[1826] | 1 | __all__ = ["model", "skydip"]
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[1689] | 2 | import os
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| 3 | import math
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[1826] | 4 | from asap.scantable import scantable
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| 5 | from asap.asapmath import merge
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| 6 | from asap.asapfitter import fitter
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| 7 | from asap.selector import selector
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| 8 | from asap.parameters import rcParams
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[1725] | 9 | from asap._asap import atmosphere
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[1689] | 10 |
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[1725] | 11 |
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| 12 | class model(object):
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| 13 | def _to_pascals(self, val):
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| 14 | if val > 2000:
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| 15 | return val
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| 16 | return val*100
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| 17 |
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| 18 | def __init__(self, temperature=288, pressure=101325., humidity=0.5,
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| 19 | elevation=700.):
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| 20 | """
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| 21 | This class implements opacity/atmospheric brightness temperature model
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[1726] | 22 | equivalent to the model available in MIRIAD. The actual math is a
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[1725] | 23 | convertion of the Fortran code written by Bob Sault for MIRIAD.
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[1726] | 24 | It implements a simple model of the atmosphere and Liebe's model (1985)
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[1725] | 25 | of the complex refractive index of air.
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| 26 |
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| 27 | The model of the atmosphere is one with an exponential fall-off in
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[1726] | 28 | the water vapour content (scale height of 1540 m) and a temperature
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| 29 | lapse rate of 6.5 mK/m. Otherwise the atmosphere obeys the ideal gas
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[1725] | 30 | equation and hydrostatic equilibrium.
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| 31 |
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[1726] | 32 | Note, the model includes atmospheric lines up to 800 GHz, but was not
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| 33 | rigorously tested above 100 GHz and for instruments located at
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[1725] | 34 | a significant elevation. For high-elevation sites it may be necessary to
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| 35 | adjust scale height and lapse rate.
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| 36 |
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| 37 | Parameters:
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| 38 | temperature: air temperature at the observatory (K)
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[1726] | 39 | pressure: air pressure at the sea level if the observatory
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| 40 | elevation is set to non-zero value (note, by
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[1725] | 41 | default is set to 700m) or at the observatory
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[1726] | 42 | ground level if the elevation is set to 0. (The
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[1725] | 43 | value is in Pascals or hPa, default 101325 Pa
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[1726] | 44 | humidity: air humidity at the observatory (fractional),
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[1725] | 45 | default is 0.5
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| 46 | elevation: observatory elevation about sea level (in meters)
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| 47 | """
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[1826] | 48 | self._atm = atmosphere(temperature, self._to_pascals(pressure),
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[1754] | 49 | humidity)
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[1726] | 50 | self.set_observatory_elevation(elevation)
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[1725] | 51 |
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| 52 | def get_opacities(self, freq, elevation=None):
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| 53 | """Get the opacity value(s) for the fiven frequency(ies).
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| 54 | If no elevation is given the opacities for the zenith are returned.
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| 55 | If an elevation is specified refraction is also taken into account.
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| 56 | Parameters:
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| 57 | freq: a frequency value in Hz, or a list of frequency values.
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| 58 | One opacity value per frequency is returned as a scalar
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| 59 | or list.
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| 60 | elevation: the elevation at which to compute the opacity. If `None`
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| 61 | is given (default) the zenith opacity is returned.
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| 62 |
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| 63 |
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| 64 | """
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| 65 | func = None
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| 66 | if isinstance(freq, (list, tuple)):
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| 67 | if elevation is None:
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| 68 | return self._atm.zenith_opacities(freq)
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| 69 | else:
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| 70 | elevation *= math.pi/180.
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| 71 | return self._atm.opacities(freq, elevation)
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| 72 | else:
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| 73 | if elevation is None:
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| 74 | return self._atm.zenith_opacity(freq)
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| 75 | else:
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| 76 | elevation *= math.pi/180.
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| 77 | return self._atm.opacity(freq, elevation)
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| 78 |
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| 79 | def set_weather(self, temperature, pressure, humidity):
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| 80 | """Update the model using the given environmental parameters.
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| 81 | Parameters:
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| 82 | temperature: air temperature at the observatory (K)
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[1726] | 83 | pressure: air pressure at the sea level if the observatory
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| 84 | elevation is set to non-zero value (note, by
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[1725] | 85 | default is set to 700m) or at the observatory
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[1726] | 86 | ground level if the elevation is set to 0. (The
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[1725] | 87 | value is in Pascals or hPa, default 101325 Pa
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[1726] | 88 | humidity: air humidity at the observatory (fractional),
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[1725] | 89 | default is 0.5
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| 90 | """
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| 91 | pressure = self._to_pascals(pressure)
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| 92 | self._atm.set_weather(temperature, pressure, humidity)
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| 93 |
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[1726] | 94 | def set_observatory_elevation(self, elevation):
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[1725] | 95 | """Update the model using the given the observatory elevation
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| 96 | Parameters:
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| 97 | elevation: the elevation at which to compute the opacity. If `None`
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| 98 | is given (default) the zenith opacity is returned.
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| 99 | """
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[1754] | 100 | self._atm.set_observatory_elevation(elevation)
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[1725] | 101 |
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| 102 |
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[1689] | 103 | def _import_data(data):
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[1722] | 104 | if not isinstance(data, (list,tuple)):
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[1689] | 105 | if isinstance(data, scantable):
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| 106 | return data
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| 107 | elif isinstance(data, str):
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| 108 | return scantable(data)
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| 109 | tables = []
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| 110 | for d in data:
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| 111 | if isinstance(d, scantable):
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| 112 | tables.append(d)
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| 113 | elif isinstance(d, str):
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| 114 | if os.path.exists(d):
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| 115 | tables.append(scantable(d))
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| 116 | else:
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| 117 | raise IOError("Data file doesn't exists")
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| 118 | else:
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| 119 | raise TypeError("data is not a scantable or valid file")
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| 120 | return merge(tables)
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| 121 |
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[1725] | 122 | def skydip(data, averagepol=True, tsky=300., plot=False,
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| 123 | temperature=288, pressure=101325., humidity=0.5):
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[1689] | 124 | """Determine the opacity from a set of 'skydip' obervations.
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| 125 | This can be any set of observations over a range of elevations,
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| 126 | but will ususally be a dedicated (set of) scan(s).
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| 127 | Return a list of 'n' opacities for 'n' IFs. In case of averagepol
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| 128 | being 'False' a list of 'n*m' elements where 'm' is the number of
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| 129 | polarisations, e.g.
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| 130 | nIF = 3, nPol = 2 => [if0pol0, if0pol1, if1pol0, if1pol1, if2pol0, if2pol1]
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| 131 |
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| 132 | The opacity is determined by fitting a first order polynomial to:
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| 133 |
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| 134 |
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| 135 | Tsys(airmass) = p0 + airmass*p1
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| 136 |
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| 137 | where
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| 138 |
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| 139 | airmass = 1/sin(elevation)
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| 140 |
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| 141 | tau = p1/Tsky
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| 142 |
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| 143 | Parameters:
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| 144 | data: a list of file names or scantables or a single
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| 145 | file name or scantable.
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| 146 | averagepol: Return the average of the opacities for the polarisations
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| 147 | This might be useful to set to 'False' if one polarisation
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| 148 | is corrupted (Mopra). If set to 'False', an opacity value
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| 149 | per polarisation is returned.
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| 150 | tksy: The sky temperature (default 300.0K). This might
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| 151 | be read from the data in the future.
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| 152 | plot: Plot each fit (airmass vs. Tsys). Default is 'False'
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| 153 | """
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[1722] | 154 | rcsave = rcParams['verbose']
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| 155 | rcParams['verbose'] = False
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[1725] | 156 | if plot:
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| 157 | from matplotlib import pylab
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[1689] | 158 | scan = _import_data(data)
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| 159 | f = fitter()
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| 160 | f.set_function(poly=1)
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| 161 | sel = selector()
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| 162 | basesel = scan.get_selection()
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| 163 | inos = scan.getifnos()
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| 164 | pnos = scan.getpolnos()
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| 165 | opacities = []
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[1754] | 166 | om = model(temperature, pressure, humidity)
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[1689] | 167 | for ino in inos:
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| 168 | sel.set_ifs(ino)
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| 169 | opacity = []
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[1722] | 170 | fits = []
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| 171 | airms = []
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| 172 | tsyss = []
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| 173 | if plot:
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[1725] | 174 | pylab.cla()
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| 175 | pylab.ioff()
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| 176 | pylab.clf()
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| 177 | pylab.xlabel("Airmass")
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| 178 | pylab.ylabel(r"$T_{sys}$")
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[1689] | 179 | for pno in pnos:
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| 180 | sel.set_polarisations(pno)
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| 181 | scan.set_selection(basesel+sel)
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[1722] | 182 | freq = scan.get_coordinate(0).get_reference_value()/1e9
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| 183 | freqstr = "%0.4f GHz" % freq
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[1689] | 184 | tsys = scan.get_tsys()
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| 185 | elev = scan.get_elevation()
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| 186 | airmass = [ 1./math.sin(i) for i in elev ]
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[1722] | 187 | airms.append(airmass)
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| 188 | tsyss.append(tsys)
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[1689] | 189 | f.set_data(airmass, tsys)
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| 190 | f.fit()
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[1722] | 191 | fits.append(f.get_fit())
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[1689] | 192 | params = f.get_parameters()["params"]
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| 193 | opacity.append(params[1]/tsky)
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| 194 | if averagepol:
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| 195 | opacities.append(sum(opacity)/len(opacity))
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| 196 | else:
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| 197 | opacities += opacity
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[1722] | 198 | if plot:
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| 199 | colors = ['b','g','k']
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[1725] | 200 | n = len(airms)
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| 201 | for i in range(n):
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| 202 | pylab.plot(airms[i], tsyss[i], 'o', color=colors[i])
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| 203 | pylab.plot(airms[i], fits[i], '-', color=colors[i])
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| 204 | pylab.figtext(0.7,0.3-(i/30.0),
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[1722] | 205 | r"$\tau_{fit}=%0.2f$" % opacity[i],
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| 206 | color=colors[i])
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| 207 | if averagepol:
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[1725] | 208 | pylab.figtext(0.7,0.3-(n/30.0),
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| 209 | r"$\tau_{avg}=%0.2f$" % opacities[-1],
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[1722] | 210 | color='r')
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[1725] | 211 | n +=1
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| 212 | pylab.figtext(0.7,0.3-(n/30.0),
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| 213 | r"$\tau_{model}=%0.2f$" % om.get_opacities(freq*1e9),
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| 214 | color='grey')
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[1726] | 215 |
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[1725] | 216 | pylab.title("IF%d : %s" % (ino, freqstr))
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[1722] | 217 |
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[1725] | 218 | pylab.ion()
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| 219 | pylab.draw()
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[1722] | 220 | raw_input("Hit <return> for next fit...")
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[1689] | 221 | sel.reset()
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[1722] | 222 |
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[1689] | 223 | scan.set_selection(basesel)
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[1722] | 224 | rcParams['verbose'] = rcsave
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| 225 | if plot:
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[1725] | 226 | pylab.close()
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[1689] | 227 | return opacities
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