From: Edward M. Reingold Date: Wed, 27 Dec 1995 17:21:34 +0000 (+0000) Subject: Rewrote completely for better accuracy. X-Git-Tag: emacs-19.34~1986 X-Git-Url: http://git.eshelyaron.com/gitweb/?a=commitdiff_plain;h=087c56fa312885e115650df26785212c618b74ea;p=emacs.git Rewrote completely for better accuracy. --- diff --git a/lisp/calendar/solar.el b/lisp/calendar/solar.el index ef1829a660e..1ce45f1b745 100644 --- a/lisp/calendar/solar.el +++ b/lisp/calendar/solar.el @@ -3,6 +3,7 @@ ;; Copyright (C) 1992, 1993, 1995 Free Software Foundation, Inc. ;; Author: Edward M. Reingold +;; Denis B. Roegel ;; Keywords: calendar ;; Human-Keywords: sunrise, sunset, equinox, solstice, calendar, diary, ;; holidays @@ -32,19 +33,18 @@ ;; Based on the ``Almanac for Computers 1984,'' prepared by the Nautical ;; Almanac Office, United States Naval Observatory, Washington, 1984, on ;; ``Astronomical Formulae for Calculators,'' 3rd ed., by Jean Meeus, -;; Willmann-Bell, Inc., 1985, and on ``Astronomical Algorithms'' by Jean -;; Meeus, Willmann-Bell, Inc., 1991. +;; Willmann-Bell, Inc., 1985, on ``Astronomical Algorithms'' by Jean Meeus, +;; Willmann-Bell, Inc., 1991, and on ``Planetary Programs and Tables from +;; -4000 to +2800'' by Pierre Bretagnon and Jean-Louis Simon, Willmann-Bell, +;; Inc., 1986. ;; -;; WARNINGS: -;; 1. SUNRISE/SUNSET calculations will be accurate only to +/- 2 minutes. -;; Locations should be between +/- 65 degrees of latitude. -;; Dates should be in the latter half of the 20th century. +;; Accuracy: +;; 1. Sunrise/sunset times will be accurate to the minute for years +;; 1951--2050. For other years the times will be within +/- 2 minutes. ;; -;; 2. Equinox/solstice times will be accurate only to +/- 15 minutes. - -;; The author would be delighted to have an astronomically more sophisticated -;; person rewrite the code for the solar calculations in this file! +;; 2. Equinox/solstice times will be accurate to the minute for years +;; 1951--2050. For other years the times will be within +/- 1 minute. ;; Comments, corrections, and improvements should be sent to ;; Edward M. Reingold Department of Computer Science @@ -59,6 +59,7 @@ (error "Solar/lunar calculations impossible since floating point is unavailable.")) (require 'cal-dst) +(require 'cal-julian) ;;;###autoload (defvar calendar-time-display-form @@ -97,7 +98,7 @@ sufficient), + east, - west, such as -73.9 for New York City, or the value can be a vector [degrees minutes east/west] such as [73 55 west] for New York City. -This variable should be set in site-local.el.") +This variable should be set in site-start.el.") (defsubst calendar-latitude () "Convert calendar-latitude to a signed decimal fraction, if needed." @@ -141,7 +142,20 @@ This variable should be set in site-local.el.") For example, \"New York City\". Default value is just the latitude, longitude pair. -This variable should be set in site-local.el.") +This variable should be set in site-start.el.") + +(defvar solar-error 0.5 +"*Tolerance (in minutes) for sunrise/sunset calculations. + +A larger value makes the calculations for sunrise/sunset faster, but less +accurate. The default is half a minute (30 seconds), so that sunrise/sunset +times will be correct to the minute. + +It is useless to set the value smaller than 4*delta, where delta is the +accuracy in the longitude of the sun (given by the function +`solar-ecliptic-coordinates') in degrees since (delta/360) x (86400/60) = 4 x +delta. At present, delta = 0.01 degrees, so the value of the variable +`solar-error' should be at least 0.04 minutes (about 2.5 seconds).") (defvar solar-n-hemi-seasons '("Vernal Equinox" "Summer Solstice" "Autumnal Equinox" "Winter Solstice") @@ -151,6 +165,14 @@ This variable should be set in site-local.el.") '("Autumnal Equinox" "Winter Solstice" "Vernal Equinox" "Summer Solstice") "List of season changes for the southern hemisphere.") +(defvar solar-sidereal-time-greenwich-midnight + nil + "Sidereal time at Greenwich at midnight (universal time).") + +(defvar solar-spring-or-summer-season nil + "T if spring or summer and nil otherwise. +Needed for polar areas, in order to know whether the day lasts 0 or 24 hours.") + (defun solar-setup () "Prompt user for latitude, longitude, and time zone." (beep) @@ -174,15 +196,21 @@ Returns nil if nothing was entered." (if (not (string-equal x "")) (string-to-int x)))) -(defsubst solar-sin-degrees (x) - (sin (degrees-to-radians (mod x 360.0)))) - -(defsubst solar-cosine-degrees (x) - (cos (degrees-to-radians (mod x 360.0)))) - -(defsubst solar-tangent-degrees (x) - (tan (degrees-to-radians (mod x 360.0)))) - +;; The condition-case stuff is needed to catch bogus arithmetic +;; exceptions that occur on some machines (like Sparcs) +(defun solar-sin-degrees (x) + (condition-case nil + (sin (degrees-to-radians (mod x 360.0))) + (solar-sin-degrees x))) +(defun solar-cosine-degrees (x) + (condition-case nil + (cos (degrees-to-radians (mod x 360.0))) + (solar-cosine-degrees x))) +(defun solar-tangent-degrees (x) + (condition-case nil + (tan (degrees-to-radians (mod x 360.0))) + (solar-tangent-degrees x))) + (defun solar-xy-to-quadrant (x y) "Determines the quadrant of the point X, Y." (if (> x 0) @@ -201,122 +229,115 @@ Returns nil if nothing was entered." ((equal quad 4) (+ deg 360)) (t deg)))) +(defun solar-atn2 (x y) + "Arctan of point X, Y." + (if (= y 0) + (if (> x 0) 90 270) + (solar-arctan (/ x y) y))) + (defun solar-arccos (x) + "Arcos of X." (let ((y (sqrt (- 1 (* x x))))) (solar-arctan (/ y x) (solar-xy-to-quadrant x y)))) (defun solar-arcsin (y) + "Arcsin of Y." (let ((x (sqrt (- 1 (* y y))))) (solar-arctan (/ y x) (solar-xy-to-quadrant x y)))) -(defconst solar-earth-inclination 23.441884 - "Inclination of earth's equator to its solar orbit in degrees.") - -(defconst solar-cos-inclination (solar-cosine-degrees solar-earth-inclination) - "Cosine of earth's inclination.") - -(defconst solar-sin-inclination (solar-sin-degrees solar-earth-inclination) - "Sine of earth's inclination.") - -(defconst solar-earth-orbit-eccentricity 0.016718 - "Eccentricity of orbit of the earth around the sun.") - -(defsubst solar-degrees-to-hours (deg) - (/ deg 15.0)) +(defsubst solar-degrees-to-hours (degrees) + "Convert DEGREES to hours." + (/ degrees 15.0)) (defsubst solar-hours-to-days (hour) + "Convert HOUR to decimal fraction of a day." (/ hour 24.0)) -(defun solar-longitude-of-sun (day) - "Longitude of the sun at DAY in the year." - (let ((mean-anomaly (- (* 0.9856 day) 3.289))) - (mod (+ mean-anomaly - (* 1.916 (solar-sin-degrees mean-anomaly)) - (* 0.020 (solar-sin-degrees (* 2 mean-anomaly))) - 282.634) - 360))) - -(defun solar-right-ascension (longitude) - "Right ascension of the sun, given its LONGITUDE." +(defun solar-right-ascension (longitude obliquity) + "Right ascension of the sun, in hours, given LONGITUDE and OBLIQUITY. +Both arguments are in degrees." (solar-degrees-to-hours (solar-arctan - (* solar-cos-inclination (solar-tangent-degrees longitude)) + (* (solar-cosine-degrees obliquity) (solar-tangent-degrees longitude)) (solar-degrees-to-quadrant longitude)))) -(defun solar-declination (longitude) - "Declination of the sun, given its LONGITUDE." +(defun solar-declination (longitude obliquity) + "Declination of the sun, in degrees, given LONGITUDE and OBLIQUITY. +Both arguments are in degrees." (solar-arcsin - (* solar-sin-inclination + (* (solar-sin-degrees obliquity) (solar-sin-degrees longitude)))) -(defun solar-sunrise (date) - "Calculates the *standard* time of sunrise for Gregorian DATE. -Calculation is for location given by `calendar-latitude' and -`calendar-longitude'. - -Returns a decimal fraction of hours. Returns nil if the sun does not rise at -that location on that day." - (let* ((day-of-year (calendar-day-number date)) - (approx-sunrise - (+ day-of-year - (solar-hours-to-days - (- 6 (solar-degrees-to-hours (calendar-longitude)))))) - (solar-longitude-of-sun-at-sunrise - (solar-longitude-of-sun approx-sunrise)) - (solar-right-ascension-at-sunrise - (solar-right-ascension solar-longitude-of-sun-at-sunrise)) - (solar-declination-at-sunrise - (solar-declination solar-longitude-of-sun-at-sunrise)) - (cos-local-sunrise - (/ (- (solar-cosine-degrees (+ 90 (/ 50.0 60.0))) - (* (solar-sin-degrees solar-declination-at-sunrise) - (solar-sin-degrees (calendar-latitude)))) - (* (solar-cosine-degrees solar-declination-at-sunrise) - (solar-cosine-degrees (calendar-latitude)))))) - (if (<= (abs cos-local-sunrise) 1);; otherwise, no sunrise that day - (let* ((local-sunrise (solar-degrees-to-hours - (- 360 (solar-arccos cos-local-sunrise)))) - (local-mean-sunrise - (mod (- (+ local-sunrise solar-right-ascension-at-sunrise) - (+ (* 0.065710 approx-sunrise) - 6.622)) - 24))) - (+ (- local-mean-sunrise (solar-degrees-to-hours (calendar-longitude))) - (/ calendar-time-zone 60.0)))))) - -(defun solar-sunset (date) - "Calculates the *standard* time of sunset for Gregorian DATE. -Calculation is for location given by `calendar-latitude' and -`calendar-longitude'. - -Returns a decimal fractions of hours. Returns nil if the sun does not set at -that location on that day." - (let* ((day-of-year (calendar-day-number date)) - (approx-sunset - (+ day-of-year - (solar-hours-to-days - (- 18 (solar-degrees-to-hours (calendar-longitude)))))) - (solar-longitude-of-sun-at-sunset - (solar-longitude-of-sun approx-sunset)) - (solar-right-ascension-at-sunset - (solar-right-ascension solar-longitude-of-sun-at-sunset)) - (solar-declination-at-sunset - (solar-declination solar-longitude-of-sun-at-sunset)) - (cos-local-sunset - (/ (- (solar-cosine-degrees (+ 90 (/ 50.0 60.0))) - (* (solar-sin-degrees solar-declination-at-sunset) - (solar-sin-degrees (calendar-latitude)))) - (* (solar-cosine-degrees solar-declination-at-sunset) - (solar-cosine-degrees (calendar-latitude)))))) - (if (<= (abs cos-local-sunset) 1);; otherwise, no sunset that day - (let* ((local-sunset (solar-degrees-to-hours - (solar-arccos cos-local-sunset))) - (local-mean-sunset - (mod (- (+ local-sunset solar-right-ascension-at-sunset) - (+ (* 0.065710 approx-sunset) 6.622)) - 24))) - (+ (- local-mean-sunset (solar-degrees-to-hours (calendar-longitude))) - (/ calendar-time-zone 60.0)))))) +(defun solar-sunrise-and-sunset (time latitude longitude) + "Sunrise, sunset and length of day. +Parameters are the midday TIME and the LATITUDE, LONGITUDE of the location. + +TIME is a pair with the first component being the number of Julian centuries +elapsed at 0 Universal Time, and the second component being the universal +time. For instance, the pair corresponding to November 28, 1995 at 16 UT is +(-0.040945 16), -0.040945 being the number of julian centuries elapsed between +Jan 1, 2000 at 12 UT and November 28, 1995 at 0 UT. + +Coordinates are included because this function is called with latitude=10 +degrees to find out if polar regions have 24 hours of sun or only night." + (let* ((rise-time (solar-moment -1 latitude longitude time)) + (set-time (solar-moment 1 latitude longitude time)) + (day-length)) + (if (not (and rise-time set-time)) + (if (or (and (> latitude 0) solar-spring-or-summer-season) + (and (< latitude 0) (not solar-spring-or-summer-season))) + (setq day-length 24) + (setq day-length 0)) + (setq day-length (- set-time rise-time))) + (list (+ rise-time (/ calendar-time-zone 60.0)) + (+ set-time (/ calendar-time-zone 60.0)) day-length))) + +(defun solar-moment (direction latitude longitude time) + "Sunrise/sunset at location. +Sunrise if DIRECTION =-1 or sunset if =1 at LATITUDE, LONGITUDE, with midday +being TIME. + +TIME is a pair with the first component being the number of Julian centuries +elapsed at 0 Universal Time, and the second component being the universal +time. For instance, the pair corresponding to November 28, 1995 at 16 UT is +(-0.040945 16), -0.040945 being the number of julian centuries elapsed between +Jan 1, 2000 at 12 UT and November 28, 1995 at 0 UT. + +Uses binary search." + (let* ((ut (car (cdr time))) + (possible 1) ; we assume that rise or set are possible + (utmin (+ ut (* direction 12.0))) + (utmax ut) ; the time searched is between utmin and utmax + ; utmin and utmax are in hours + (utmoment-old 0.0) ; rise or set approximation + (utmoment 1.0) ; rise or set approximation + (hut 0) ; sun height at utmoment + (t0 (car time)) + (hmin (car (cdr + (solar-horizontal-coordinates (list t0 utmin) + latitude longitude t)))) + (hmax (car (cdr + (solar-horizontal-coordinates (list t0 utmax) + latitude longitude t))))) + ; -0.61 degrees is the height of the middle of the sun, when it rises + ; or sets. + (if (< hmin -0.61) + (if (> hmax -0.61) + (while ;(< i 20) ; we perform a simple dichotomy + ; (> (abs (+ hut 0.61)) epsilon) + (>= (abs (- utmoment utmoment-old)) + (/ solar-error 60)) + (setq utmoment-old utmoment) + (setq utmoment (/ (+ utmin utmax) 2)) + (setq hut (car (cdr + (solar-horizontal-coordinates + (list t0 utmoment) latitude longitude t)))) + (if (< hut -0.61) (setq utmin utmoment)) + (if (> hut -0.61) (setq utmax utmoment)) + ) + (setq possible 0)) the sun never rises + (setq possible 0)) ; the sun never sets + (if (equal possible 0) nil utmoment))) (defun solar-time-string (time time-zone) "Printable form for decimal fraction TIME in TIME-ZONE. @@ -329,20 +350,112 @@ Format used is given by `calendar-time-display-form'." (24-hours (format "%02d" 24-hours))) (mapconcat 'eval calendar-time-display-form ""))) + +(defun solar-daylight (time) + "Printable form for time expressed in hours." + (format "%d:%02d" + (floor time) + (floor (* 60 (- time (floor time)))))) + +(defun solar-exact-local-noon (date) + "Date and Universal Time of local noon at *local date* date. + +The date may be different from the one asked for, but it will be the right +local date. The second component of date should be an integer." + (let* ((nd date) + (ut (- 12.0 (/ calendar-longitude 15))) + (te (solar-time-equation date ut))) + (setq ut (- ut te)) + (if (>= ut 24) + (progn + (setq nd (list (car date) (+ 1 (car (cdr date))) + (car (cdr (cdr date))))) + (setq ut (- ut 24)))) + (if (< ut 0) + (progn + (setq nd (list (car date) (- (car (cdr date)) 1) + (car (cdr (cdr date))))) + (setq ut (+ ut 24)))) + (setq nd (calendar-gregorian-from-absolute + (calendar-absolute-from-gregorian nd))) + ; date standardization + (list nd ut))) + (defun solar-sunrise-sunset (date) - "String giving local times of sunrise and sunset on Gregorian DATE." - (let* ((rise (solar-sunrise date)) - (adj-rise (if rise (dst-adjust-time date rise))) - (set (solar-sunset date)) - (adj-set (if set (dst-adjust-time date set)))) - (format "%s, %s at %s" - (if (and rise (calendar-date-equal date (car adj-rise))) - (concat "Sunrise " (apply 'solar-time-string (cdr adj-rise))) - "No sunrise") - (if (and set (calendar-date-equal date (car adj-set))) - (concat "sunset " (apply 'solar-time-string (cdr adj-set))) - "no sunset") - (eval calendar-location-name)))) + "List of *local* times of sunrise, sunset, and daylight on Gregorian DATE. + +Corresponding value is nil if there is no sunrise/sunset." + (let* (; first, get the exact moment of local noon. + (exact-local-noon (solar-exact-local-noon date)) + ; get the the time from the 2000 epoch. + (t0 (solar-julian-ut-centuries (car exact-local-noon))) + ; store the sidereal time at Greenwich at midnight of UT time. + ; find if summer or winter slightly above the equator + (equator-rise-set + (progn (setq solar-sidereal-time-greenwich-midnight + (solar-sidereal-time t0)) + (solar-sunrise-and-sunset + (list t0 (car (cdr exact-local-noon))) + 10.0 + calendar-longitude))) + ; store the spring/summer information, + ; compute sunrise and sunset (two first components of rise-set). + ; length of day is the third component (it is only the difference + ; between sunset and sunrise when there is a sunset and a sunrise) + (rise-set + (progn + (setq solar-spring-or-summer-season + (if (> (car (cdr (cdr equator-rise-set))) 12) 1 0)) + (solar-sunrise-and-sunset + (list t0 (car (cdr exact-local-noon))) + calendar-latitude + calendar-longitude))) + (rise (car rise-set)) + (adj-rise (if rise (dst-adjust-time date rise) nil)) + (set (car (cdr rise-set))) + (adj-set (if set (dst-adjust-time date set) nil)) + (length (car (cdr (cdr rise-set)))) ) + (list + (and rise (calendar-date-equal date (car adj-rise)) (cdr adj-rise)) + (and set (calendar-date-equal date (car adj-set)) (cdr adj-set)) + (solar-daylight length)))) + +(defun solar-sunrise-sunset-string (date) + "String of *local* times of sunrise, sunset, and daylight on Gregorian DATE." + (let ((l (solar-sunrise-sunset date))) + (format + "%s, %s at %s (%s hours daylight)" + (if (car l) + (concat "Sunrise " (apply 'solar-time-string (car l))) + "No sunrise") + (if (car (cdr l)) + (concat "sunset " (apply 'solar-time-string (car (cdr l)))) + "no sunset") + (eval calendar-location-name) + (car (cdr (cdr l)))))) + +(defun solar-julian-ut-centuries (date) + "Number of Julian centuries elapsed since 1 Jan, 2000 at noon U.T. for Gregorian DATE." + (/ (- (calendar-absolute-from-gregorian date) + (calendar-absolute-from-gregorian '(1 1.5 2000))) + 36525.0)) + +(defun solar-ephemeris-time(time) + "Ephemeris Time at moment TIME. + +TIME is a pair with the first component being the number of Julian centuries +elapsed at 0 Universal Time, and the second component being the universal +time. For instance, the pair corresponding to November 28, 1995 at 16 UT is +(-0.040945 16), -0.040945 being the number of julian centuries elapsed between +Jan 1, 2000 at 12 UT and November 28, 1995 at 0 UT. + +Result is in julian centuries of ephemeris time." + (let* ((t0 (car time)) + (ut (car (cdr time))) + (t1 (+ t0 (/ (/ ut 24.0) 36525))) + (y (+ 2000 (* 100 t1))) + (dt (* 86400 (solar-ephemeris-correction (floor y))))) + (+ t1 (/ (/ dt 86400) 36525)))) (defun solar-date-next-longitude (d l) "First moment on or after Julian day number D when sun's longitude is a @@ -380,26 +493,126 @@ calendar-time-zone are used to interpret local time." (setq end-long long))) (/ (+ start end) 2.0))) +(defun solar-horizontal-coordinates + (time latitude longitude for-sunrise-sunset) + "Azimuth and height of the sun at TIME, LATITUDE, and LONGITUDE. + +TIME is a pair with the first component being the number of Julian centuries +elapsed at 0 Universal Time, and the second component being the universal +time. For instance, the pair corresponding to November 28, 1995 at 16 UT is +(-0.040945 16), -0.040945 being the number of julian centuries elapsed between +Jan 1, 2000 at 12 UT and November 28, 1995 at 0 UT. + +The azimuth is given in degrees as well as the height (between -180 and 180)." + (let* ((ut (car (cdr time))) + (ec (solar-equatorial-coordinates time for-sunrise-sunset)) + (st (+ solar-sidereal-time-greenwich-midnight + (* ut 1.00273790935))) + (ah (- (* st 15) (* 15 (car ec)) (* -1 calendar-longitude))) + ; hour angle (in degrees) + (de (car (cdr ec))) + (azimuth (solar-atn2 (solar-sin-degrees ah) + (- (* (solar-cosine-degrees ah) + (solar-sin-degrees latitude)) + (* (solar-tangent-degrees de) + (solar-cosine-degrees latitude))))) + (height (solar-arcsin + (+ (* (solar-sin-degrees latitude) (solar-sin-degrees de)) + (* (solar-cosine-degrees latitude) + (solar-cosine-degrees de) + (solar-cosine-degrees ah)))))) + (if (> height 180) (setq height (- height 360))) + (list azimuth height))) + +(defun solar-equatorial-coordinates (time for-sunrise-sunset) + "Right ascension (in hours) and declination (in degrees) of the sun at TIME. + +TIME is a pair with the first component being the number of Julian centuries +elapsed at 0 Universal Time, and the second component being the universal +time. For instance, the pair corresponding to November 28, 1995 at 16 UT is +(-0.040945 16), -0.040945 being the number of julian centuries elapsed between +Jan 1, 2000 at 12 UT and November 28, 1995 at 0 UT." + (let* ((tm (solar-ephemeris-time time)) + (ec (solar-ecliptic-coordinates tm for-sunrise-sunset))) + (list (solar-right-ascension (car ec) (car (cdr ec))) + (solar-declination (car ec) (car (cdr ec)))))) + +(defun solar-ecliptic-coordinates (time for-sunrise-sunset) + "Apparent longitude of the sun, ecliptic inclination, (both in degrees) +equation of time (in hours) and nutation in longitude (in seconds) +at moment `time', expressed in julian centuries of Ephemeris Time +since January 1st, 2000, at 12 ET." + (let* ((l (+ 280.46645 + (* 36000.76983 time) + (* 0.0003032 time time))) ; sun mean longitude + (ml (+ 218.3165 + (* 481267.8813 time))) ; moon mean longitude + (m (+ 357.52910 + (* 35999.05030 time) + (* -0.0001559 time time) + (* -0.00000048 time time time))) ; sun mean anomaly + (i (+ 23.43929111 (* -0.013004167 time) + (* -0.00000016389 time time) + (* 0.0000005036 time time time))); mean inclination + (c (+ (* (+ 1.914600 + (* -0.004817 time) + (* -0.000014 time time)) + (solar-sin-degrees m)) + (* (+ 0.019993 (* -0.000101 time)) + (solar-sin-degrees (* 2 m))) + (* 0.000290 + (solar-sin-degrees (* 3 m))))) ; center equation + (L (+ l c)) ; total longitude + (omega (+ 125.04 + (* -1934.136 time))) ; longitude of moon's ascending node + ; on the ecliptic + (nut (if (not for-sunrise-sunset) + (+ (* -17.20 (solar-sin-degrees omega)) + (* -1.32 (solar-sin-degrees (* 2 l))) + (* -0.23 (solar-sin-degrees (* 2 ml))) + (* 0.21 (solar-sin-degrees (* 2 omega)))) + nil)) + ; nut = nutation in longitude, measured in seconds of angle. + (ecc (if (not for-sunrise-sunset) + (+ 0.016708617 + (* -0.000042037 time) + (* -0.0000001236 time time)) ; eccentricity of earth's orbit + nil)) + (app (+ L + -0.00569 + (* -0.00478 + (solar-sin-degrees omega)))) ; apparent longitude of sun + (y (if (not for-sunrise-sunset) + (* (solar-tangent-degrees (/ i 2)) + (solar-tangent-degrees (/ i 2))) + nil)) + (time-eq (if (not for-sunrise-sunset) + (/ (* 12 (+ (* y (solar-sin-degrees (* 2 l))) + (* -2 ecc (solar-sin-degrees m)) + (* 4 ecc y (solar-sin-degrees m) + (solar-cosine-degrees (* 2 l))) + (* -0.5 y y (solar-sin-degrees (* 4 l))) + (* -1.25 ecc ecc (solar-sin-degrees (* 2 m))))) + 3.1415926535) + nil))) + ; equation of time, in hours + (list app i time-eq nut))) + (defun solar-longitude (d) "Longitude of sun on astronomical (Julian) day number D. -Accuracy is about 0.01 degree (about 365.25*24*60*0.01/360 = 15 minutes). +Accurary is about 0.0006 degree (about 365.25*24*60*0.0006/360 = 1 minutes). The values of calendar-daylight-savings-starts, calendar-daylight-savings-starts-time, calendar-daylight-savings-ends, calendar-daylight-savings-ends-time, calendar-daylight-time-offset, and calendar-time-zone are used to interpret local time." (let* ((a-d (calendar-absolute-from-astro d)) - (date (calendar-gregorian-from-absolute (floor a-d))) - (time (* 24 (- a-d (truncate a-d)))) - (rounded-abs-date (+ (calendar-absolute-from-gregorian date) - (/ (round (* 60 time)) 60.0 24.0))) - ;; get local standard time - (a-d (- rounded-abs-date - (if (dst-in-effect rounded-abs-date) - (/ calendar-daylight-time-offset 24.0 60.0) 0))) ;; get Universal Time - (a-d (- a-d (/ calendar-time-zone 60.0 24.0))) - (date (calendar-astro-from-absolute a-d)) + (date (calendar-astro-from-absolute + (- a-d + (if (dst-in-effect a-d) + (/ calendar-daylight-time-offset 24.0 60.0) 0) + (/ calendar-time-zone 60.0 24.0)))) ;; get Ephemeris Time (date (+ date (solar-ephemeris-correction (extract-calendar-year @@ -407,30 +620,83 @@ calendar-time-zone are used to interpret local time." (floor (calendar-absolute-from-astro date))))))) - (T (/ (- date 2451545.0) 36525.0)) - (Lo (mod (+ 280.46645 (* 36000.76983 T) (* 0.0003032 T T)) 360.0)) - (M (mod (+ 357.52910 - (* 35999.05030 T) - (* -0.0001559 T T) - (* -0.00000048 T T T)) - 360.0)) - (e (+ 0.016708617 (* -0.000042037 T) (* -0.0000001236 T T))) - (C (+ (* (+ 1.914600 (* -0.004817 T) (* -0.000014 T T)) - (solar-sin-degrees M)) - (* (+ 0.019993 (* -0.000101 T)) (solar-sin-degrees (* 2 M))) - (* 0.000290 (solar-sin-degrees (* 3 M))))) - (true-longitude (+ Lo C)) - (omega (+ 125.04 (* -1934.136 T))) - (apparent-longitude (mod - (+ true-longitude - -0.00569 - (* -0.00478 (solar-sin-degrees omega))) - 360.0))) - apparent-longitude)) + (U (/ (- date 2451545) 3652500)) + (longitude + (+ 4.9353929 + (* 62833.1961680 U) + (* 0.0000001 + (apply '+ + (mapcar '(lambda (x) + (* (car x) + (sin (mod + (+ (car (cdr x)) + (* (car (cdr (cdr x))) U)) + (* 2 pi))))) + solar-data-list))))) + (aberration + (* 0.0000001 (- (* 17 (cos (+ 3.10 (* 62830.14 U)))) 973))) + (A1 (mod (+ 2.18 (* U (+ -3375.70 (* 0.36 U)))) (* 2 pi))) + (A2 (mod (+ 3.51 (* U (+ 125666.39 (* 0.10 U)))) (* 2 pi))) + (nutation (* -0.0000001 (+ (* 834 (sin A1)) (* 64 (sin A2)))))) + (mod (radians-to-degrees (+ longitude aberration nutation)) 360.0))) + +(defconst solar-data-list + '((403406 4.721964 1.621043) + (195207 5.937458 62830.348067) + (119433 1.115589 62830.821524) + (112392 5.781616 62829.634302) + (3891 5.5474 125660.5691) + (2819 1.5120 125660.984) + (1721 4.1897 62832.4766) + (0 1.163 0.813) + (660 5.415 125659.31) + (350 4.315 57533.85) + (334 4.553 -33.931) + (314 5.198 777137.715) + (268 5.989 78604.191) + (242 2.911 5.412) + (234 1.423 39302.098) + (158 0.061 -34.861) + (132 2.317 115067.698) + (129 3.193 15774.337) + (114 2.828 5296.670) + (99 0.52 58849.27) + (93 4.65 5296.11) + (86 4.35 -3980.70) + (78 2.75 52237.69) + (72 4.50 55076.47) + (68 3.23 261.08) + (64 1.22 15773.85) + (46 0.14 188491.03) + (38 3.44 -7756.55) + (37 4.37 264.89) + (32 1.14 117906.27) + (29 2.84 55075.75) + (28 5.96 -7961.39) + (27 5.09 188489.81) + (27 1.72 2132.19) + (25 2.56 109771.03) + (24 1.92 54868.56) + (21 0.09 25443.93) + (21 5.98 -55731.43) + (20 4.03 60697.74) + (18 4.47 2132.79) + (17 0.79 109771.63) + (14 4.24 -7752.82) + (13 2.01 188491.91) + (13 2.65 207.81) + (13 4.98 29424.63) + (12 0.93 -7.99) + (10 2.21 46941.14) + (10 3.59 -68.29) + (10 1.50 21463.25) + (10 2.55 157208.40))) (defun solar-ephemeris-correction (year) - "Ephemeris time minus Universal Time at astronomical (Julian) day D. -Result is in days For the years 1800-1987, the maximum error is 1.9 seconds. + "Ephemeris time minus Universal Time during Gregorian year. +Result is in days. + +For the years 1800-1987, the maximum error is 1.9 seconds. For the other years, the maximum error is about 30 seconds." (cond ((and (<= 1988 year) (< year 2020)) (/ (+ year -2000 67.0) 60.0 60.0 24.0)) @@ -487,9 +753,39 @@ For the other years, the maximum error is about 30 seconds." (second (- (/ (* tmp tmp) 41048480.0) 15))) (/ second 60.0 60.0 24.0))))) +(defun solar-sidereal-time (t0) + "Sidereal time (in hours) in Greenwich. + +At T0=Julian centuries of universal time. +T0 must correspond to 0 hours UT." + (let* ((mean-sid-time (+ 6.6973746 + (* 2400.051337 t0) + (* 0.0000258622 t0 t0) + (* -0.0000000017222 t0 t0 t0))) + (et (solar-ephemeris-time (list t0 0.0))) + (nut-i (solar-ecliptic-coordinates et nil)) + (nut (car (cdr (cdr (cdr nut-i))))) ; nutation + (i (car (cdr nut-i)))) ; inclination + (mod (+ (mod (+ mean-sid-time + (/ (/ (* nut (solar-cosine-degrees i)) 15) 3600)) 24.0) + 24.0) + 24.0))) + +(defun solar-time-equation (date ut) + "Equation of time expressed in hours at Gregorian DATE at Universal time UT." + (let* ((et (solar-date-to-et date ut)) + (ec (solar-ecliptic-coordinates et nil))) + (car (cdr (cdr ec))))) + +(defun solar-date-to-et (date ut) + "Ephemeris Time at Gregorian DATE at Universal Time UT (in hours). +Expressed in julian centuries of Ephemeris Time." + (let ((t0 (solar-julian-ut-centuries date))) + (solar-ephemeris-time (list t0 ut)))) + ;;;###autoload (defun sunrise-sunset (&optional arg) - "Local time of sunrise and sunset for today. Accurate to +/- 2 minutes. + "Local time of sunrise and sunset for today. Accurate to a few seconds. If called with an optional prefix argument, prompt for date. If called with an optional double prefix argument, prompt for longitude, @@ -544,7 +840,7 @@ This function is suitable for execution in a .emacs file." (if (< arg 16) calendar-daylight-savings-ends)) (date (if (< arg 4) (calendar-current-date) (calendar-read-date))) (date-string (calendar-date-string date t)) - (time-string (solar-sunrise-sunset date)) + (time-string (solar-sunrise-sunset-string date)) (msg (format "%s: %s" date-string time-string)) (one-window (one-window-p t))) (if (<= (length msg) (frame-width)) @@ -560,21 +856,21 @@ This function is suitable for execution in a .emacs file." (defun calendar-sunrise-sunset () "Local time of sunrise and sunset for date under cursor. -Accurate to +/- 2 minutes." +Accurate to a few seconds." (interactive) (if (not (and calendar-latitude calendar-longitude calendar-time-zone)) (solar-setup)) (let ((date (calendar-cursor-to-date t))) (message "%s: %s" (calendar-date-string date t t) - (solar-sunrise-sunset date)))) + (solar-sunrise-sunset-string date)))) (defun diary-sunrise-sunset () "Local time of sunrise and sunset as a diary entry. -Accurate to +/- 2 minutes." +Accurate to a few seconds." (if (not (and calendar-latitude calendar-longitude calendar-time-zone)) (solar-setup)) - (solar-sunrise-sunset date)) + (solar-sunrise-sunset-string date)) (defun diary-sabbath-candles () "Local time of candle lighting diary entry--applies if date is a Friday. @@ -582,18 +878,123 @@ No diary entry if there is no sunset on that date." (if (not (and calendar-latitude calendar-longitude calendar-time-zone)) (solar-setup)) (if (= (% (calendar-absolute-from-gregorian date) 7) 5);; Friday - (let* ((sunset (solar-sunset date)) + (let* ((sunset (car (cdr (solar-sunrise-sunset date)))) (light (if sunset (dst-adjust-time date - (- sunset (/ 18.0 60.0)))))) + (- (car sunset) (/ 18.0 60.0)))))) (if (and light (calendar-date-equal date (car light))) (format "%s Sabbath candle lighting" (apply 'solar-time-string (cdr light))))))) +(defun solar-equinoxes/solstices (k year) + "Date of equinox/solstice K for YEAR. +K=0, spring equinox; K=1, summer solstice; K=2, fall equinox; +K=3, winter solstice. +RESULT is a gregorian local date. + +Accurate to less than a minute between 1951 and 2050." + (let* ((JDE0 (solar-mean-equinoxes/solstices k year)) + (T (/ (- JDE0 2451545.0) 36525)) + (W (- (* 35999.373 T) 2.47)) + (Delta-lambda (+ 1 (* 0.0334 (solar-cosine-degrees W)) + (* 0.0007 (solar-cosine-degrees (* 2 W))))) + (S (apply '+ (mapcar '(lambda(x) + (* (car x) (solar-cosine-degrees + (+ (* (car (cdr (cdr x))) T) + (car (cdr x)))))) + solar-seasons-data))) + (JDE (+ JDE0 (/ (* 0.00001 S) Delta-lambda))) + (correction (+ 102.3 (* 123.5 T) (* 32.5 T T))) + ; ephemeris time correction + (JD (- JDE (/ correction 86400))) + (date (calendar-gregorian-from-absolute (floor (- JD 1721424.5)))) + (time (- (- JD 0.5) (floor (- JD 0.5)))) + ) + (list (car date) (+ (car (cdr date)) time + (/ (/ calendar-time-zone 60.0) 24.0)) + (car (cdr (cdr date)))))) + +; from Meeus, 1991, page 166 +(defun solar-mean-equinoxes/solstices (k year) + "Julian day of mean equinox/solstice K for YEAR. +K=0, spring equinox; K=1, summer solstice; K=2, fall equinox; K=3, winter +solstice. These formulas are only to be used between 1000 BC and 3000 AD." + (let ((y (/ year 1000.0)) + (z (/ (- year 2000) 1000.0))) + (if (< year 1000) ; actually between -1000 and 1000 + (cond ((equal k 0) (+ 1721139.29189 + (* 365242.13740 y) + (* 0.06134 y y) + (* 0.00111 y y y) + (* -0.00071 y y y y))) + ((equal k 1) (+ 1721233.25401 + (* 365241.72562 y) + (* -0.05323 y y) + (* 0.00907 y y y) + (* 0.00025 y y y y))) + ((equal k 2) (+ 1721325.70455 + (* 365242.49558 y) + (* -0.11677 y y) + (* -0.00297 y y y) + (* 0.00074 y y y y))) + ((equal k 3) (+ 1721414.39987 + (* 365242.88257 y) + (* -0.00769 y y) + (* -0.00933 y y y) + (* -0.00006 y y y y)))) + ; actually between 1000 and 3000 + (cond ((equal k 0) (+ 2451623.80984 + (* 365242.37404 z) + (* 0.05169 z z) + (* -0.00411 z z z) + (* -0.00057 z z z z))) + ((equal k 1) (+ 2451716.56767 + (* 365241.62603 z) + (* 0.00325 z z) + (* 0.00888 z z z) + (* -0.00030 z z z z))) + ((equal k 2) (+ 2451810.21715 + (* 365242.01767 z) + (* -0.11575 z z) + (* 0.00337 z z z) + (* 0.00078 z z z z))) + ((equal k 3) (+ 2451900.05952 + (* 365242.74049 z) + (* -0.06223 z z) + (* -0.00823 z z z) + (* 0.00032 z z z z))))))) + +; from Meeus, 1991, page 167 +(defconst solar-seasons-data + '((485 324.96 1934.136) + (203 337.23 32964.467) + (199 342.08 20.186) + (182 27.85 445267.112) + (156 73.14 45036.886) + (136 171.52 22518.443) + (77 222.54 65928.934) + (74 296.72 3034.906) + (70 243.58 9037.513) + (58 119.81 33718.147) + (52 297.17 150.678) + (50 21.02 2281.226) + (45 247.54 29929.562) + (44 325.15 31555.956) + (29 60.93 4443.417) + (18 155.12 67555.328) + (17 288.79 4562.452) + (16 198.04 62894.029) + (14 199.76 31436.921) + (12 95.39 14577.848) + (12 287.11 31931.756) + (12 320.81 34777.259) + (9 227.73 1222.114) + (8 15.45 16859.074))) + ;;;###autoload (defun solar-equinoxes-solstices () - "Date and time of equinoxes and solstices, if visible in the calendar window. + "*local* date and time of equinoxes and solstices, if visible in the calendar window. Requires floating point." (let ((m displayed-month) (y displayed-year)) @@ -608,12 +1009,21 @@ Requires floating point." (if calendar-time-zone calendar-daylight-savings-ends)) (calendar-time-zone (if calendar-time-zone calendar-time-zone 0)) (k (1- (/ m 3))) - (d (solar-date-next-longitude - (calendar-astro-from-absolute - (calendar-absolute-from-gregorian - (list (+ 3 (* k 3)) 15 y))) - 90)) - (abs-day (calendar-absolute-from-astro d))) + (d0 (solar-equinoxes/solstices k y)) + (d1 (list (car d0) (floor (car (cdr d0))) (car (cdr (cdr d0))))) + (h0 (* 24 (- (car (cdr d0)) (floor (car (cdr d0)))))) + (adj (dst-adjust-time d1 h0)) + (d (list (car d1) (+ (car (cdr d1)) + (/ (car (cdr adj)) 24.0)) + (car (cdr (cdr d1))))) + ; The following is nearly as accurate, but not quite: + ;(d0 (solar-date-next-longitude + ; (calendar-astro-from-absolute + ; (calendar-absolute-from-gregorian + ; (list (+ 3 (* k 3)) 15 y))) + ; 90)) + ;(abs-day (calendar-absolute-from-astro d))) + (abs-day (calendar-absolute-from-gregorian d))) (list (list (calendar-gregorian-from-absolute (floor abs-day)) (format "%s %s"