const RAD = Math.PI / 180; const DEG = 180 / Math.PI; function jdn(date) { return (date instanceof Date ? date : new Date(date)) / 86400000 + 2440587.5; } function jdnToDate(jd) { return new Date((jd - 2440587.5) * 86400000); } function sunPosition(lat, lon, date = new Date()) { const d = jdn(date) - 2451545.0; const L = (280.46 + 0.9856474 * d) % 360; const g = (357.528 + 0.9856003 * d) % 360; const lam = L + 1.915 * Math.sin(g * RAD) + 0.02 * Math.sin(2 * g * RAD); const eps = 23.439 - 0.0000004 * d; const sinL = Math.sin(lam * RAD); const ra = Math.atan2(Math.cos(eps * RAD) * sinL, Math.cos(lam * RAD)) * DEG; const dec = Math.asin(Math.sin(eps * RAD) * sinL) * DEG; const UT = date.getUTCHours() + date.getUTCMinutes() / 60 + date.getUTCSeconds() / 3600; const GMST = (6.697375 + 0.0657098242 * d + UT) % 24; const LMST = (GMST + lon / 15) % 24; const ha = LMST * 15 - ra; const elev = Math.asin( Math.sin(lat * RAD) * Math.sin(dec * RAD) + Math.cos(lat * RAD) * Math.cos(dec * RAD) * Math.cos(ha * RAD) ) * DEG; const az = Math.atan2( -Math.sin(ha * RAD), Math.tan(dec * RAD) * Math.cos(lat * RAD) - Math.sin(lat * RAD) * Math.cos(ha * RAD) ) * DEG; return { sun_elevation: Math.round(elev * 10) / 10, sun_azimuth: Math.round(((az + 360) % 360) * 10) / 10, }; } function sunriseSunset(lat, lon, date = new Date()) { const d = Math.floor(jdn(date)) - 2451545; const noon = 2451545 + 0.0009 + ((-lon) / 360) + Math.round(d - (-lon) / 360); const M = (357.5291 + 0.98560028 * (noon - 2451545)) % 360; const C = 1.9148 * Math.sin(M * RAD) + 0.02 * Math.sin(2 * M * RAD) + 0.0003 * Math.sin(3 * M * RAD); const lam = (M + C + 180 + 102.9372) % 360; const jnoon = noon + 0.0053 * Math.sin(M * RAD) - 0.0069 * Math.sin(2 * lam * RAD); const dec = Math.asin(Math.sin(23.4397 * RAD) * Math.sin(lam * RAD)) * DEG; const cosH = (Math.sin(-0.8333 * RAD) - Math.sin(lat * RAD) * Math.sin(dec * RAD)) / (Math.cos(lat * RAD) * Math.cos(dec * RAD)); if(Math.abs(cosH) > 1) { return {sunrise: null, sunset: null, daytime: cosH < -1}; } const H = Math.acos(cosH) * DEG; const rise = jdnToDate(jnoon - H / 360); const set = jdnToDate(jnoon + H / 360); const noon_d = jdnToDate(jnoon); // Round to nearest second, drop milliseconds const fmt = d => new Date(Math.round(d.getTime() / 1000) * 1000).toISOString(); return { sunrise: fmt(rise), sunset: fmt(set), daylight: Math.round((set - rise) / 36000) / 100, daytime: cosH < -1 }; } // Smooth sunspot number approximation from solar flux F10.7 // SSN ≈ 1.61 * F10.7 - 63.7 (linear regression, valid for F10.7 > 70) export function ssnFromFlux(f107) { if(!f107) return null; return Math.max(0, Math.round(1.61 * f107 - 63.7)); } export function sunActivityLabel(f107) { if(!f107) return null; if(f107 < 80) return 'Very Low'; if(f107 < 100) return 'Low'; if(f107 < 150) return 'Moderate'; if(f107 < 200) return 'High'; return 'Very High'; } function moonPosition(lat, lon, date = new Date()) { const d = jdn(date) - 2451545; const L = (218.316 + 13.176396 * d) % 360; const M = (134.963 + 13.064993 * d) % 360; const F = (93.272 + 13.229350 * d) % 360; const lon_ = L + 6.289 * Math.sin(M * RAD); const b = 5.128 * Math.sin(F * RAD); const dec = Math.asin( Math.sin(b * RAD) * Math.cos(23.4397 * RAD) + Math.cos(b * RAD) * Math.sin(23.4397 * RAD) * Math.sin(lon_ * RAD) ) * DEG; const ra = Math.atan2( Math.sin(lon_ * RAD) * Math.cos(23.4397 * RAD) - Math.tan(b * RAD) * Math.sin(23.4397 * RAD), Math.cos(lon_ * RAD) ) * DEG; const UT = date.getUTCHours() + date.getUTCMinutes() / 60 + date.getUTCSeconds() / 3600; const GMST = (6.697375 + 0.0657098242 * d + UT) % 24; const LMST = (GMST + lon / 15) % 24; const ha = LMST * 15 - ra; const elev = Math.asin( Math.sin(lat * RAD) * Math.sin(dec * RAD) + Math.cos(lat * RAD) * Math.cos(dec * RAD) * Math.cos(ha * RAD) ) * DEG; const az = Math.atan2( -Math.sin(ha * RAD), Math.tan(dec * RAD) * Math.cos(lat * RAD) - Math.sin(lat * RAD) * Math.cos(ha * RAD) ) * DEG; return { moon_elevation: Math.round(elev * 10) / 10, moon_azimuth: Math.round(((az + 360) % 360) * 10) / 10, }; } function sunMoonDistance(date = new Date()) { const d = jdn(date) - 2451545; // Sun ecliptic longitude const Ls = (280.46 + 0.9856474 * d) % 360; const gs = (357.528 + 0.9856003 * d) % 360; const sunLon = Ls + 1.915 * Math.sin(gs * RAD) + 0.02 * Math.sin(2 * gs * RAD); // Moon ecliptic longitude const Lm = (218.316 + 13.176396 * d) % 360; const Mm = (134.963 + 13.064993 * d) % 360; const Fm = (93.272 + 13.229350 * d) % 360; const moonLon = Lm + 6.289 * Math.sin(Mm * RAD); const moonLat = 5.128 * Math.sin(Fm * RAD); // Angular separation const dLon = (moonLon - sunLon) * RAD; const sep = Math.acos( Math.cos(moonLat * RAD) * Math.cos(dLon) ) * DEG; return { sun_moon_separation: Math.round(sep * 10) / 10 }; } function moonPhase(date = new Date()) { const jd = jdn(date); const cycle = 29.53058867; const known = 2451550.1; const phase = ((jd - known) % cycle + cycle) % cycle; // More accurate illumination using proper phase angle const illum = Math.round((1 - Math.cos(phase / cycle * 2 * Math.PI)) / 2 * 1000) / 10; let name; if(phase < 1.85) name = 'New Moon'; else if(phase < 7.38) name = 'Waxing Crescent'; else if(phase < 9.22) name = 'First Quarter'; else if(phase < 14.76) name = 'Waxing Gibbous'; else if(phase < 16.61) name = 'Full Moon'; else if(phase < 22.15) name = 'Waning Gibbous'; else if(phase < 23.99) name = 'Last Quarter'; else name = 'Waning Crescent'; return { moon_phase: name, moon_illumination: illum }; } function nextMoonEvents(date = new Date()) { const cycle = 29.53058867; const jd = jdn(date); const known = 2451550.1; const phase = ((jd - known) % cycle + cycle) % cycle; const toNew = (cycle - phase) % cycle; const toFull = phase < 14.76 ? 14.76 - phase : cycle - phase + 14.76; return { moon_new: jdnToDate(jd + toNew).toISOString(), moon_full: jdnToDate(jd + toFull).toISOString(), }; } function moonriseMoonset(lat, lon, date = new Date()) { const base = new Date(date); base.setUTCHours(0, 0, 0, 0); let prev = null; let moonrise = null; let moonset = null; // Scan 48h in 10min steps — covers edge cases where moon rises/sets next UTC day for(let m = 0; m <= 2880; m += 10) { const t = new Date(base.getTime() + m * 60000); const d = jdn(t) - 2451545; const L = (218.316 + 13.176396 * d) % 360; const M = (134.963 + 13.064993 * d) % 360; const F = (93.272 + 13.229350 * d) % 360; const lon_ = L + 6.289 * Math.sin(M * RAD); const b = 5.128 * Math.sin(F * RAD); const dec = Math.asin( Math.sin(b * RAD) * Math.cos(23.4397 * RAD) + Math.cos(b * RAD) * Math.sin(23.4397 * RAD) * Math.sin(lon_ * RAD) ) * DEG; const GMST = (6.697375 + 0.0657098242 * d + (t.getUTCHours() + t.getUTCMinutes() / 60)) % 24; const LMST = (GMST + lon / 15) % 24; const ra = Math.atan2( Math.sin(lon_ * RAD) * Math.cos(23.4397 * RAD) - Math.tan(b * RAD) * Math.sin(23.4397 * RAD), Math.cos(lon_ * RAD) ) * DEG; const ha = LMST * 15 - ra; const elev = Math.asin( Math.sin(lat * RAD) * Math.sin(dec * RAD) + Math.cos(lat * RAD) * Math.cos(dec * RAD) * Math.cos(ha * RAD) ) * DEG; if(prev !== null) { if(prev < 0 && elev >= 0 && !moonrise) moonrise = new Date(t.getTime() - 5 * 60000).toISOString(); if(prev >= 0 && elev < 0 && !moonset) moonset = new Date(t.getTime() - 5 * 60000).toISOString(); } prev = elev; if(moonrise && moonset) break; } return {moonrise: moonrise, moonset: moonset}; } function nextSolsticeEquinox(date = new Date()) { const y = date.getFullYear(); return { summer_solstice: new Date(Date.UTC(y, 5, 21)), winter_solstice: new Date(Date.UTC(y, 11, 21)), vernal_equinox: new Date(Date.UTC(y, 2, 20)), autumnal_equinox: new Date(Date.UTC(y + 1, 2, 20)), }; } export function getCelestialCurrent(lat, lon, date = new Date()) { return { ...sunPosition(lat, lon, date), ...sunriseSunset(lat, lon, date), ...moonPhase(date), ...moonPosition(lat, lon, date), ...sunMoonDistance(date), ...nextMoonEvents(date), ...moonriseMoonset(lat, lon, date), }; } export function getCelestialForecast(lat, lon, hours) { return hours.map((data) => Object.assign(data, getCelestialCurrent(lat, lon, new Date(data.time)))) }