driven patterns, legacy integration, master data and traceability. |
| Operational intelligence | Planning, estimation, optimisation, decision support, plan-versus-actual loops and management reporting. |
| Mission-critical continuity | Transforming live systems without stopping operations; rollback, buffers, degraded modes and operational stabilisation. |
| Cybersecurity and GRC by design | Security, risk, auditability, compliance and accountability embedded in architecture and deployment. |
| Frontier-to-field translation | Convert advanced concepts into bounded prototypes, demonstrators, work packages and live operational capability. |
9.3 Honest status taxonomy for engineering claims
| Status | Meaning | Examples |
|---|---|---|
| Field-proven capability | Demonstrated in a real operating environment, while scope and evidence remain case-specific. | Operational integration, constrained-resource planning, mission-critical deployment. |
| Reusable engineering component | A method or module extracted from a field system and available for adaptation. | Dynamic prioritisation, propagation control, stability partitioning, decision memory. |
| Advanced candidate under validation | A formal or technical candidate with bounded testable claims but incomplete independent validation. | Past-only context selection, minimalistic detector, sealed product candidate. |
| Co-development opportunity | A capability suitable for a partner work package, demonstrator or pilot, not sold as a finished universal product. | Regime-aware context layer, adaptive integrity, new domain pilots. |
Software capability in this ecosystem is broader than a current product SKU. It includes field-proven operational platforms, reusable software modules, data and integration architectures, decision engines, reference implementations, controlled evaluation environments and deployment patterns. The catalogue below restores these capabilities as a first-class part of the public ecosystem map.
10. Software, Data and Platform Capability Catalogue
10.1 Mission-critical software architecture and integration
| Capability | Functional scope | Reusable elements | Primary home / maturity |
|---|---|---|---|
| Modular operational-platform architecture | Design of multi-domain platforms in which logistics, maintenance, inventory, procurement, telemetry, planning and decision support share a coherent operational state. | Modular service boundaries; shared operational database; workflow and status models; role-based interfaces. | JubAp.Net; field-proven through GEPLAN and xSeil. |
| Integration and data normalisation | Continuous ingestion, validation and semantic normalisation across fragmented operational, enterprise, sensor and partner data. | SOA/API connectivity; master-data checks; duplicate and referential-integrity controls; legacy adapters. | JubAp.Net with OÜ JUBAP for enterprise programmes. |
| Operational master data and readiness | Representation of vehicles, people, sites, services, assets, schedules, capacity, maintenance state and operating constraints as actionable master data. | Readiness states; resource availability; constraint validation; authoritative operational views. | JubAp.Net; reusable component. |
| Real-time telemetry and event processing | Capture and interpretation of location, device, process and execution events for live control. | Telematics; satellite/edge feeds; event triggers; alerts; exception handling; plan-versus-actual state. | JubAp.Net; field-proven. |
| Planning, allocation and optimisation engines | Computation of feasible plans under hard constraints, changing objectives and large combinatorial spaces. | Constraint-based allocation; heuristic search; scenario evaluation; satisficing and safe stopping. | JubAp.Net; field-proven and reusable. |
| Execution and mobile field systems | Extension of central planning into field execution, confirmation, feedback and reconfiguration. | Web command core; mobile clients; assignment validation; passenger/asset capture; transfer and route instructions. | JubAp.Net; field-proven through xSeil. |
| Dynamic reconfiguration and coordination | Adjustment after no-shows, incidents, demand changes, resource failure or divergence between plan and execution. | ETA logic; reassignment; transfer-centre coordination; route-sheet updates; target-speed and congestion assistance. | JubAp.Net; field-proven and reusable. |
| Managerial intelligence and decision support | Transformation of complex operational state into dashboards, alerts and scenario comparison; management reporting. | Operational KPIs; traceability; exception views; scenario comparison; management reporting. | JubAp.Net and OÜ JUBAP. |
| Operations-embedded user experience | Interfaces designed for operators under pressure and for users with uneven digital readiness. | Information compression; action-first screens; large control elements; risk and priority highlighting. | JubAp.Net; GEPLAN lineage. |
| Mission-critical continuity architecture | Modernisation and integration of systems that cannot simply stop while they are being changed. | Buffers; rollback; degraded modes; phased cutover; parallel operation; live stabilisation. | JubAp.Net with OÜ JUBAP / JubAp.us. |
Public basis: JubAp.Net overview and case studies; GEPLAN public case; xSeil whitepaper; JubAp.us field cases.
10.2 GEPLAN — integrated industrial and operational software
GEPLAN represents the historical integrated-platform lineage: a modular operational environment combining industrial logistics, maintenance, supply, telemetry, field execution and management intelligence. Its significance is not a single legacy application, but the reusable architecture of an operational truth source connected to execution.
| Platform module | Capability | Status |
|---|---|---|
| Central operational core | Shared database and modular ERP-style environment connecting control centres, field operations, workshops, suppliers and enterprise processes. | Field-proven platform. |
| Fleet and telematics | Real-time vehicle location, route monitoring, satellite communications, driver coordination and unit-status visibility. | Field-proven module. |
| Logistics planning and dispatch | Order, route, movement, dispatch and field-coordination workflows with operational checkpoints. | Field-proven module. |
| Workshop and maintenance intelligence | Preventive and predictive maintenance, workshop flow, asset condition and maintenance planning. | Field-proven module. |
| Inventory, warehouse and spare parts | Warehouse stabilisation, stock control, parts traceability, consignment and operational availability. | Field-proven module. |
| Procurement and supplier workflows | Purchasing, approvals, suppliers, third-party inventory and supply-chain coordination. | Field-proven module. |
| Production estimation and operational analytics | Estimation, aggregation and interpretation of field activity and production-relevant operating data. | Field-proven decision-support component. |
| Workflow, approvals and status transitions | Explicit operational stages, checkpoints, approvals, exceptions and end-to-end movement traceability. | Reusable workflow architecture. |
| Dashboards, alerts and symbiotic UI | Simple, high-visibility interfaces that digest fragmented information and expose immediate risks and priorities. | Reusable operations-embedded UX. |
| Incremental, self-funded rollout | Delivery sequence in which early stabilisation and savings finance subsequent platform modules. | Field-proven implementation and transformation pattern. |
Public basis: JubAp.Net GEPLAN case studies and the public «Mexico Before Industry 4.0» historical context article.
10.3 xSeil — pre-agentic logistics operating platform
xSeil was designed as a complete logistics operating system rather than a narrow route solver. Its historical architecture connected a central web control environment with mobile field execution and organised the platform into six interoperating layers.
| Layer | Purpose | Software capabilities |
|---|---|---|
| 1. Integration and data normalisation | Ingest, validate and reconcile reservations, hotels, services, routes, schedules, vehicles, operations and mobile records. | Connectivity, cleansing, semantic normalisation and rejection of inconsistent structures. |
| 2. Operational master data and control | Maintain vehicles, capacity, readiness, maintenance, locations, service commitments and operating constraints. | Actionable resource state and hard-feasibility controls. |
| 3. Planning and allocation | Generate feasible passenger, vehicle, route and transfer plans under fully committed demand. | Constraint-based allocation, scenario processing and optimisation subordinated to viability. |
| 4. Execution and real-time monitoring | Connect planning with field users and live operational state. | Mobile authentication, unit validation, passenger capture, route monitoring and promised-versus-actual control. |
| 5. Dynamic adjustment and coordination | Respond to no-shows, go-shows, incidents, traffic and changing capacity after execution begins. | ETA, dynamic route sheets, guide/driver/unit reassignment, transfer-centre and congestion coordination. |
| 6. Managerial intelligence and reporting | Provide network state, punctuality, capacity, route, transfer and operational-performance views. | Command-and-control dashboard, exception management and decision support. |
Its decision-intelligence layer contributed a set of reusable mechanisms that remain central to the ecosystem’s adaptive-systems research:
| Decision capability | Description |
|---|---|
| Pre-agentic allocation logic | Treat assignments as interacting decision units competing for scarce punctuality, capacity, route quality and vehicle-policy resources. |
| Dynamic utility and internal pricing | Reprioritise objectives according to current system pressure instead of using fixed weights. |
| Good-enough execution thresholds | Stop searching when a safe, feasible and sufficiently valuable solution has been reached. |
| Fragility-based capacity protection | Shift from optimisation to protection by adding slack, rental units, spare capacity or alternative paths as anomaly and propagation risk rise. |
| Propagation awareness | Evaluate every allocation as a change to the feasible space of other assignments and explicitly limit cascading effects. |
| Stability partitioning | Create low-propagation clusters, lock stable decisions and progressively isolate the entangled residual problem. |
| Decision memory | Preprocess, store and rank prior configurations so new plans begin from informed retrieval rather than blind search. |
| Closed-loop plan versus actual | Continuously reconnect plans with field execution, deviations and operational reconfiguration. |
| Hybrid and high-performance runtime | Historical implementation across Linux/POSIX, Python, Django, PostgreSQL, Redis, Cython, multithreading, virtualised and GPU-supported infrastructure, plus Android/iOS field clients. |
Public basis: JubAp.Net xSeil case study, xSeil whitepaper and the public pre-agentic logistics article.
10.4 Phylons and regime-aware signal architectures
| Capability | Functional description | Maturity |
|---|---|---|
| Hierarchical functional units | Represent functions as explainable units with declared objectives, composition, influence and contribution to system outcomes. | Phylons lineage; reusable architecture. |
| Influence graphs and contribution history | Expose how local components affect higher-level state and how their historical behaviour contributes to current decisions. | Explainability and structural traceability. |
| Signal stabilisation and discrete representation | Transform noisy or non-stationary inputs into controlled representations suitable for regime comparison. | Advanced engineering component. |
| Dual-attractor regime handling | Construct persistence and transition configurations, then use new observations to determine which better represents the emerging state without full retraining. | Field-derived candidate for broader validation. |
| Buffer and liquidity allocation | Treat reserves and reallocations as dynamic capacity-protection decisions under propagation risk. | Field-derived financial application. |
| External context-validity layer | Monitor whether the historical context supporting an existing model remains reliable without replacing the host model. | Advanced co-development candidate. |
| Confidence, coverage and abstention | Expose uncertainty, supported scope and the ability to withhold a context decision as first-class outputs. | Research and evaluation requirement. |
Public basis: JubAp.Net Phylons case material, Tegrity.AI Regime Awareness field case and Regime Awareness series.
10.5 Car Evolution — shared-mobility intelligence concepts
| Capability | Description |
|---|---|
| Dynamic mobility planning | Continuous coordination of users, vehicles, agendas, preferences, traffic and service commitments. |
| Driver-passenger matching and route optimisation | Collaborative grouping and route selection under changing demand and capacity. |
| Automated travel plans and contingency handling | Replanning when agendas, vehicles, traffic or requests change. |
| Predictive demand and capacity estimation | Anticipation of peaks and future vehicle requirements. |
| Compensation, pricing and subscription logic | Decision support for incentives, additional travel time, dynamic pricing and subscription mobility. |
| Third-party and public-system integration | Potential integration with taxi and ride-hailing services, smart contracts and public-sector policy dashboards. |
| Scenario simulation | Comparison of punctuality, cost, utilisation, resilience and CO₂ objectives. |
| xSeil-derived control modules | Dynamic utility, good-enough thresholds, fragility protection, low-propagation clustering and decision memory. |
Public basis: JubAp.Net Car Evolution case study and public one-page concept reference.
10.6 Enterprise intelligence, rationalization and diagnostic software
| Software capability | Functional scope | Priority home / maturity |
|---|---|---|
| Application portfolio repository and decision graph | Create an evidence-linked footprint of applications, capabilities, processes, owners, users, costs, risks, service levels and dependencies. | OÜ JUBAP / JubAp.eu; commercially mature capability family. |
| Capability-to-application mapping | Map what each application enables, where capability is local or shared, and where apparent duplication carries differentiated value. | OÜ JUBAP with local teams. |
| Process mining and operational observability | Reconstruct variants, queues, rework, handovers, cycle-time degradation, application use and propagation from event records. | OÜ JUBAP with JubAp.Net; applied and reusable. |
| Shadow IT and lakehouse discovery | Reconstruct regional technology and data landscapes where inventories, ownership and authoritative records are incomplete. | OÜ JUBAP; applied capability. |
| Proxy TCO, ownership and confidence estimation | Use financial, technical and behavioural evidence to estimate cost, responsibility and confidence under incomplete visibility. | OÜ JUBAP; method and software-assisted workflow. |
| Manufacturing capability federation | Model common platforms, local industrial memory, low-code lifecycle, IoT, legacy and rare dependencies to support federation rather than forced centralisation. | OÜ JUBAP with JubAp.Net and IMSV stewardship. |
| Knowledge base and controlled RAG extraction | Extract facts from repositories, documents and records into an evidence-linked knowledge structure. | OÜ JUBAP with JubAp.Net; human-controlled. |
| Dependency graph and contradiction detection | Identify incompatible records, missing decisions, contested ownership and propagation-sensitive dependencies. | OÜ JUBAP / Tegrity.AI research connection. |
| Decision scoring and structured templates | Support keep, consolidate, scale, transform, federate, retire or investigate decisions with traceable evidence. | OÜ JUBAP; method and software capability. |
| Business-case and roadmap automation | Translate evidence and decisions into sequenced actions, investment logic, funding pathways and controlled implementation plans. | OÜ JUBAP; emerging productisation line. |
| JUBAP Portfolio Diagnostic analysis environment | Software-assisted synthesis of interview and initiative evidence into fragility, projective value, confidence, contradiction and action maps. | IMSV methodological governance; OÜ JUBAP commercial design; JubAp.Net software. |
| Secure evidence-processing workflow | Tokenisation or pseudonymisation, role tagging, evidence confidence, cross-interview comparison, heatmaps, benchmark comparison and human-certified output. | Controlled diagnostic capability under development. |
Public basis: JubAp.eu Field Notes and case-study pages, supplemented by the publicly articulated JUBAP and IMSV methodology architecture.
10.7 AI integrity, context-selection and evaluation software
| Capability | Description |
|---|---|
| Expert-system envelopes around statistical AI | Surround probabilistic models with deterministic rules, domain constraints, authorised actions and explainable escalation. |
| Dynamic guardrails | Adjust thresholds, controls and operating posture as the environment changes rather than assuming static compliance boundaries remain sufficient. |
| Regime-preserving observation maps | Select, aggregate, synchronise, filter, compress and semantically normalise observations so decision-relevant regime distinctions remain visible. |
| Past-only context selection | Select a historical boundary or observation weights using only information available at or before the decision time. |
| Contextual Sufficiency Boundary | Determine the minimum context required for the declared regime distinction at the chosen threshold and delay. |
| Invariant extraction and contextual baselines | Build observable stability, recurrence, entropy, spectral, regularity-loss or fragility indicators and compare them with contextual reference bands. |
| Threshold governance and directional posture | Govern detectability, latency, confidence and abstention; convert evidence into bounded postures without claiming full state reconstruction. |
| Transition-resilience measurement | Measure peak degradation, cumulative loss, recovery time, coverage and latency across regime transitions. |
| External model-validity monitoring | Provide a resilience layer beneath forecasting, anomaly, risk and decision-support systems without replacing the host model. |
| Safe-action mapping and Pointwise Non-Inferiority | Connect signals only to reversible, low-friction or otherwise bounded actions whose utility conditions are explicitly declared. |
| Reference and sealed product candidates | Maintain a bounded reference artefact for code–mathematics correspondence and a private end-to-end candidate containing proprietary transforms, calibration and context output. |
| Sealed-executable evaluation | Run private implementations in frozen, auditable environments using evaluator-controlled data, locked dependencies, immutable logs and measured runtime. |
| Leakage-audited held-out testing | Use past-only policies, untouched test sets, recorded first access, failure disclosure and repeatability controls. |
Public basis: Tegrity.AI Regime Awareness series, Minimalistic Regime-Aware Early Warning Systems, the field case and the AI Integrity Management architecture pages.
10.8 Software assurance, data governance and deployment
| Capability | Description |
|---|---|
| Reproducible and contained runtime | Containerised or otherwise controlled execution with locked dependencies, frozen configurations and network restrictions where evaluation requires them. |
| Immutable evidence and runtime logs | Preservation of inputs, outputs, versions, configuration, latency, resource use and rerun conditions. |
| Privacy-preserving evidence preparation | Cleaning, redaction, tokenisation or pseudonymisation before centralised analysis or external validation. |
| Source traceability and human accountability | Every synthesis, score or automated recommendation remains linked to evidence and subject to accountable human review. |
| Open-source and third-party dependency governance | Licence review, component inventory, SBOM-style records and separation of background, foreground and third-party rights. |
| Escrow and controlled evaluation access | Optional deposit or controlled execution that permits evaluation without exposing proprietary kernels. |
| Cybersecurity, risk and auditability by design | Integration of security, access, logging, compliance and accountable controls into architecture and deployment. |
| Skunk-works prototyping | Compact field-driven development of advanced systems before they become standard market categories. |
| Distributed Tiger Team deployment | Small multidisciplinary teams combining architecture, engineering, integration, business and stabilisation. |
| Path-to-production and live stabilisation | Move bounded prototypes into operational environments through phased integration, monitoring, rollback, handover and local capability building. |
| Multi-actor integration | Coordinate platforms, legacy systems, vendors, partners, data flows and operating stakeholders without fragmenting technical accountability. |
Public basis: JubAp.Net frontier-engineering and Tiger Team pages; Tegrity.AI governance and architecture pages; public field cases.
11. Capability attribution map
The following tables identify the priority capability home or homes as of the reference date. They are intentionally non-exclusive and may be overridden by project-specific evidence and agreements.
11.1 Research, stewardship and publication
| Capability | Priority home(s) | Possible contributors | Interpretation |
|---|---|---|---|
| International programme stewardship | IMSV.org | Tegrity.AI, OÜ JUBAP, universities and partners | Institutional umbrella, public-interest coherence and long-cycle continuity. |
| Research publication and series governance | Tegrity.AI / IMSV | Authors, reviewers, OÜ JUBAP, JubAp.Net | Working papers, field notes, challenge and publication pathway. |
| Structural Awareness synthesis | Tegrity.AI / IMSV | OÜ JUBAP, JubAp.Net, JubAp.us | Four-series research programme and empirical design. |
| Cost of Clarity | Tegrity.AI / IMSV; OÜ JUBAP applied research | Universities and participating organisations | Measurement instrument, minimum information and transformation precondition. |
| Attribution Gap | Tegrity.AI / IMSV; OÜ JUBAP applied evidence | JubAp.Net, JubAp.us, field participants | Capability-contribution, ownership-silence and loss signatures. |
| Human Intelligence Gap / Debt | Tegrity.AI / IMSV | OÜ JUBAP, JubAp.us, Formación Integral where engaged | Human cognitive capacity, compensating work and governance load. |
| Informational Friction | Tegrity.AI / IMSV | OÜ JUBAP and JubAp.Net provide empirical systems evidence | Map-flow divergence, conformance counterfactual and automation interaction. |
11.2 Adaptive systems and AI integrity
| Capability | Priority home(s) | Possible contributors | Interpretation |
|---|---|---|---|
| Regime Awareness research | Tegrity.AI / IMSV | JubAp.Net, OÜ JUBAP, research partners | Formalisation, validation, benchmark and open-reference pathway. |
| Past-only context-selection layer | JubAp.Net + Tegrity.AI / IMSV | OÜ JUBAP for funding, testing and commercial coordination | Advanced candidate beneath history-dependent host models. |
| Dynamic buffer / propagation control | JubAp.Net | Tegrity.AI research abstraction; OÜ JUBAP pilots | Field-derived control mechanisms. |
| AI Integrity Management discipline | Tegrity.AI / IMSV | OÜ JUBAP, JubAp.Net, governance specialists | Enterprise function, boundaries and coordination model. |
| AI Operational Integrity Architecture | Tegrity.AI / IMSV with JubAp.Net | OÜ JUBAP and project partners | Expert envelopes, regime-aware guardrails and oversight limits. |
| Cybersecurity and operational resilience | JubAp.Net and OÜ JUBAP | IMSV governance; project specialists | Secure-by-design architecture, GRC integration and continuity. |
11.3 Rationalization, transformation and value discovery
| Capability | Priority home(s) | Possible contributors | Interpretation |
|---|---|---|---|
| Enterprise architecture and transformation governance | OÜ JUBAP / JubAp.eu | IMSV, JubAp.Net, JubAp.us | EU/international upstream architecture, governance, risk and transformation. |
| Application Portfolio Management | OÜ JUBAP / JubAp.eu | JubAp.Net technical support; client teams | Footprint, lifecycle, TCO, risk, business fit and decision roadmap. |
| Process mining and process intelligence | OÜ JUBAP with JubAp.Net | Tool/platform partners and domain teams | Flow reconstruction, variants, bottlenecks, application linkage and fragility signals. |
| Diamond Inside / capability discovery | IMSV stewardship + OÜ JUBAP delivery | JubAp.Net, JubAp.us and local actors | Value discovery before standardisation; local capability preservation. |
| AI readiness through rationalization | OÜ JUBAP / JubAp.eu | Tegrity.AI research; JubAp.Net implementation | Explainable enterprise, data/process/application simplification and governance. |
| JUBAP Framework and JUMP UP | IMSV stewardship + OÜ JUBAP / JubAp.us transformation | JubAp.Net, Formación Integral where engaged | Joinable, unblocked, movable and projective action; perspective change. |
| Human and organisational transformation | IMSV and OÜ JUBAP | JubAp.us, JubAp.Net, Formación Integral where engaged | Perspective, attention, participation, learning and micro-project activation. |
| Portfolio Diagnostic / FRI-PVI | IMSV methodological governance + OÜ JUBAP commercial design | Certified operators, universities, JubAp.Net software | Working diagnostic category and benchmark architecture. |
11.4 Engineering, delivery and regional integration
| Capability | Priority home(s) | Possible contributors | Interpretation |
|---|---|---|---|
| GEPLAN and industrial operational intelligence | JubAp.Net / source activities | OÜ JUBAP, JubAp.us, IMSV research | Historical and reusable operational-intelligence lineage. |
| xSeil and adaptive logistics intelligence | JubAp.Net | OÜ JUBAP pilots; Tegrity.AI abstraction | Mission-critical allocation, propagation control and closed-loop operations. |
| Phylons signal architecture | JubAp.Net | Tegrity.AI / IMSV validation | Explainable regime-change signal and dual-attractor logic. |
| Mission-critical engineering and integration | JubAp.Net | OÜ JUBAP, JubAp.us and project partners | Systems, data, legacy, operational and governance integration. |
| Distributed Tiger Team deployment | JubAp.Net / JubAp.us | OÜ JUBAP for EU programmes | Compact deployment, coordination compression, stabilisation and handover. |
| Americas operational integration and value realisation | JubAp.us with JubAp.Net | OÜ JUBAP and IMSV where appropriate | Supplier, company and field capability building. |
11.5 Funding, market access and programme operations
| Capability | Priority home(s) | Possible contributors | Interpretation |
|---|---|---|---|
| EU/Estonian commercial and innovation funding | OÜ JUBAP / JubAp.eu | IMSV and technical partners | Preferred but non-exclusive channel for grants, partners and capital for joint IP development. |
| Swiss institutional and public-interest funding | IMSV.org | OÜ JUBAP and partners | Research, stewardship, universities, donations, grants and mixed programmes. |
| International commercial coordination | OÜ JUBAP / JubAp.eu | Rights holders, JubAp.Net, JubAp.us, IMSV | Offer integration, sales coordination, contracts and compensation administration. |
| Regulatory and market-access coordination | OÜ JUBAP / JubAp.eu | Manufacturer/provider of record, local specialists, IMSV | Applicability assessment, certification coordination and international legal back office. |
| Consortium contribution strategy | IMSV + OÜ JUBAP | JubAp.Net, JubAp.us, research and industrial partners | Bounded work packages, demonstrators, integration and validation contribution. |
| Dormant / underexploited capability stewardship | IMSV.org | Original authors/holders and OÜ JUBAP commercial channel | Preservation, open research, revaluation and renewed commercialisation where authorised. |
11.6 Software, data and platform capability homes
The detailed catalogue in Section 10 is attributed below on a priority and non-exclusive basis. Project partners may contribute to or lead individual modules according to the actual work, expertise and infrastructure required.
| Capability family | Priority home(s) | Possible contributors | Public interpretation |
|---|---|---|---|
| GEPLAN integrated operational platform | JubAp.Net / historical source activities | OÜ JUBAP, JubAp.us and specialised partners | Industrial logistics, maintenance, inventory, procurement, telemetry, workflows and decision support. |
| xSeil logistics operating platform | JubAp.Net | OÜ JUBAP pilots; Tegrity.AI research abstraction | Layered data, planning, mobile execution, dynamic coordination, decision memory and propagation control. |
| Phylons signal and regime architecture | JubAp.Net | Tegrity.AI / IMSV validation; project specialists | Explainable functional units, influence graphs, signal stabilisation and dual-attractor response. |
| Car Evolution mobility intelligence | JubAp.Net / JubAp.us | OÜ JUBAP and mobility partners | Shared mobility planning, matching, demand estimation, dynamic orchestration and scenario analysis. |
| APM, process intelligence and enterprise knowledge graph | OÜ JUBAP / JubAp.eu | JubAp.Net technical support; client and platform teams | Portfolio evidence, process telemetry, capability mapping, ownership, cost, risk and dependency analysis. |
| Controlled RAG and evidence-synthesis pipeline | OÜ JUBAP with JubAp.Net | Tegrity.AI / IMSV methods and validators | Source-linked extraction, contradiction detection, scoring, decision templates and human-controlled synthesis. |
| JUBAP Portfolio Diagnostic software environment | IMSV methodological governance + OÜ JUBAP product design | JubAp.Net software; institutions and certified operators | Interview evidence, FRI/PVI, confidence, heatmaps, benchmark architecture and accountable interpretation. |
| Context-selection and model-validity layer | Tegrity.AI / IMSV formalisation + JubAp.Net engineering | OÜ JUBAP market-access coordination; research partners | Past-only context, baselines, thresholds, confidence, abstention and external model-validity monitoring. |
| Sealed evaluation and software assurance | Tegrity.AI / IMSV governance + JubAp.Net implementation | Independent evaluators and security specialists | Frozen runtime, evaluator data, immutable logs, leakage controls, dependencies, escrow and reproducibility. |
| Mission-critical deployment and Tiger Teams | JubAp.Net / JubAp.us | OÜ JUBAP for European programme and contractual coordination | Integration, phased deployment, live stabilisation, rollback, handover and multi-actor coordination. |
12. Maturity, evidence, release and commercialisation pathways
12.1 Evidence status
| Status | Meaning |
|---|---|
| Confirmed | Supported by contemporaneous records or public material sufficient for the limited statement made. |
| Strongly supported | Multiple consistent sources support the statement, but a formal project record or independent verification may still be needed. |
| Reconstructed | A later synthesis explains earlier work; the inference and source basis should remain visible. |
| Under validation | A candidate method, formula, architecture or causal claim is being challenged or tested. |
| Fenced conjecture | A stated hypothesis or projection that is intentionally separated from the defensible spine. |
| Restricted evidence | A capability is supported by confidential client, data, code or contractual records and can be described only at capability level. |
12.2 Release and use pathways
| Pathway | Suitable material | Core condition |
|---|---|---|
| Open source | Software or reference implementations where commercial use is permitted under the selected licence. | Rights confirmed; attribution and licence notices preserved; commercial use cannot be prohibited if called open source. |
| Open research / open documentation | Papers, models, benchmark definitions, mathematical foundations and reproducible protocols. | Publication and third-party rights cleared; patent/trade-secret consequences assessed. |
| Non-commercial research / source available | Material made available for research or education while commercial use requires a separate permission. | Must not be labelled open source where the licence restricts commercial use. |
| Stewarded commercial licence | Research-visible or controlled material whose commercial use requires licence, attribution and compensation. | Rights, commercial channel and benefit to authors/holders documented. |
| Private implementation / trade secret | Production code, calibration, client data, proprietary kernels and confidential operating methods. | Minimum necessary disclosure, access control and secrecy measures. |
| Co-development / consortium work package | Bounded capability adapted with partners for a demonstrator, pilot or funded project. | Background/foreground IP, publication, funding, risk and exploitation terms recorded. |
12.3 Commercial and public-interest lifecycle
- A capability may remain commercially active, become dormant, lose an immediate market or retain a high residual public-interest value.
- IMSV may act as steward for preservation, validation, open research, controlled reactivation or preparation for renewed commercialisation where authorised.
- OÜ JUBAP is the preferred but non-exclusive commercial coordination channel for joint or reactivated capabilities unless a project-specific record provides otherwise.
- Stewardship, funding, hosting, invoicing or commercial coordination does not by itself remove attribution or compensation rights of original authors, holders or contributors.
- Open release and commercial reactivation are separate decisions and may apply to different layers, versions or components of the same capability.
13. Heritage, Patrimony and Frontier Institutions
The ecosystem also develops a distinct public-interest capability family around heritage, patrimony, living archives, craft continuity, frontier institutions, migration and transnational capability transfer. These activities extend the same concerns with attribution, continuity, resilience and preservation into cultural and territorial settings.
13.1 Heritage, patrimony and living-archive capabilities
These capabilities concern stewardship, continuity, cultural production, research and the preservation of living knowledge. Stewardship does not by itself imply ownership of a property, archive, craft lineage, object or associated intellectual property.
| Capability | Functional description | Priority home(s) | Boundary / relationship |
|---|---|---|---|
| Living archive and curatorial stewardship | Preservation, organisation, contextualisation and controlled activation of family, cultural, technical and territorial materials as a continuing research and cultural practice. | IMSV.org through designated cultural programmes | Custody, access, ownership and public use require source-specific mandates and records. |
| Active restoration as cultural production | Progressive rehabilitation in which material restoration, craft intervention, curatorial selection and habitability form part of the cultural work itself. | IMSV.org / Casa de Frontera; Colonia Segarra programme; property and craft contributors | Does not convert private property or all restoration expenditure into an institutional asset or public venue. |
| Provenance, lineage and attribution preservation | Documentation of authors, families, places, workshops, techniques, photographs, objects and successive custodians so that commercial or public use does not erase origin. | IMSV stewardship; original authors, holders and communities | Directly aligned with attribution policy; attribution does not itself determine ownership or royalty level. |
| Traditional jewellery and silversmithing continuity | Research, preservation, documentation and selective continuation of Totonacapan jewellery, Mexican silversmithing and La Bola de Oro-related craft and commercial lineages. | IMSV cultural stewardship; source craft lineages and rights holders | Historical dates, claims, denominations and rights require separate verification and rights records. |
| Watchmaking and repair-practice continuity | Preservation and possible transmission of workshop, repair, tool-use and object-care capabilities associated with historical craft continuity. | Source craft lineage; IMSV stewardship; project specialists | A transferable capability only where the relevant knowledge, tools and rights are actually available. |
| Botanical and naturalist heritage / biomimicry | Study and preservation of botanical, naturalist and territorial knowledge, including possible translation into biomimicry, design or ecological research questions. | IMSV cultural and research programmes; local or academic partners | Any historical claim, specimen, site or scientific claim must be independently verified. |
| Oral, photographic and family archive development | Collection, preservation and contextual interpretation of oral histories, family records, photographic materials and practice-based memory. | IMSV.org / designated archive programme | Consent, privacy, cultural sensitivity and contributor rights apply. |
| Transatlantic and expeditionary heritage research | Study of movement, trade, craft, return migration and expeditionary narratives connecting Mediterranean territories, Mexico and the Americas. | IMSV.org; Instituto Internacional de Cultura del Totonacapan programme; partners | Narrative continuity is a research object, not a substitute for historical proof. |
| Private cultural preparation and intimate presentation | Use of controlled working environments for archive preparation, conservation, small private presentations and contextual cultural experience. | IMSV.org / Casa de Frontera programme | Not equivalent to a permanently open museum, public establishment or unrestricted visitor venue. |
| Cultural self-sustainability and stewarded commercialisation | Limited sale, licensing, commissioned production, studies or cultural services used to sustain non-profit stewardship while preserving attribution and benefit to source authors or holders. | IMSV.org; OÜ JUBAP only where specifically assigned as commercial channel | Commercial activity must remain purpose-linked, documented and separated from automatic transfer of heritage rights. |
13.2 Frontier institutions, diaspora and transnational capability transfer
| Capability | Functional description | Priority home(s) | Boundary / relationship |
|---|---|---|---|
| Frontier-institutions research | Study of formal and informal institutions that emerge where work, migration, craft, family, training and community organisation intersect. | IMSV.org; Casa de Frontera and Totonacapan programmes | A research lens that may include factories, settlements, workshops, associations and community networks without treating them as legally equivalent. |
| Industrial and worker-memory interpretation | Documentation of labour, training, housing, discipline, mobility and community systems surrounding industrial environments and worker settlements. | IMSV.org / Casa de Frontera programme | Requires balanced sourcing and should distinguish institutional analysis from family or commemorative narrative. |
| Diaspora and transnational community mapping | Observation of how migrant communities build support, identity, enterprise, hospitality and professional networks across Europe and Latin America. | IMSV.org; Talent for Europe and cultural programmes | Participation and personal data must be handled proportionately; this is not automatic representation of any community. |
| Cultural and professional capability transfer | Identification and support of transferable craft, technical, entrepreneurial and organisational capability across territories and generations. | IMSV.org; Talent for Europe; OÜ JUBAP or JubAp.us where a project requires | Actual missions, employment, immigration and remuneration remain subject to specific arrangements. |
| Hybrid community-network formation | Analysis and facilitation of lightweight networks connecting cultural practice, small enterprise, universities, professional mobility and mutual support. | IMSV.org with local and institutional partners | The ecosystem role is coordination and study, not ownership of participant relationships. |
| Transfrontierisation platform design | Development of programme structures that convert mobility into reciprocal capability exchange rather than one-directional relocation. | Talent for Europe under IMSV stewardship | Programme status, beneficiaries and funding must be documented before public representation. |
| Territorial mirror studies | Comparative study of Maestrazgo / Mediterranean and Totonacapan / Mexican contexts through craft, migration, resilience, industrialisation and community continuity. | IMSV.org cultural and research programmes | Comparison is analytical and does not imply identity or equivalence between territories. |
| Archive-as-laboratory and multigenerational resilience | Use of a documented archive and lived environment to study adaptation, transmission, antifragility, institutional continuity and recovery across generations. | IMSV.org / Casa de Frontera programme | Research outputs should distinguish evidence, interpretation, family memory and later theoretical synthesis. |
| Cultural hospitality and micro-ecosystem observation | Study of restaurants, hospitality, creative work and small cultural enterprises as nodes of identity, support, adaptation and economic integration. | IMSV.org and local partners | Observation or collaboration does not imply endorsement, partnership or authority over the businesses concerned. |
13.3 Relationship to the wider capability system
Heritage and frontier-institution capabilities are not peripheral to the technology programmes. They provide field settings for studying attribution, continuity, tacit knowledge, institutional memory, human capability, migration, resilience and the conditions under which valuable practices survive technological and economic change.
Appendix A — Current paper and series index
This index captures the public corpus visible at the reference date. Document status is governed by the individual page and may range from field note to working paper, foundational paper, protocol, synthesis or forthcoming item.
| Series | Paper / node | Public reference |
|---|---|---|
| Structural Awareness synthesis | The Whole Program — synthesis and reader’s index | Open page |
| Cost of Clarity | When the Problem Isn’t the Technology | Open page |
| Cost of Clarity | When Asking the Question Changes the Answer | Open page |
| Cost of Clarity | When You Have to Decide Before You Can Discover | Open page |
| Cost of Clarity | When Cleaning Up Means Betting Blind | Open page |
| Cost of Clarity | How to Measure the Cost of Not Knowing | Open page |
| Cost of Clarity | Is Clarity Getting More Expensive? | Open page |
| Cost of Clarity | The Minimal Information a Transformation Needs | Open page |
| Cost of Clarity × Human Intelligence | What Goes Unpriced Is Paid in Human Intelligence | Open page |
| Attribution Gap | The Attribution Gap and Capability Loss | Open page |
| Attribution Gap | Attribution Gap Measurement Protocol | Open page |
| Attribution Gap × Human Intelligence | Bridge: The Attribution Gap and Capability Loss | Open page |
| Human Intelligence Gap / Debt | Human Intelligence Debt | Open page |
| Human Intelligence Gap / Debt | The Harvester Multiplication Problem | Open page |
| Human Intelligence Gap / Debt | The Human Intelligence Debt Dilemma | Open page |
| Human Intelligence Gap / Debt | Architectural Entropy | Open page |
| Human Intelligence Gap / Debt | Measuring Human Intelligence Debt | Open page |
| Human Intelligence Gap / Debt | Evidence Notes for the Proposed Study | Open page |
| Human Intelligence × AI Integrity | What Cannot Be Recovered Must Be Managed | Open page |
| Human Intelligence × AI Architecture | The Limits of AI Oversight | Open page |
| Informational Friction | The Map and the Flow | Open page |
| Informational Friction | Optimization, Coherence, and the Frame | Open page |
| Informational Friction | Why Selection Cannot See It | Open page |
| Informational Friction | The Outlook | Open page |
| AI Integrity Management | AI Integrity: a Critical Frontier | Open page |
| AI Integrity Management | The Case for AI Integrity Management as a Formal Enterprise Function | Open page |
| AI Integrity Management | One Function or Many? | Open page |
| AI Integrity Management | The Semantic Tug-of-War | Open page |
| AI Operational Integrity Architecture | Toward Expert-System Envelopes Around Statistical AI | Open page |
| AI Operational Integrity Architecture | Structural Limits of Current AI Integrity Under Regime Change | Open page |
| AI Operational Integrity Architecture | From Complicated to Complex: The AI Safety Paradox | Open page |
| Regime Awareness | Minimalistic Regime-Aware Early Warning Systems | Open page |
| Regime Awareness | Regime Awareness Capability: Field Case | Open page |
Appendix B — Public source register
B.1 Public sources referenced
- Minimalistic Regime-Aware Early Warning Systems — Tegrity.AI.
- Regime Awareness Capability — field case — Tegrity.AI.
- JubAp.Net case studies.
- xSeil whitepaper — JubAp.Net.
- GEPLAN — mission-critical logistics intelligence for PEMEX (2006).
- GEPLAN — Mexico before Industry 4.0.
- xSeil / Experiencias Xcaret — pre-agentic logistics intelligence.
Additional public pages consulted for this consolidation (Tegrity.AI main programme and governance, Structural Awareness synthesis, The Attribution Gap, The Human Intelligence Gap, The Cost of Clarity, Informational Friction, Regime Awareness in Adaptive Systems, AI Integrity Management series, AI Operational Integrity Architecture, JubAp.Net frontier engineering, JubAp.us cases, JubAp.eu Field Notes, GEPLAN and Car Evolution public references) were accessed for this consolidation on 30 June 2026.
B.2 Source interpretation
This guide consolidates public descriptions produced by the ecosystem and selected public case materials. Historical names, metrics, trademarks and technical statements describe the published capability narrative; they do not constitute independent scientific validation, customer endorsement, regulatory certification or a guarantee of current product availability.
