public static double helio_jd(double date, double ra, double dec) { double radeg = 180.0 / Math.PI; Precess.Correct(ref ra, ref dec, 2000.0, 1950.0); double delta_t = (date - 33282.42345905) / 36525.0; double epsilon_sec = 44.836 - 46.8495 * delta_t - 0.00429 * delta_t * delta_t + 0.00181 * delta_t * delta_t * delta_t; double epsilon = (23.433333 + epsilon_sec / 3600.0) / radeg; double ra1 = ra / radeg; double dec1 = dec / radeg; double x = 0, y = 0, z = 0; XYZ(date, ref x, ref y, ref z); //Find extra distance light must travel in AU, multiply by 1.49598e13 cm/AU, //and divide by the speed of light, and multiply by 86400 second/year double time = -499.00522 * (Math.Cos(dec1) * Math.Cos(ra1) * x + (Math.Tan(epsilon) * Math.Sin(dec1) + Math.Cos(dec1) * Math.Sin(ra1)) * y); return(date + time / 86400.0); }
static void Main(string[] args) { Console.Beep(); Console.ForegroundColor = ConsoleColor.Yellow; Console.WriteLine("*******************************************************"); Console.WriteLine("* RTT-150 CES *"); Console.WriteLine("* SPECTRA REDUCTION PIPELINE *"); Console.WriteLine("*******************************************************"); Console.ForegroundColor = ConsoleColor.White; //InitFile.ReadInitFile("INIT.dat"); Init.Initialize("INIT.dat"); if (Init.ErrorString != "") { Console.WriteLine("Error in INIT file!"); Console.WriteLine(Init.ErrorString); goto STOP; } string dir_main = (string)Init.Value("DIR_MAIN"); if (!Directory.Exists(dir_main)) { try { Directory.CreateDirectory(dir_main); } catch { Console.WriteLine("Cannot create main directory.\r\n"); goto STOP; } } string[] bias_files = null, flat_files = null, thar_files = null, obj_files = null; Console.WriteLine("Searching for Bias, Flat, ThAr and Object files..."); try { bias_files = ImageSelector.GetFilesByHDU( (string)Init.Value("DIR_BIAS"), (string)Init.Value("FMASK_BIAS"), "imagetyp", "*"); flat_files = ImageSelector.GetFilesByHDU( (string)Init.Value("DIR_FLAT"), (string)Init.Value("FMASK_FLAT"), "imagetyp", "*"); thar_files = ImageSelector.GetFilesByHDU( (string)Init.Value("DIR_CLBR"), (string)Init.Value("FMASK_CLBR"), "imagetyp", "*"); obj_files = ImageSelector.GetFilesByHDU( (string)Init.Value("DIR_OBJ"), (string)Init.Value("FMASK_OBJ"), "imagetyp", "*"); } catch { Console.WriteLine("Error in files searching..."); goto STOP; } Console.WriteLine("Bias files number: {0}", bias_files.Length); Console.WriteLine("Flat files number: {0}", flat_files.Length); Console.WriteLine("ThAr files number: {0}", thar_files.Length); Console.WriteLine("Object files number: {0}", obj_files.Length); if (bias_files.Length == 0 || flat_files.Length == 0 || thar_files.Length == 0 || obj_files.Length == 0) { Console.WriteLine("Some necessary files were not found..."); goto STOP; } Image[] biases = new Image[bias_files.Length]; Image[] flats = new Image[flat_files.Length]; Image[] thars = new Image[thar_files.Length]; Image[] objects = new Image[obj_files.Length]; Console.WriteLine("Loading Bias images..."); for (int i = 0; i < bias_files.Length; i++) { Console.WriteLine("->" + bias_files[i]); biases[i] = new Image(); biases[i].LoadImage(bias_files[i]); } Console.WriteLine("Bias images averaging..."); Image bias_aver = ImageCombinator.Median(biases); for (int i = 0; i < bias_files.Length; i++) { biases[i] = null; } Console.WriteLine("Loading Flat images..."); for (int i = 0; i < flat_files.Length; i++) { Console.WriteLine("->" + flat_files[i]); flats[i] = new Image(); flats[i].LoadImage(flat_files[i]); } Console.WriteLine("Flat images averaging..."); Image flat_aver = ImageCombinator.Median(flats); for (int i = 0; i < flat_files.Length; i++) { flats[i] = null; } Console.WriteLine("Loading Th-Ar images..."); for (int i = 0; i < thar_files.Length; i++) { Console.WriteLine("->" + thar_files[i]); thars[i] = new Image(); thars[i].LoadImage(thar_files[i]); } Console.WriteLine("ThAr images averaging..."); Image Thar_aver = ImageCombinator.Median(thars); for (int i = 0; i < thar_files.Length; i++) { thars[i] = null; } Console.WriteLine("Bias substraction from averanged Flat image..."); Image flat_aver_db = flat_aver - bias_aver; Console.WriteLine("Bias substraction from averanged ThAr image..."); Image Thar_aver_db = Thar_aver - bias_aver; Console.WriteLine("Replasing pixels values:\r\n negative -> 1 for flat;\r\n negative -> 0 for Th-Ar;"); for (int i = 0; i < flat_aver_db.NAXIS1; i++) { for (int j = 0; j < flat_aver_db.NAXIS2; j++) { if (flat_aver_db[i, j] <= 0) { flat_aver_db[i, j] = 1; } if (Thar_aver_db[i, j] < 0) { Thar_aver_db[i, j] = 0; } } } Console.WriteLine("Search for order locations..."); int polinim_degree_order = 3; Locator.Locate(ref flat_aver_db, polinim_degree_order); double[][] pos_ord = Locator.Ord_Pos; double[][] pos_min = Locator.Min_Pos; double[][] fluxes; Console.WriteLine("Extraction of the flat spectra..."); Extractor.Extract(flat_aver_db, pos_ord, pos_min, -1); fluxes = Extractor.FluxDebiased; Saver.SaveOrderedDistribution(fluxes, dir_main + "\\Flat_Orders.dat"); // Flat spectra normalization; Console.ForegroundColor = ConsoleColor.Yellow; Console.WriteLine("Flat spectra normalization..."); Console.ForegroundColor = ConsoleColor.White; Normator.Norm(fluxes, 12, 0, 13); Saver.SaveOrderedDistribution(Normator.OrdersNorm, dir_main + "\\Flat_Orders_Norm.dat"); Saver.SaveOrderedDistribution(Normator.FitCurves, dir_main + "\\Flat_Orders_Fit.dat"); // Th-Ar spectra extraction; Console.ForegroundColor = ConsoleColor.Yellow; Console.WriteLine("Extraction of the Th-Ar spectrum..."); Console.ForegroundColor = ConsoleColor.White; Extractor.Extract(Thar_aver_db, pos_ord, pos_min, -1); fluxes = Extractor.FluxDebiased; Saver.SaveOrderedDistribution(fluxes, dir_main + "\\thar_extacted.txt"); Saver.SaveOrderedDistribution(Extractor.Background, dir_main + "\\thar_bkg.dat"); Saver.SaveOrderedDistribution(Extractor.Flux, dir_main + "\\thar_flx_and_bkg.dat"); Saver.SaveOrderedDistribution(Extractor.fluxes_min0, dir_main + "\\Back.0.dat"); // Wavelength calibration; double[][] lambdas; Console.ForegroundColor = ConsoleColor.Yellow; Console.WriteLine("Wavelength calibration..."); Console.ForegroundColor = ConsoleColor.White; EcheData.LoadDispCurves("CalibrationCurves.dat"); //int oo = 9, ox = 5; //double cutLimit = 3, fluxLimit = 500; //int iterNum = 20; int oo = (int)Init.Value("WAVE_OO"); int ox = (int)Init.Value("WAVE_OX"); int iterNum = (int)Init.Value("WAVE_NINER"); double cutLimit = (double)Init.Value("WAVE_REJ"); double fluxLimit = 500; Console.WriteLine("OO = {0}; OX = {1}; Reject = {2}; IterNum = {3}; FluxLimit = {4}", oo, ox, cutLimit, iterNum, fluxLimit); WLCalibration.Calibrate(fluxes, oo, ox, cutLimit, iterNum, fluxLimit); lambdas = WLCalibration.Lambdas; Saver.SaveOrderedDistribution(lambdas, dir_main + "\\lambdas.dat"); // processing object images; Console.ForegroundColor = ConsoleColor.Yellow; Console.WriteLine("Processing object spectra..."); Console.ForegroundColor = ConsoleColor.White; // observatory coordinates and altitude reading; IIDType obs_lat = (IIDType)Init.Value("OBS_LAT"); IIDType obs_long = (IIDType)Init.Value("OBS_LONG"); double obs_alt = (double)Init.Value("OBS_ALT"); double obs_lat_deg = obs_lat.DH + obs_lat.MM / 60.0 + obs_lat.SS / 3600.0; double obs_long_deg = obs_long.DH + obs_long.MM / 60.0 + obs_long.SS / 3600.0; int time_zone = (int)Init.Value("TIME_ZONE"); string time_type = (string)Init.Value("TIME_TYPE"); string ra_str = (string)Init.Value("OBJ_RASTR"); string de_str = (string)Init.Value("OBJ_DESTR"); bool read_coord_fits = (bool)Init.Value("OBJ_INFITS"); IIDType ra = null, de = null; double ra_hh = 0, de_deg = 0; string time_str = (string)Init.Value("TIME_STR"); string date_str = (string)Init.Value("DATE_STR"); string expo_str = (string)Init.Value("EXPO_STR"); if (!read_coord_fits) { ra = (IIDType)Init.Value("OBJ_RA"); de = (IIDType)Init.Value("OBJ_DEC"); ra_hh = ra.DH + ra.MM / 60.0 + ra.SS / 3600.0; de_deg = ra.DH + ra.MM / 60.0 + ra.SS / 3600.0; } StreamWriter output = new StreamWriter(dir_main + "\\output.dat"); FITSHeaderReader fhr = new FITSHeaderReader(); Image object_image = null; for (int i = 0; i < obj_files.Length; i++) { // Lading object image; Console.WriteLine("Loading Object image {0}", obj_files[i]); object_image = new Image(); object_image.LoadImage(obj_files[i]); // Reading FITS-header data; if (read_coord_fits) { ra = fhr.ReadAsIID(obj_files[i], ra_str); de = fhr.ReadAsIID(obj_files[i], de_str); ra_hh = ra.DH + ra.MM / 60.0 + ra.SS / 3600.0; de_deg = ra.DH + ra.MM / 60.0 + ra.SS / 3600.0; } IIDType time = fhr.ReadAsIID(obj_files[i], time_str); IIDType date = fhr.ReadAsIID(obj_files[i], date_str); double exposure = fhr.ReadAsDouble(obj_files[i], expo_str); DateTime dt = new DateTime(date.DH, date.MM, (int)date.SS, time.DH, time.MM, (int)time.SS); if (time_type == "LT") { dt.AddHours(-(double)time_zone); } dt.AddSeconds(0.5 * exposure); // Calculate JD and HJD; double jd = DateConvertors.JDCnv(dt.Year, dt.Month, dt.Day, (double)dt.Hour + dt.Minute / 60.0 + dt.Second / 3600.0); double epoch = dt.Year + dt.Month / 12.0 + dt.Day / 365.0 + dt.Hour / (24 * 365.0) + dt.Minute / (24 * 365.0 * 60.0); Precess.Correct(ref ra_hh, ref de_deg, 2000.0, epoch); double hjd = DateConvertors.helio_jd(jd, ra_hh, de_deg); // Calculate components of observer motion to the object direction; double vdiurnal = 0, vbar = 0, vhel = 0, corr = 0; HelCorr.DoCorrection(obs_long_deg, obs_lat_deg, obs_alt, 360 - ra_hh, de_deg, jd, ref vdiurnal, ref vbar, ref vhel); corr = vdiurnal + vbar + vhel; // Bias substraction; Console.WriteLine("Bias substraction..."); object_image = object_image - bias_aver; for (int j = 0; j < object_image.NAXIS1; j++) { for (int k = 0; k < object_image.NAXIS2; k++) { if (object_image[j, k] < 0) { object_image[j, k] = 0; } } } // Image optimization; Smooth.DoSmooth(ref object_image); // Create directory for extracted spectra; string dirName = obj_files[i].Substring(0, obj_files[i].IndexOf(".fit")); int first = obj_files[i].LastIndexOf("\\"); int last = obj_files[i].IndexOf(".fit"); string fileName = dirName + "\\" + obj_files[i].Substring(first, last - first); Directory.CreateDirectory(dirName); // save object data; output.WriteLine("{0}\t{1}\t{2}\t{3}" + "\t{4:0.0000000}\t{5:0.0000000}\t{6:0.000}\t{7:0.000}\t{8:0.000}\t{9:0.000}", obj_files[i].Substring(first + 1), ra.ToString(), de.ToString(), dt.ToString(), jd, hjd, vdiurnal, vbar, vhel, corr); output.Flush(); Console.WriteLine("Extraction spectra from {0} ", obj_files[i]); Extractor.Extract(object_image, pos_ord, pos_min, -1); fluxes = Extractor.FluxDebiased; double[][] backgr = Extractor.Background; Saver.SaveOrderedDistribution(backgr, fileName + "_bkg.dat"); Saver.SaveOrderedDistribution(fluxes, fileName + "_x.dat"); for (int k = 0; k < fluxes.Length; k++) { for (int j = 0; j < fluxes[0].Length; j++) { fluxes[k][j] = fluxes[k][j] / Normator.OrdersNorm[k][j]; } } Saver.SaveOrderedDistribution(fluxes, fileName + "_x_n.dat"); for (int k = 0; k < fluxes.Length; k++) { StreamWriter sw = new StreamWriter(fileName + string.Format("_{0:000}", k) + ".dat"); for (int j = 0; j < fluxes[k].Length; j++) { sw.WriteLine( string.Format("{0:0000.0000}\t{1:0.00000E000}", lambdas[k][j], fluxes[k][j]).Replace(",", ".")); } sw.Close(); } } output.Close(); STOP: Console.ForegroundColor = ConsoleColor.Yellow; Console.WriteLine("End of the pipeline. Press any key to exit..."); Console.Beep(); Console.ReadKey(); }