Noe Brucy
185 lines
5.4 KiB
Python
185 lines
5.4 KiB
Python
# coding: utf-8
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import numpy as np
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from plotter import U
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def get_dispersion(dset, name):
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"""
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Compute dispersion from dset["name"]
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"""
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vel = dset[name]
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mass = dset["mass_kg"]
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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_polar_sigma(dset):
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"""
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Get speed dispersion in polar coordinates
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"""
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return {
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velname: get_dispersion(dset, velname) for velname in ["velphi", "velr", "velz"]
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}
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def get_gas_dm_stars(pp):
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# Load arrays
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pp.load_parts()
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pp.load_cells()
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cells = pp.cells
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parts = pp.parts
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# Compute extra fields and convert units
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for dset in (cells, parts):
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dset["pos_kpc"] = dset["pos"] - np.array([0.5, 0.5, 0.5])
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dset["pos_kpc"] *= pp.info["unit_length"].express(U.kpc)
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dset["r"] = np.sqrt(np.sum(dset["pos_kpc"][:, :2] ** 2, axis=1))
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dset["phi"] = np.angle(dset["pos_kpc"][:, 0] + dset["pos_kpc"][:, 1] * 1j)
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dset["velphi"] = pp.getter_vect_phi(dset, "vel") * pp.info[
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"unit_velocity"
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].express(U.km_s)
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dset["velr"] = pp.getter_vect_r(dset, "vel") * pp.info["unit_velocity"].express(
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U.km_s
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)
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dset["velz"] = dset["vel"][:, 2] * pp.info["unit_velocity"].express(U.km_s)
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cells["mass_kg"] = (
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cells["rho"]
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* cells["dx"] ** 3
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* (pp.info["unit_density"] * pp.info["unit_length"] ** 3).express(U.kg)
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)
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parts["mass_kg"] = parts["mass"] * pp.info["unit_mass"].express(U.kg)
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for dset in (cells, parts):
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dset["ek"] = dset["mass_kg"] * np.sum(dset["vel"] ** 2, axis=1)
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dset["ek"] *= (U.kg * pp.info["unit_velocity"] ** 2).express(U.J)
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# Separate DM from stars
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mass_dm = np.max(parts["mass_kg"])
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mask_dm = parts["mass_kg"] == mass_dm
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mask_star = parts["mass_kg"] < mass_dm
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# Create separated arrays
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gas = cells
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dm = {key: parts[key][mask_dm] for key in parts}
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stars = {key: parts[key][mask_star] for key in parts}
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# Store arrays and return them
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pp.gas = gas
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pp.dm = dm
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pp.stars = stars
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return gas, dm, stars
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def extract_polar_region(dset, r=4, dr=0.5, phi=0, dphi=0.125, z=0, dz=0.5):
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"""
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Returns a mask for dset of the polar volume within polar coordinates
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[r - dr, r + dr] x [phi - dphi, phi + dphi] x [z -dz, z + dz]
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"""
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mask_box = (
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(np.abs(dset["r"] - r) < dr)
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& (np.abs(dset["phi"] - phi) < dphi)
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& (np.abs(dset["pos"][:, 2] - z) < dz)
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)
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return {key: dset[key][mask_box] for key in dset}
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def sector_analysis(pp, r=4, dr=0.5, phi=0, dphi=0.125, z=0, dz=0.5):
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"""
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Analyze box at given coordinates
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"""
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gds = [pp.gas, pp.dm, pp.stars]
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gds_box = [extract_polar_region(dset, r, dr, phi, dphi, z, dz) for dset in gds]
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result = {}
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result["ek"] = np.array([np.sum(dset["ek"]) for dset in gds_box]) # J
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result["mass"] = np.array([np.sum(dset["mass_kg"]) for dset in gds_box]) # kg
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result["ek_spe"] = result["ek"] / result["mass"] # J.kg^-1
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for dset in gds_box:
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sigma = get_polar_sigma(dset)
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for key in sigma:
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keyres = "sigma_" + key
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if keyres in result:
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result[keyres].append(sigma[key])
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else:
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result[keyres] = [sigma[key]]
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return result
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def ring_analysis(pp, r=4, dr=0.5, dphi=0.125, z=0, dz=0.5, do_mean=True):
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"""
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Compute the average at a given of quantities computed in polar sectors.
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"""
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phi_sectors = np.arange(-np.pi + dphi, np.pi - dphi, 2 * dphi)
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data_sec = [sector_analysis(pp, r, dr, phi, dphi, z, dz) for phi in phi_sectors]
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data = {}
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mwavg = {}
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tot_mass = [np.sum([d["mass"][i] for d in data_sec]) for i in range(3)]
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for key in data_sec[0]:
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mwavg[key] = []
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for i in range(3):
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mwavg[key].append(
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np.sum([d["mass"][i] * d[key][i] for d in data_sec]) / tot_mass[i]
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)
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data[key] = np.array([d[key] for d in data_sec])
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return mwavg, phi_sectors, data
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def get_time_from_relax(pp):
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pp.load_parts()
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try:
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epoch = pp.parts["epoch"].copy()
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epoch *= pp.info["unit_time"].express(U.Myr)
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trelax = np.min(epoch[epoch > 0])
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tfromrelax = np.max(epoch - trelax)
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except KeyError:
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tfromrelax = 0.0
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return tfromrelax
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def get_last_sfr(pp):
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pp.load_parts()
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try:
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epoch = pp.parts["epoch"].copy()
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epoch *= pp.info["unit_time"].express(U.year)
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mass = pp.parts["mass"].copy()
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mass *= pp.info["unit_mass"].express(U.Msun)
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mask = epoch > 0
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masstot, time = np.histogram(epoch[mask], weights=mass[mask], bins=100)
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dtime = np.diff(time)
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sfr = masstot[-1] / dtime[-1]
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except KeyError:
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sfr = 0.0
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return sfr
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def colmean4kpc(pp):
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pp.coldens("z")
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pp.rr("z")
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col = pp.get_value("/maps/coldens_z", unit=U.coldens)
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rr = pp.get_value("/maps/rr_z", unit=U.kpc)
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colmean = np.mean(col[np.abs(rr - 4) < 0.5])
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return colmean
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def allinone(pp):
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get_gas_dm_stars(pp)
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res = {}
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res["run"] = pp.run
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res["num"] = pp.num
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res["coldens"] = colmean4kpc(pp)
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res["sfr"] = get_last_sfr(pp)
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res["time"] = get_time_from_relax(pp)
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ring = ring_analysis(pp)[0]
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for key in ring:
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for i, fluid in enumerate(["gas", "dm", "stars"]):
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res[f"{key}_{fluid}"] = ring[key][i]
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return res
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