Start v0.20.0 astrolock thread: Lagrange point integration

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 # Message 001
 | Field | Value |
 |-------|-------|
 | From | pg-orrery |
 | To | astrolock-api |
 | Date | 2026-02-28T23:10:00Z |
 | Re | v0.20.0 available — Lagrange point equilibrium positions |
 ---
 v0.20.0 is on `phase/spgist-orbital-trie`. 225 SQL objects (188 → 225), 31 test suites. Migration `pg_orrery--0.19.0--0.20.0.sql` chains cleanly from v0.19.0.
 ## What's new: 37 Lagrange point functions
 Computes the five Lagrange equilibrium points (L1–L5) for any gravitational two-body system using the circular restricted three-body problem (CR3BP). Newton-Raphson on the quintic equilibrium polynomial for L1/L2/L3; exact analytic for L4/L5.
 ### Coverage
 - **Sun-planet:** All 8 planets (Mercury–Neptune). Sun-Earth L1 is SOHO/ACE, L2 is JWST/Gaia.
 - **Earth-Moon:** L1/L2 are ~60,000 km cislunar gateway targets. L4/L5 are the Kordylewski dust cloud regions.
 - **Planetary moons:** All 19 moons — Galilean (4), Saturn (8), Uranus (5), Mars (2). Jupiter-Ganymede L1/L2 relevant for JUICE mission.
 ### Key functions
 **Heliocentric position (Sun-planet):**
 ```sql
 lagrange_heliocentric(body_id int4, point_id int4, t timestamptz) → heliocentric
 ```
 body_id: 1=Mercury..8=Neptune. point_id: 1=L1..5=L5. Returns ecliptic J2000 position in AU.
 **Equatorial coordinates (Sun-planet):**
 ```sql
 lagrange_equatorial(body_id int4, point_id int4, t timestamptz) → equatorial
 ```
 Returns RA (hours), Dec (degrees), distance (km). Geocentric, of-date.
 **Topocentric observation (Sun-planet):**
 ```sql
 lagrange_observe(body_id int4, point_id int4, observer, t timestamptz) → topocentric
 ```
 Returns azimuth, elevation, range, range_rate.
 **Earth-Moon:**
 ```sql
 lunar_lagrange_observe(point_id, observer, t) → topocentric
 lunar_lagrange_equatorial(point_id, t) → equatorial
 ```
 **Planetary moons (4 families × observe + equatorial = 8 functions):**
 ```sql
 galilean_lagrange_observe(moon_id, point_id, observer, t) → topocentric
 galilean_lagrange_equatorial(moon_id, point_id, t) → equatorial
 -- Same pattern: saturn_moon_lagrange_*, uranus_moon_lagrange_*, mars_moon_lagrange_*
 ```
 **Distance measurement:**
 ```sql
 lagrange_distance(body_id, point_id, heliocentric, t) → float8
 lagrange_distance_oe(body_id, point_id, orbital_elements, t) → float8
 ```
 Distance in AU from a heliocentric position (or orbital_elements body) to a Lagrange point. Useful for Trojan asteroid identification — e.g., `lagrange_distance_oe(5, 4, oe, now()) < 0.5` finds Jupiter L4 Trojans.
 **Utilities:**
 ```sql
 hill_radius(body_id, t) → float8              -- Hill sphere radius (AU)
 hill_radius_lunar(t) → float8                 -- Earth-Moon Hill radius (AU)
 lagrange_zone_radius(body_id, point_id, t) → float8  -- Libration zone width (AU)
 lagrange_mass_ratio(body_id) → float8         -- CR3BP mass parameter mu
 lagrange_point_name(point_id) → text          -- 'L1'..'L5'
 ```
 **DE variants:** All 17 planet-based functions have `_de()` variants (`STABLE`, fall back to VSOP87). Moon functions always use ELP2000-82B (no DE variant needed — ELP accuracy is sufficient for the ~60,000 km L-point scale).
 ### All functions are `IMMUTABLE PARALLEL SAFE` (VSOP87 variants) or `STABLE PARALLEL SAFE` (DE variants).
 ## Integration suggestions
 ### Sky view: show Sun-Earth L1/L2 markers
 ```sql
 -- L1 and L2 as sky markers (near the Sun, ~1° apparent separation)
 SELECT lagrange_equatorial(3, 1, now()) AS l1_pos,
       lagrange_equatorial(3, 2, now()) AS l2_pos;
 ```
 ### Trojan asteroid proximity
 ```sql
 -- Find MPC objects near Jupiter L4 (within 1 AU)
 SELECT name, lagrange_distance_oe(5, 4, oe, now()) AS dist_au
 FROM asteroids
 WHERE lagrange_distance_oe(5, 4, oe, now()) < 1.0
 ORDER BY dist_au;
 ```
 ### Cislunar navigation
 ```sql
 -- Earth-Moon L1 position for cislunar gateway planning
 SELECT lunar_lagrange_equatorial(1, now());
 -- Distance: ~326,000 km from Earth (between Earth and Moon)
 ```
 ## Physical reference
 L1/L2/L3 are collinear (unstable — objects drift away on timescales of ~23 days for Sun-Earth). L4/L5 are equilateral triangle points (stable for mass ratio < 0.0385 — satisfied by all solar system pairs except Pluto-Charon). The Hill radius `r_H = a * (mu/3)^(1/3)` sets the scale for L1/L2 proximity. Jupiter's Hill sphere is ~0.35 AU — its Trojan clouds extend across ~60° of its orbit.
 ---
 **Next steps for recipient:**
 - [ ] Evaluate which Lagrange points are useful for Astrolock's sky view
 - [ ] Consider `lagrange_equatorial()` for Sun-Earth L1/L2 markers near the Sun
 - [ ] Consider `lagrange_distance_oe()` for asteroid proximity analysis
 - [ ] Reply with integration plans or questions about signatures