function month(name, numdays, abbr) { this.name = name; this.numdays = numdays; this.abbr = abbr; } //*******************/ function ans(daySave,value) { this.daySave = daySave; this.value = value; } //*********************************/ function city(name, lat, lng, zoneHr) { this.name = name; this.lat = lat; this.lng = lng; this.zoneHr = zoneHr; } //**************************/ //* Data for Selectbox Controls */ var monthList = new Array(); // list of months and days for non-leap year var i = 0; monthList[i++] = new month("January", 31, "Jan"); monthList[i++] = new month("February", 28, "Feb"); monthList[i++] = new month("March", 31, "Mar"); monthList[i++] = new month("April", 30, "Apr"); monthList[i++] = new month("May", 31, "May"); monthList[i++] = new month("June", 30, "Jun"); monthList[i++] = new month("July", 31, "Jul"); monthList[i++] = new month("August", 31, "Aug"); monthList[i++] = new month("September", 30, "Sep"); monthList[i++] = new month("October", 31, "Oct"); monthList[i++] = new month("November", 30, "Nov"); monthList[i++] = new month("December", 31, "Dec"); var YesNo = new Array(); //Daylight Saving array i=0; YesNo[i++] = new ans("No",0); YesNo[i++] = new ans("Yes",60); function setLatLong(f, index) { // Decimal degrees are passed in the array. Temporarily store these // degs in lat and lon deg and have convLatLong modify them. //alert("index=" + index); f["latDeg"].value = City[index].lat; f["lonDeg"].value = City[index].lng; // These are needed to prevent iterative adding of min and sec when // set button is clicked. f["latMin"].value = 0; f["latSec"].value = 0; f["lonMin"].value = 0; f["lonSec"].value = 0; //call convLatLong to convert decimal degrees into table form. convLatLong(f); //Local time zone value set in table f["hrsToGMT"].value = City[index].zoneHr; } //*************************/ // isLeapYear returns 1 if the 4-digit yr is a leap year, 0 if it is not function isLeapYear(yr) { return ((yr % 4 == 0 && yr % 100 != 0) || yr % 400 == 0); } function isPosInteger(inputVal) { inputStr = ("" + inputVal); for (var i = 0; i < inputStr.length; i++) { var oneChar = inputStr.charAt(i); if (oneChar < "0" || oneChar > "9") return false; } return true; } function isInteger(inputVal) { inputStr = "" + inputVal; if(inputStr == "NaN") return false; if(inputStr == "-NaN") return false; for (var i = 0; i < inputStr.length; i++) { var oneChar = inputStr.charAt(i); if (i == 0 && (oneChar == "-" || oneChar == "+")) { continue; } if (oneChar < "0" || oneChar > "9") { return false; } } return true; } function isNumber(inputVal) { var oneDecimal = false; var inputStr = "" + inputVal; for (var i = 0; i < inputStr.length; i++) { var oneChar = inputStr.charAt(i); if (i == 0 && (oneChar == "-" || oneChar == "+")) { continue; } if (oneChar == "." && !oneDecimal) { oneDecimal = true; continue; } if (oneChar < "0" || oneChar > "9") { return false; } } return true; } // isValidInput makes sure valid input is entered before going ahead to // calculate the sunrise and sunset. False is returned if an invalid entry // was made, true is the entry is valid. function isValidInput(f, index, latLongForm) { if (f["day"].value == "") { // see if the day field is empty alert("You must enter a day before attempting the calculation."); return false; } else if (f["year"].value == "") { // see if the year field is empty alert("You must enter a year before attempting the calculation."); return false; } else if (!isPosInteger(f["day"].value) || f["day"].value == 0) { alert("The day must be a positive integer."); return false; } else if (!isInteger(f["year"].value)) { alert("The year must be an integer."); return false; } else if ( (f["year"].value < -1000) || (f["year"].value > 3000) ) { alert("The algorithm used is not valid for years outside of/nthe range -1000 to 3000."); return false; } // For the non-February months see if the day entered is greater than // the number of days in the selected month else if ((index != 1) && (f["day"].value > monthList[index].numdays)) { alert("There are only " + monthList[index].numdays + " days in " + monthList[index].name + "."); return false; } // First see if the year entered is a leap year. If so we have to make sure // the days entered is <= 29. If not a leap year we make sure that the days // entered is <= 28. else if (index == 1) { // month selected is February the screwball month if (isLeapYear(f["year"].value)) { // year entered is a leap year if (f["day"].value > (monthList[index].numdays + 1)) { alert("There are only " + (monthList[index].numdays + 1) + " days in " + monthList[index].name + "."); return false; } else return true; } else { // year entered is not a leap year if (f["day"].value > monthList[index].numdays) { alert("There are only " + monthList[index].numdays + " days in " + monthList[index].name + "."); return false; } else return true; } } else return true; } //***********************************/ function convLatLong(f) { var neg = 0; if(f["latDeg"].value.charAt(0) == '-') { neg = 1; } if(neg != 1) { var latSeconds = (parseFloat(f["latDeg"].value))*3600 + parseFloat(f["latMin"].value)*60 + parseFloat(f["latSec"].value)*1; f["latDeg"].value = Math.floor(latSeconds/3600); f["latMin"].value = Math.floor((latSeconds - (parseFloat(f["latDeg"].value)*3600))/60); f["latSec"].value = Math.floor((latSeconds - (parseFloat(f["latDeg"].value)*3600) - (parseFloat(f["latMin"].value)*60)) + 0.5); } else if(parseFloat(f["latDeg"].value) > -1) { var latSeconds = parseFloat(f["latDeg"].value)*3600 - parseFloat(f["latMin"].value)*60 - parseFloat(f["latSec"].value)*1; f["latDeg"].value = "-0"; f["latMin"].value = Math.floor((-latSeconds)/60); f["latSec"].value = Math.floor( (-latSeconds - (parseFloat(f["latMin"].value)*60)) + 0.5); } else { var latSeconds = parseFloat(f["latDeg"].value)*3600 - parseFloat(f["latMin"].value)*60 - parseFloat(f["latSec"].value)*1; f["latDeg"].value = Math.ceil(latSeconds/3600); f["latMin"].value = Math.floor((-latSeconds + (parseFloat(f["latDeg"].value)*3600))/60); f["latSec"].value = Math.floor((-latSeconds + (parseFloat(f["latDeg"].value)*3600) - (parseFloat(f["latMin"].value)*60)) + 0.5); } neg = 0; if(f["lonDeg"].value.charAt(0) == '-') { neg = 1; } if(neg != 1) { var lonSeconds = parseFloat(f["lonDeg"].value)*3600 + parseFloat(f["lonMin"].value)*60 + parseFloat(f["lonSec"].value)*1; f["lonDeg"].value = Math.floor(lonSeconds/3600); f["lonMin"].value = Math.floor((lonSeconds - (parseFloat(f["lonDeg"].value)*3600))/60); f["lonSec"].value = Math.floor((lonSeconds - (parseFloat(f["lonDeg"].value)*3600) - (parseFloat(f["lonMin"].value))*60) + 0.5); } else if(parseFloat(f["lonDeg"].value) > -1) { var lonSeconds = parseFloat(f["lonDeg"].value)*3600 - parseFloat(f["lonMin"].value)*60 - parseFloat(f["lonSec"].value)*1; f["lonDeg"].value = "-0"; f["lonMin"].value = Math.floor((-lonSeconds)/60); f["lonSec"].value = Math.floor((-lonSeconds - (parseFloat(f["lonMin"].value)*60)) + 0.5); } else { var lonSeconds = parseFloat(f["lonDeg"].value)*3600 - parseFloat(f["lonMin"].value)*60 - parseFloat(f["lonSec"].value)*1; f["lonDeg"].value = Math.ceil(lonSeconds/3600); f["lonMin"].value = Math.floor((-lonSeconds + (parseFloat(f["lonDeg"].value)*3600))/60); f["lonSec"].value = Math.floor((-lonSeconds + (parseFloat(f["lonDeg"].value)*3600) - (parseFloat(f["lonMin"].value)*60)) + 0.5); } //Test for invalid lat/long input if(latSeconds > 324000) { alert("You have entered an invalid latitude.\n Setting lat= 89.8."); f["latDeg"].value = 89.8; f["latMin"].value = 0; f["latSec"].value = 0; } if(latSeconds < -324000) { alert("You have entered an invalid latitude.\n Setting lat= -89.8."); f["latDeg"].value = -89.8; f["latMin"].value = 0; f["latSec"].value = 0; } if(lonSeconds > 648000) { alert("You have entered an invalid longitude.\n Setting lon= 180."); f["lonDeg"].value = 180; f["lonMin"].value = 0; f["lonSec"].value = 0; } if(lonSeconds < -648000) { alert("You have entered an invalid longitude.\n Setting lon= -180."); f["lonDeg"].value = -180; f["lonMin"].value = 0; f["lonSec"].value =0; } } // Convert radian angle to degrees function radToDeg(angleRad) { return (180.0 * angleRad / Math.PI); } //*****************/ // Convert degree angle to radians function degToRad(angleDeg) { return (Math.PI * angleDeg / 180.0); } //***********************/ function calcDayOfYear(mn, dy, lpyr) { var k = (lpyr ? 1 : 2); var doy = Math.floor((275 * mn)/9) - k * Math.floor((mn + 9)/12) + dy -30; return doy; } function calcDayOfWeek(juld) { var A = (juld + 1.5) % 7; var DOW = (A==0)?"Sunday":(A==1)?"Monday":(A==2)?"Tuesday":(A==3)?"Wednesday":(A==4)?"Thursday":(A==5)?"Friday":"Saturday"; return DOW; } function calcJD(year, month, day) { if (month <= 2) { year -= 1; month += 12; } var A = Math.floor(year/100); var B = 2 - A + Math.floor(A/4); var JD = Math.floor(365.25*(year + 4716)) + Math.floor(30.6001*(month+1)) + day + B - 1524.5; //alert("jd="+JD); return JD; } function calcDateFromJD(jd) { var z = Math.floor(jd + 0.5); var f = (jd + 0.5) - z; if (z < 2299161) { var A = z; } else { alpha = Math.floor((z - 1867216.25)/36524.25); var A = z + 1 + alpha - Math.floor(alpha/4); } var B = A + 1524; var C = Math.floor((B - 122.1)/365.25); var D = Math.floor(365.25 * C); var E = Math.floor((B - D)/30.6001); var day = B - D - Math.floor(30.6001 * E) + f; var month = (E < 14) ? E - 1 : E - 13; var year = (month > 2) ? C - 4716 : C - 4715; // alert ("date: " + day + "-" + monthList[month-1].name + "-" + year); return (day + "-" + monthList[month-1].name + "-" + year); } function calcDayFromJD(jd) { var z = Math.floor(jd + 0.5); var f = (jd + 0.5) - z; if (z < 2299161) { var A = z; } else { alpha = Math.floor((z - 1867216.25)/36524.25); var A = z + 1 + alpha - Math.floor(alpha/4); } var B = A + 1524; var C = Math.floor((B - 122.1)/365.25); var D = Math.floor(365.25 * C); var E = Math.floor((B - D)/30.6001); var day = B - D - Math.floor(30.6001 * E) + f; var month = (E < 14) ? E - 1 : E - 13; var year = (month > 2) ? C - 4716 : C - 4715; return ((day<10 ? "0" : "") + day + monthList[month-1].abbr); } function calcTimeJulianCent(jd) { var T = (jd - 2451545.0)/36525.0; return T; } function calcJDFromJulianCent(t) { var JD = t * 36525.0 + 2451545.0; return JD; } function calcGeomMeanLongSun(t) { //alert(t); var L0 = 280.46646 + t * (36000.76983 + 0.0003032 * t); //alert(L0); while(L0 > 360.0) { L0 -= 360.0; } while(L0 < 0.0) { L0 += 360.0; } return L0; // in degrees } function calcGeomMeanAnomalySun(t) { var M = 357.52911 + t * (35999.05029 - 0.0001537 * t); return M; // in degrees } function calcEccentricityEarthOrbit(t) { var e = 0.016708634 - t * (0.000042037 + 0.0000001267 * t); return e; // unitless } function calcSunEqOfCenter(t) { var m = calcGeomMeanAnomalySun(t); var mrad = degToRad(m); var sinm = Math.sin(mrad); var sin2m = Math.sin(mrad+mrad); var sin3m = Math.sin(mrad+mrad+mrad); var C = sinm * (1.914602 - t * (0.004817 + 0.000014 * t)) + sin2m * (0.019993 - 0.000101 * t) + sin3m * 0.000289; return C; // in degrees } function calcSunTrueLong(t) { var l0 = calcGeomMeanLongSun(t); var c = calcSunEqOfCenter(t); var O = l0 + c; return O; // in degrees } function calcSunTrueAnomaly(t) { var m = calcGeomMeanAnomalySun(t); var c = calcSunEqOfCenter(t); var v = m + c; return v; // in degrees } function calcSunRadVector(t) { var v = calcSunTrueAnomaly(t); var e = calcEccentricityEarthOrbit(t); var R = (1.000001018 * (1 - e * e)) / (1 + e * Math.cos(degToRad(v))); return R; // in AUs } function calcSunApparentLong(t) { var o = calcSunTrueLong(t); var omega = 125.04 - 1934.136 * t; var lambda = o - 0.00569 - 0.00478 * Math.sin(degToRad(omega)); return lambda; // in degrees } function calcMeanObliquityOfEcliptic(t) { var seconds = 21.448 - t*(46.8150 + t*(0.00059 - t*(0.001813))); var e0 = 23.0 + (26.0 + (seconds/60.0))/60.0; return e0; // in degrees } function calcObliquityCorrection(t) { var e0 = calcMeanObliquityOfEcliptic(t); var omega = 125.04 - 1934.136 * t; var e = e0 + 0.00256 * Math.cos(degToRad(omega)); return e; // in degrees } function calcSunRtAscension(t) { var e = calcObliquityCorrection(t); var lambda = calcSunApparentLong(t); var tananum = (Math.cos(degToRad(e)) * Math.sin(degToRad(lambda))); var tanadenom = (Math.cos(degToRad(lambda))); var alpha = radToDeg(Math.atan2(tananum, tanadenom)); return alpha; // in degrees } function calcSunDeclination(t) { var e = calcObliquityCorrection(t); var lambda = calcSunApparentLong(t); var sint = Math.sin(degToRad(e)) * Math.sin(degToRad(lambda)); var theta = radToDeg(Math.asin(sint)); return theta; // in degrees } function calcEquationOfTime(t) { var epsilon = calcObliquityCorrection(t); var l0 = calcGeomMeanLongSun(t); var e = calcEccentricityEarthOrbit(t); var m = calcGeomMeanAnomalySun(t); var y = Math.tan(degToRad(epsilon)/2.0); y *= y; var sin2l0 = Math.sin(2.0 * degToRad(l0)); var sinm = Math.sin(degToRad(m)); var cos2l0 = Math.cos(2.0 * degToRad(l0)); var sin4l0 = Math.sin(4.0 * degToRad(l0)); var sin2m = Math.sin(2.0 * degToRad(m)); var Etime = y * sin2l0 - 2.0 * e * sinm + 4.0 * e * y * sinm * cos2l0 - 0.5 * y * y * sin4l0 - 1.25 * e * e * sin2m; return radToDeg(Etime)*4.0; // in minutes of time } function calcHourAngleSunrise(lat, solarDec) { var latRad = degToRad(lat); var sdRad = degToRad(solarDec) var HAarg = (Math.cos(degToRad(90.833))/(Math.cos(latRad)*Math.cos(sdRad))-Math.tan(latRad) * Math.tan(sdRad)); var HA = (Math.acos(Math.cos(degToRad(90.833))/(Math.cos(latRad)*Math.cos(sdRad))-Math.tan(latRad) * Math.tan(sdRad))); return HA; // in radians } function calcHourAngleSunset(lat, solarDec) { var latRad = degToRad(lat); var sdRad = degToRad(solarDec) var HAarg = (Math.cos(degToRad(90.833))/(Math.cos(latRad)*Math.cos(sdRad))-Math.tan(latRad) * Math.tan(sdRad)); var HA = (Math.acos(Math.cos(degToRad(90.833))/(Math.cos(latRad)*Math.cos(sdRad))-Math.tan(latRad) * Math.tan(sdRad))); return -HA; // in radians } function calcSunriseUTC(JD, latitude, longitude) { var t = calcTimeJulianCent(JD); // *** First pass to approximate sunrise var eqTime = calcEquationOfTime(t); var solarDec = calcSunDeclination(t); var hourAngle = calcHourAngleSunrise(latitude, solarDec); var delta = longitude - radToDeg(hourAngle); var timeDiff = 4 * delta; // in minutes of time var timeUTC = 720 + timeDiff - eqTime; // in minutes //alert("eqTime = " + eqTime + "\nsolarDec = " + solarDec + "\ntimeUTC = " + timeUTC); // *** Second pass includes fractional jday in gamma calc var newt = calcTimeJulianCent(calcJDFromJulianCent(t) + timeUTC/1440.0); eqTime = calcEquationOfTime(newt); solarDec = calcSunDeclination(newt); hourAngle = calcHourAngleSunrise(latitude, solarDec); delta = longitude - radToDeg(hourAngle); timeDiff = 4 * delta; timeUTC = 720 + timeDiff - eqTime; // in minutes //alert("eqTime = " + eqTime + "\nsolarDec = " + solarDec + "\ntimeUTC = " + timeUTC); return timeUTC; } function calcSolNoonUTC(t, longitude) { var newt = calcTimeJulianCent(calcJDFromJulianCent(t) + 0.5 + longitude/360.0); var eqTime = calcEquationOfTime(t); var solarNoonDec = calcSunDeclination(t); var solNoonUTC = 720 + (longitude * 4) - eqTime; // min return solNoonUTC; } function calcSunsetUTC(JD, latitude, longitude) { var t = calcTimeJulianCent(JD); // First calculates sunrise and approx length of day var eqTime = calcEquationOfTime(t); var solarDec = calcSunDeclination(t); var hourAngle = calcHourAngleSunset(latitude, solarDec); var delta = longitude - radToDeg(hourAngle); var timeDiff = 4 * delta; var timeUTC = 720 + timeDiff - eqTime; // first pass used to include fractional day in gamma calc var newt = calcTimeJulianCent(calcJDFromJulianCent(t) + timeUTC/1440.0); eqTime = calcEquationOfTime(newt); solarDec = calcSunDeclination(newt); hourAngle = calcHourAngleSunset(latitude, solarDec); delta = longitude - radToDeg(hourAngle); timeDiff = 4 * delta; timeUTC = 720 + timeDiff - eqTime; // in minutes return timeUTC; } function getLatitude(latLongForm) { var neg = 0; var degs = parseFloat(latLongForm["latDeg"].value); if (latLongForm["latDeg"].value.charAt(0) == '-') { neg = 1; } var mins = parseFloat(latLongForm["latMin"].value); var secs = parseFloat(latLongForm["latSec"].value); if(neg != 1) { var decLat = degs + (mins / 60) + (secs / 3600); } else if(neg == 1) { var decLat = degs - (mins / 60) - (secs / 3600); } else { return -9999; } return decLat; } function getLongitude(latLongForm) { var neg = 0; var degs = parseFloat(latLongForm["lonDeg"].value); if (latLongForm["lonDeg"].value.charAt(0) == '-') { neg = 1; } var mins = parseFloat(latLongForm["lonMin"].value); var secs = parseFloat(latLongForm["lonSec"].value); var decLon = degs + (mins / 60) + (secs / 3600); if(neg != 1) { var decLon = degs + (mins / 60) + (secs / 3600); } else if(neg == 1) { var decLon = degs - (mins / 60) - (secs / 3600); } else { return -9999; } return decLon; } function findRecentSunrise(jd, latitude, longitude) { var julianday = jd; var time = calcSunriseUTC(julianday, latitude, longitude); while(!isNumber(time)){ julianday -= 1.0; time = calcSunriseUTC(julianday, latitude, longitude); } return julianday; } function findRecentSunset(jd, latitude, longitude) { var julianday = jd; var time = calcSunsetUTC(julianday, latitude, longitude); while(!isNumber(time)){ julianday -= 1.0; time = calcSunsetUTC(julianday, latitude, longitude); } return julianday; } function findNextSunrise(jd, latitude, longitude) { var julianday = jd; var time = calcSunriseUTC(julianday, latitude, longitude); while(!isNumber(time)){ julianday += 1.0; time = calcSunriseUTC(julianday, latitude, longitude); } return julianday; } function findNextSunset(jd, latitude, longitude) { var julianday = jd; var time = calcSunsetUTC(julianday, latitude, longitude); while(!isNumber(time)){ julianday += 1.0; time = calcSunsetUTC(julianday, latitude, longitude); } return julianday; } function timeString(minutes) // timeString returns a zero-padded string (HH:MM:SS) given time in minutes { var floatHour = minutes / 60; var hour = Math.floor(floatHour); var floatMinute = 60 * (floatHour - Math.floor(floatHour)); var minute = Math.floor(floatMinute); var floatSec = 60 * (floatMinute - Math.floor(floatMinute)); var second = Math.floor(floatSec); var timeStr = hour + ":"; if (minute < 10) // i.e. only one digit timeStr += "0" + minute + ":"; else timeStr += minute + ":"; if (second < 10) // i.e. only one digit timeStr += "0" + second; else timeStr += second; return timeStr; } // timeStringShortAMPM returns a zero-padded string (HH:MM *M) given time in // minutes and appends short date if time is > 24 or < 0, resp. function timeStringShortAMPM(minutes, JD) { var julianday = JD; var floatHour = minutes / 60; var hour = Math.floor(floatHour); var floatMinute = 60 * (floatHour - Math.floor(floatHour)); var minute = Math.floor(floatMinute); var floatSec = 60 * (floatMinute - Math.floor(floatMinute)); var second = Math.floor(floatSec); var PM = false; minute += (second >= 30)? 1 : 0; if (minute >= 60) { minute -= 60; hour ++; } var daychange = false; if (hour > 23) { hour -= 24; daychange = true; julianday += 1.0; } if (hour < 0) { hour += 24; daychange = true; julianday -= 1.0; } if (hour > 11) { hour -= 12; PM = true; } if (hour == 0) { PM = false; hour = 12; } var timeStr = hour + ":"; if (minute < 10) // i.e. only one digit timeStr += "0" + minute + ((PM)?"PM":"AM"); else timeStr += "" + minute + ((PM)?"PM":"AM"); if (daychange) return timeStr + " " + calcDayFromJD(julianday); return timeStr; } // timeStringAMPMDate returns a zero-padded string (HH:MM[AM/PM]) given time // in minutes and julian day, and appends the short date function timeStringAMPMDate(minutes, JD) { var julianday = JD; var floatHour = minutes / 60; var hour = Math.floor(floatHour); var floatMinute = 60 * (floatHour - Math.floor(floatHour)); var minute = Math.floor(floatMinute); var floatSec = 60 * (floatMinute - Math.floor(floatMinute)); var second = Math.floor(floatSec); minute += (second >= 30)? 1 : 0; if (minute >= 60) { minute -= 60; hour ++; } if (hour > 23) { hour -= 24; julianday += 1.0; } if (hour < 0) { hour += 24; julianday -= 1.0; } var PM = false; if (hour > 11) { hour -= 12; PM = true; } if (hour == 0) { PM = false; hour = 12; } var timeStr = hour + ":"; if (minute < 10) // i.e. only one digit timeStr += "0" + minute + ((PM)?"PM":"AM"); else timeStr += minute + ((PM)?"PM":"AM"); return timeStr + " " + calcDayFromJD(julianday); } // timeStringDate returns a zero-padded string (HH:MM) given time in minutes // and julian day, and appends the short date if time crosses a day boundary function timeStringDate(minutes, JD) { var julianday = JD; var floatHour = minutes / 60; var hour = Math.floor(floatHour); var floatMinute = 60 * (floatHour - Math.floor(floatHour)); var minute = Math.floor(floatMinute); var floatSec = 60 * (floatMinute - Math.floor(floatMinute)); var second = Math.floor(floatSec); minute += (second >= 30)? 1 : 0; if (minute >= 60) { minute -= 60; hour ++; } var daychange = false; if (hour > 23) { hour -= 24; julianday += 1.0; daychange = true; } if (hour < 0) { hour += 24; julianday -= 1.0; daychange = true; } var timeStr = hour + ":"; if (minute < 10) // i.e. only one digit timeStr += "0" + minute; else timeStr += minute; if (daychange) return timeStr + " " + calcDayFromJD(julianday); return timeStr; } function calcSun(riseSetForm, latLongForm, index, index2) { setLatLong(latLongForm, index2); var latitude = getLatitude(latLongForm); var longitude = getLongitude(latLongForm); var indexRS = riseSetForm.mos.selectedIndex if (isValidInput(riseSetForm, indexRS, latLongForm)) { if((latitude >= -90) && (latitude < -89.8)) { alert("All latitudes between 89.8 and 90 S\n will be set to -89.8"); latLongForm["latDeg"].value = -89.8; latitude = -89.8; } if ((latitude <= 90) && (latitude > 89.8)) { alert("All latitudes between 89.8 and 90 N\n will be set to 89.8"); latLongForm["latDeg"].value = 89.8; latitude = 89.8; } //***** Calculate the time of sunrise var JD = (calcJD(parseFloat(riseSetForm["year"].value), indexRS + 1, parseFloat(riseSetForm["day"].value))); //alert(JD); var dow = calcDayOfWeek(JD); var doy = calcDayOfYear(indexRS + 1, parseFloat(riseSetForm["day"].value), isLeapYear(riseSetForm["year"].value)); var T = calcTimeJulianCent(JD); //var L0 = calcGeomMeanLongSun(T); //var M = calcGeomMeanAnomalySun(T); //var e = calcEccentricityEarthOrbit(T); //var C = calcSunEqOfCenter(T); //var O = calcSunTrueLong(T); //var v = calcSunTrueAnomaly(T); //var R = calcSunRadVector(T); //var lambda = calcSunApparentLong(T); //var epsilon0 = calcMeanObliquityOfEcliptic(T); //var epsilon = calcObliquityCorrection(T); var alpha = calcSunRtAscension(T); var theta = calcSunDeclination(T); var Etime = calcEquationOfTime(T); //riseSetForm["dbug"].value = doy; //***********************************/ var eqTime = Etime; var solarDec = theta; riseSetForm["eqTime"].value = (Math.floor(100*eqTime))/100; riseSetForm["solarDec"].value = (Math.floor(100*(solarDec)))/100; // Calculate sunrise for this date // if no sunrise is found, set flag nosunrise var nosunrise = false; var riseTimeGMT = calcSunriseUTC(JD, latitude, longitude); if (!isNumber(riseTimeGMT)) { nosunrise = true; } // Calculate sunset for this date // if no sunset is found, set flag nosunset var nosunset = false; var setTimeGMT = calcSunsetUTC(JD, latitude, longitude); if (!isNumber(setTimeGMT)) { nosunset = true; } var daySavings = 60; // = 0 (no) or 60 (yes) //var daySavings = YesNo[index].value; // = 0 (no) or 60 (yes) var zone = latLongForm["hrsToGMT"].value; if(zone > 12 || zone < -12.5) { alert("The offset must be between -12.5 and 12. \n Setting \"Off-Set\"=0"); zone = "0"; latLongForm["hrsToGMT"].value = zone; } if (!nosunrise) // Sunrise was found { var riseTimeLST = riseTimeGMT - (60 * zone) + daySavings; // in minutes var riseStr = timeStringShortAMPM(riseTimeLST, JD); var utcRiseStr = timeStringDate(riseTimeGMT, JD); riseSetForm["sunrise"].value = riseStr; riseSetForm["utcsunrise"].value = utcRiseStr; } if (!nosunset) // Sunset was found { var setTimeLST = setTimeGMT - (60 * zone) + daySavings; var setStr = timeStringShortAMPM(setTimeLST, JD); var utcSetStr = timeStringDate(setTimeGMT, JD); riseSetForm["sunset"].value = setStr; riseSetForm["utcsunset"].value = utcSetStr; } // Calculate solar noon for this date var solNoonGMT = calcSolNoonUTC(T, longitude); var solNoonLST = solNoonGMT - (60 * zone) + daySavings; document.form.solnoonLST.value=solNoonLST; var solnStr = timeString(solNoonLST); var utcSolnStr = timeString(solNoonGMT); riseSetForm["solnoon"].value = solnStr; riseSetForm["utcsolnoon"].value = utcSolnStr; //***********Convert lat and long to standard format convLatLong(latLongForm); // report special cases of no sunrise if(nosunrise) { riseSetForm["utcsunrise"].value = ""; // if Northern hemisphere and spring or summer, OR // if Southern hemisphere and fall or winter, use // previous sunrise and next sunset if ( ((latitude > 66.4) && (doy > 79) && (doy < 267)) || ((latitude < -66.4) && ((doy < 83) || (doy > 263))) ) { newjd = findRecentSunrise(JD, latitude, longitude); newtime = calcSunriseUTC(newjd, latitude, longitude) - (60 * zone) + daySavings; if (newtime > 1440) { newtime -= 1440; newjd += 1.0; } if (newtime < 0) { newtime += 1440; newjd -= 1.0; } riseSetForm["sunrise"].value = timeStringAMPMDate(newtime, newjd); riseSetForm["utcsunrise"].value = "prior sunrise"; } // if Northern hemisphere and fall or winter, OR // if Southern hemisphere and spring or summer, use // next sunrise and previous sunset else if ( ((latitude > 66.4) && ((doy < 83) || (doy > 263))) || ((latitude < -66.4) && (doy > 79) && (doy < 267)) ) { newjd = findNextSunrise(JD, latitude, longitude); newtime = calcSunriseUTC(newjd, latitude, longitude) - (60 * zone) + daySavings; if (newtime > 1440) { newtime -= 1440; newjd += 1.0; } if (newtime < 0) { newtime += 1440; newjd -= 1.0; } riseSetForm["sunrise"].value = timeStringAMPMDate(newtime, newjd); // riseSetForm["sunrise"].value = calcDayFromJD(newjd) // + " " + timeStringDate(newtime, newjd); riseSetForm["utcsunrise"].value = "next sunrise"; } else { alert("Cannot Find Sunrise!"); } //alert("Last Sunrise was on day " + findRecentSunrise(JD, latitude, longitude)); //alert("Next Sunrise will be on day " + findNextSunrise(JD, latitude, longitude)); } if(nosunset) { riseSetForm["utcsunset"].value = ""; // if Northern hemisphere and spring or summer, OR // if Southern hemisphere and fall or winter, use // previous sunrise and next sunset if ( ((latitude > 66.4) && (doy > 79) && (doy < 267)) || ((latitude < -66.4) && ((doy < 83) || (doy > 263))) ) { newjd = findNextSunset(JD, latitude, longitude); newtime = calcSunsetUTC(newjd, latitude, longitude) - (60 * zone) + daySavings; if (newtime > 1440) { newtime -= 1440; newjd += 1.0; } if (newtime < 0) { newtime += 1440; newjd -= 1.0; } riseSetForm["sunset"].value = timeStringAMPMDate(newtime, newjd); riseSetForm["utcsunset"].value = "next sunset"; riseSetForm["utcsolnoon"].value = ""; } // if Northern hemisphere and fall or winter, OR // if Southern hemisphere and spring or summer, use // next sunrise and last sunset else if ( ((latitude > 66.4) && ((doy < 83) || (doy > 263))) || ((latitude < -66.4) && (doy > 79) && (doy < 267)) ) { newjd = findRecentSunset(JD, latitude, longitude); newtime = calcSunsetUTC(newjd, latitude, longitude) - (60 * zone) + daySavings; if (newtime > 1440) { newtime -= 1440; newjd += 1.0; } if (newtime < 0) { newtime += 1440; newjd -= 1.0; } riseSetForm["sunset"].value = timeStringAMPMDate(newtime, newjd); riseSetForm["utcsunset"].value = "prior sunset"; riseSetForm["solnoon"].value = "N/A"; riseSetForm["utcsolnoon"].value = ""; } else { alert ("Cannot Find Sunset!"); } } } } //***********************************/