コード例 #1
0
def parse_eph(filenm):
    global period, time
    suffix = filenm.split(".")[-1]
    if suffix == "bestprof":
        x = bestprof.bestprof(filenm)
        fs = pu.p_to_f(x.p0_bary, x.p1_bary, x.p2_bary)
        epoch = x.epochi_bary + x.epochf_bary
        T = x.T
    elif suffix == "par":
        x = parfile.psr_par(filenm)
        # Try to see how many freq derivs we have
        fs = [x.F0]
        for ii in range(1, 20):  # hopefully 20 is an upper limit!
            attrib = "F%d" % ii
            if hasattr(x, attrib):
                fs.append(getattr(x, attrib))
            else:
                break
        epoch = x.PEPOCH
        T = (x.FINISH - x.START) * 86400.0
    else:
        print("I don't recognize the file type for", filenm)
        sys.exit()
    newts = epoch + num.arange(int(T / 10.0 + 0.5), dtype=num.float) / 8640.0
    time = num.concatenate((time, newts))
    newps = 1.0 / pu.calc_freq(newts, epoch, *fs)
    period = num.concatenate((period, newps))
    print("%13.7f (%0.1f sec): " % (epoch, T), fs)
コード例 #2
0
    def __init__(self, filename):
        self.pfd_filename = filename
        infile = open(filename, "rb")
        # See if the .bestprof file is around
        try:
            self.bestprof = bestprof(filename + ".bestprof")
        except IOError:
            self.bestprof = 0
        swapchar = '<'  # this is little-endian
        data = infile.read(5 * 4)
        testswap = struct.unpack(swapchar + "i" * 5, data)
        # This is a hack to try and test the endianness of the data.
        # None of the 5 values should be a large positive number.
        if (Num.fabs(Num.asarray(testswap))).max() > 100000:
            swapchar = '>'  # this is big-endian
        (self.numdms, self.numperiods, self.numpdots, self.nsub, self.npart) = \
                      struct.unpack(swapchar+"i"*5, data)
        (self.proflen, self.numchan, self.pstep, self.pdstep, self.dmstep, \
         self.ndmfact, self.npfact) = struct.unpack(swapchar+"i"*7, infile.read(7*4))

        self.filenm = infile.read(
            struct.unpack(swapchar + "i", infile.read(4))[0])
        self.candnm = infile.read(
            struct.unpack(swapchar + "i", infile.read(4))[0]).decode("utf-8")
        self.telescope = infile.read(
            struct.unpack(swapchar + "i", infile.read(4))[0]).decode("utf-8")
        self.pgdev = infile.read(
            struct.unpack(swapchar + "i", infile.read(4))[0])
        test = infile.read(16)
        if not test[:8] == b"Unknown" and b':' in test:
            self.rastr = test[:test.find(b'\0')]
            test = infile.read(16)
            self.decstr = test[:test.find(b'\0')]
        else:
            self.rastr = "Unknown"
            self.decstr = "Unknown"
            if ':' not in test:
                infile.seek(-16, 1)  # rewind the file before the bad read
        (self.dt, self.startT) = struct.unpack(swapchar + "dd",
                                               infile.read(2 * 8))
        (self.endT, self.tepoch, self.bepoch, self.avgvoverc, self.lofreq, \
         self.chan_wid, self.bestdm) = struct.unpack(swapchar+"d"*7, infile.read(7*8))
        # The following "fixes" (we think) the observing frequency of the Spigot
        # based on tests done by Ingrid on 0737 (comparing it to GASP)
        # The same sorts of corrections should be made to WAPP data as well...
        # The tepoch corrections are empirically determined timing corrections
        # Note that epoch is only double precision and so the floating
        # point accuracy is ~1 us!
        if self.telescope == 'GBT':
            if (Num.fabs(Num.fmod(self.dt, 8.192e-05) < 1e-12) and \
                ("spigot" in filename.lower() or "guppi" not in filename.lower()) and \
                (self.tepoch < 54832.0)):
                sys.stderr.write("Assuming SPIGOT data...\n")
                if self.chan_wid == 800.0 / 1024:  # Spigot 800 MHz mode 2
                    self.lofreq -= 0.5 * self.chan_wid
                    # original values
                    #if self.tepoch > 0.0: self.tepoch += 0.039334/86400.0
                    #if self.bestprof: self.bestprof.epochf += 0.039334/86400.0
                    # values measured with 1713+0747 wrt BCPM2 on 13 Sept 2007
                    if self.tepoch > 0.0: self.tepoch += 0.039365 / 86400.0
                    if self.bestprof:
                        self.bestprof.epochf += 0.039365 / 86400.0
                elif self.chan_wid == 800.0 / 2048:
                    self.lofreq -= 0.5 * self.chan_wid
                    if self.tepoch < 53700.0:  # Spigot 800 MHz mode 16 (downsampled)
                        if self.tepoch > 0.0: self.tepoch += 0.039352 / 86400.0
                        if self.bestprof:
                            self.bestprof.epochf += 0.039352 / 86400.0
                    else:  # Spigot 800 MHz mode 14
                        # values measured with 1713+0747 wrt BCPM2 on 13 Sept 2007
                        if self.tepoch > 0.0: self.tepoch += 0.039365 / 86400.0
                        if self.bestprof:
                            self.bestprof.epochf += 0.039365 / 86400.0
                elif self.chan_wid == 50.0 / 1024 or self.chan_wid == 50.0 / 2048:  # Spigot 50 MHz modes
                    self.lofreq += 0.5 * self.chan_wid
                    # Note: the offset has _not_ been measured for the 2048-lag mode
                    if self.tepoch > 0.0: self.tepoch += 0.039450 / 86400.0
                    if self.bestprof:
                        self.bestprof.epochf += 0.039450 / 86400.0
        (self.topo_pow, tmp) = struct.unpack(swapchar + "f" * 2,
                                             infile.read(2 * 4))
        (self.topo_p1, self.topo_p2, self.topo_p3) = struct.unpack(swapchar+"d"*3, \
                                                                   infile.read(3*8))
        (self.bary_pow, tmp) = struct.unpack(swapchar + "f" * 2,
                                             infile.read(2 * 4))
        (self.bary_p1, self.bary_p2, self.bary_p3) = struct.unpack(swapchar+"d"*3, \
                                                                   infile.read(3*8))
        (self.fold_pow, tmp) = struct.unpack(swapchar + "f" * 2,
                                             infile.read(2 * 4))
        (self.fold_p1, self.fold_p2, self.fold_p3) = struct.unpack(swapchar+"d"*3, \
                                                                   infile.read(3*8))
        # Save current p, pd, pdd
        # NOTE: Fold values are actually frequencies!
        self.curr_p1, self.curr_p2, self.curr_p3 = \
                psr_utils.p_to_f(self.fold_p1, self.fold_p2, self.fold_p3)
        self.pdelays_bins = Num.zeros(self.npart, dtype='d')
        (self.orb_p, self.orb_e, self.orb_x, self.orb_w, self.orb_t, self.orb_pd, \
         self.orb_wd) = struct.unpack(swapchar+"d"*7, infile.read(7*8))
        self.dms = Num.asarray(struct.unpack(swapchar+"d"*self.numdms, \
                                             infile.read(self.numdms*8)))
        if self.numdms == 1:
            self.dms = self.dms[0]
        self.periods = Num.asarray(struct.unpack(swapchar+"d"*self.numperiods, \
                                                 infile.read(self.numperiods*8)))
        self.pdots = Num.asarray(struct.unpack(swapchar+"d"*self.numpdots, \
                                               infile.read(self.numpdots*8)))
        self.numprofs = self.nsub * self.npart
        if (swapchar == '<'):  # little endian
            self.profs = Num.zeros((self.npart, self.nsub, self.proflen),
                                   dtype='d')
            for ii in range(self.npart):
                for jj in range(self.nsub):
                    self.profs[ii,
                               jj, :] = Num.fromfile(infile, Num.float64,
                                                     self.proflen)
        else:
            self.profs = Num.asarray(struct.unpack(swapchar+"d"*self.numprofs*self.proflen, \
                                                   infile.read(self.numprofs*self.proflen*8)))
            self.profs = Num.reshape(self.profs,
                                     (self.npart, self.nsub, self.proflen))
        if (self.numchan == 1):
            try:
                idata = infodata.infodata(
                    self.filenm[:self.filenm.rfind(b'.')] + b".inf")
                try:
                    if idata.waveband == "Radio":
                        self.bestdm = idata.DM
                        self.numchan = idata.numchan
                except:
                    self.bestdm = 0.0
                    self.numchan = 1
            except IOError:
                print("Warning!  Can't open the .inf file for " + filename +
                      "!")
        self.binspersec = self.fold_p1 * self.proflen
        self.chanpersub = self.numchan // self.nsub
        self.subdeltafreq = self.chan_wid * self.chanpersub
        self.hifreq = self.lofreq + (self.numchan - 1) * self.chan_wid
        self.losubfreq = self.lofreq + self.subdeltafreq - self.chan_wid
        self.subfreqs = Num.arange(self.nsub, dtype='d')*self.subdeltafreq + \
                        self.losubfreq
        self.subdelays_bins = Num.zeros(self.nsub, dtype='d')
        # Save current DM
        self.currdm = 0
        self.killed_subbands = []
        self.killed_intervals = []
        self.pts_per_fold = []
        # Note: a foldstats struct is read in as a group of 7 doubles
        # the correspond to, in order:
        #    numdata, data_avg, data_var, numprof, prof_avg, prof_var, redchi
        self.stats = Num.zeros((self.npart, self.nsub, 7), dtype='d')
        for ii in range(self.npart):
            currentstats = self.stats[ii]
            for jj in range(self.nsub):
                if (swapchar == '<'):  # little endian
                    currentstats[jj] = Num.fromfile(infile, Num.float64, 7)
                else:
                    currentstats[jj] = Num.asarray(struct.unpack(swapchar+"d"*7, \
                                                                 infile.read(7*8)))
            self.pts_per_fold.append(
                self.stats[ii][0][0])  # numdata from foldstats
        self.start_secs = Num.add.accumulate([0] +
                                             self.pts_per_fold[:-1]) * self.dt
        self.pts_per_fold = Num.asarray(self.pts_per_fold)
        self.mid_secs = self.start_secs + 0.5 * self.dt * self.pts_per_fold
        if (not self.tepoch == 0.0):
            self.start_topo_MJDs = self.start_secs / 86400.0 + self.tepoch
            self.mid_topo_MJDs = self.mid_secs / 86400.0 + self.tepoch
        if (not self.bepoch == 0.0):
            self.start_bary_MJDs = self.start_secs / 86400.0 + self.bepoch
            self.mid_bary_MJDs = self.mid_secs / 86400.0 + self.bepoch
        self.Nfolded = Num.add.reduce(self.pts_per_fold)
        self.T = self.Nfolded * self.dt
        self.avgprof = (self.profs / self.proflen).sum()
        self.varprof = self.calc_varprof()
        # nominal number of degrees of freedom for reduced chi^2 calculation
        self.DOFnom = float(self.proflen) - 1.0
        # corrected number of degrees of freedom due to inter-bin correlations
        self.dt_per_bin = self.curr_p1 / self.proflen / self.dt
        self.DOFcor = self.DOFnom * self.DOF_corr()
        infile.close()
        self.barysubfreqs = None
        if self.avgvoverc == 0:
            if self.candnm.startswith("PSR_"):
                # If this doesn't work, we should try to use the barycentering calcs
                # in the presto module.
                try:
                    psrname = self.candnm[4:]
                    self.polycos = polycos.polycos(psrname,
                                                   filenm=self.pfd_filename +
                                                   ".polycos")
                    midMJD = self.tepoch + 0.5 * self.T / 86400.0
                    self.avgvoverc = self.polycos.get_voverc(
                        int(midMJD), midMJD - int(midMJD))
                    #sys.stderr.write("Approximate Doppler velocity (in c) is:  %.4g\n"%self.avgvoverc)
                    # Make the Doppler correction
                    self.barysubfreqs = self.subfreqs * (1.0 + self.avgvoverc)
                except IOError:
                    self.polycos = 0
        if self.barysubfreqs is None:
            self.barysubfreqs = self.subfreqs
コード例 #3
0
    else:
        if sys.argv[1].endswith(".pfd"):
            print("Input is PFD")
            # Input is pfd file
            pfdfn = sys.argv[1]
            # Check for bestprof
            if not os.path.exists(pfdfn+".bestprof"):
                print("Creating bestprof file")
                # Create bestprof file with show_pfd
                devnull = open(os.devnull, 'w')
                subprocess.call(['show_pfd', '-noxwin', pfdfn], 
                                stdout=devnull)
                devnull.close()
            filenm = pfdfn+".bestprof"
        else:
            filenm = sys.argv[1]
        prof = read_profile(filenm, normalize=0)
        if len(sys.argv)>=3:
            noise_stdev = float(sys.argv[2])
        else:
            try:
                bprof = bestprof(sys.argv[1])
                noise_stdev = bprof.prof_std
            except:
                noise_stdev = 1.0
    fig = plt.figure()
    dataplot = fig.add_subplot(211)
    interactor = GaussianSelector(dataplot, prof, noise_stdev, filenm)
    plt.show()
    
コード例 #4
0
ファイル: fitorbit.py プロジェクト: gdesvignes/fitorbit
    def __init__(self, filenames, master=None, input_parfile=None):

        super().__init__(master)
        self.master = master

        self.data = Data()

        if filenames:
            suffix = '.bestprof'
            for fn in filenames:
                if fn.endswith(suffix):
                    prof = bestprof.bestprof(fn)
                    for minute in np.arange(int(prof.T / 60.0 + 0.5)):
                        t = minute * 60.
                        time = prof.epochi + prof.epochf + minute / 1440.0
                        period = prof.p0 + t * (prof.p1 + 0.5 * t * prof.p2)

                        self.data.add(time, period, ptype='s')

            try:
                mjds, periods, uncertainties = np.loadtxt(filenames[0],
                                                          usecols=(0, 1, 2),
                                                          unpack=True)
                self.data.set_mjd(mjds)
                self.data.set_period(periods)
                self.data.set_unc(uncertainties)
                #print (self.data.get_mjd(), self.data.get_period(), self.data.get_unc())
            except:
                print("Input format not recognized")
                raise

        # Variables Init
        self.ra_str = "00:00:00"
        self.dec_str = "+00:00:00"
        self.init_parameters()

        # Build Main window
        self.create_ui()

        self.draw_options()

        self.draw_param()

        self.set_entries()

        if input_parfile:
            self.read_parfile(input_parfile)
            self.set_entries()
            #if len(self.data.mjds):
            #    self.plot_model()

        # Add graphic box and display Label
        self.plot_orbital = False
        self.xlabel = "MJD"
        self.ylabel = "Period (ms)"
        self.fig = Figure(facecolor='white')
        #self.fig.canvas.mpl_connect('key_press_event', self.key_press_menu)
        self.master.bind('<KeyPress>', self.key_press_menu)
        self.master.bind('<Return>', self.onReturn)
        self.ax1 = self.fig.add_subplot(3, 1, (1, 2))
        self.ax2 = self.fig.add_subplot(3, 1, 3)
        self.ax1.format_coord = lambda x, y: ""
        self.ax2.format_coord = lambda x, y: ""

        ###########
        #left, width = 0.1, 0.8
        #rect1 = [left, 0.1, width, 0.7]
        #rect2 = [left, 0.8, width, 0.1]

        self.ax1.set_xlabel(self.xlabel)
        self.ax1.set_ylabel(self.ylabel)
        self.ax1.xaxis.set_major_formatter(ScalarFormatter(useOffset=False))
        self.ax1.yaxis.set_major_formatter(ScalarFormatter(useOffset=False))

        self.ax2.set_xlabel(self.xlabel)
        self.ax2.set_ylabel("Residuals (mP0)")
        self.ax2.xaxis.set_major_formatter(ScalarFormatter(useOffset=False))
        self.ax2.yaxis.set_major_formatter(ScalarFormatter(useOffset=False))

        self.canvas = FigureCanvas(self.fig, master=master)
        #self.canvas.grid(row=8)
        #self.canvas.draw()
        #self.box_param.pack_start(self.canvas, True, True, 0)

        # Add Toolbar box
        #toolbar = NavigationToolbar(self.canvas, self)
        #self.box_param.pack_start(toolbar, False, False)

        # plot
        #print ("Have Unc?", self.data.get_unc())
        if len(self.data.get_unc()):
            self.ax1.errorbar(self.data.get_mjd(),
                              self.data.get_period(),
                              yerr=self.data.get_unc(),
                              color='r',
                              fmt='o',
                              zorder=10)
        else:
            self.ax1.scatter(self.data.get_mjd(),
                             self.data.get_period(),
                             color='r',
                             s=20,
                             edgecolor='r',
                             marker='o',
                             zorder=10)

        self.canvas.get_tk_widget().grid(row=6,
                                         columnspan=6,
                                         sticky=N + S + E + W)

        toolbarFrame = Frame(master=root)
        toolbarFrame.grid(row=7, columnspan=6)
        toolbar = NavigationToolbar(self.canvas, toolbarFrame)

        self.connect()
        self.cidAx1 = self.ax1.callbacks.connect('xlim_changed',
                                                 self.on_xlims_change)
        #self.ax1.callbacks.connect('ylim_changed', self.on_ylims_change)
        self.cidAx2 = self.ax2.callbacks.connect('xlim_changed',
                                                 self.on_xlims_change)
        #self.ax2.callbacks.connect('ylim_changed', self.on_ylims_change)

        xmin, xmax = self.ax1.get_xlim()
        self.oxmin, self.oxmax = self.ax1.get_xlim()
        self.ax2.set_xlim(xmin, xmax)

        self.canvas.draw()