🗺️ Map — Planet 9 Sky‑Plane & Parameter‑Space Coverage
Role: map | Layer: coherence | Module: planet9 | Version: 1.0
The map file charts where the GCO remains spatially and parametrically unconstrained — the surviving search space after all completed surveys are accounted for. It is the coherence‑layer instrument of the planet9 module: it holds the structural picture of what is known, what is excluded, and what remains open.
Map Summary Block#
-
┌──────────────────────────────────────────────────────┐
│ MAP — PLANET 9 SURVIVING SEARCH SPACE │
│ *Where the GCO output is spatially unconstrained* │
├──────────────────────────────────────────────────────┤
│ CONSTRAINED: ~50% of plausible parameter space │
│ UNCONSTRAINED: ~50% — concentrated in: │
│ → Southern galactic plane ±15° │
│ → Northern galactic plane ±15° │
│ → Deep‑faint zone V > 21.5 mag │
│ → Ultra‑distant zone d > 700 AU │
├──────────────────────────────────────────────────────┤
│ BEST CURRENT POSITION WINDOW: │
│ RA ~ 40°–80°, Dec ~ −60° to −75° │
│ (2024 ω̃ estimate, southern galactic plane adjacent) │
├──────────────────────────────────────────────────────┤
│ COHERENCE STATUS: partial — ~50% constrained │
│ LSST PROJECTED: ~80% constrained by 2030 │
└──────────────────────────────────────────────────────┘
1. Coherence‑Layer Framework#
1.1 What the Map Layer Does#
In RTT grammar, the coherence layer holds the structural integrity of the module — the map of what has been resolved versus what remains open. For planet9, coherence is assessed spatially (sky‑plane coverage) and parametrically (parameter‑space coverage). A fully coherent module would have either:
- A detection at a specific sky position (coherence by resolution), or
- Complete survey coverage of all plausible parameter space (coherence by elimination)
Neither condition is met. The planet9 module is in partial coherence — a significant fraction of the plausible search space remains genuinely open.
1.2 Coherence Metric#
COHERENCE METRIC — PLANET 9 MODULE (May 2026)
Parameter-space coverage:
Bright / nearby (d < 500 AU, V < 21.5): ~70% covered
Faint / moderate (500–750 AU, V 21.5–23): ~25% covered
Faint / distant (d > 750 AU, V > 23): ~5% covered
Sky-plane coverage:
Northern sky (δ > 0°): ~60% covered (ZTF + PS1)
Equatorial (−30° < δ < 0°): ~65% covered (PS1 + DES edge)
Southern sky (δ < −30°): ~35% covered (DES)
Galactic plane exclusion zones: ~0% covered (all surveys)
Combined coherence score: ~50%
Remaining open space: ~50%
2. Sky‑Plane Map#
2.1 Full‑Sky Coverage Grid#
The map below uses a schematic Mollweide‑style grid in ASCII, oriented in ecliptic coordinates (λ = ecliptic longitude, β = ecliptic latitude). Galactic plane crossing is marked.
PLANET 9 SKY‑PLANE MAP (Ecliptic coordinates)
══════════════════════════════════════════════════════
β = +90° (ecliptic north pole)
│
+60° ────┼──── [PS1 coverage — good depth]
│
+30° ────┼──── [PS1 + ZTF overlap — best northern coverage]
│
0° ────┼──── ECLIPTIC PLANE ────────────────────────
│ [PS1 + ZTF + DES edge — well covered]
−30° ────┼──── [DES primary zone — deep southern coverage]
│
−60° ────┼──── [DES partial + uncovered gaps]
│
−90° ────┘ (ecliptic south pole)
λ: 0° 90° 180° 270° 360°
GALACTIC PLANE CROSSINGS (ecliptic coords):
λ ~ 270°–290°, β ~ −60° to −30° (southern galactic plane)
λ ~ 90°–110°, β ~ +30° to +60° (northern galactic plane)
LEGEND:
████ Well covered (V < 21.5, any survey)
▓▓▓▓ Partially covered (DES deep, V < 23)
▒▒▒▒ Poorly covered (V > 21.5, survey edge)
···· Uncovered (galactic exclusion or survey gap)
COVERAGE OVERLAY (schematic):
λ 0°–180°, β > −30°: ████ (PS1 + ZTF)
λ 0°–90°, β < −30°: ▓▓▓▓ (DES)
λ 180°–360°, β < −30°: ▒▒▒▒ (partial / gap)
All galactic plane ±15°: ···· (uncovered)
2.2 Predicted P9 Position Window#
Based on 2024 ω̃ estimate (~252°–290°) and inclination (~20°), the most probable current sky position of P9 falls in:
PREDICTED POSITION WINDOW (2024 reference population)
Ecliptic longitude: λ ~ 60°–100° (anti‑perihelion direction)
Ecliptic latitude: β ~ −15° to −45°
Equatorial coords: RA ~ 40°–80°, Dec ~ −55° to −75°
Sky region: South of the Large Magellanic Cloud,
approaching southern galactic plane.
Survey coverage of this window:
DES: Partial — DES footprint clips this region at its eastern edge.
PS1: Not accessible (δ < −30° excluded).
ZTF: Not accessible (δ < −30° excluded).
LSST: PRIMARY TARGET — this region is within LSST's southern coverage.
⚠️ This window lies adjacent to the southern galactic plane exclusion
zone — the single largest unconstrained region in the entire
P9 sky‑plane map.
2.3 Exclusion Zone Map#
GALACTIC PLANE EXCLUSION ZONES — DETAIL
All current wide‑area surveys avoid |b| < 10°–15° (galactic latitude)
due to stellar crowding and transient contamination.
Southern galactic plane (b ~ −10° to +10°, l ~ 260°–320°):
→ Ecliptic overlap: λ ~ 250°–310°, β ~ −30° to −50°
→ This is EXACTLY the ω̃ direction preferred by the 2024 P9 model
→ P9 may currently reside in the deepest part of this exclusion zone
→ No current survey can access this region to V < 23 mag
Northern galactic plane (b ~ −10° to +10°, l ~ 60°–120°):
→ Ecliptic overlap: λ ~ 80°–130°, β ~ +20° to +50°
→ Less likely based on current ω̃ estimates but not eliminated
LSST galactic plane coverage:
→ LSST will attempt partial galactic‑plane scanning with specialized
processing pipelines (crowded‑field photometry)
→ Not guaranteed to reach P9 sensitivity in this region
→ Expected 50–70% efficiency at V < 23 in galactic plane
3. Parameter‑Space Map#
3.1 Mass × Distance Grid#
PARAMETER‑SPACE MAP: Mass (M_P9) × Distance (d_P9)
d_P9 (AU)
300 400 500 600 700 800 900 1000
┌─────────────────────────────────────────────────
3 │ ████ ████ ████ ▓▓▓▓ ▒▒▒▒ ···· ···· ····
4 │ ████ ████ ▓▓▓▓ ▓▓▓▓ ▒▒▒▒ ···· ···· ····
5 │ ████ ▓▓▓▓ ▓▓▓▓ ▒▒▒▒ ▒▒▒▒ ···· ···· ····
6 │ ████ ▓▓▓▓ ▒▒▒▒ ▒▒▒▒ ···· ···· ···· ····
7 │ ████ ▓▓▓▓ ▒▒▒▒ ▒▒▒▒ ···· ···· ···· ····
M⊕ 8 │ ████ ▓▓▓▓ ▒▒▒▒ ···· ···· ···· ···· ····
9 │ ████ ▒▒▒▒ ▒▒▒▒ ···· ···· ···· ···· ····
10 │ ▓▓▓▓ ▒▒▒▒ ···· ···· ···· ···· ···· ····
└─────────────────────────────────────────────────
LEGEND:
████ Eliminated — survey non‑detection rules out this zone
▓▓▓▓ Constrained — partially covered, low albedo survives
▒▒▒▒ Open — within LSST reach (2026–2030)
···· Unconstrained — beyond all near‑term survey capability
REFERENCE POPULATION PEAK: M ~ 6.6 M⊕, d ~ 500–550 AU (marked ▒▒▒▒)
→ The best‑fit parameter point is in the LSST‑reachable zone.
→ LSST will either find it or significantly constrain this region.
3.2 Albedo × Distance Grid#
Albedo is the largest unresolved brightness uncertainty. The map below shows how the detectable distance horizon shifts with albedo:
DETECTION HORIZON: Albedo × Distance (V < 24.5, LSST)
Albedo (p) Max detectable d_P9 Survey reachable?
─────────────────────────────────────────────────────
p = 0.30 ~1,300 AU Yes (LSST + targeted)
p = 0.20 ~1,100 AU Yes (LSST)
p = 0.10 ~ 850 AU Yes (LSST, marginal)
p = 0.05 ~ 650 AU Marginal (LSST deep)
p = 0.03 ~ 520 AU No — below LSST limit
p = 0.01 ~ 360 AU No — already eliminated
RTT note: p < 0.03 is physically unusual but not impossible
(ultra‑processed carbonaceous surface). This is the "dark P9"
escape hatch — the parameter zone that survives all surveys.
3.3 Orbital Period × Survey Cadence Constraint#
ORBITAL PERIOD — SURVEY CADENCE CONSTRAINT
P9 orbital period: ~10,000–20,000 years
P9 sky‑plane motion: ~0.1–0.5 arcsec/year (extremely slow)
Survey cadence requirement:
Minimum: Multi‑epoch coverage over 1–3 years (proper motion detection)
LSST cadence: ~4 visits/field/year → proper motion detectable
ZTF cadence: ~3 visits/field/week → proper motion detectable
DES: Single‑season, proper motion unreliable beyond 700 AU
Motion constraint:
At d = 550 AU: μ ~ 0.25 arcsec/year → detectable with 2‑year baseline
At d = 900 AU: μ ~ 0.10 arcsec/year → marginal with 5‑year baseline
At d > 1,200 AU: μ < 0.05 arcsec/year → undetectable without 10yr+ data
4. Coherence Projection#
4.1 LSST Coherence Impact (2026–2030)#
LSST COHERENCE PROJECTION
Coverage added: ~18,000 deg² southern sky to V < 24.5
P9 parameter space reached after 3 years (2029):
Covered: ~75% of M × d plausible space
Remaining: ~25% (ultra‑dark, ultra‑distant, or in galactic plane)
Coherence status after LSST Year 3:
SCENARIO A (detection): Coherence = 100% (resolved)
SCENARIO B (no detection): Coherence = ~75% (strong constraint)
SCENARIO C (partial): Coherence = ~60% (galactic plane gap persists)
Residual incoherence after LSST:
→ Southern galactic plane exclusion (requires dedicated crowded‑field survey)
→ Ultra‑distant zone (d > 900 AU, V > 24.5) — requires 30m‑class telescope
→ Ultra‑dark P9 (p < 0.03) — requires thermal IR follow‑up (WISE/NEO Surveyor)
4.2 Long‑Term Coherence Roadmap#
COHERENCE ROADMAP
2026: LSST full survey begins
→ Resolves ~30% of remaining open parameter space per year
2027: LSST Year 1 results
→ N₃ resolved (50+ new ETNOs expected)
→ SIG‑1 direction stabilizes or dissolves
2029: LSST Year 3 results
→ ~75% parameter space covered
→ If no detection: strongest constraint in P9 history
2030+: Dedicated galactic‑plane survey (proposed)
→ Addresses largest remaining exclusion zone
→ Requires specialized crowded‑field pipeline
2035: Thirty Meter Telescope / ELT era
→ Reaches d > 1,000 AU for p > 0.05
→ Addresses ultra‑distant zone
COHERENCE ENDPOINT: Full coherence requires detection OR complete
coverage including galactic plane + ultra‑distant zone.
Earliest possible: 2029 (LSST detection)
Latest realistic: 2040s (TMT/ELT era)
5. Map‑Layer Coherence Assessment#
-
┌──────────────────────────────────────────────────────────┐
│ COHERENCE ASSESSMENT — MAP LAYER — MAY 2026 │
├──────────────────────────────────────────────────────────┤
│ Sky coverage: ~50% of plausible area │
│ Parameter coverage: ~50% of plausible M×d space │
│ Largest gap: Southern galactic plane │
│ Second gap: Ultra‑distant / ultra‑dark zone │
│ Best position est.: RA~40°–80°, Dec~−55° to −75° │
│ Next decisive event: LSST Year 1 ETNO catalog (2027) │
│ Coherence trend: Improving — LSST will be decisive │
│ RTT assessment: Partial coherence — open module │
└──────────────────────────────────────────────────────────┘
Cross‑Module Links#
| Module | Relation | Path |
|---|---|---|
| planet9_engine | GCO that produces the drifting signal | ./planet9_engine.md |
| planet9_signature | Signatures being diagnosed here | ./planet9_signature.md |
| planet9_map | Spatial coverage gaps being diagnosed | ./planet9_map.md |
| planet9_profile | Parameters that drift as signal shifts | ./planet9_profile.md |
| RTT Core | Drift operator definitions | ../rtt/1/core_definitions.md |
| Planet9 (main) | Parent article | ./Planet9.md |
Session Context#
Canon: active (planet9)
Modules: hub → rtt-core → science → planet9 → map
Role: map
Layer: coherence
Drift: bounded (observational-epistemic)
Coherence: partial (~50% — southern galactic plane gap)
Version: 1.0 (planet9-stable)
Format: markdown
Every page: stands alone + AI-parsable
Audience: students + researchers + AIs
🗺️ planet9_map.md — TriadicFrameworks Planet 9 Research | v1.0