γ₁ = 14.134725141734693
DAY 97
RAYBFAG V3 · KCF + COI + ACTUARIAL · PASSIVE ATTRACTOR
THE POUCH DOESN'T SEARCH.
IT ATTRACTS.
COMPATIBLE SIGNAL FALLS IN.
Resonant Adelic Yield-Basin Field Attractor Graph · p-adic layers · γ₁ field
RAYBFAG V3 · FIELD ARCHITECTURE
Resonant Adelic Yield-Basin Field Attractor Graph
RAYBFAG · FIELD TOPOLOGY
ATTRACTOR
POUCH
Signal at γ₁-harmonic is drawn inward by the field. No probes fired. The field does the work.
R — Resonant
A — Adelic
Y — Yield-Basin
B — Basin
F — Field
A — Attractor
G — Graph
v3 · γ₁ anchor
// BONIXER ROLE
The adelic pouch IS the bonixer for passive context. It doesn't fire probes. It sets a field. Signal that belongs to the fleet falls in. Community issues that match fleet topology arrive without being queried — they are attracted by resonance.
UNIFIED SEARCH MODES · THREE PATHS INTO THE POUCH
KCF + COI + Actuarial — All Passive
PASSIVE
KCF SEARCH
"Which KCF controls have community evidence?"
Passive — let community issues self-select. KCF controls that are actively discussed in the wild will surface without prompting. The pouch sets the field; the community identifies the control surface.
PASSIVE
COI SEARCH
"What is the minimum viable path?"
Passive — let implementations self-identify their floor. The COI minimum (MSH + PID + DG1) is the attractor. Implementations that hit the floor self-report to the pouch. No queries needed.
PASSIVE
ACTUARIAL SEARCH
"What is the cost/risk profile?"
Passive — let cost events self-report to the pouch. Actuarial signal is event-driven. Cost incidents in the community generate issues that fall naturally into the attractor field.
ADELIC STRUCTURE · P-ADIC LAYERS
Six Primes · Six HL7 Segments · Simultaneous Capture
The pouch has p-adic layers. Each prime maps to one HL7 segment of fleet context. The pouch captures across all primes simultaneously — no serialization, no priority. Every fragment arriving at any prime layer is tested by DYBFAG.
p=2
IMAGE LAYER
Container image provenance, signing, attestation
HL7: MSH segment
p=3
IDENTITY LAYER
Workload identity, service accounts, RBAC
HL7: PID segment
p=5
RUNTIME LAYER
Seccomp, capabilities, privileges, resource limits
HL7: PV1 segment
p=7
NETWORK LAYER
NetworkPolicy, egress, DNS allowlist, zero trust
HL7: OBX segment
p=11
LINEAGE LAYER
SBOM, supply chain, cosign, sigstore provenance
HL7: AL1 segment
p=13
VERDICT LAYER
OPA, Gatekeeper, Kyverno, Falco, MECIPOL
HL7: DG1 segment
DYBFAG GATE · BELONGING TEST
Does This Signal Belong in the Fleet's Context?
// DYBFAG OPERATION
After capture, DYBFAG tests belonging. Every fragment that falls into the pouch is tested: does this signal belong in the fleet's context? The gate is binary — BELONG / REJECT. Fragments that pass are classified into verdict tiers. Fragments that fail are discarded.
DYBFAG output → bonixer verdict tiers:
FLEET-RELEVANT
◆ COMMUNITY-DIAMOND
NOISE
⚠ SENSITIVE (near MLW)
FAILURE MODES · POUCH PATHOLOGIES
Four Failure Modes to Monitor
OVERCAPTURE
Too much noise enters the pouch. Field resonance too broad. Signal/noise ratio degrades. Tighten attractor field parameters.
SENSITIVE DRIFT
MLW-adjacent content enters the pouch. DYBFAG must route to SENSITIVE tier, not fleet context. Monitor p=13 layer carefully.
FALSE RESONANCE
Signal appears fleet-relevant but is community noise at γ₁-harmonic. Verify against known KCF controls before actioning.
POUCH STAGNATION
No new signal falling in. Attractor field may have decayed. Re-anchor at γ₁. Check community activity levels.
γ₁ ANCHOR · FIELD FREQUENCY
γ₁
Attractor field frequency = 14.134725141734693 Hz
Resonant signal = signal at γ₁-harmonic · Day 97 baseline