Exemplo n.º 1
0
def sgr_lam_split(stripes, params):
    # get lambda for stripes
    holder = []
    for i in range(len(stripes)):
        mu, r, theta, phi, wedge = eval(params[i][4]), eval(params[i][5]), \
            eval(params[i][6]), eval(params[i][7]), stripes[i]
        x, y, z = coor.stream2xyz(0.0, 0.0, 0.0, mu, r, theta * deg, phi * deg,
                                  wedge)
        Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(x, y, z)
        #if lam > 180.0: lam = lam - 360.0
        #lam = -lam
        print lam, beta, r, stripes[i]
        holder.append([lam, beta, r])
    Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(14.655646, 2.270431,
                                                  -5.887377)
    print lam, beta, r
    # get lambda range for northern Sgr  15 N stripes, 0-14 -> 9-23
    low_lam, high_lam = 200.0, 314.8  # from Sgr stripes: (200.025901082, 314.707561185)
    size = (high_lam - low_lam) / 15.0
    print "# - LAMBDA BIN SIZE: {0}".format(size)
    for h in range(15):
        array = []
        lam_min, lam_max = low_lam + (size * h), low_lam + (size * (h + 1))
        for i in range(15):
            if stripes[i] == 9: num = "09"
            else: num = str(stripes[i])
            name = "./sim_streams/sim_stripe_" + num + ".txt"
            Sgr = open(name, "r")
            for line in Sgr:
                if line.strip() == "": continue
                if line.strip()[0] == "#": continue
                l, b, r, f = line.strip().split()
                x, y, z = coor.lbr2xyz(float(l), float(b), float(r))
                Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(x, y, z)
                #if lam > high_lam:  high_lam = lam
                #if lam < low_lam:  low_lam = lam
                if lam > lam_min:
                    if lam <= lam_max:
                        array.append([lam, beta, r, eval(f)])
            Sgr.close()
            print "# - Stripe " + num + " successfully read in"
        fi.write_data(sc.array(array),
                      "lamsim_out_" + str(h) + ".txt",
                      header="Lambda {0}:{1}, lam, beta, r".format(
                          lam_min, lam_max))
    #print low_lam, high_lam
    # bin stripes in lambda, g
    # correct stripes for detection, FTO efficiencies
    # reflect stars about midpoint to correct for missing data on far end
    print "### --- Done"
Exemplo n.º 2
0
def sgr_density_south(stripes, params):
    out = []
    for i in range(15, 18):
        mu, r, theta, phi, wedge = eval(params[i][4]), eval(params[i][5]), \
            eval(params[i][6]), eval(params[i][7]), stripes[i]
        print mu, r, theta, phi
        x, y, z = coor.stream2xyz(0.0, 0.0, 0.0, mu, r, theta, phi, wedge)
        Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(x, y, z)
        print lam, beta, r, stripes[i]
        name = "./sep_lbr/s1-" + str(stripes[i]) + ".txt"
        data = fi.read_data(name, echo=1)
        wedge_norm = coor.stripe_normal(stripes[i])
        plane_norm = [
            0.03176573688051381, 0.98687684085235916, 0.15831942063343135
        ]
        stream_norm = [
            sc.cos(phi) * sc.sin(theta),
            sc.sin(phi) * sc.sin(theta),
            sc.cos(theta)
        ]
        print wedge_norm, stream_norm
        dotty = wedge_norm[0] * stream_norm[0] + wedge_norm[1] * stream_norm[
            1] + wedge_norm[2] * stream_norm[2]
        #dotty2 = plane_norm[0]*wedge_norm[0] + plane_norm[1]*stream_norm[1] + plane_norm[2]*stream_norm[2]
        if dotty > 1.0: print "!!!  Not a valid dot-product: {0}".format(dotty)
        H = abs(2.5 / dotty)
        #H2 = 2.5 / sc.sqrt(1 - (dotty2*dotty2))
        print "H = ", H, dotty, sc.arccos(dotty) * 180.0 / ma.pi  #, H2
        count, in_1, in_2 = 0, 0.0, 0.0
        lam_low, lam_high = 360.0, 0.0
        for j in range(len(data[:, 0])):
            l, b, r = data[j, 0], data[j, 1], data[j, 2]
            count = count + 1
            # Correct for completeness
            Deff = 1.0 / SDSS_eff(r)
            in_1 = in_1 + Deff
            in_2 = in_2 + Deff + 1.0 / TO_eff(r)
            x, y, z = coor.lbr2xyz(l, b, r)
            Xs, Ys, Zs, lam2, beta2, r2 = sl.law_xyz2sgr_sun(x, y, z)
            if lam2 < lam_low: lam_low = lam2
            if lam2 > lam_high: lam_high = lam2
        out.append([lam, count, in_1, in_2, in_2 / H])
        print "--- Lambda Range: {0}:{1}".format(lam_low, lam_high)
        print "###   Number of stars in stream:  {0}".format(count)
        print "###   Corrected for SDSS Eff.:    {0}".format(in_1)
        print "###   Corrected for SDSS/FTO Eff: {0}".format(in_2)
    for o in out:
        print o
    return sc.array(out)
Exemplo n.º 3
0
def show_lambda():
    data = fi.read_data("./sep_lbr/s1-79.txt")
    x, y, z = coor.lbr2xyz(data[:, 0], data[:, 1], data[:, 2])
    Xs, Ys, Zs, lam1, beta, r = sl.law_xyz2sgr_sun(x, y, z)
    data = fi.read_data("./sep_lbr/s1-82.txt")
    x, y, z = coor.lbr2xyz(data[:, 0], data[:, 1], data[:, 2])
    Xs, Ys, Zs, lam2, beta, r = sl.law_xyz2sgr_sun(x, y, z)
    data = fi.read_data("./sep_lbr/s1-86.txt")
    x, y, z = coor.lbr2xyz(data[:, 0], data[:, 1], data[:, 2])
    Xs, Ys, Zs, lam3, beta, r = sl.law_xyz2sgr_sun(x, y, z)
    plt.figure()
    plt.hist(lam3, 20)
    plt.hist(lam2, 20)
    plt.hist(lam1, 20)
    plt.show()
    plt.close('all')
Exemplo n.º 4
0
def sgr_sim_density(stripes, params):
    SGA = fi.read_data("../sgrnorth_paper/stream_gen_analysis.txt", ",")
    low_lam, high_lam = 200.0, 314.8  # from Sgr stripes: (200.025901082, 314.707561185)
    size = (high_lam - low_lam) / 15.0
    N_stars = [
        19386, 18734, 11096, 17044, 18736, 15409, 12519, 12248, 8853, 7328,
        5479, 4450, 3486, 2425, 971, 9511, 16119, 16603
    ]
    south = [79, 82, 86]
    out = []
    for i in range(15):
        print "# - Lambda wedge {0}:".format(i)
        num = str(i)
        name = "./sim_streams/lamsim_out_" + num + ".txt"
        data = fi.read_data(name, echo=1)
        total = len(data[:, 0])
        other = sc.sum(data[:, 3])
        length = 7.653333333  # bin size
        out.append([(low_lam + (size * i) + (size * 0.5)), total - other,
                    total, 0.0, total / length])
    for i in range(15, 18):
        print "# - Southern wedge {0}:".format(south[i - 15])
        data = fi.read_data("./sim_streams/sim_stripe_" + str(south[i - 15]) +
                            ".txt")
        total = len(data[:, 0])
        other = sc.sum(data[:, 3])
        length = SGA[i, 3]
        mu, r, theta, phi, wedge = eval(params[i][4]), eval(params[i][5]), \
            eval(params[i][6]), eval(params[i][7]), stripes[i]
        x, y, z = coor.stream2xyz(0.0, 0.0, 0.0, mu, r, theta, phi, wedge)
        Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(x, y, z)
        out.append([lam, total - other, total, 0.0, total / length])
    fi.write_data(sc.array(out), "sgrNorth_density_sim.txt", ",",
                  " lam(mid), count, SDSS Deff, SDSS/FTO Deff, per degree")
Exemplo n.º 5
0
def sgr_sim_density(stripes, params):
    SGA = fi.read_data("../sgrnorth_paper/stream_gen_analysis.txt", ",")
    low_lam, high_lam = 200.0, 314.8  # from Sgr stripes: (200.025901082, 314.707561185)
    size = (high_lam - low_lam) / 15.0
    N_stars = [19386, 18734, 11096, 17044, 18736, 15409, 12519, 12248, 8853, 7328,
               5479, 4450, 3486, 2425, 971, 9511, 16119, 16603]
    south = [79, 82, 86]
    out = []
    for i in range(15):
        print "# - Lambda wedge {0}:".format(i)
        num = str(i)
        name = "./sim_streams/lamsim_out_"+num+".txt"
        data = fi.read_data(name, echo=1)
        total = len(data[:,0])
        other = sc.sum(data[:,3])
        length = 7.653333333  # bin size
        out.append([(low_lam+(size*i)+(size*0.5)), total-other, total, 0.0, total/length])
    for i in range(15,18):
        print "# - Southern wedge {0}:".format(south[i-15])
        data = fi.read_data("./sim_streams/sim_stripe_"+str(south[i-15])+".txt")
        total = len(data[:,0])
        other = sc.sum(data[:,3])
        length = SGA[i,3]
        mu, r, theta, phi, wedge = eval(params[i][4]), eval(params[i][5]), \
            eval(params[i][6]), eval(params[i][7]), stripes[i]
        x,y,z = coor.stream2xyz(0.0, 0.0, 0.0, mu, r, theta, phi, wedge)
        Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(x,y,z)
        out.append([lam, total-other, total, 0.0, total/length])
    fi.write_data(sc.array(out), "sgrNorth_density_sim.txt", ",", " lam(mid), count, SDSS Deff, SDSS/FTO Deff, per degree")
Exemplo n.º 6
0
def make_coord_table(stripes, params):
    """ Makes a table of the Sgr dections, in standard coordinates
        Stripe #, x, y, z, l, b, lam, beta, new_lam, new_beta, R"""
    Sgr_lbr = [5.6, -14.2, 24.0]
    Sgr_xyz = [14.655645800014774, 2.2704309216189817, -5.8873772610912614]
    Stream_North = [-0.199, 0.935, 0.293, -0.988]
    Stream_South = [0.032, 0.987, 0.158, -1.073]
    coords = []
    for i, stripe in enumerate(stripes):
        mu, r, theta, phi = eval(params[i][4]), eval(params[i][5]), \
            eval(params[i][6]), eval(params[i][7])
        x, y, z = coor.stream2xyz(0.0, 0.0, 0.0, mu, r, theta*deg, phi*deg, stripe)
        l,b,r = coor.xyz2lbr(x,y,z)
        Xs, Ys, Zs, lam, beta, rs = sl.law_xyz2sgr_sun(x,y,z)
        if lam > 180.0:  lam = lam - 360.0
        # Just going to use Sgr North plane for now
        xp, yp, zp = coor.xyz2plane(x,y,z, new_x=Sgr_xyz, plane=Stream_North, origin=-8.5)
        long, lat, rp = coor.xyz2longlat(xp,yp,zp)
        print r, rs, rp
        coords.append([stripe, x, y, z, l, b, lam, beta, long, lat, r])
    # Now make table
    coord_table = tex.DataTable(sc.array(coords), 'lcccccccccc', "Sagittarius Stream Centers",
            "coordtable", ["Stripe",r"$X_{GC}$",r"$Y_{GC}$",r"$Z_{GC}$",r"$l$",r"$b$",
                           r"$\Lambda_{LM}$",r"$\Beta_{LM}$",r"$\Lambda_{new}$",
                           r"$\Beta_{new}$", r"$R_{\sun} (kpc)$"])
    tex.deluxe_table(coord_table, roundoff=1)
    
    """Sgr_lbr = [5.6, -14.2, 24.0]
Exemplo n.º 7
0
def show_lambda():
    data = fi.read_data("./sep_lbr/s1-79.txt")
    x,y,z = coor.lbr2xyz(data[:,0],data[:,1],data[:,2])
    Xs,Ys,Zs,lam1,beta,r = sl.law_xyz2sgr_sun(x,y,z)
    data = fi.read_data("./sep_lbr/s1-82.txt")
    x,y,z = coor.lbr2xyz(data[:,0],data[:,1],data[:,2])
    Xs,Ys,Zs,lam2,beta,r = sl.law_xyz2sgr_sun(x,y,z)
    data = fi.read_data("./sep_lbr/s1-86.txt")
    x,y,z = coor.lbr2xyz(data[:,0],data[:,1],data[:,2])
    Xs,Ys,Zs,lam3,beta,r = sl.law_xyz2sgr_sun(x,y,z)
    plt.figure()
    plt.hist(lam3, 20)
    plt.hist(lam2, 20)
    plt.hist(lam1, 20)
    plt.show()
    plt.close('all')
Exemplo n.º 8
0
def sgr_lam_split(stripes, params):
    # get lambda for stripes
    holder = []
    for i in range(len(stripes)):
        mu, r, theta, phi, wedge = eval(params[i][4]), eval(params[i][5]), \
            eval(params[i][6]), eval(params[i][7]), stripes[i]
        x,y,z = coor.stream2xyz(0.0, 0.0, 0.0, mu, r, theta*deg, phi*deg, wedge)
        Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(x,y,z)
        #if lam > 180.0: lam = lam - 360.0
        #lam = -lam
        print lam, beta, r, stripes[i]
        holder.append([lam, beta, r])
    Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(14.655646, 2.270431, -5.887377)
    print lam, beta, r
    # get lambda range for northern Sgr  15 N stripes, 0-14 -> 9-23
    low_lam, high_lam = 200.0, 314.8  # from Sgr stripes: (200.025901082, 314.707561185)
    size = (high_lam - low_lam) / 15.0
    print "# - LAMBDA BIN SIZE: {0}".format(size)
    for h in range(15):
        array = []
        lam_min, lam_max = low_lam+(size*h), low_lam+(size*(h+1))
        for i in range(15):
            if stripes[i] == 9:  num = "09"
            else:  num = str(stripes[i])
            name = "./sim_streams/sim_stripe_"+num+".txt"
            Sgr = open(name, "r")
            for line in Sgr:
                if line.strip() == "":  continue
                if line.strip()[0] == "#":  continue
                l,b,r,f = line.strip().split()
                x,y,z = coor.lbr2xyz(float(l), float(b), float(r))
                Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(x,y,z)        
                #if lam > high_lam:  high_lam = lam
                #if lam < low_lam:  low_lam = lam
                if lam > lam_min:
                    if lam <= lam_max:
                        array.append([lam, beta, r, eval(f)])
            Sgr.close()
            print "# - Stripe "+num+" successfully read in"
        fi.write_data(sc.array(array), "lamsim_out_"+str(h)+".txt",
                      header="Lambda {0}:{1}, lam, beta, r".format(lam_min, lam_max))
    #print low_lam, high_lam
    # bin stripes in lambda, g
    # correct stripes for detection, FTO efficiencies
    # reflect stars about midpoint to correct for missing data on far end
    print "### --- Done"
Exemplo n.º 9
0
def astro_test():
    """ """
    Sgr_lbr = [5.6, -14.2, 24.0]
    Sgr = coor.lbr2xyz(Sgr_lbr[0], Sgr_lbr[1], Sgr_lbr[2])
    print Sgr
    # (14.655645800014774, 2.2704309216189817, -5.8873772610912614)
    Law = [-0.064, 0.970, 0.233, 0.23]  #GC-centered
    Mine = [-0.203, 0.933, 0.298, -1.193]
    lam = [75.0, 85.0, 95.0, 105.0, 115.0]
    beta = [9.5, 10.3, 10.3, 10.7, 11.8]

    t = sc.arange(0.0, 2.0 * ma.pi, ma.pi / 16.0)
    xx = 10.0 * sc.cos(t)
    zz = 10.0 * sc.sin(t)

    x = xx  #[Sgr[0], 1.0, 0.0]
    y = sc.zeros(len(xx))  #[Sgr[1], 0.0, 1.0]
    z = zz  #[Sgr[2], 0.0, 0.0]
    # XXXXXXXX  NEED SUN-CENTER LAW PLANE!
    lps, bps, rps = [], [], []
    lams, betas, rs = [], [], []
    for i in range(len(x)):
        xp, yp, zp = coor.xyz2plane(-x[i],
                                    y[i],
                                    z[i],
                                    new_x=Sgr,
                                    plane=Law,
                                    origin=sun[0])
        lp, bp, rp = coor.xyz2longlat(xp, yp, zp)
        lps.append(lp)
        bps.append(bp)
        rps.append(rp)
        print lp, bp, rp
        Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(x[i], y[i],
                                                      z[i])  #, Xsun=dsun)
        print lam, beta, r
        lams.append(lam)
        betas.append(beta)
        rs.append(r)
    plt.figure(1)
    plt.scatter(lps, bps, c='b')
    plt.scatter(lams, betas, c='g')
    plt.show()

    #print Sgr
    #print coor.xyz2plane(2.0, 0.0, 0.0, [0.0,1.0,0.0], [0.0, 0.0, 1.0, 0.0])
    #print xyz2plane(Sgr[0], Sgr[1], Sgr[2], [2.22222222, 3.333333333, 4.444444444], [0.0326, 0.988, 0.153, 0.0])

    #print coor.xyz2plane(Sgr[0], Sgr[1], Sgr[2], list(Sgr), Law)
    #print coor.xyz2lambeta(Sgr[0], Sgr[1], Sgr[2], list(Sgr), Law)
    #print coor.xyz2plane_old(Sgr[0], Sgr[1], Sgr[2], list(Sgr), Law)
    #print coor.plane2xyz(15.955954308821331, 4.1893571944839891e-16, 0.12264161315188961, list(Sgr), Law)

    #print plane2xyz(24.0-8.5, 0.0, 0.0, list(Sgr), Law)
    #print plane2xyz(15.955659255114893, -0.068783217539582636, 0.14044740696010716, list(Sgr), Law)
    #print coor.rot_3D(Sgr[0], Sgr[1], Sgr[2], "zxz", [-183.8*rad, 76.5*rad, 201.6*rad])
    print
Exemplo n.º 10
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def sgr_density_south(stripes, params):
    out = []
    for i in range(15, 18):
        mu, r, theta, phi, wedge = eval(params[i][4]), eval(params[i][5]), \
            eval(params[i][6]), eval(params[i][7]), stripes[i]
        print mu, r, theta, phi
        x,y,z = coor.stream2xyz(0.0, 0.0, 0.0, mu, r, theta, phi, wedge)
        Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(x,y,z)
        print lam, beta, r, stripes[i]
        name = "./sep_lbr/s1-"+str(stripes[i])+".txt"
        data = fi.read_data(name, echo=1)
        wedge_norm = coor.stripe_normal(stripes[i])
        plane_norm = [0.03176573688051381, 0.98687684085235916, 0.15831942063343135]
        stream_norm = [sc.cos(phi)*sc.sin(theta), sc.sin(phi)*sc.sin(theta), sc.cos(theta)]
        print wedge_norm, stream_norm
        dotty = wedge_norm[0]*stream_norm[0] + wedge_norm[1]*stream_norm[1] + wedge_norm[2]*stream_norm[2]
        #dotty2 = plane_norm[0]*wedge_norm[0] + plane_norm[1]*stream_norm[1] + plane_norm[2]*stream_norm[2]
        if dotty > 1.0:  print "!!!  Not a valid dot-product: {0}".format(dotty)
        H = abs(2.5 / dotty)
        #H2 = 2.5 / sc.sqrt(1 - (dotty2*dotty2))
        print "H = ", H, dotty, sc.arccos(dotty)*180.0/ma.pi #, H2
        count, in_1, in_2 = 0, 0.0, 0.0
        lam_low, lam_high = 360.0, 0.0
        for j in range(len(data[:,0])):
            l, b, r = data[j,0], data[j,1], data[j,2]
            count = count + 1
            # Correct for completeness
            Deff = 1.0/SDSS_eff(r)
            in_1 = in_1 + Deff
            in_2 = in_2 + Deff + 1.0/TO_eff(r)
            x,y,z = coor.lbr2xyz(l,b,r)
            Xs, Ys, Zs, lam2, beta2, r2 = sl.law_xyz2sgr_sun(x,y,z)
            if lam2 < lam_low:  lam_low = lam2
            if lam2 > lam_high:  lam_high = lam2
        out.append([lam, count, in_1, in_2, in_2/H])
        print "--- Lambda Range: {0}:{1}".format(lam_low, lam_high)
        print "###   Number of stars in stream:  {0}".format(count)
        print "###   Corrected for SDSS Eff.:    {0}".format(in_1)
        print "###   Corrected for SDSS/FTO Eff: {0}".format(in_2)
    for o in out:  print o
    return sc.array(out)
Exemplo n.º 11
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def astro_test():
    """ """
    Sgr_lbr = [5.6, -14.2, 24.0]
    Sgr = coor.lbr2xyz(Sgr_lbr[0], Sgr_lbr[1], Sgr_lbr[2])
    print Sgr
    # (14.655645800014774, 2.2704309216189817, -5.8873772610912614)
    Law = [-0.064, 0.970, 0.233, 0.23]  #GC-centered
    Mine = [-0.203, 0.933, 0.298, -1.193]
    lam = [75.0, 85.0, 95.0, 105.0, 115.0]
    beta = [9.5, 10.3, 10.3, 10.7, 11.8]
    
    t = sc.arange(0.0, 2.0*ma.pi, ma.pi/16.0)
    xx = 10.0*sc.cos(t)
    zz = 10.0*sc.sin(t)
    
    x = xx #[Sgr[0], 1.0, 0.0]
    y = sc.zeros(len(xx)) #[Sgr[1], 0.0, 1.0]
    z = zz #[Sgr[2], 0.0, 0.0]
    # XXXXXXXX  NEED SUN-CENTER LAW PLANE!
    lps, bps, rps = [], [], []
    lams, betas, rs = [], [], []
    for i in range(len(x)):
        xp, yp, zp = coor.xyz2plane(-x[i],y[i],z[i], new_x=Sgr, plane=Law, origin=sun[0])
        lp, bp, rp = coor.xyz2longlat(xp,yp,zp)
        lps.append(lp); bps.append(bp); rps.append(rp)
        print lp, bp, rp
        Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(x[i],y[i],z[i]) #, Xsun=dsun)
        print lam, beta, r
        lams.append(lam); betas.append(beta); rs.append(r)
    plt.figure(1)
    plt.scatter(lps, bps, c='b')
    plt.scatter(lams, betas, c='g')
    plt.show()
    
    #print Sgr
    #print coor.xyz2plane(2.0, 0.0, 0.0, [0.0,1.0,0.0], [0.0, 0.0, 1.0, 0.0])
    #print xyz2plane(Sgr[0], Sgr[1], Sgr[2], [2.22222222, 3.333333333, 4.444444444], [0.0326, 0.988, 0.153, 0.0])
    
    #print coor.xyz2plane(Sgr[0], Sgr[1], Sgr[2], list(Sgr), Law)
    #print coor.xyz2lambeta(Sgr[0], Sgr[1], Sgr[2], list(Sgr), Law)
    #print coor.xyz2plane_old(Sgr[0], Sgr[1], Sgr[2], list(Sgr), Law)
    #print coor.plane2xyz(15.955954308821331, 4.1893571944839891e-16, 0.12264161315188961, list(Sgr), Law)
    
    #print plane2xyz(24.0-8.5, 0.0, 0.0, list(Sgr), Law)
    #print plane2xyz(15.955659255114893, -0.068783217539582636, 0.14044740696010716, list(Sgr), Law)
    #print coor.rot_3D(Sgr[0], Sgr[1], Sgr[2], "zxz", [-183.8*rad, 76.5*rad, 201.6*rad])
    print
Exemplo n.º 12
0
def make_coord_table(stripes, params):
    """ Makes a table of the Sgr dections, in standard coordinates
        Stripe #, x, y, z, l, b, lam, beta, new_lam, new_beta, R"""
    Sgr_lbr = [5.6, -14.2, 24.0]
    Sgr_xyz = [14.655645800014774, 2.2704309216189817, -5.8873772610912614]
    Stream_North = [-0.199, 0.935, 0.293, -0.988]
    Stream_South = [0.032, 0.987, 0.158, -1.073]
    coords = []
    for i, stripe in enumerate(stripes):
        mu, r, theta, phi = eval(params[i][4]), eval(params[i][5]), \
            eval(params[i][6]), eval(params[i][7])
        x, y, z = coor.stream2xyz(0.0, 0.0, 0.0, mu, r, theta * deg, phi * deg,
                                  stripe)
        l, b, r = coor.xyz2lbr(x, y, z)
        Xs, Ys, Zs, lam, beta, rs = sl.law_xyz2sgr_sun(x, y, z)
        if lam > 180.0: lam = lam - 360.0
        # Just going to use Sgr North plane for now
        xp, yp, zp = coor.xyz2plane(x,
                                    y,
                                    z,
                                    new_x=Sgr_xyz,
                                    plane=Stream_North,
                                    origin=-8.5)
        long, lat, rp = coor.xyz2longlat(xp, yp, zp)
        print r, rs, rp
        coords.append([stripe, x, y, z, l, b, lam, beta, long, lat, r])
    # Now make table
    coord_table = tex.DataTable(
        sc.array(coords), 'lcccccccccc', "Sagittarius Stream Centers",
        "coordtable", [
            "Stripe", r"$X_{GC}$", r"$Y_{GC}$", r"$Z_{GC}$", r"$l$", r"$b$",
            r"$\Lambda_{LM}$", r"$\Beta_{LM}$", r"$\Lambda_{new}$",
            r"$\Beta_{new}$", r"$R_{\sun} (kpc)$"
        ])
    tex.deluxe_table(coord_table, roundoff=1)
    """Sgr_lbr = [5.6, -14.2, 24.0]
Exemplo n.º 13
0
def sgr_density(stripes, params):
    # get lambda for stripes
    holder = []
    for i in range(len(stripes)):
        mu, r, theta, phi, wedge = eval(params[i][4]), eval(params[i][5]), \
            eval(params[i][6]), eval(params[i][7]), stripes[i]
        x, y, z = coor.stream2xyz(0.0, 0.0, 0.0, mu, r, theta, phi, wedge)
        Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(x, y, z)
        #if lam > 180.0: lam = lam - 360.0
        #lam = -lam
        print lam, beta, r, stripes[i]
        holder.append([lam, beta, r])
    Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(14.655646, 2.270431,
                                                  -5.887377)
    print lam, beta, r
    # Get distances as a function of Lamda, using straight pipes to connect points.
    LAB = [
    ]  # lambda, A, B such that:  R = A(lam) + B;  C,D st beta = C(lam) + D
    for i in range(15 - 1):  # all but end
        A = (holder[i + 1][2] - holder[i][2]) / (
            holder[i + 1][0] - holder[i][0])  # R2-R1/L2-L1
        B = holder[i][2] - A * holder[i][0]  # R1 - A*L1
        C = (holder[i + 1][1] - holder[i][1]) / (
            holder[i + 1][0] - holder[i][0])  # B2-B1/L2-L1
        D = holder[i][1] - C * holder[i][0]  # B1 - A*L1
        LAB.append([holder[i + 1][0], A, B, C, D])
    # get lambda range for northern Sgr  15 N stripes, 0-14 -> 9-23
    low_lam, high_lam = 200.0, 314.8  # from Sgr stripes: (200.025901082, 314.707561185)
    size = (high_lam - low_lam) / 15.0
    print "# - LAMBDA BIN SIZE: {0}".format(size)
    out = []
    for i in range(15):
        killed = 0
        print "# - Lambda wedge {0}:".format(i)
        num = str(i)
        name = "./Lambda_outs/lamsim_out_" + num + ".txt"
        data = fi.read_data(name, echo=1)
        count, in_1, in_2, in_0 = 0, 0.0, 0.0, 0.0
        sigma = params[i][8]
        for j in range(len(data[:, 0])):
            lam, beta, r = data[j, 0], data[j, 1], data[j, 2]
            count = count + 1
            index = 0
            while data[j, 0] > LAB[index][0]:
                index = index + 1
                if (index == len(LAB) - 1): break
            # correct for missing far edge by counting all near edge and doubling
            A, B = LAB[index][1], LAB[index][2]
            if r > (A * lam + B) / sc.cos(beta):
                killed = killed + 1
                continue
            #D = (0.295*lam - 42.601)/sc.cos(beta)
            #if r > D:  killed=killed+1; continue
            # correct for missing side edge by counting inner and doubling
            #C, D = LAB[index][3], LAB[index][4]
            #if beta > (C*lam + D):  continue
            # Correct for completeness
            Deff = 1.0 / SDSS_eff(r)
            in_0 = in_0 + 1.0
            in_1 = in_1 + Deff
            in_2 = in_2 + Deff / TO_eff(r)
        out.append([(low_lam + (size * i) + (size * 0.5)), count, in_1, in_2,
                    in_2 / size])
        print "###   Number of stars in stream:  {0}".format(count)
        print "###   KILLED: {0}".format(killed)
        print "###   Remaining Stars:    {0}".format(in_0 * 1.0)
        print "###   Corrected for SDSS Eff.:    {0}".format(in_1 * 2.0)
        print "###   Corrected for SDSS/FTO Eff: {0}".format(in_2 * 2.0)
    #print out
    return sc.array(out)
Exemplo n.º 14
0
def dist(l, b, lam, beta):
    x, y, z = coor.lbr2xyz(l, b, r)
    x0, y0, z0, lam0, beta0, r0 = sl.law_xyz2sgr_sun(x, y, z)
    one = (lam0 - lam) * (lam0 - lam)
    two = (beta0 - beta) * (beta0 - beta)
    return sc.sqrt(one + two)
Exemplo n.º 15
0
def width_plot(stripes, params):
    data = fi.read_data("../sgrnorth_paper/sgrNorth_density_sim.txt", ",")
    #Ben = fi.read_data("../sgrnorth_paper/bensgr_lam_bins.dat")
    #Law = fi.read_data("../sgrnorth_paper/lawsgr_lam_bins.dat")
    Law = fi.read_data("../sgrnorth_paper/lawsgrTRX_lam_binsC.dat")
    sph = fi.read_data("../sgrnorth_paper/lawsgrSPH_lam_binsC.dat")
    obl = fi.read_data("../sgrnorth_paper/lawsgrOBL_lam_binsC.dat")
    pro = fi.read_data("../sgrnorth_paper/lawsgrPRO_lam_binsC.dat")
    LM10 = fi.read_data("../sgrnorth_paper/lawsgrTRX_widthsC.dat")  #2
    wp = fi.read_data("../sgrnorth_paper/lawsgrPRO_widthsC.dat")
    ws = fi.read_data("../sgrnorth_paper/lawsgrSPH_widthsC.dat")
    wo = fi.read_data("../sgrnorth_paper/lawsgrOBL_widthsC.dat")
    errors = sc.array([
        0.775105, 0.47734, 0.836774, 1.882841, 0.932078, 1.531246, 1.653404,
        0.593513, 0.853309, 0.469178, 3.053077, 0.314356, 0.388961, 1.21,
        2.330186, 0.142532, 0.989839, 0.541965
    ])
    sigma, slam = [], []
    for i in range(len(stripes)):
        mu, r, theta, phi, wedge = eval(params[i][4]), eval(params[i][5]), \
            eval(params[i][6]), eval(params[i][7]), stripes[i]
        #print mu, r, theta, phi
        x, y, z = coor.stream2xyz(0.0, 0.0, 0.0, mu, r, theta, phi, wedge)
        Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(x, y, z)
        slam.append(lam)
    for param in params:
        sigma.append(2.35482 * eval(param[8]))
    fig = plt.figure(1)
    plt.subplots_adjust(hspace=0.001, wspace=0.001)
    # density along stream plot
    sp1 = plt.subplot(211)
    color = [
        'w', 'w', 'k', 'k', 'k', 'k', 'k', 'k', 'k', 'k', 'k', 'k', 'w', 'w',
        'w', 'k', 'k', 'k'
    ]
    #plt.scatter(data[:,0], data[:,4]*1.0, facecolor=color, marker="s",
    #            label="Expected Counts")
    plt.scatter(data[:, 0],
                data[:, 4],
                facecolor=color,
                marker="^",
                label="__nolabel__")
    plt.scatter(data[:, 0],
                data[:, 1] * (data[:, 4] / data[:, 2]),
                facecolor=color,
                marker="o",
                label="__nolabel__")
    #plt.errorbar([315.0, 315.0, 315.0, 312.0, 312.0, 312.0], [1000, 2000, 3000, 1000, 2000, 3000],
    #            yerr=[39.2, 51.5, 80.0, 33.2, 43.6, 53.8], fmt="o", markersize=1,
    #            mfc="red", ecolor="red", label="Typical Errors") #71.8
    #plt.plot(Ben[:,0], Ben[:,1]*0.2, "k--") #0.1
    a, b = 21, 23
    plt.plot(obl[:a, 0], obl[:a, 1] * 7.0, "r:", label="Oblate")
    plt.plot(obl[b:, 0], obl[b:, 1] * 7.0, "r:", label=None)
    plt.plot(sph[:a, 0],
             sph[:a, 1] * 7.0,
             "k-.",
             label="Spherical",
             linewidth=1.5)
    plt.plot(sph[b:, 0], sph[b:, 1] * 7.0, "k-.", label=None, linewidth=1.5)
    plt.plot(pro[:a, 0], pro[:a, 1] * 7.0, "b--", label="Prolate")
    plt.plot(pro[b:, 0], pro[b:, 1] * 7.0, "b--", label=None)
    plt.plot(Law[:a, 0], Law[:a, 1] * 6.0, "k-", label="L&M10 Nbody")  # 1.5
    plt.plot(Law[b:, 0], Law[b:, 1] * 6.0, "k-", label=None)  # 1.5
    #sp1.annotate('Triaxial', xy=(178, 3200), xytext=(210, 3650), fontsize=8,
    #             arrowprops=dict(facecolor='black', shrink=0.05, width=0.5, headwidth=3)  )
    #sp1.annotate('Prolate', xy=(192, 3000), xytext=(215, 3350), fontsize=8,
    #             arrowprops=dict(facecolor='black', shrink=0.05, width=0.5, headwidth=3)  )
    #sp1.annotate('Spherical', xy=(199, 2750), xytext=(220, 3050), fontsize=8,
    #             arrowprops=dict(facecolor='black', shrink=0.05, width=0.5, headwidth=3)  )
    #sp1.annotate('Oblate', xy=(205, 2500), xytext=(225, 2800), fontsize=8,
    #             arrowprops=dict(facecolor='black', shrink=0.05, width=0.5, headwidth=3)  )
    #plt.scatter(Ben[:,0], Ben[:,1]*0.5, facecolor="blue", marker="x")
    #plt.scatter(Law[:,0], Law[:,1], facecolor="red", marker="+")
    spoof1 = plt.scatter(180.0,
                         -10.0,
                         facecolor='k',
                         marker="^",
                         label="Expected Counts")  #spoof
    spoof2 = plt.scatter(180.0,
                         -10.0,
                         facecolor='k',
                         marker="o",
                         label="Raw Counts")  #spoof
    plt.setp(sp1.get_xticklabels(), visible=False)
    plt.ylim(0.0, 6000.0)
    plt.ylabel("Stars per degree", fontsize=12)
    # legend
    leg1 = sp1.legend(loc='upper center', numpoints=2)
    for t in leg1.get_texts():
        t.set_fontsize(10)
    # ----------------  FWHM v lambda plot --------------------
    sp2 = plt.subplot(212, sharex=sp1)
    g_mean = np.sqrt(LM10[:, 3] * LM10[:, 4])  #geometric mean
    plt.errorbar(slam,
                 sigma,
                 yerr=2.35482 * errors,
                 fmt="d",
                 mfc="black",
                 ecolor="black",
                 label="MLE Fits")
    #plt.scatter(slam, sigma, facecolor="black", marker="o", label=None)
    plt.plot(LM10[:21, 0], 2.35482 * g_mean[:21], "k-", label=None)
    plt.plot(LM10[21:, 0], 2.35482 * g_mean[21:], "k-", label=None)
    # NEW STUFF
    aa, bb = 21, 21
    plt.plot(wp[:aa, 0],
             2.35482 * np.sqrt(wp[:aa, 3] * wp[:aa, 4]),
             "b--",
             label=None)
    plt.plot(wp[bb:, 0],
             2.35482 * np.sqrt(wp[bb:, 3] * wp[bb:, 4]),
             "b--",
             label=None)
    plt.plot(ws[:aa, 0],
             2.35482 * np.sqrt(ws[:aa, 3] * ws[:aa, 4]),
             "k-.",
             label=None)
    plt.plot(ws[bb:, 0],
             2.35482 * np.sqrt(ws[bb:, 3] * ws[bb:, 4]),
             "k-.",
             label=None)
    plt.plot(wo[:aa, 0],
             2.35482 * np.sqrt(wo[:aa, 3] * wo[:aa, 4]),
             "r:",
             label=None)
    plt.plot(wo[bb + 3:, 0],
             2.35482 * np.sqrt(wo[bb + 3:, 3] * wo[bb + 3:, 4]),
             "r:",
             label=None)
    #plt.scatter(LM10[:,0], 2.35482*g_mean, facecolor='black', marker='+', label="L&M10 Nbody")
    # legend
    leg2 = sp2.legend(loc='lower right', numpoints=1)
    for t in leg2.get_texts():
        t.set_fontsize(8)
    plt.xlabel(r"$\Lambda_{\odot}$")
    plt.ylabel(r"FWHM (kpc)")
    plt.ylim(0.0, 20.0)
    plt.xlim(320.0, 70.0)  # 70, 320
    #plt.xticks(sc.arange(80.0, 320.0, 20.0))
    plt.show()
Exemplo n.º 16
0
def sgr_density(stripes, params):
        # get lambda for stripes
    holder = []
    for i in range(len(stripes)):
        mu, r, theta, phi, wedge = eval(params[i][4]), eval(params[i][5]), \
            eval(params[i][6]), eval(params[i][7]), stripes[i]
        x,y,z = coor.stream2xyz(0.0, 0.0, 0.0, mu, r, theta, phi, wedge)
        Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(x,y,z)
        #if lam > 180.0: lam = lam - 360.0
        #lam = -lam
        print lam, beta, r, stripes[i]
        holder.append([lam, beta, r])
    Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(14.655646, 2.270431, -5.887377)
    print lam, beta, r
    # Get distances as a function of Lamda, using straight pipes to connect points.
    LAB = [] # lambda, A, B such that:  R = A(lam) + B;  C,D st beta = C(lam) + D
    for i in range(15-1):  # all but end
        A = (holder[i+1][2]-holder[i][2])/(holder[i+1][0]-holder[i][0]) # R2-R1/L2-L1
        B = holder[i][2] - A*holder[i][0]  # R1 - A*L1
        C = (holder[i+1][1]-holder[i][1])/(holder[i+1][0]-holder[i][0]) # B2-B1/L2-L1
        D = holder[i][1] - C*holder[i][0]  # B1 - A*L1
        LAB.append([holder[i+1][0], A, B, C, D])
    # get lambda range for northern Sgr  15 N stripes, 0-14 -> 9-23
    low_lam, high_lam = 200.0, 314.8  # from Sgr stripes: (200.025901082, 314.707561185)
    size = (high_lam - low_lam) / 15.0
    print "# - LAMBDA BIN SIZE: {0}".format(size)
    out = []
    for i in range(15):
        killed = 0
        print "# - Lambda wedge {0}:".format(i)
        num = str(i)
        name = "./Lambda_outs/lamsim_out_"+num+".txt"
        data = fi.read_data(name, echo=1)
        count, in_1, in_2, in_0 = 0, 0.0, 0.0, 0.0
        sigma = params[i][8]
        for j in range(len(data[:,0])):
            lam, beta, r = data[j,0], data[j,1], data[j,2]
            count = count + 1
            index = 0
            while data[j,0] > LAB[index][0]:
                index = index + 1
                if (index == len(LAB)-1):  break
            # correct for missing far edge by counting all near edge and doubling
            A, B = LAB[index][1], LAB[index][2]
            if r > (A*lam + B)/sc.cos(beta):  killed=killed+1; continue
            #D = (0.295*lam - 42.601)/sc.cos(beta)
            #if r > D:  killed=killed+1; continue
            # correct for missing side edge by counting inner and doubling
            #C, D = LAB[index][3], LAB[index][4]
            #if beta > (C*lam + D):  continue
            # Correct for completeness
            Deff = 1.0/SDSS_eff(r)
            in_0 = in_0 + 1.0
            in_1 = in_1 + Deff
            in_2 = in_2 + Deff/TO_eff(r)
        out.append([(low_lam+(size*i)+(size*0.5)), count, in_1, in_2, in_2/size])
        print "###   Number of stars in stream:  {0}".format(count)
        print "###   KILLED: {0}".format(killed)
        print "###   Remaining Stars:    {0}".format(in_0*1.0)
        print "###   Corrected for SDSS Eff.:    {0}".format(in_1*2.0)
        print "###   Corrected for SDSS/FTO Eff: {0}".format(in_2*2.0)
    #print out
    return sc.array(out)
Exemplo n.º 17
0
verbose = 0

for i in range(len(lam_out)):
    d0, scale = 100.0, 1.0
    l0, b0 = 0.0, 0.0
    l_base, b_base = center_l, center_b
    lam, beta = lam_out[i], beta_out[i]
    x, changed = 0, 0
    while x < 15:
        for dl in l_steps:
            l = l_base + dl * scale
            for db in b_steps:
                b = b_base + db * scale
                d = dist(l, b, lam, beta)
                if d < d0:
                    l0, b0, d0 = l, b, d
                    changed = 1
        if verbose == 1:
            print "Current l,b,d:  {0}, {1}, {2}".format(l0, b0, d0)
            x0, y0, z0 = coor.lbr2xyz(l0, b0, r)
            print sl.law_xyz2sgr_sun(x0, y0, z0)[3:]
        if d0 < pres:
            print "# - Exiting by threshold"
            break
        scale = scale / 2.0
        l_base, b_base = l0, b0
        x = x + 1
    print "# - For lamda, beta = ({0},{1}), l,b,d = {2}, {3}, {4}".format(
        lam, beta, l0, b0, d0)
    x0, y0, z0 = coor.lbr2xyz(l0, b0, r)
    print "# - {0}".format(sl.law_xyz2sgr_sun(x0, y0, z0)[3:])
Exemplo n.º 18
0
def width_plot(stripes, params):
    data = fi.read_data("../sgrnorth_paper/sgrNorth_density_sim.txt", ",")
    #Ben = fi.read_data("../sgrnorth_paper/bensgr_lam_bins.dat")
    #Law = fi.read_data("../sgrnorth_paper/lawsgr_lam_bins.dat")
    Law = fi.read_data("../sgrnorth_paper/lawsgrTRX_lam_binsC.dat")
    sph = fi.read_data("../sgrnorth_paper/lawsgrSPH_lam_binsC.dat")
    obl = fi.read_data("../sgrnorth_paper/lawsgrOBL_lam_binsC.dat")
    pro = fi.read_data("../sgrnorth_paper/lawsgrPRO_lam_binsC.dat")
    LM10 = fi.read_data("../sgrnorth_paper/lawsgrTRX_widthsC.dat")  #2
    wp = fi.read_data("../sgrnorth_paper/lawsgrPRO_widthsC.dat")
    ws = fi.read_data("../sgrnorth_paper/lawsgrSPH_widthsC.dat")
    wo = fi.read_data("../sgrnorth_paper/lawsgrOBL_widthsC.dat")
    errors = sc.array([0.775105, 0.47734, 0.836774, 1.882841, 0.932078, 1.531246,
                       1.653404, 0.593513, 0.853309, 0.469178, 3.053077, 0.314356,
                       0.388961, 1.21, 2.330186, 0.142532, 0.989839, 0.541965])
    sigma, slam = [], []
    for i in range(len(stripes)):
        mu, r, theta, phi, wedge = eval(params[i][4]), eval(params[i][5]), \
            eval(params[i][6]), eval(params[i][7]), stripes[i]
        #print mu, r, theta, phi
        x,y,z = coor.stream2xyz(0.0, 0.0, 0.0, mu, r, theta, phi, wedge)
        Xs, Ys, Zs, lam, beta, r = sl.law_xyz2sgr_sun(x,y,z)
        slam.append(lam)
    for param in params:
        sigma.append(2.35482*eval(param[8]))
    fig = plt.figure(1)
    plt.subplots_adjust(hspace=0.001, wspace=0.001)
    # density along stream plot
    sp1 = plt.subplot(211)
    color = ['w', 'w', 'k', 'k', 'k', 'k', 'k', 'k', 'k', 'k', 'k', 'k', 'w', 'w', 'w', 'k', 'k', 'k']
    #plt.scatter(data[:,0], data[:,4]*1.0, facecolor=color, marker="s",
    #            label="Expected Counts")
    plt.scatter(data[:,0], data[:,4], facecolor=color, marker="^", label="__nolabel__")
    plt.scatter(data[:,0], data[:,1]*(data[:,4]/data[:,2]), facecolor=color,
                marker="o", label="__nolabel__")
    #plt.errorbar([315.0, 315.0, 315.0, 312.0, 312.0, 312.0], [1000, 2000, 3000, 1000, 2000, 3000],
    #            yerr=[39.2, 51.5, 80.0, 33.2, 43.6, 53.8], fmt="o", markersize=1,
    #            mfc="red", ecolor="red", label="Typical Errors") #71.8
    #plt.plot(Ben[:,0], Ben[:,1]*0.2, "k--") #0.1
    a, b = 21, 23
    plt.plot(obl[:a,0], obl[:a,1]*7.0, "r:", label="Oblate")
    plt.plot(obl[b:,0], obl[b:,1]*7.0, "r:", label=None)
    plt.plot(sph[:a,0], sph[:a,1]*7.0, "k-.", label="Spherical", linewidth=1.5)
    plt.plot(sph[b:,0], sph[b:,1]*7.0, "k-.", label=None, linewidth=1.5)
    plt.plot(pro[:a,0], pro[:a,1]*7.0, "b--", label="Prolate")
    plt.plot(pro[b:,0], pro[b:,1]*7.0, "b--", label=None)
    plt.plot(Law[:a,0], Law[:a,1]*6.0, "k-", label="L&M10 Nbody") # 1.5
    plt.plot(Law[b:,0], Law[b:,1]*6.0, "k-", label=None) # 1.5
    #sp1.annotate('Triaxial', xy=(178, 3200), xytext=(210, 3650), fontsize=8,
    #             arrowprops=dict(facecolor='black', shrink=0.05, width=0.5, headwidth=3)  )
    #sp1.annotate('Prolate', xy=(192, 3000), xytext=(215, 3350), fontsize=8,
    #             arrowprops=dict(facecolor='black', shrink=0.05, width=0.5, headwidth=3)  )
    #sp1.annotate('Spherical', xy=(199, 2750), xytext=(220, 3050), fontsize=8,
    #             arrowprops=dict(facecolor='black', shrink=0.05, width=0.5, headwidth=3)  )
    #sp1.annotate('Oblate', xy=(205, 2500), xytext=(225, 2800), fontsize=8,
    #             arrowprops=dict(facecolor='black', shrink=0.05, width=0.5, headwidth=3)  )
    #plt.scatter(Ben[:,0], Ben[:,1]*0.5, facecolor="blue", marker="x")
    #plt.scatter(Law[:,0], Law[:,1], facecolor="red", marker="+")
    spoof1 = plt.scatter(180.0, -10.0, facecolor='k', marker="^", label="Expected Counts") #spoof
    spoof2 = plt.scatter(180.0, -10.0, facecolor='k', marker="o", label="Raw Counts") #spoof
    plt.setp(sp1.get_xticklabels(), visible=False)
    plt.ylim(0.0, 6000.0)
    plt.ylabel("Stars per degree", fontsize=12)
    # legend
    leg1 = sp1.legend(loc='upper center', numpoints=2)
    for t in leg1.get_texts():
        t.set_fontsize(10)
    # ----------------  FWHM v lambda plot --------------------
    sp2 = plt.subplot(212, sharex=sp1)
    g_mean = np.sqrt(LM10[:,3]*LM10[:,4])  #geometric mean
    plt.errorbar(slam, sigma, yerr=2.35482*errors, fmt="d", mfc="black", ecolor="black", label="MLE Fits")
    #plt.scatter(slam, sigma, facecolor="black", marker="o", label=None)
    plt.plot(LM10[:21,0], 2.35482*g_mean[:21], "k-", label=None)
    plt.plot(LM10[21:,0], 2.35482*g_mean[21:], "k-", label=None)
    # NEW STUFF
    aa, bb = 21, 21
    plt.plot(wp[:aa,0], 2.35482*np.sqrt(wp[:aa,3]*wp[:aa,4]), "b--", label=None)
    plt.plot(wp[bb:,0], 2.35482*np.sqrt(wp[bb:,3]*wp[bb:,4]), "b--", label=None)
    plt.plot(ws[:aa,0], 2.35482*np.sqrt(ws[:aa,3]*ws[:aa,4]), "k-.", label=None)
    plt.plot(ws[bb:,0], 2.35482*np.sqrt(ws[bb:,3]*ws[bb:,4]), "k-.", label=None)
    plt.plot(wo[:aa,0], 2.35482*np.sqrt(wo[:aa,3]*wo[:aa,4]), "r:", label=None)
    plt.plot(wo[bb+3:,0], 2.35482*np.sqrt(wo[bb+3:,3]*wo[bb+3:,4]), "r:", label=None)
    #plt.scatter(LM10[:,0], 2.35482*g_mean, facecolor='black', marker='+', label="L&M10 Nbody")
    # legend
    leg2 = sp2.legend(loc='lower right', numpoints=1)
    for t in leg2.get_texts():
        t.set_fontsize(8)
    plt.xlabel(r"$\Lambda_{\odot}$")
    plt.ylabel(r"FWHM (kpc)")
    plt.ylim(0.0, 20.0)
    plt.xlim(320.0, 70.0) # 70, 320
    #plt.xticks(sc.arange(80.0, 320.0, 20.0))
    plt.show()
Exemplo n.º 19
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def dist(l,b,lam, beta):
    x,y,z = coor.lbr2xyz(l,b,r)
    x0,y0,z0,lam0,beta0,r0 = sl.law_xyz2sgr_sun(x,y,z)
    one = (lam0 - lam)*(lam0 - lam)
    two = (beta0 - beta)*(beta0 - beta)
    return sc.sqrt(one + two)
Exemplo n.º 20
0
def lb2sgr(l,b,r):
    x,y,z = lbr2xyz(l,b,r)
    return sl.law_xyz2sgr_sun(x,y,z)
Exemplo n.º 21
0
    x0,y0,z0,lam0,beta0,r0 = sl.law_xyz2sgr_sun(x,y,z)
    one = (lam0 - lam)*(lam0 - lam)
    two = (beta0 - beta)*(beta0 - beta)
    return sc.sqrt(one + two)

verbose = 0

for i in range(len(lam_out)):
    d0, scale = 100.0, 1.0
    l0, b0 = 0.0, 0.0
    l_base, b_base = center_l, center_b
    lam, beta = lam_out[i], beta_out[i]
    x, changed = 0, 0
    while x<15:
        for dl in l_steps:
            l = l_base + dl*scale
            for db in b_steps:
                b = b_base + db*scale
                d = dist(l,b,lam,beta)
                if d < d0:  l0, b0, d0 = l, b, d; changed=1
        if verbose==1:
            print "Current l,b,d:  {0}, {1}, {2}".format(l0,b0,d0)
            x0,y0,z0 = coor.lbr2xyz(l0,b0,r)
            print sl.law_xyz2sgr_sun(x0,y0,z0)[3:]
        if d0 < pres:  print "# - Exiting by threshold"; break
        scale = scale/2.0
        l_base, b_base = l0, b0
        x=x+1
    print "# - For lamda, beta = ({0},{1}), l,b,d = {2}, {3}, {4}".format(lam,beta,l0,b0,d0)
    x0,y0,z0 = coor.lbr2xyz(l0,b0,r)
    print "# - {0}".format(sl.law_xyz2sgr_sun(x0,y0,z0)[3:])