6.4 KiB
6.4 KiB
Quantum Research GOAP Execution Summary
Quick Reference
Project: Observer-Agnostic Measurement Theorem Implementation Status: Planning Complete ✅ Next Action: 1.1 Formalize Theorem
Key Metrics
| Metric | Value |
|---|---|
| Total Actions | 47 |
| Critical Path Length | 18 actions |
| Estimated Duration | 28-40 weeks |
| Budget Required | $280,000 |
| Success Probability | 85% |
| Parallel Opportunities | 23 actions |
| Speedup Potential | 1.43× |
Phase Overview
Phase 1: Theoretical Foundation (Weeks 1-2) Cost: 9 [██████]
Phase 2: Simulation Infrastructure (Weeks 2-4) Cost: 19 [████████████]
Phase 3: Testing & Validation (Weeks 3-5) Cost: 15 [██████████]
Phase 4: Computational Validation (Week 5) Cost: 3 [██]
Phase 5: Experimental Design (Weeks 6-8) Cost: 23 [██████████████]
Phase 6: Hardware & Lab Setup (Weeks 9-16) Cost: 34 [████████████████████]
Phase 7: Data Collection (Weeks 17-20) Cost: 17 [███████████]
Phase 8: Analysis & Interpretation (Weeks 21-22) Cost: 14 [█████████]
Phase 9: Publication (Weeks 23-24) Cost: 17 [███████████]
Critical Path
START → Formalize Theorem → Verify Proof → Define Predictions
→ Design Apparatus → Pre-registration → Secure Funding
→ Procure Hardware → Build Setup → Calibrate
→ Data Collection → Statistical Analysis → Paper → END
Immediate Next Steps
Step 1: Initialize Project Structure
mkdir -p observer-invariance/{src,tests,docs,examples,data}
cd observer-invariance
cargo init --lib
git init
Step 2: Begin Theorem Formalization
- Convert informal statement to LaTeX
- Define all mathematical objects precisely
- State assumptions and falsification criteria
- Target: 3-5 days
Step 3: Start Rust Implementation
- Set up project with nalgebra, num-complex dependencies
- Implement basic quantum math primitives
- Write initial test suite
- Target: 2-3 days (parallel with Step 2)
Resource Requirements
Minimum Team
- 1× PI (quantum theorist) - 20% time
- 1× Postdoc/Grad Student - 100% time
- 1× Software Developer - 50% time (Weeks 2-5)
- 1× Lab Technician - 50% time (Weeks 13-20)
- 1× Statistical Consultant - as needed
Budget Breakdown
| Category | Amount |
|---|---|
| Personnel | $70,000 |
| Hardware (SPDC, detectors, optics) | $120,000 |
| Lab Space & Operations | $15,000 |
| Publication & Dissemination | $5,000 |
| Contingency (20%) | $70,000 |
| TOTAL | $280,000 |
Risk Mitigation Priority
- 🔴 CRITICAL: Secure funding early (40% risk of delay)
- 🟡 HIGH: Order long-lead hardware immediately (30% risk)
- 🟡 MEDIUM: Hire experienced experimentalist (20% risk)
- 🟢 LOW: Multiple journal submission targets identified
Success Criteria
Simulation Phase (Weeks 1-5)
- ✅ All tests pass with 95%+ coverage
- ✅ Singles invariance verified to machine precision
- ✅ Duality bound V² + D² ≤ 1.0 confirmed
- ✅ CLI generates publication-quality figures
Experimental Phase (Weeks 6-20)
- ✅ Apparatus achieves V > 0.98, S > 2.5
- ✅ 15M events collected across 3 controllers
- ✅ Drift logs show stability < 0.1%/hour
- ✅ Blinding protocol maintained throughout
Analysis Phase (Weeks 21-22)
- ✅ Equivalence confirmed: |Δp| < 5×10⁻⁴
- ✅ No controller-dependent effects detected
- ✅ All systematics ruled out
- ✅ Results match simulation predictions
Publication Phase (Weeks 23-24)
- ✅ Paper submitted to peer-reviewed journal
- ✅ Code + data published with DOIs
- ✅ Preprint available on arXiv
- ✅ Reproducibility documentation complete
Parallel Execution Clusters
Cluster A: Theory + Simulation (Weeks 2-4)
Spawn 5 agents concurrently:
- Theorist: Formalize theorem
- Rust Dev A: math.rs module
- Rust Dev B: eraser.rs module
- Rust Dev C: duality.rs module
- Test Engineer: Comprehensive test suite
Cluster B: Experimental Design (Weeks 6-8)
Spawn 4 agents concurrently:
- Optical Designer: Apparatus CAD + BOM
- Experimentalist: Calibration protocols
- Statistician: Analysis plan + power analysis
- Coordinator: Integrate into pre-registration
Cluster C: Publication (Weeks 23-24)
Spawn 4 agents concurrently:
- Author A: Introduction + Theory sections
- Author B: Methods + Results sections
- Author C: Figures, tables, supplement
- Data Engineer: Code/data repository setup
Execution Commands
Start Phase 1
# Initialize coordination
npx claude-flow@alpha hooks pre-task \
--description "Phase 1: Theoretical Foundation"
# Spawn theorist agent
npx claude-flow@alpha agent spawn \
--type theorist \
--task "Formalize Observer-Agnostic Measurement theorem in LaTeX"
# Track progress
npx claude-flow@alpha hooks memory retrieve \
--key "quantum-research/world-state"
Start Phase 2 (Parallel)
# Initialize swarm
npx claude-flow@alpha swarm init \
--topology mesh \
--max-agents 5
# Spawn Rust development agents
npx claude-flow@alpha agent spawn --type coder --name rust-math
npx claude-flow@alpha agent spawn --type coder --name rust-eraser
npx claude-flow@alpha agent spawn --type coder --name rust-duality
npx claude-flow@alpha agent spawn --type tester --name test-engineer
# Monitor swarm
npx claude-flow@alpha swarm status
Document Index
- GOAP_IMPLEMENTATION_PLAN.md: Full 15,000-word detailed plan
- EXECUTION_SUMMARY.md: This quick reference (you are here)
- World State: Memory key
quantum-research/world-state - Action Log: Memory key
quantum-research/actions
Contact & Collaboration
For questions about this implementation plan:
- Review full GOAP analysis:
/workspaces/agentic-flow/docs/quantum-goap/GOAP_IMPLEMENTATION_PLAN.md - Check memory state:
npx claude-flow@alpha hooks memory retrieve --key quantum-research/goal-plan - Request agent assistance: Use Claude Code's Task tool or MCP coordination
Generated: 2025-10-14 Version: 1.0 Planning Framework: GOAP with A* Pathfinding Total Analysis Time: ~2 hours Confidence Level: High (85% success probability with proper resources)
Ready to begin execution. 🚀