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author | Aaron LI <aaronly.me@outlook.com> | 2016-06-28 13:04:44 +0800 |
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committer | Aaron LI <aaronly.me@outlook.com> | 2016-06-28 13:04:44 +0800 |
commit | 42a24715eac465bec8e73a36726589869deed207 (patch) | |
tree | 136435cf404d3be898c74d7e63e1e11c015ee09b | |
parent | d9f691c7961c3ea8ff196f1668b0444f86bf75aa (diff) | |
download | cexcess-42a24715eac465bec8e73a36726589869deed207.tar.bz2 |
deproject_sbp.py: fit smoothing splines by calling R "mgcv::gam()"
-rwxr-xr-x | deproject_sbp.py | 124 |
1 files changed, 111 insertions, 13 deletions
diff --git a/deproject_sbp.py b/deproject_sbp.py index 413cb03..991cd30 100755 --- a/deproject_sbp.py +++ b/deproject_sbp.py @@ -2,9 +2,13 @@ # # Weitian LI # Created: 2016-06-10 -# Updated: 2016-06-26 +# Updated: 2016-06-27 # # Change logs: +# 2016-06-27: +# * Fit smoothing spline to SBP and cooling function profiles by +# calling the R `mgcv::gam()`: "fit_spline()" and "eval_spline()" +# * Update "plot()" to also plot the fitted smoothing spline # 2016-06-26: # * Split out method "save()" for class "BrightnessProfile" # * Split classes 'FitModel', 'ABModel' and 'PLCModel' into separate @@ -164,6 +168,9 @@ from matplotlib.backends.backend_agg import FigureCanvasAgg as FigureCanvas from matplotlib.figure import Figure from configobj import ConfigObj +import rpy2.robjects as ro +from rpy2.robjects.packages import importr + from astro_params import AstroParams, ChandraPixel from projection import Projection from fitting_models import ABModel, PLCModel @@ -629,6 +636,8 @@ class BrightnessProfile: * The brightness should have unit [ photon s^-1 cm^-2 pixel^-2 ], i.e., [ Flux pixel^-2 ] (radial profile column `SUR_FLUX`) """ + # available splines + SPLINES = ["brightness", "cooling_function"] # allowed density profile types DENSITY_TYPES = ["electron", "gas"] # input SBP data: [r, r_err, s, s_err] @@ -642,12 +651,18 @@ class BrightnessProfile: pixel = None # flag to indicate whether the units are converted units_converted = False - # fitted smoothing spline to the SBP - s_spline = None # calculated electron density profile ne = None # calculated gas mass density profile rho_gas = None + # fitted smoothing spline to the SBP + s_spline = None + s_spline_log10 = None + # fitted smoothing spline to the cooling function profile + cf_spline = None + cf_spline_log10 = None + # call R through `rpy2` + mgcv = importr("mgcv") def __init__(self, sbp_data, cf_data, z): self.load_data(data=sbp_data) @@ -685,6 +700,80 @@ class BrightnessProfile: def get_radius(self): return (self.r.copy(), self.r_err.copy()) + def fit_spline(self, spline, log10=True): + """ + Fit a smoothing line to the specified spline data, + by calling the R `mgcv::gam()` function. + + If 'log10' is True, the input data are first applied the log-scale + transform, and then fitted by the smoothing spline. + + The fitted spline allows extrapolation. + """ + if spline not in self.SPLINES: + raise ValueError("invalid spline: %s" % spline) + # + if spline == "brightness": + if log10: + x = ro.FloatVector(np.log10(self.r)) + y = ro.FloatVector(np.log10(self.s)) + self.s_spline_log10 = True + else: + x = ro.FloatVector(self.r) + y = ro.FloatVector(self.s) + self.s_spline_log10 = False + weights = ro.FloatVector(self.s / self.s_err) + self.s_spline = self.mgcv.gam( + ro.Formula("y ~ s(x, bs='ps')"), + weights=weights, + data=ro.DataFrame({"x": x, "y": y}), + method="REML") + elif spline == "cooling_function": + if log10: + x = ro.FloatVector(np.log10(self.cf_radius)) + y = ro.FloatVector(np.log10(self.cf_value)) + self.cf_spline_log10 = True + else: + x = ro.FloatVector(self.cf_radius) + y = ro.FloatVector(self.cf_value) + self.cf_spline_log10 = False + self.cf_spline = self.mgcv.gam( + ro.Formula("y ~ s(x, bs='ps')"), + data=ro.DataFrame({"x": x, "y": y}), + method="REML") + + def eval_spline(self, spline, x): + """ + Evaluate the specified spline at the supplied positions. + Also check whether the spline was fitted in the log-scale space, + and transform the evaluated values if necessary. + """ + x = np.array(x) + if x.shape == (): + x = x.reshape((1,)) + if spline == "brightness": + spl = self.s_spline + log10 = self.s_spline_log10 + elif spline == "cooling_function": + spl = self.cf_spline + log10 = self.cf_spline_log10 + else: + raise ValueError("invalid spline: %s" % spline) + # + if log10: + x_new = ro.ListVector({"x": ro.FloatVector(np.log10(x))}) + y_pred = self.mgcv.predict_gam(spl, newdata=x_new) + y_pred = 10 ** np.array(y_pred) + else: + x_new = ro.ListVector({"x": ro.FloatVector(x)}) + y_pred = self.mgcv.predict_gam(spl, newdata=x_new) + y_pred = np.array(y_pred) + # + if len(y_pred) == 1: + return y_pred[0] + else: + return y_pred + def calc_electron_density(self): """ Deproject the surface brightness profile to derive the 3D @@ -693,14 +782,18 @@ class BrightnessProfile: unit: [ cm^-3 ] if the units converted for input data """ + if self.s_spline is None: + self.fit_spline(spline="brightness", log10=True) + if self.cf_spline is None: + self.fit_spline(spline="cooling_function", log10=False) + # + s_new = self.eval_spline(spline="brightness", x=self.r) + cf_new = self.eval_spline(spline="cooling_function", x=self.r) + # projector = Projection(rout=self.r+self.r_err) - s_deproj = projector.deproject(self.s) - # allow extrapolation - # XXX: smooth spline better ?? - cf_spline = interpolate.InterpolatedUnivariateSpline( - x=self.cf_radius, y=self.cf_value, ext="const") + s_deproj = projector.deproject(s_new) # emission measure per unit volume - em_v = s_deproj / cf_spline(self.r) + em_v = s_deproj / cf_new ne = np.sqrt(em_v * AstroParams.ratio_ne_np) self.ne = ne return ne @@ -764,6 +857,11 @@ class BrightnessProfile: eb = ax.errorbar(r, self.s, xerr=r_err, yerr=self.s_err, fmt="none", elinewidth=2, capthick=2, label="Brightness profile") + # fitted smoothing spline to SBP + s_new = self.eval_spline(spline="brightness", x=self.r) + line1, = ax.plot(r, s_new, linestyle="dashed", linewidth=2, + label="SBP smoothing spline") + # r_min = 1.0 r_max = max(r + r_err) s_min = min(self.s) / 1.2 @@ -776,9 +874,9 @@ class BrightnessProfile: ax.set_ylabel(r"Surface brightness (%s)" % s_unit) # deprojected density profile ax2 = ax.twinx() - line, = ax2.plot(r, density, color="black", - linestyle="solid", linewidth=2, - label="Density profile") + line2, = ax2.plot(r, density, color="black", + linestyle="solid", linewidth=2, + label="Density profile") d_min = min(density) / 1.2 d_max = max(density) * 1.2 ax2.set_xlim(r_min, r_max) @@ -786,7 +884,7 @@ class BrightnessProfile: ax2.set_yscale(ax.get_yscale()) ax2.set_ylabel(r"%s (%s)" % (d_name, d_unit)) # legend - handles = [eb, line] + handles = [eb, line1, line2] labels = [h.get_label() for h in handles] ax.legend(handles=handles, labels=labels, loc=0) fig.tight_layout() |