[17] | 1 | from __future__ import absolute_import
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| 2 |
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| 3 | import collections
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| 4 | import numpy as np
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| 5 |
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[63] | 6 | import pointingerrorgenerators
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[17] | 7 |
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[63] | 8 |
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[17] | 9 | class UVMapGenerator(object):
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| 10 | """Class to generate the UV map of the simulated observation.
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| 11 | """
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| 12 |
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[63] | 13 | def __init__(self, parameters, previous_results):
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[17] | 14 | self.parameters = parameters
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[63] | 15 | self.previous_results = previous_results
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[17] | 16 | self.result = collections.OrderedDict()
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| 17 |
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| 18 | def run(self):
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| 19 | print 'UVMapGenerator.run'
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[63] | 20 |
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| 21 | # The FTS mirror positions per scan. This is found from the
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| 22 | # FTS results that should have already been calculated.
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| 23 | fts = self.previous_results['fts']
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| 24 | self.result['ftsnsample'] = ftsnsample = fts['ftsnsample']
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| 25 | delta_opd = fts['delta_opd']
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| 26 |
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[17] | 27 | interferometer = self.parameters['substages']['Interferometer']
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| 28 |
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| 29 | # slightly awkward getting pattern value as it's keyed by its
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| 30 | # row number in the spreadsheet
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| 31 | row = interferometer['Pattern'].keys()[0]
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| 32 | pattern = interferometer['Pattern'][row]
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| 33 |
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| 34 | if pattern.lower() == 'spiral':
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| 35 | bmax = interferometer['bmax [m]'][row]
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| 36 | bmin = interferometer['bmin [m]'][row]
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| 37 | n_baselines = int(interferometer['Num Baselines'][row])
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| 38 | bstep = interferometer['bstep [m]'][row]
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| 39 |
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| 40 | # baseline increases by bstep for each circuit of spiral
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| 41 | n_laps = (bmax - bmin) / bstep
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| 42 |
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[63] | 43 | # n_baselines = 50
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[17] | 44 | bxby = np.zeros([n_baselines,2])
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[63] | 45 | # bxby[0,0] = 10.0
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| 46 | # bxby[0,1] = 0.0
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| 47 | # bxby[1,0] = 20.0
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| 48 | # bxby[1,1] = 0.0
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| 49 | # bxby[2,0] = 30.0
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| 50 | # bxby[2,1] = 0.0
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| 51 | # bxby[3,0] = 40.0
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| 52 | # bxby[3,1] = 0.0
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| 53 | # bxby[4,0] = 0.0
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| 54 | # bxby[4,1] = 10.0
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| 55 | # bxby[5,0] = 0.0
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| 56 | # bxby[5,1] = 20.0
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| 57 | # bxby[6,0] = 0.0
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| 58 | # bxby[6,1] = 30.0
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| 59 | # bxby[7,0] = 0.0
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| 60 | # bxby[7,1] = 40.0
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| 61 | # bxby[8,0] = 40.0
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| 62 | # bxby[8,1] = 40.0
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| 63 | # bxby[9,0] = 20.0
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| 64 | # bxby[9,1] = 20.0
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| 65 | # bxby[10,0] = 30.0
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| 66 | # bxby[10,1] = 30.0
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[17] | 67 |
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[63] | 68 |
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[17] | 69 | # n_baselines is total number of points along spiral
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[63] | 70 | for ib in range(n_baselines):
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[17] | 71 | # phi is angle around spiral, r its radius
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[63] | 72 | phi = n_laps * 2 * np.pi * (n_baselines-ib) / n_baselines
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[17] | 73 | r = bmin + bstep * phi / (2 * np.pi)
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| 74 |
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[63] | 75 | bxby[ib,:] = [r * np.cos(phi), r * np.sin(phi)]
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[17] | 76 |
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[63] | 77 | self.result['pattern'] = pattern
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[17] | 78 | self.result['bxby'] = bxby
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| 79 | self.result['bmin'] = bmin
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| 80 | self.result['bmax'] = bmax
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| 81 | self.result['n_baselines'] = n_baselines
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| 82 |
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[63] | 83 | # Construct the obs framework that will give one FTS
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| 84 | # scan at each baseline.
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| 85 |
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| 86 | # The framework will hold the baseline and FTS mirror position
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| 87 | # for each time that the detector is read.
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| 88 |
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| 89 | # The observation consists of a series of FTS scans. The
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| 90 | # instrument baseline, pointing etc. can change continuously
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| 91 | # as the scan is performed.
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| 92 |
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| 93 | obs_framework = []
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| 94 | Config = collections.namedtuple('Config', [
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| 95 | 'scan_number',
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| 96 | 'baseline_x', 'baseline_y', 'baseline_z', 'baseline_number',
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| 97 | 'fts_position', 'fts_nominal_position', 'fts_start',
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| 98 | 'point1_x_error', 'point1_y_error',
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| 99 | 'point2_x_error', 'point2_y_error',
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| 100 | 'data'],
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| 101 | verbose=False)
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| 102 |
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| 103 | for ib in range(n_baselines):
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| 104 | opd_start = -((ftsnsample + 1) / 2) * delta_opd
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| 105 |
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| 106 | fts_start = True
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| 107 | for ifts in np.arange(ftsnsample):
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| 108 | opd = opd_start + float(ifts) * delta_opd
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| 109 | fts_mirror = opd / 2.0
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| 110 | config = Config(ib, bxby[ib][0], bxby[ib][1], 0.0, ib,
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| 111 | fts_mirror, fts_mirror, fts_start, 0.0, 0.0, 0.0,
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| 112 | 0.0, None)
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| 113 | obs_framework.append(config)
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| 114 | fts_start = False
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| 115 |
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| 116 | png = pointingerrorgenerators.GaussianPointingErrors(mu0=1.0,
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| 117 | sigma0=0.0, mu1=0.0, sigma1=0.0)
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| 118 | png.fill(obs_framework)
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| 119 |
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| 120 | self.result['obs_framework'] = obs_framework
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| 121 |
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[17] | 122 | else:
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| 123 | raise Exception, 'unknown baseline pattern: %s' % pattern
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| 124 |
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| 125 | return self.result
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| 126 |
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| 127 | def __repr__(self):
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[63] | 128 | return '''
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| 129 | UVMapGenerator:
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| 130 | uv pattern : {pattern}
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| 131 | FTS samples/scan: {ftsnsample}
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| 132 | obs.framework length: {len_framework}
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| 133 | '''.format(
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| 134 | pattern=self.result['pattern'],
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| 135 | ftsnsample=self.result['ftsnsample'],
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| 136 | len_framework=len(self.result['obs_framework']))
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[17] | 137 |
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[63] | 138 |
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