Exemplo n.º 1
0
        /// <summary>
        /// A method that calculates UTC sunrise as well as any time based on an
        /// angle above or below sunrise. This abstract method is implemented by the
        /// classes that extend this class.
        /// </summary>
        /// <param name="astronomicalCalendar">Used to calculate day of year.</param>
        /// <param name="zenith">the azimuth below the vertical zenith of 90 degrees. for
        /// sunrise typically the <see cref="AstronomicalCalculator.AdjustZenith">zenith</see> used for
        /// the calculation uses geometric zenith of 90°; and
        /// <see cref="AstronomicalCalculator.AdjustZenith">adjusts</see> this slightly to account for
        /// solar refraction and the sun's radius. Another example would
        /// be <see cref="AstronomicalCalendar.GetBeginNauticalTwilight"/>
        /// that passes <see cref="AstronomicalCalendar.NAUTICAL_ZENITH"/> to
        /// this method.</param>
        /// <param name="adjustForElevation">if set to <c>true</c> [adjust for elevation].</param>
        /// <returns>
        /// The UTC time of sunrise in 24 hour format. 5:45:00 AM will return
        /// 5.75.0. If an error was encountered in the calculation (expected
        /// behavior for some locations such as near the poles,
        /// <see cref="Double.NaN"/> will be returned.
        /// </returns>
        /// <seealso cref="AstronomicalCalculator.GetUtcSunrise"/>
        public override double GetUtcSunrise(IAstronomicalCalendar astronomicalCalendar, double zenith,
                                             bool adjustForElevation)
        {
            double doubleTime = double.NaN;

            if (adjustForElevation)
            {
                zenith = AdjustZenith(zenith, astronomicalCalendar.DateWithLocation.Location.Elevation);
            }
            else
            {
                zenith = AdjustZenith(zenith, 0);
            }
            doubleTime = GetTimeUtc(astronomicalCalendar.DateWithLocation.Date.Year,
                                    astronomicalCalendar.DateWithLocation.Date.Month,
                                    astronomicalCalendar.DateWithLocation.Date.Day,
                                    astronomicalCalendar.DateWithLocation.Location.Longitude,
                                    astronomicalCalendar.DateWithLocation.Location.Latitude, zenith, TYPE_SUNRISE);
            return(doubleTime);
        }
Exemplo n.º 2
0
        /// <summary>
        /// A method that calculates UTC sunrise as well as any time based on an
        /// angle above or below sunrise. This abstract method is implemented by the
        /// classes that extend this class.
        /// </summary>
        /// <param name="astronomicalCalendar">Used to calculate day of year.</param>
        /// <param name="zenith">the azimuth below the vertical zenith of 90 degrees. for
        /// sunrise typically the <see cref="AstronomicalCalculator.AdjustZenith">zenith</see> used for
        /// the calculation uses geometric zenith of 90°; and
        /// <see cref="AstronomicalCalculator.AdjustZenith">adjusts</see> this slightly to account for
        /// solar refraction and the sun's radius. Another example would
        /// be <see cref="AstronomicalCalendar.GetBeginNauticalTwilight"/>
        /// that passes <see cref="AstronomicalCalendar.NAUTICAL_ZENITH"/> to
        /// this method.</param>
        /// <param name="adjustForElevation">if set to <c>true</c> [adjust for elevation].</param>
        /// <returns>
        /// The UTC time of sunrise in 24 hour format. 5:45:00 AM will return
        /// 5.75.0. If an error was encountered in the calculation (expected
        /// behavior for some locations such as near the poles,
        /// <see cref="Double.NaN"/> will be returned.
        /// </returns>
        /// <seealso cref="AstronomicalCalculator.GetUtcSunrise"/>
        public override double GetUtcSunrise(IAstronomicalCalendar astronomicalCalendar, double zenith,
                                             bool adjustForElevation)
        {
            //		if (astronomicalCalendar.getCalendar().get(Calendar.YEAR) <= 2000) {
            //			throw new ZmanimException(
            //					"NOAACalculator can not calculate times earlier than the year 2000.	Please try a date with a different year.");
            //		}

            if (adjustForElevation)
            {
                zenith = AdjustZenith(zenith, astronomicalCalendar.DateWithLocation.Location.Elevation);
            }
            else
            {
                zenith = AdjustZenith(zenith, 0);
            }

            double sunRise = CalcSunriseUtc(CalcJd(astronomicalCalendar.DateWithLocation),
                                            astronomicalCalendar.DateWithLocation.Location.Latitude,
                                            -astronomicalCalendar.DateWithLocation.Location.Longitude, zenith);
            return sunRise / 60;
        }
Exemplo n.º 3
0
        public override double GetUtcSunrise(IAstronomicalCalendar astronomicalCalendar, double zenith,
                                             bool adjustForElevation)
        {
            //		if (astronomicalCalendar.getCalendar().get(Calendar.YEAR) == 2000) {
            //			throw new ZmanimException(
            //					"JSuntimeCalculator can not calculate times for the year 2000. Please try a date with a different year.");
            //		}

            if (adjustForElevation)
            {
                zenith = AdjustZenith(zenith, astronomicalCalendar.DateWithLocation.Location.Elevation);
            }
            else
            {
                zenith = AdjustZenith(zenith, 0);
            }
            double timeMins = MorningPhenomenon(DateToJulian(astronomicalCalendar.DateWithLocation),
                                                astronomicalCalendar.DateWithLocation.Location.Latitude,
                                                -astronomicalCalendar.DateWithLocation.Location.Longitude, zenith);

            return(timeMins / 60);
        }
Exemplo n.º 4
0
        /// <summary>
        /// A method that calculates UTC sunrise as well as any time based on an
        /// angle above or below sunrise. This abstract method is implemented by the
        /// classes that extend this class.
        /// </summary>
        /// <param name="astronomicalCalendar">Used to calculate day of year.</param>
        /// <param name="zenith">the azimuth below the vertical zenith of 90 degrees. for
        /// sunrise typically the <see cref="AstronomicalCalculator.AdjustZenith">zenith</see> used for
        /// the calculation uses geometric zenith of 90°; and
        /// <see cref="AstronomicalCalculator.AdjustZenith">adjusts</see> this slightly to account for
        /// solar refraction and the sun's radius. Another example would
        /// be <see cref="AstronomicalCalendar.GetBeginNauticalTwilight"/>
        /// that passes <see cref="AstronomicalCalendar.NAUTICAL_ZENITH"/> to
        /// this method.</param>
        /// <param name="adjustForElevation">if set to <c>true</c> [adjust for elevation].</param>
        /// <returns>
        /// The UTC time of sunrise in 24 hour format. 5:45:00 AM will return
        /// 5.75.0. If an error was encountered in the calculation (expected
        /// behavior for some locations such as near the poles,
        /// <see cref="Double.NaN"/> will be returned.
        /// </returns>
        /// <seealso cref="AstronomicalCalculator.GetUtcSunrise"/>
        public override double GetUtcSunrise(IAstronomicalCalendar astronomicalCalendar, double zenith,
                                             bool adjustForElevation)
        {
            //		if (astronomicalCalendar.getCalendar().get(Calendar.YEAR) <= 2000) {
            //			throw new ZmanimException(
            //					"NOAACalculator can not calculate times earlier than the year 2000.	Please try a date with a different year.");
            //		}

            if (adjustForElevation)
            {
                zenith = AdjustZenith(zenith, astronomicalCalendar.DateWithLocation.Location.Elevation);
            }
            else
            {
                zenith = AdjustZenith(zenith, 0);
            }

            double sunRise = CalcSunriseUtc(CalcJd(astronomicalCalendar.DateWithLocation),
                                            astronomicalCalendar.DateWithLocation.Location.Latitude,
                                            -astronomicalCalendar.DateWithLocation.Location.Longitude, zenith);

            return(sunRise / 60);
        }
Exemplo n.º 5
0
        /// <summary>
        /// A method that calculates UTC sunrise as well as any time based on an
        /// angle above or below sunrise. This abstract method is implemented by the
        /// classes that extend this class.
        /// </summary>
        /// <param name="astronomicalCalendar">Used to calculate day of year.</param>
        /// <param name="zenith">the azimuth below the vertical zenith of 90 degrees. for
        /// sunrise typically the <see cref="AstronomicalCalculator.AdjustZenith">zenith</see> used for
        /// the calculation uses geometric zenith of 90°; and
        /// <see cref="AstronomicalCalculator.AdjustZenith">adjusts</see> this slightly to account for
        /// solar refraction and the sun's radius. Another example would
        /// be <see cref="AstronomicalCalendar.GetBeginNauticalTwilight"/>
        /// that passes <see cref="AstronomicalCalendar.NAUTICAL_ZENITH"/> to
        /// this method.</param>
        /// <param name="adjustForElevation">if set to <c>true</c> [adjust for elevation].</param>
        /// <returns>
        /// The UTC time of sunrise in 24 hour format. 5:45:00 AM will return
        /// 5.75.0. If an error was encountered in the calculation (expected
        /// behavior for some locations such as near the poles,
        /// <see cref="Double.NaN"/> will be returned.
        /// </returns>
        /// <seealso cref="AstronomicalCalculator.GetUtcSunrise"/>
        public override double GetUtcSunrise(IAstronomicalCalendar astronomicalCalendar, double zenith,
                                             bool adjustForElevation)
        {
            double doubleTime = double.NaN;

            if (adjustForElevation)
            {
                zenith = AdjustZenith(zenith, astronomicalCalendar.DateWithLocation.Location.Elevation);
            }
            else
            {
                zenith = AdjustZenith(zenith, 0);
            }
            doubleTime = GetTimeUtc(astronomicalCalendar.DateWithLocation.Date.Year,
                                    astronomicalCalendar.DateWithLocation.Date.Month,
                                    astronomicalCalendar.DateWithLocation.Date.Day,
                                    astronomicalCalendar.DateWithLocation.Location.Longitude,
                                    astronomicalCalendar.DateWithLocation.Location.Latitude, zenith, TYPE_SUNRISE);
            return doubleTime;
        }
Exemplo n.º 6
0
 /// <summary>
 /// A method that calculates UTC sunset as well as any time based on an angle
 /// above or below sunset. This abstract method is implemented by the classes
 /// that extend this class.
 /// </summary>
 /// <param name="astronomicalCalendar">Used to calculate day of year.</param>
 /// <param name="zenith">the azimuth below the vertical zenith of 90°;. For sunset
 /// typically the <see cref="AstronomicalCalculator.AdjustZenith">zenith</see> used for the
 /// calculation uses geometric zenith of 90°; and
 /// <see cref="AstronomicalCalculator.AdjustZenith">adjusts</see> this slightly to account for
 /// solar refraction and the sun's radius. Another example would
 /// be <see cref="AstronomicalCalendar.GetEndNauticalTwilight"/> that
 /// passes <see cref="AstronomicalCalendar.NAUTICAL_ZENITH"/> to this
 /// method.</param>
 /// <param name="adjustForElevation">if set to <c>true</c> [adjust for elevation].</param>
 /// <returns>
 /// The UTC time of sunset in 24 hour format. 5:45:00 AM will return
 /// 5.75.0. If an error was encountered in the calculation (expected
 /// behavior for some locations such as near the poles,
 /// <seealso cref="Double.NaN"/> will be returned.
 /// </returns>
 public abstract double GetUtcSunset(IAstronomicalCalendar astronomicalCalendar, double zenith, bool adjustForElevation);
Exemplo n.º 7
0
 /// <summary>
 /// A method that calculates UTC sunset as well as any time based on an angle
 /// above or below sunset. This abstract method is implemented by the classes
 /// that extend this class.
 /// </summary>
 /// <param name="astronomicalCalendar">Used to calculate day of year.</param>
 /// <param name="zenith">the azimuth below the vertical zenith of 90°;. For sunset
 /// typically the <see cref="AstronomicalCalculator.AdjustZenith">zenith</see> used for the
 /// calculation uses geometric zenith of 90°; and
 /// <see cref="AstronomicalCalculator.AdjustZenith">adjusts</see> this slightly to account for
 /// solar refraction and the sun's radius. Another example would
 /// be <see cref="AstronomicalCalendar.GetEndNauticalTwilight"/> that
 /// passes <see cref="AstronomicalCalendar.NAUTICAL_ZENITH"/> to this
 /// method.</param>
 /// <param name="adjustForElevation">if set to <c>true</c> [adjust for elevation].</param>
 /// <returns>
 /// The UTC time of sunset in 24 hour format. 5:45:00 AM will return
 /// 5.75.0. If an error was encountered in the calculation (expected
 /// behavior for some locations such as near the poles,
 /// <seealso cref="Double.NaN"/> will be returned.
 /// </returns>
 public abstract double GetUtcSunset(IAstronomicalCalendar astronomicalCalendar, double zenith, bool adjustForElevation);
Exemplo n.º 8
0
        public override double GetUtcSunrise(IAstronomicalCalendar astronomicalCalendar, double zenith,
                                             bool adjustForElevation)
        {
            //		if (astronomicalCalendar.getCalendar().get(Calendar.YEAR) == 2000) {
            //			throw new ZmanimException(
            //					"JSuntimeCalculator can not calculate times for the year 2000. Please try a date with a different year.");
            //		}

            if (adjustForElevation)
            {
                zenith = AdjustZenith(zenith, astronomicalCalendar.DateWithLocation.Location.Elevation);
            }
            else
            {
                zenith = AdjustZenith(zenith, 0);
            }
            double timeMins = MorningPhenomenon(DateToJulian(astronomicalCalendar.DateWithLocation),
                                                astronomicalCalendar.DateWithLocation.Location.Latitude,
                                                -astronomicalCalendar.DateWithLocation.Location.Longitude, zenith);
            return timeMins/60;
        }
Exemplo n.º 9
0
        /// <summary>
        /// A method that calculates UTC sunrise as well as any time based on an
        /// angle above or below sunrise. This abstract method is implemented by the
        /// classes that extend this class.
        /// </summary>
        /// <param name="astronomicalCalendar">Used to calculate day of year.</param>
        /// <param name="zenith">the azimuth below the vertical zenith of 90 degrees. for
        /// sunrise typically the <see cref="AstronomicalCalculator.AdjustZenith">zenith</see> used for
        /// the calculation uses geometric zenith of 90°; and
        /// <see cref="AstronomicalCalculator.AdjustZenith">adjusts</see> this slightly to account for
        /// solar refraction and the sun's radius. Another example would
        /// be <see cref="AstronomicalCalendar.GetBeginNauticalTwilight"/>
        /// that passes <see cref="AstronomicalCalendar.NAUTICAL_ZENITH"/> to
        /// this method.</param>
        /// <param name="adjustForElevation"></param>
        /// <returns>
        /// The UTC time of sunrise in 24 hour format. 5:45:00 AM will return
        /// 5.75.0. If an error was encountered in the calculation (expected
        /// behavior for some locations such as near the poles,
        /// <see cref="Double.NaN"/> will be returned.
        /// </returns>
        public override double GetUtcSunrise(IAstronomicalCalendar astronomicalCalendar, double zenith,
                                             bool adjustForElevation)
        {
            // zenith = adjustZenithForElevation(astronomicalCalendar, zenith,
            // geoLocation.getElevation());
            // double elevationAdjustment = this.getElevationAdjustment(zenith,
            // geoLocation.getElevation());
            // double refractionAdjustment = this.getRefraction(zenith);
            // zenith = zenith + elevationAdjustment + refractionAdjustment;
            if (adjustForElevation)
            {
                zenith = AdjustZenith(zenith, astronomicalCalendar.DateWithLocation.Location.Elevation);
            }
            else
            {
                zenith = AdjustZenith(zenith, 0);
            }


            // step 1: First calculate the day of the year
            // NOT NEEDED in this implementation

            // step 2: convert the longitude to hour value and calculate an
            // approximate time
            double lngHour = astronomicalCalendar.DateWithLocation.Location.Longitude / 15;

            double t = astronomicalCalendar.DateWithLocation.Date.DayOfYear + ((6 - lngHour) / 24); // use 18 for
            // sunset instead
            // of 6

            // step 3: calculate the sun's mean anomaly
            double m = (0.9856 * t) - 3.289;

            // step 4: calculate the sun's true longitude
            double l = m + (1.916 * Math.Sin(MathExtensions.ToRadians(m))) + (0.020 * Math.Sin(MathExtensions.ToRadians(2 * m))) +
                       282.634;

            while (l < 0)
            {
                double Lx = l + 360;
                l = Lx;
            }
            while (l >= 360)
            {
                double Lx = l - 360;
                l = Lx;
            }

            // step 5a: calculate the sun's right ascension
            double RA = MathExtensions.ToDegree(Math.Atan(0.91764 * Math.Tan(MathExtensions.ToRadians(l))));

            while (RA < 0)
            {
                double RAx = RA + 360;
                RA = RAx;
            }
            while (RA >= 360)
            {
                double RAx = RA - 360;
                RA = RAx;
            }

            // step 5b: right ascension value needs to be in the same quadrant as L
            double lQuadrant  = Math.Floor(l / 90) * 90;
            double raQuadrant = Math.Floor(RA / 90) * 90;

            RA = RA + (lQuadrant - raQuadrant);

            // step 5c: right ascension value needs to be converted into hours
            RA /= 15;

            // step 6: calculate the sun's declination
            double sinDec = 0.39782 * Math.Sin(MathExtensions.ToRadians(l));
            double cosDec = Math.Cos(Math.Asin(sinDec));

            // step 7a: calculate the sun's local hour angle
            double cosH = (Math.Cos(MathExtensions.ToRadians(zenith)) -
                           (sinDec * Math.Sin(MathExtensions.ToRadians(astronomicalCalendar.DateWithLocation.Location.Latitude)))) /
                          (cosDec * Math.Cos(MathExtensions.ToRadians(astronomicalCalendar.DateWithLocation.Location.Latitude)));

            // the following line would throw an Exception if the sun never rose.
            // this is not needed since the calculation will return a Double.NaN
            // if (cosH > 1) throw new Exception("doesnthappen");

            // FOR SUNSET use the following instead of the above if statement.
            // if (cosH < -1)

            // step 7b: finish calculating H and convert into hours
            double H = 360 - MathExtensions.ToDegree(Math.Acos(cosH));

            // FOR SUNSET remove "360 - " from the above

            H = H / 15;

            // step 8: calculate local mean time

            double T = H + RA - (0.06571 * t) - 6.622;

            // step 9: convert to UTC
            double UT = T - lngHour;

            while (UT < 0)
            {
                double UTx = UT + 24;
                UT = UTx;
            }
            while (UT >= 24)
            {
                double UTx = UT - 24;
                UT = UTx;
            }
            return(UT);
        }
Exemplo n.º 10
0
        /// <summary>
        /// A method that calculates UTC sunset as well as any time based on an angle
        /// above or below sunset. This abstract method is implemented by the classes
        /// that extend this class.
        /// </summary>
        /// <param name="astronomicalCalendar">Used to calculate day of year.</param>
        /// <param name="zenith">the azimuth below the vertical zenith of 90°;. For sunset
        /// typically the <see cref="AstronomicalCalculator.AdjustZenith">zenith</see> used for the
        /// calculation uses geometric zenith of 90°; and
        /// <see cref="AstronomicalCalculator.AdjustZenith">adjusts</see> this slightly to account for
        /// solar refraction and the sun's radius. Another example would
        /// be <see cref="AstronomicalCalendar.GetEndNauticalTwilight"/> that
        /// passes <see cref="AstronomicalCalendar.NAUTICAL_ZENITH"/> to this
        /// method.</param>
        /// <param name="adjustForElevation"></param>
        /// <returns>
        /// The UTC time of sunset in 24 hour format. 5:45:00 AM will return
        /// 5.75.0. If an error was encountered in the calculation (expected
        /// behavior for some locations such as near the poles,
        /// <seealso cref="Double.NaN"/> will be returned.
        /// </returns>
        public override double GetUtcSunset(IAstronomicalCalendar astronomicalCalendar, double zenith,
                                            bool adjustForElevation)
        {
            // zenith = adjustZenithForElevation(astronomicalCalendar, zenith,
            // geoLocation.getElevation());
            // double elevationAdjustment = this.getElevationAdjustment(zenith,
            // geoLocation.getElevation());
            // double refractionAdjustment = this.getRefraction(zenith);
            // zenith = zenith + elevationAdjustment + refractionAdjustment;

            if (adjustForElevation)
            {
                zenith = AdjustZenith(zenith, astronomicalCalendar.DateWithLocation.Location.Elevation);
            }
            else
            {
                zenith = AdjustZenith(zenith, 0);
            }

            // step 1: First calculate the day of the year
            // int calendarDayOfYear = calelendar.DAY_OF_YEAR;

            // int N=theday - date(1,1,theday.year()) + 1;
            int N = astronomicalCalendar.DateWithLocation.Date.DayOfYear;

            // step 2: convert the longitude to hour value and calculate an
            // approximate time
            double lngHour = astronomicalCalendar.DateWithLocation.Location.Longitude / 15;

            double t = N + ((18 - lngHour) / 24);

            // step 3: calculate the sun's mean anomaly
            double M = (0.9856 * t) - 3.289;

            // step 4: calculate the sun's true longitude
            double L = M + (1.916 * Math.Sin(MathExtensions.ToRadians(M))) + (0.020 * Math.Sin(MathExtensions.ToRadians(2 * M))) +
                       282.634;

            while (L < 0)
            {
                double Lx = L + 360;
                L = Lx;
            }
            while (L >= 360)
            {
                double Lx = L - 360;
                L = Lx;
            }

            // step 5a: calculate the sun's right ascension
            double RA = MathExtensions.ToDegree(Math.Atan(0.91764 * Math.Tan(MathExtensions.ToRadians(L))));

            while (RA < 0)
            {
                double RAx = RA + 360;
                RA = RAx;
            }
            while (RA >= 360)
            {
                double RAx = RA - 360;
                RA = RAx;
            }

            // step 5b: right ascension value needs to be in the same quadrant as L
            double Lquadrant  = Math.Floor(L / 90) * 90;
            double RAquadrant = Math.Floor(RA / 90) * 90;

            RA = RA + (Lquadrant - RAquadrant);

            // step 5c: right ascension value needs to be converted into hours
            RA /= 15;

            // step 6: calculate the sun's declination
            double sinDec = 0.39782 * Math.Sin(MathExtensions.ToRadians(L));
            double cosDec = Math.Cos(Math.Asin(sinDec));

            // step 7a: calculate the sun's local hour angle
            double cosH = (Math.Cos(MathExtensions.ToRadians(zenith)) -
                           (sinDec * Math.Sin(MathExtensions.ToRadians(astronomicalCalendar.DateWithLocation.Location.Latitude)))) /
                          (cosDec * Math.Cos(MathExtensions.ToRadians(astronomicalCalendar.DateWithLocation.Location.Latitude)));

            // the following line would throw an Exception if the sun never set.
            // this is not needed since the calculation will return a Double.NaN
            // if (cosH < -1) throw new ZmanimException("doesnthappen");

            // step 7b: finish calculating H and convert into hours
            double H = MathExtensions.ToDegree(Math.Acos(cosH));

            H = H / 15;

            // step 8: calculate local mean time

            double T = H + RA - (0.06571 * t) - 6.622;

            // step 9: convert to UTC
            double UT = T - lngHour;

            while (UT < 0)
            {
                double UTx = UT + 24;
                UT = UTx;
            }
            while (UT >= 24)
            {
                double UTx = UT - 24;
                UT = UTx;
            }
            return(UT);
        }