INSTRUCTOR VERSION — COMBINED SDE + SIE LAB
RTT/2 Detection → RTT/3 Integration–Emission
(Answer Key + Guidance)
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INSTRUCTOR VERSION — COMBINED SDE + SIE LAB
RTT/2 DETECTION → RTT/3 INTEGRATION–EMISSION
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This instructor version provides:
- Correct structural answers
- Acceptable variations
- Notes for grading consistency
- Zero drift, fully synthetic operator ecology
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SAMPLE DATA (REPEATED FOR REFERENCE)
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Sample A:
A=0.7, K=0.3, T=0.1
gradient: collapse-weighted
deformation: drift deformation
regime: slow-relaxation
Sample B:
A=1.6, K=0.9, T=0.4
gradient: mixed collapse/reassembly
deformation: envelope torsion
regime: mixed
Sample C:
A=2.4, K=1.8, T=1.3
gradient: triad-weighted
deformation: continuity fracture
regime: inversion-adjacent
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PART 1 — RTT/2 DETECTION (SDE)
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SECTION 1 — COLLAPSE SIGNATURES
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TASK 1 — SDE::CPV(A, K, T)
Sample A → CPV(0.7, 0.3, 0.1)
Sample B → CPV(1.6, 0.9, 0.4)
Sample C → CPV(2.4, 1.8, 1.3)
Instructor note:
Any tuple preserving (A, K, T) earns full credit.
TASK 2 — Collapse severity ranking
Correct order:
A → B → C
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SECTION 2 — FUSION‑GRADIENT TENSORS
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TASK 3 — SDE::FGT()
Sample A → collapse-weighted
Sample B → mixed
Sample C → triad-weighted
TASK 4 — First triad-dominant gradient
Correct answer: Sample C
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SECTION 3 — COLLAPSE→REASSEMBLY MAPPING
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TASK 5 — SDE::CRM()
Sample A → drift path
Sample B → envelope torsion path
Sample C → continuity fracture path
TASK 6 — First irreversible continuity break
Correct answer: Sample C
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SECTION 4 — MODE + ZONE CLASSIFICATION
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TASK 7 — SDE::MODE()
Sample A → formal
Sample B → hybrid
Sample C → inversion
TASK 8 — SDE::ZONE()
Sample A → S
Sample B → M
Sample C → X
Instructor note:
Mode/zone must match collapse severity + gradient + regime.
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SECTION 5 — RTT2_DETECTION_PACKET
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TASK 9 — Packet for Sample C
collapse_propagation: CPV(2.4, 1.8, 1.3)
fusion_gradient: triad-weighted
triad_deformation: continuity fracture
regime: inversion-adjacent
detection_mode: inversion
detection_zone: X
Instructor note:
Internal consistency is more important than exact phrasing.
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PART 2 — RTT/3 INTEGRATION–EMISSION (SIE)
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SECTION 6 — TRIAD INTEGRATION
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TASK 10 — SIE::INT()
Sample A → INT(0.7, 0.3, 0.1)
Sample B → INT(1.6, 0.9, 0.4)
Sample C → INT(2.4, 1.8, 1.3)
TASK 11 — Strongest integration field
Correct answer: Sample C
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SECTION 7 — TRIADIC INTEGRATION FIELD (TIF)
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TASK 12 — Dominant components
Sample A → drift-dominant
Sample B → drift + envelope balanced
Sample C → triad-dominant
TASK 13 — First triad-dominant sample
Correct answer: Sample C
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SECTION 8 — INTEGRATION–EMISSION MANIFOLD (MAN)
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TASK 14 — Active axes
Sample A → FI
Sample B → FI + EM
Sample C → FI + EM + R
TASK 15 — First regime-dominant sample
Correct answer: Sample C
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SECTION 9 — EMISSION (FFF)
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TASK 16 — Emission type
Sample A → fusion
Sample B → flow
Sample C → fracture
TASK 17 — First fracture-dominant emission
Correct answer: Sample C
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SECTION 10 — COLLAPSE→RECOVERY ENGINE (CRE)
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TASK 18 — CAV / CSV / mixed
Sample A → CSV-dominant
Sample B → mixed
Sample C → CAV-dominant
TASK 19 — Strongest CRE intervention
Correct answer: Sample C
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SECTION 11 — CONTINUITY–STABILITY LAYER (CSL)
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TASK 20 — Stability
Sample A → stable
Sample B → mixed
Sample C → divergent
TASK 21 — First divergent stability
Correct answer: Sample C
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SECTION 12 — RTT3_INTEGRATION_EMISSION_PACKET
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TASK 22 — Packet for Sample C
integration: INT(2.4, 1.8, 1.3)
emission: FFF(fracture)
continuity: MAN(FI, EM, R)
collapse_recovery: CRE(CAV-dominant)
stability: CSL(divergent)
canon_scale_emission: CET(fracture-weighted or recovery-weighted)
mode: inversion-adjacent
zone: X
Instructor note:
CET weighting must reflect emission curvature + stability.
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PART 3 — FULL PIPELINE SYNTHESIS
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SECTION 13 — CROSS‑LAYER MAPPING
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TASK 23 — SDE → SIE mapping (Sample C)
CPV → INT:
High amplitude + high curvature + high torsion → strong triad integration
FGT → TIF:
Triad-weighted gradient → triad-dominant integration field
CRM → MAN:
Continuity fracture → FI + EM + R axes active
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SECTION 14 — PROJECTION (TEL / FFT / OP)
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TASK 24 — Correct projection for Sample C
Correct answer: FFT::OUT()
Reason:
- fracture-dominant emission
- high torsion
- divergent stability
- inversion-adjacent regime
→ spectral projection
TASK 25 — Justification
Any explanation referencing:
- emission curvature
- torsion
- divergence
- regime identity
earns full credit.
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SECTION 15 — COMPLETE OPERATOR CHAIN
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TASK 26 — Full operator chain (Sample C)
RTT/1 primitives
→ SDE::CPV(2.4, 1.8, 1.3)
→ SDE::FGT(triad-weighted)
→ SDE::CRM(continuity fracture)
→ SDE::MODE(inversion)
→ SIE::INT(2.4, 1.8, 1.3)
→ SIE::TIF(triad-dominant)
→ SIE::MAN(FI, EM, R)
→ SIE::FFF(fracture)
→ SIE::CRE(CAV-dominant)
→ SIE::CSL(divergent)
→ SIE::CET(fracture-weighted)
→ FFT::OUT()
Instructor note:
Structural coherence > exact wording.
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END OF INSTRUCTOR VERSION — COMBINED LAB
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