Learning Objectives
- Apply the c-ECO framework to a real or realistic Space Infrastructure engagement.
- Translate sector data into TFP variables and prudential classifications.
- Design pre-threshold governance mechanisms for orbital congestion and debris cascade boundaries, collision and mission-loss thresholds, spectrum interference and service integrity limits.
- Present systemic analysis to non-technical stakeholders.
- Produce a professional-grade CSAM packet suitable for controlled institutional coordination.
Field Project: The c-ECO Space Infrastructure Stability Assessment
Your Role: c-ECO Fellow assigned to conduct a supervised Systemic Stability Assessment for a satellite constellation, launch system, ground segment, remote-sensing service, orbital slot, spectrum dependency, or space-based critical service exposed to congestion, debris, cyber, and continuity risk.
Project Scope: Produce a professional-grade CSAM packet that defines system boundary, signals, thresholds, actors, reversibility exposure, and institutional translation options. This is a Fellowship analytical exercise and does not authorize independent deployment.
- System boundary identification: orbital slots, satellites, debris environment, conjunction management, spectrum, ground stations, launch systems, remote-sensing services, and critical dependency networks.
- Safe Operating Space boundary identification for the selected subsystem.
- Current Position assessment with uncertainty treatment.
- Trajectory analysis using historical, reported, modeled, or field-linked data.
- Reversibility Liquidity evaluation of technical, financial, institutional, and temporal capacity.
- Band classification: Green, Amber, Red/Safe Mode, or Black/Restoration First.
- Contractual and governance recommendations for pre-threshold intervention.
- Implementation roadmap for supervised institutional use where authorized.
Select Your Space Infrastructure Subsystem
conjunction warning frequency and collision probability growth.
debris density, fragmentation events, and cascade exposure.
spectrum interference, jamming, and service degradation.
ground segment outage, cyber compromise, and power dependency.
satellite operators and launch providers, space agencies, regulators, and spectrum managers, insurers, financiers, and payload customers.
collision avoidance covenants, debris mitigation triggers, orbital service continuity schedules.
Required Deliverables
Format: 12–18 page professional report.
- Executive Summary for cohort or institutional coordination.
- System boundary, actor map, and exposure logic.
- Data audit: sources, coverage, gaps, uncertainty, and monitoring frequency.
- TFP variables: P, ΔV, σ, Lr with transparent assumptions.
- Prudential classification and escalation conditions.
- Safe Mode or Restoration First implications where applicable.
Format: Case-Specific Analytical Mandate with scope, evidence, limits, and intervention logic.
- Case purpose and institutional boundary.
- Threshold map and signal architecture.
- Actor duties and information dependencies.
- Confidentiality, data, and methodological limitations.
Format: 15-minute presentation plus questions.
Translate technical findings into clear governance consequences for satellite operators and launch providers, space agencies, regulators, and spectrum managers, insurers, financiers, and payload customers, data users, public agencies, and emergency services.
Format: 3-page reflection on where ordinary compliance would arrive too late, how c-ECO changes responsibility, and how the Fellow preserves institutional boundaries.
Assessment Rubric
| Criterion | Excellent | Good | Satisfactory | Needs Work |
|---|---|---|---|---|
| Technical Accuracy | Precise TFP logic, strong evidence treatment, and credible sector assumptions. | Mostly correct with minor gaps. | Basic variables, limited sensitivity analysis. | Major conceptual or measurement errors. |
| Systemic Interpretation | Clearly distinguishes incident, trajectory, and reversibility loss. | Good analysis with some generic passages. | Identifies risk but weakly links it to thresholds. | Treats case as ordinary compliance. |
| CSAM Quality | Scope, actors, evidence, limits, and intervention logic are coherent and usable. | Strong structure with minor omissions. | Basic mandate, incomplete operational logic. | Mandate unclear or not case-specific. |
| Professional Communication | Board-ready, concise, and disciplined. | Professional with minor polish needed. | Understandable but not executive-ready. | Unclear or overly generic. |
Project Timeline
Week 1:
- Days 1–2: Select subsystem, define case boundary, gather data.
- Days 3–4: Calculate P, ΔV, σ, and Lr; identify preliminary band classification.
- Days 5–7: Draft Technical Assessment Report and identify missing monitoring data.
Week 2:
- Days 8–10: Complete Safe Mode / Restoration First analysis and CSAM draft.
- Days 11–12: Prepare institutional briefing.
- Day 13: Submit all deliverables through cohort coordination.
- Day 14: Live presentation to instructor and peers.
Resources and Support
Technical Resources
- Modules 1–4 notes and TFP variable templates.
- Sector data sources: UNOOSA space sustainability guidelines; IADC debris mitigation guidance; ITU spectrum materials.
- Office hours: one 30-minute consultation during Week 1.
Governance and Instrument Sources
- Collision avoidance covenants.
- Debris mitigation triggers.
- Orbital service continuity schedules.
- Remote-sensing reliability clauses.
- Space infrastructure Safe Mode protocols.