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I am using this code for calculating sunrise and sunset times.

// Get the daylight status of the current time.
bool
SunLight::CalculateDaylightStatus()
{
   // Calculate the current time of day.
   time_t currentTime = time(NULL);
   m_LocalTime = localtime(&currentTime);

   // Initialize the sunrise and set times.
   *m_Sunrise = *m_LocalTime;
   *m_Sunset = *m_LocalTime;

   // Flags to check whether sunrise or set available on the day or not.
   m_IsSunrise = false;
   m_IsSunset = false;

   m_RiseAzimuth = 0.0;
   m_SetAzimuth = 0.0;

   for (unsigned int i = 0; i < 3; i++)
   {
      m_RightAscention[i] = 0.0;
      m_Decension[i] = 0.0;
      m_VHz[i] = 0.0;
   }

   for (unsigned int i = 0; i < 2; i++)
   {
      m_SunPositionInSky[i] = 0.0;
      m_RiseTime[i] = 0;
      m_SetTime[i] = 0;
   }

   // Calculate the sunrise and set times.
   CalculateSunRiseSetTimes();

   return (mktime(m_LocalTime) >= mktime(m_Sunrise) && mktime(m_LocalTime) < mktime(m_Sunset))
         ? true
         : false;
}
//---------------------------------------------------------------------

bool
SunLight::CalculateSunRiseSetTimes()
{
   double zone = timezone/3600 - m_LocalTime->tm_isdst;

   // Julian day relative to Jan 1.5, 2000.
   double jd = GetJulianDay() - 2451545;

   if ((Sign(zone) == Sign(m_Config->Longitude())) && (zone != 0))
   {
      return false;
   }

   double tz = zone / 24;

   // Centuries since 1900.0
   double ct = jd / 36525 + 1;

   // Local sidereal time.
   double t0 = LocalSiderealTimeForTimeZone(jd, tz, m_Config->Longitude()/360);

   // Get sun position at start of day.
   jd += tz;

   // Calculate the position of the sun.
   CalculateSunPosition(jd, ct);

   double ra0 = m_SunPositionInSky[0];
   double dec0 = m_SunPositionInSky[1];

   // Get sun position at end of day.
   jd += 1;

   // Calculate the position of the sun.
   CalculateSunPosition(jd, ct);

   double ra1 = m_SunPositionInSky[0];
   double dec1 = m_SunPositionInSky[1];

   // make continuous
   if (ra1 < ra0)
      ra1 += 2 * M_PI;

   m_RightAscention[0] = ra0;
   m_Decension[0] = dec0;

   // check each hour of this day
   for (int k = 0; k < 24; k++)
   {
      m_RightAscention[2] = ra0 + (k + 1) * (ra1 - ra0) / 24;
      m_Decension[2] = dec0 + (k + 1) * (dec1 - dec0) / 24;
      m_VHz[2] = TestHour(k, t0, m_Config->Latitude());

      // advance to next hour
      m_RightAscention[0] = m_RightAscention[2];
      m_Decension[0] = m_Decension[2];
      m_VHz[0] = m_VHz[2];
   }

   // Update the tm structure with time values.
   m_Sunrise->tm_hour = m_RiseTime[0];
   m_Sunrise->tm_min = m_RiseTime[1];

   m_Sunset->tm_hour = m_SetTime[0];
   m_Sunset->tm_min = m_SetTime[1];

   // neither sunrise nor sunset
   if ((!m_IsSunrise) && (!m_IsSunset))
   {
      // Sun down all day.
      if (m_VHz[2] < 0)
         m_IsSunset = true;

      // Sun up all day.
      else
         m_IsSunrise = true;
   }
   return true;
}
//---------------------------------------------------------------------

int
SunLight::Sign(double value)
{
   if (value > 0.0)
      return 1;
   else if (value < 0.0)
      return -1;
   else
      return 0;
}
//---------------------------------------------------------------------

// Local Sidereal Time for zone.
double
SunLight::LocalSiderealTimeForTimeZone(double jd, double z, double lon)
{
   double s = 24110.5 + 8640184.812999999 * jd / 36525 + 86636.6 * z + 86400 * lon;
   s = s / 86400;
   s = s - floor(s);
   return s * 360 * cDegToRad;
}
//---------------------------------------------------------------------

// Determine Julian day from calendar date
// (Jean Meeus, "Astronomical Algorithms", Willmann-Bell, 1991).
double
SunLight::GetJulianDay()
{
   int month = m_LocalTime->tm_mon + 1;
   int day = m_LocalTime->tm_mday;
   int year = 1900 + m_LocalTime->tm_year;

   bool gregorian = (year < 1583) ? false : true;

   if ((month == 1) || (month == 2))
   {
      year = year - 1;
      month = month + 12;
   }

   double a = floor((double)year / 100);
   double b = 0;

   if (gregorian)
      b = 2 - a + floor(a / 4);
   else
      b = 0.0;

   double jd = floor(365.25 * (year + 4716))
         + floor(30.6001 * (month + 1))
         + day + b - 1524.5;

   return jd;
}
//---------------------------------------------------------------------

// Sun's position using fundamental arguments
// (Van Flandern & Pulkkinen, 1979).
void
SunLight::CalculateSunPosition(double jd, double ct)
{
   double g, lo, s, u, v, w;

   lo = 0.779072 + 0.00273790931 * jd;
   lo = lo - floor(lo);
   lo = lo * 2 * M_PI;

   g = 0.993126 + 0.0027377785 * jd;
   g = g - floor(g);
   g = g * 2 * M_PI;

   v = 0.39785 * sin(lo);
   v = v - 0.01 * sin(lo - g);
   v = v + 0.00333 * sin(lo + g);
   v = v - 0.00021 * ct * sin(lo);

   u = 1 - 0.03349 * cos(g);
   u = u - 0.00014 * cos(2 * lo);
   u = u + 0.00008 * cos(lo);

   w = -0.0001 - 0.04129 * sin(2 * lo);
   w = w + 0.03211 * sin(g);
   w = w + 0.00104 * sin(2 * lo - g);
   w = w - 0.00035 * sin(2 * lo + g);
   w = w - 0.00008 * ct * sin(g);

   // compute sun's right ascension
   s = w / sqrt(u - v * v);
   m_SunPositionInSky[0] = lo + atan(s / sqrt(1 - s * s));

   // ...and declination
   s = v / sqrt(u);
   m_SunPositionInSky[1] = atan(s / sqrt(1 - s * s));
}
//---------------------------------------------------------------------

// Test an hour for an event.
double
SunLight::TestHour(int k, double t0, double prmLatitude)
{
   double ha[3];
   double a, b, c, d, e, s, z;
   double time;
   double az, dz, hz, nz;
   int hr, min;

   ha[0] = t0 - m_RightAscention[0] + k * cK1;
   ha[2] = t0 - m_RightAscention[2] + k * cK1 + cK1;

   ha[1] = (ha[2] + ha[0]) / 2;    // hour angle at half hour
   m_Decension[1] = (m_Decension[2] + m_Decension[0]) / 2;  // declination at half hour

   s = sin(prmLatitude * cDegToRad);
   c = cos(prmLatitude * cDegToRad);
   z = cos(90.833 * cDegToRad);    // refraction + sun semi-diameter at horizon

   if (k <= 0)
      m_VHz[0] = s * sin(m_Decension[0]) + c * cos(m_Decension[0]) * cos(ha[0]) - z;

   m_VHz[2] = s * sin(m_Decension[2]) + c * cos(m_Decension[2]) * cos(ha[2]) - z;

   if (Sign(m_VHz[0]) == Sign(m_VHz[2]))
      return m_VHz[2];  // no event this hour

   m_VHz[1] = s * sin(m_Decension[1]) + c * cos(m_Decension[1]) * cos(ha[1]) - z;

   a = 2 * m_VHz[0] - 4 * m_VHz[1] + 2 * m_VHz[2];
   b = -3 * m_VHz[0] + 4 * m_VHz[1] - m_VHz[2];
   d = b * b - 4 * a * m_VHz[0];

   if (d < 0)
      return m_VHz[2];  // no event this hour

   d = sqrt(d);
   e = (-b + d) / (2 * a);

   if ((e > 1) || (e < 0))
      e = (-b - d) / (2 * a);

   time = (double)k + e + (double)1 / (double)120; // time of an event

   hr = (int)floor(time);
   min = (int)floor((time - hr) * 60);

   hz = ha[0] + e * (ha[2] - ha[0]);                 // azimuth of the sun at the event
   nz = -cos(m_Decension[1]) * sin(hz);
   dz = c * sin(m_Decension[1]) - s * cos(m_Decension[1]) * cos(hz);
   az = atan2(nz, dz) / cDegToRad;
   if (az < 0) az = az + 360;

   if ((m_VHz[0] < 0) && (m_VHz[2] > 0))
   {
      m_RiseTime[0] = hr;
      m_RiseTime[1] = min;
      m_RiseAzimuth = az;
      m_IsSunrise = true;
   }

   if ((m_VHz[0] > 0) && (m_VHz[2] < 0))
   {
      m_SetTime[0] = hr;
      m_SetTime[1] = min;
      m_SetAzimuth = az;
      m_IsSunset = true;
   }

   return m_VHz[2];
}
//---------------------------------------------------------------------

I need to introduce altitude in the formula which gives more accurate result. Can someone give me a quick solution what I have to modify to add altitude in the formula?

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5  
Stack Overflow is not going to read all of that. Can you express your problem more compactly in mathematical form instead of as code? –  Li-aung Yip May 21 '12 at 7:51
    
As far as I understand, this is not programming related, despite the amount of code inculded in the question. –  mouviciel May 21 '12 at 15:36

1 Answer 1

That algorithm is nowhere near calculating the times of sunrise and sunset. What you need is Jean Meeus' book "Astronomical Algorithms". You will need to account for the observer's longitude and latitude, the difference between dynamical time and universal time, and the eccentricity of the Earth's orbit to obtain even a low accuracy result.

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You need to spell out "this" so that this answer will still be useful when the link goes dead. –  Mark Ransom May 21 '12 at 16:22
    
Done, thanks for the hint. –  Dabbler May 21 '12 at 16:25
    
@Dabbler Well, the algorithm is giving me the exact result and I have given the algorithm references. I have a requirement of calculating these times by considering the altitude as well. –  Dr. Kamrul Hasan May 22 '12 at 3:51

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