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SECTION 7 — SCENARIOS (FULLY EXPANDED)
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19. ADVANCED SCENARIO GAUNTLET#
(RTT/2 → RTT/3 Multi‑Snapshot Challenges — Fully Expanded)#
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ADVANCED SCENARIO GAUNTLET
RTT/2 → RTT/3 MULTI‑SNAPSHOT CHALLENGES
====================================================================
This gauntlet contains four independent scenarios.
Each scenario includes:
- synthetic multi‑snapshot data
- RTT/2 tasks
- RTT/3 tasks
- projection tasks
- operator chain synthesis
All data is synthetic and safe.
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SCENARIO 1 — DRIFTING CORE
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Snapshot A:
A=0.9, K=0.4, T=0.2
gradient: collapse-weighted
deformation: drift deformation
triad: (0.8, 0.5, 0.3)
Snapshot B:
A=1.4, K=0.8, T=0.4
gradient: mixed
deformation: drift deformation
triad: (1.2, 0.9, 0.6)
Snapshot C:
A=1.9, K=1.3, T=0.7
gradient: mixed → triad-leaning
deformation: envelope torsion
triad: (1.7, 1.3, 1.0)
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TASKS
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1. Compute CPV for all snapshots.
2. Identify the first snapshot where collapse becomes moderate.
3. Classify FGT for all snapshots.
4. Identify the first triad‑leaning gradient.
5. Map CRM for all snapshots.
6. Compute INT for all snapshots.
7. Identify TIF dominant component for all snapshots.
8. Identify MAN axes for all snapshots.
9. Classify emission (FFF) for all snapshots.
10. Identify CRE dominance for all snapshots.
11. Classify CSL stability for all snapshots.
12. Choose the correct projection for Snapshot C.
13. Write the full operator chain for Snapshot C.
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SCENARIO 2 — ENVELOPE FRACTURE
====================================================================
Snapshot A:
A=1.2, K=0.7, T=0.3
gradient: mixed
deformation: envelope torsion
triad: (1.0, 0.8, 0.5)
Snapshot B:
A=2.0, K=1.5, T=1.0
gradient: triad-weighted
deformation: envelope torsion + shear
triad: (1.8, 1.6, 1.2)
Snapshot C:
A=2.7, K=2.1, T=1.6
gradient: triad-weighted + torsion spike
deformation: continuity fracture
triad: (2.5, 2.2, 1.8)
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TASKS
--------------------------------------------------------------------
1. Compute CPV for all snapshots.
2. Identify the first severe collapse.
3. Classify FGT for all snapshots.
4. Identify the first torsion spike.
5. Map CRM for all snapshots.
6. Compute INT for all snapshots.
7. Identify TIF dominant component for all snapshots.
8. Identify MAN axes for all snapshots.
9. Classify emission (FFF) for all snapshots.
10. Identify CRE dominance for all snapshots.
11. Classify CSL stability for all snapshots.
12. Choose the correct projection for Snapshot C.
13. Write the full operator chain for Snapshot C.
====================================================================
SCENARIO 3 — HYBRID SPIRAL
====================================================================
Snapshot A:
A=0.8, K=0.4, T=0.1
gradient: collapse-weighted
deformation: drift deformation
triad: (0.7, 0.5, 0.3)
Snapshot B:
A=1.3, K=0.9, T=0.5
gradient: mixed
deformation: envelope torsion
triad: (1.1, 0.9, 0.7)
Snapshot C:
A=1.8, K=1.4, T=1.0
gradient: mixed → triad-weighted
deformation: envelope torsion + shear
triad: (1.6, 1.4, 1.1)
Snapshot D:
A=2.2, K=1.9, T=1.5
gradient: triad-weighted
deformation: continuity fracture
triad: (2.0, 1.8, 1.4)
--------------------------------------------------------------------
TASKS
--------------------------------------------------------------------
1. Compute CPV for all snapshots.
2. Identify the first moderate collapse.
3. Classify FGT for all snapshots.
4. Identify the first triad-weighted gradient.
5. Map CRM for all snapshots.
6. Compute INT for all snapshots.
7. Identify TIF dominant component for all snapshots.
8. Identify MAN axes for all snapshots.
9. Classify emission (FFF) for all snapshots.
10. Identify CRE dominance for all snapshots.
11. Classify CSL stability for all snapshots.
12. Choose the correct projection for Snapshot D.
13. Write the full operator chain for Snapshot D.
====================================================================
SCENARIO 4 — INVERSION CASCADE
====================================================================
Snapshot A:
A=1.5, K=1.0, T=0.6
gradient: mixed
deformation: envelope torsion
triad: (1.3, 1.0, 0.8)
Snapshot B:
A=2.3, K=1.7, T=1.2
gradient: triad-weighted
deformation: continuity fracture
triad: (2.0, 1.7, 1.4)
Snapshot C:
A=3.0, K=2.3, T=1.9
gradient: triad-weighted + torsion spike
deformation: continuity fracture + shear
triad: (2.7, 2.4, 2.0)
--------------------------------------------------------------------
TASKS
--------------------------------------------------------------------
1. Compute CPV for all snapshots.
2. Identify the first severe collapse.
3. Classify FGT for all snapshots.
4. Identify the first torsion spike.
5. Map CRM for all snapshots.
6. Compute INT for all snapshots.
7. Identify TIF dominant component for all snapshots.
8. Identify MAN axes for all snapshots.
9. Classify emission (FFF) for all snapshots.
10. Identify CRE dominance for all snapshots.
11. Classify CSL stability for all snapshots.
12. Choose the correct projection for Snapshot C.
13. Write the full operator chain for Snapshot C.
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END OF ADVANCED SCENARIO GAUNTLET
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20. GRANDMASTER SCENARIO GAUNTLET#
(RTT/4 Pre‑Entry — Fully Expanded)#
====================================================================
GRANDMASTER SCENARIO GAUNTLET
RTT/4 PRE‑ENTRY — STACKED REGIME ANALYSIS
====================================================================
This gauntlet evaluates:
- stacked regime transitions
- collapse escalation
- torsion spikes
- projection instability
- multi‑packet synthesis
- pre‑RTT/4 reasoning
All data is synthetic and safe.
====================================================================
SCENARIO — FOUR‑STEP CASCADE
====================================================================
Snapshot 1:
A=1.0, K=0.6, T=0.3
gradient: mixed
deformation: drift deformation
regime: slow-relaxation
triad: (0.9, 0.7, 0.5)
Snapshot 2:
A=1.9, K=1.3, T=0.8
gradient: mixed → triad-leaning
deformation: envelope torsion
regime: mixed
triad: (1.7, 1.4, 1.1)
Snapshot 3:
A=2.6, K=2.0, T=1.4
gradient: triad-weighted
deformation: continuity fracture
regime: inversion-adjacent
triad: (2.4, 2.1, 1.7)
Snapshot 4:
A=3.3, K=2.7, T=2.1
gradient: triad-weighted + torsion spike
deformation: continuity fracture + shear
regime: inversion-adjacent → instability onset
triad: (3.0, 2.7, 2.3)
====================================================================
TASKS
====================================================================
1. Compute CPV for all snapshots.
2. Identify the first severe collapse.
3. Classify FGT for all snapshots.
4. Identify the first triad‑dominant gradient.
5. Identify the first torsion spike.
6. Map CRM for all snapshots.
7. Compute INT for all snapshots.
8. Identify TIF dominant component for all snapshots.
9. Identify MAN axes for all snapshots.
10. Classify emission (FFF) for all snapshots.
11. Identify CRE dominance for all snapshots.
12. Classify CSL stability for all snapshots.
13. Identify the earliest projection instability.
14. Choose the correct projection for Snapshot 4.
15. Build RTT2_DETECTION_PACKET for Snapshot 4.
16. Build RTT3_INTEGRATION_EMISSION_PACKET for Snapshot 4.
17. Write the full operator chain for Snapshot 4.
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END OF GRANDMASTER SCENARIO GAUNTLET
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