Example #1
0
def generate_singly_diff_fluxes(n_bins,datafile=config["nu_flux"]):
    """
    This is the newest, most streamlined function for generating the singly-differential flux arrays. 
    It has the same functionality as the old ones, but now it skips the step of filling in the regular flux array before swapping to the deposited energy flux array. 

    It goes over the different kind of fluxes and builds up a 2D or 3D array, convolving the entries with the relevant differential cross section
        the dimensionality depends on whether or we are integrating over the zenith angles
    """
    print("Depositing Energy")
    data = Data(datafile)

    e_min = 10*const.GeV
    e_max = 5*const.PeV
    extra = 0
    
    all_angles = data.angles
    
    event_edges       = np.logspace(np.log10(e_min), np.log10(e_max)+extra,n_bins+1)
    e_deposited_edges = np.logspace(np.log10(e_min)      , np.log10(e_max),n_bins+1)
    angle_edges = np.linspace(min(all_angles), max(all_angles), n_bins+1) # angle is in cos(zenith), so like -1->0
    
    nuflux = {}
    errs = {}

    for key in data.get_keys(): #flavor, current, interaction 
        if "Mu_nu" in key:
            continue
        fluxy, erry = do_for_key(event_edges,e_deposited_edges,key,data=data, angles=angle_edges)
        nuflux[key] = fluxy
        errs[key] = erry


    # if global variable "angle" isn't none, then we can separate out just a single angle

    return(event_edges,e_deposited_edges, nuflux, angle_edges, errs)
Example #2
0
def downsize(filename, destination):
    if os.path.exists(destination):
        print("Already done! Skipping {}".format(destination))
        return

    dataobj = Data(filename)

    flux = {}
    for key in dataobj.get_keys():
        flux[key] = np.zeros(shape=(Ebin, zbin))
        for i_e in range(Ebin):
            for i_z in range(zbin):
                flux[key][i_e][i_z] = dataobj.get_flux( energies[i_e], key=key, angle=zeniths[i_z])

    # okay now we pickle 
    all_data = {}
    all_data["e_true"] = energies
    all_data["a_true"] = zeniths
    all_data["flux"] = flux
    f = open(destination, 'wb')
    pickle.dump(all_data, f, -1)
    f.close()
    print("Saved {}".format(destination))
Example #3
0
    def _load_flux_file(self, filename):
        """
        simplified little thing. Just loads in the fluxes we want 
        """
        f = open(filename, 'rb')
        all_data = pickle.load(f)["flux"]
        f.close()

        if False:
            dirname, filename = os.path.split(filename)
            temp = Data(filename)
            all_data = temp.fluxes

        flux = np.zeros(shape=(len(self.e_reco), len(self.a_reco)))
        for key in all_data.keys():
            if self.check_key(key):
                flux += np.array(all_data[key]) if self.ui.recoBox.isChecked(
                ) else self.apply_xs(np.array(all_data[key]), key)

        return (flux)
Example #4
0
def load(null_bool):
    filename = "null_exp.dat" if null_bool else "ster_exp.dat"

    if False: #os.path.exists(filename):
        f = open(filename,'rb')
        data = pickle.load(f)
        f.close()
        return data
    else:
        if null_bool:
            params = SterileParams()
        else:
            params = SterileParams(0.0, 0.1609, 0.0, 4.7)
        # load the fluxes 
        fu_filename = gen_filename(config["datapath"], "raw_det_flux.dat", params)
        flux = Data(fu_filename)

        data = build_mc_flux(flux)
        f = open(filename, 'wb')
        pickle.dump(data, f, -1)
        f.close()
        return data
from cascade.utils import Data, SterileParams, gen_filename, config
from cascade.sensitivity.make_from_mc import build_mc_flux
from cascade.sensitivity.eff_area_reader import quickload

import numpy as np
import matplotlib
matplotlib.use('Qt5Agg')
import matplotlib.pyplot as plt
import os

# load the fluxes
null_f = gen_filename(config["datapath"], "raw_det_flux.dat", SterileParams())
ster_f = gen_filename(config["datapath"], "raw_det_flux.dat",
                      SterileParams(0.0, 0.1609, 0.0, 4.7))
null = Data(null_f)
ster = Data(ster_f)

# get the binning information
filename = "effective_area.nu_mu.txt"
area_data = quickload(
    os.path.join(
        os.path.join(config["datapath"], "charm_search_supplemental/"),
        filename))
e_edges = np.array(area_data["e_reco"])
a_edges = np.array(area_data["cos_th"])

e_centers = 0.5 * (e_edges[:-1] + e_edges[1:])
a_centers = 0.5 * (a_edges[:-1] + a_edges[1:])

# get the flux in the centers of each of the bins
null_flux = np.zeros(shape=(len(e_centers), len(a_centers)))
Example #6
0
from math import log10

import numpy as np
import matplotlib
matplotlib.use('TkAgg')
import matplotlib.pyplot as plt
import matplotlib.cm as cm

from cascade.utils import config, gen_filename

livetime = 10 * 3600 * 24 * 365.

null_pt = gen_filename(config["datapath"], config["nu_flux"], 0., 0., 0.)
sterile_pt = gen_filename(config["datapath"], config["nu_flux"], 0.13388166,
                          0.0, 1.3)
null_dat = Data(null_pt, 4)
sterile_dat = Data(sterile_pt, 4)

n_bin = 100

_ang_range = (min(null_dat.angles), max(null_dat.angles))
_eng_range = (min(null_dat.energies), max(null_dat.energies))

angles = np.linspace(_ang_range[0], _ang_range[1], n_bin + 1)
energies = np.logspace(log10(_eng_range[0]), log10(_eng_range[1]), n_bin)

#angles = null_dat._angles
#energies = np.array(null_dat._energies)

key_list = null_dat.get_keys()
Example #7
0
    e_bins = len(energies)
    a_bins = len(zeniths)

    inistate = np.zeros(shape=(a_bins, e_bins, 2, n_nu))

    for i_e in range(e_bins):
        for i_a in range(a_bins):
            for neut_type in range(2):
                inistate[i_a][i_e][neut_type][1] = 1.0
    return inistate


# either generate the file or load it in!
expected_fn = gen_filename(config["datapath"], "unitary_prob.dat", params)
if os.path.exists(expected_fn):
    final_probs = Data(expected_fn)
else:
    kwargs = {}
    kwargs["as_data"] = False
    kwargs["state_setter"] = state_setter
    kwargs["forced_filename"] = expected_fn
    final_probs = Data(raw_flux(params, kwargs=kwargs))

# now we need three keys
curr = "CC"  # doesn't matter
neut = "nuBar"
root_flav = "Mu"
flavors = ['E', 'Mu', 'Tau']
# flavor neutrino current
keys = ["_".join([flav, neut, curr]) for flav in flavors]
Example #8
0
def raw_flux(params, kwargs={}):
    """
    This is the main function. It saves a data file for the flux with a unique name for the given physics 
    """
    if not isinstance(params, SterileParams):
        raise TypeError("Expected {} for params, not {}".format(
            SterileParams, type(params)))

    if "forced_filename" in kwargs:
        forced_filename = kwargs["forced_filename"]
    else:
        forced_filename = None
    if "state_setter" in kwargs:
        state_setter = kwargs["state_setter"]
    else:
        state_setter = get_initial_state

    if "osc" in kwargs:
        osc = kwargs["osc"]
    else:
        osc = True
    if not osc:
        print("NOT USING OSCILLATIONS")

    if "as_data" in kwargs:
        as_data = kwargs["as_data"]
    else:
        as_data = False

    if forced_filename is not None:
        if not isinstance(forced_filename, str):
            raise TypeError("Forced filename should be {}, or {}".format(
                str, None))

    print("Propagating Neutrinos at {}".format(params))
    n_nu = 4
    Emin = 1. * un.GeV
    Emax = 10. * un.PeV
    cos_zenith_min = -0.999
    cos_zenith_max = 0.2

    use_earth_interactions = True

    zeniths = nsq.linspace(cos_zenith_min, cos_zenith_max, angular_bins)
    energies = nsq.logspace(Emin, Emax,
                            energy_bins)  # DIFFERENT FROM NUMPY LOGSPACE

    nus_atm = nsq.nuSQUIDSAtm(zeniths, energies, n_nu, nsq.NeutrinoType.both,
                              use_earth_interactions)

    nus_atm.Set_MixingAngle(0, 1, 0.563942)
    nus_atm.Set_MixingAngle(0, 2, 0.154085)
    nus_atm.Set_MixingAngle(1, 2, 0.785398)

    #sterile parameters
    nus_atm.Set_MixingAngle(0, 3, params.theta03)
    nus_atm.Set_MixingAngle(1, 3, params.theta13)
    nus_atm.Set_MixingAngle(2, 3, params.theta23)
    nus_atm.Set_SquareMassDifference(3, params.msq2)

    nus_atm.Set_SquareMassDifference(1, 7.65e-05)
    nus_atm.Set_SquareMassDifference(2, 0.00247)

    nus_atm.SetNeutrinoCrossSections(xs)

    nus_atm.Set_TauRegeneration(True)

    #settting some zenith angle stuff
    nus_atm.Set_rel_error(1.0e-6)
    nus_atm.Set_abs_error(1.0e-6)
    #nus_atm.Set_GSL_step(gsl_odeiv2_step_rk4)
    nus_atm.Set_GSL_step(nsq.GSL_STEP_FUNCTIONS.GSL_STEP_RK4)

    # we load in the initial state. Generating or Loading from a file
    inistate = state_setter(energies, zeniths, n_nu, kwargs)
    if np.min(inistate) < 0:
        raise ValueError("Found negative value in inistate: {}".format(
            np.min(inistate)))
    nus_atm.Set_initial_state(inistate, nsq.Basis.flavor)

    # we turn off the progress bar for jobs run on the cobalts
    nus_atm.Set_ProgressBar(False)
    nus_atm.Set_IncludeOscillations(osc)

    nus_atm.EvolveState()

    int_en = 700
    int_cos = 100
    int_min_e = log10(Emin)
    int_max_e = log10(Emax)

    filename = ""
    if not as_data:

        if forced_filename is None:
            filename = gen_filename(config["datapath"],
                                    config["nu_flux"] + ".dat", params)
        else:
            filename = forced_filename
        print("Saving File to {}".format(filename))

        if not config["overwrite"]:
            backup(filename)

        obj = open(filename, 'wt')
    else:
        cobalt = os.environ.get("_CONDOR_SCRATCH_DIR")
        if cobalt == None or cobalt == "" or cobalt == ".":
            this_dir = None
        else:
            this_dir = cobalt
        obj = NamedTemporaryFile(mode='wt', buffering=1, dir=this_dir)

    angle = cos_zenith_min
    energy = int_min_e
    obj.write(
        "# log10(energy) cos(zenith) flux_nuE flux_nuMu flux_nuTau flux_nuEBar flux_nuMuBar flux_nuTauBar\n"
    )
    this_value = 0.0
    while angle < cos_zenith_max:
        energy = int_min_e
        while energy < int_max_e:
            #obj.write( ~string~ )
            obj.write("{} {}".format(energy, angle))
            reg_energy = pow(10., energy)
            for flavor in range(n_nu):
                this_value = nus_atm.EvalFlavor(flavor, angle, reg_energy, 0)
                if this_value < 0:
                    this_value = 0.0
                obj.write(" {}".format(this_value))
            for flavor in range(n_nu):
                this_value = nus_atm.EvalFlavor(flavor, angle, reg_energy, 1)
                if this_value < 0:
                    this_value = 0.0
                obj.write(" {}".format(this_value))

            energy += (int_max_e - int_min_e) / int_en
            obj.write("\n")

        angle += (cos_zenith_max - cos_zenith_min) / int_cos

    if as_data:
        data_obj = Data(obj.name)
        obj.close()  # deletes tempfile
        return data_obj
    else:
        obj.close()
        return (filename)