Noe Brucy
107 lines
2.5 KiB
Python
107 lines
2.5 KiB
Python
# coding: utf-8
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import numpy as np
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import pandas as pd
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from plotter import U
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import postprocessor
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mp = 1.4 * 1.66 * 10 ** (-24) * U.g
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z0 = 150 * U.pc
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sink_header = [
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"Id",
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"M",
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"dmf",
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"x",
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"y",
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"z",
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"vx",
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"vy",
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"vz",
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"rot_period",
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"lx",
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"ly",
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"lz",
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"acc_rate",
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"acc_lum",
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"age",
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"int_lum",
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"Teff",
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]
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def convert_coldens_s(n0):
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return (np.sqrt(2 * np.pi) * mp * z0 * (n0 * U.cm ** (-3))).express(U.coldens)
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convert_coldens = np.vectorize(convert_coldens_s)
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def get_dispersion(dset, i):
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"""
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Compute dispersion from dset["name"]
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"""
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vel = dset["vel"][:, i]
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mass = dset["mass"]
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mass_tot = np.sum(mass)
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mean = np.sum(mass * vel) / mass_tot
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return np.sqrt(np.sum(mass * (vel - mean) ** 2) / mass_tot)
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def get_sinks(pp):
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csv_name = f"{pp.path}/output_{pp.num:05}/sink_{pp.num:05}.csv"
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return pd.read_csv(csv_name, header=None, names=sink_header)
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def analyze_box(pp):
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pp.cells["mass"] = postprocessor.mass_func(pp.cells)
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pp.coldens("z")
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coldens = pp.get_value("/maps/coldens_z", unit=U.coldens)
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sinks = get_sinks(pp)
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sinks["vel"] = np.array([sinks.vx, sinks.vy, sinks.vz])
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sinks["vel"] *= pp.info["unit_velocity"].express(U.km_s)
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sinks["mass"] = sinks.M
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res = {}
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dirs = ["x", "y", "z"]
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res["time"] = pp.info["time"] * pp.info["unit_time"].express(U.Myr)
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for i, dir in enumerate(dirs):
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res[f"sigma_{dir}"] = get_dispersion(pp.cells, i) * pp.info[
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"unit_velocity"
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].express(U.km_s)
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res[f"sigma_sinks_{dir}"] = get_dispersion(sinks, i) * pp.info[
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"unit_velocity"
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].express(U.km_s)
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res["coldens_mean"] = np.mean(coldens)
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res["n0"] = pp.get_nml("cloud_params/dens0")
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res["mass"] = np.sum(
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pp.cells["mass"]
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* (pp.info["unit_density"] * pp.info["unit_length"] ** 3).express(U.Msun)
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)
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res["coldens_initial"] = convert_coldens_s(res["n0"])
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res["mass_initial"] = res["coldens_initial"] * 1e6
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res["coldens_mean"] = np.mean(coldens)
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res["coldens_beam"] = res["mass"] / (pp.info["unit_length"].express(U.pc)) ** 2
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res["nsink"] = sinks.M.count()
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res["mass_sink"] = np.sum(sinks.M)
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return res
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def load_wrapper(pp, fun):
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"""
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Wrapper to load_unload data and map function
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"""
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pp.load_cells(keys=["pos", "vel", "dx", "rho"])
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pp.coldens("z")
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res = fun(pp)
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pp.unload_cells()
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pp.unload_parts()
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del pp.dm
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del pp.gas
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del pp.stars
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return res
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def allinone(pp):
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return load_wrapper(pp, analyze_box)
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