Coverage for pygeodesy/trf.py : 96%

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# -*- coding: utf-8 -*-
Classes L{RefFrame}, registry L{RefFrames} and L{TRFError}.
Transcoded from I{Chris Veness'} (C) 2006-2019 JavaScript originals U{latlon-ellipsoidal-referenceframe.js<https://GitHub.com/chrisveness/geodesy/blob/master/ latlon-ellipsoidal-referenceframe.js>} and U{latlon-ellipsoidal-referenceframe-txparams.js <https://GitHub.com/chrisveness/geodesy/blob/master/latlon-ellipsoidal-referenceframe-txparams.js>}.
Following is a copy of the comments in I{Veness}' U{latlon-ellipsoidal-referenceframe.js <https://GitHub.com/chrisveness/geodesy/blob/master/latlon-ellipsoidal-referenceframe.js>}.
Modern geodetic reference frames: a latitude/longitude point defines a geographic location on, above or below the earth’s surface, measured in degrees from the equator and the U{International Reference Meridian<https://WikiPedia.org/wiki/IERS_Reference_Meridian>} (IRM) and metres above the ellipsoid within a given I{Terrestrial Reference Frame} at a given I{epoch}.
This is scratching the surface of complexities involved in high precision geodesy, but may be of interest and/or value to those with less demanding requirements. More information U{here <https://www.Movable-Type.co.UK/scripts/geodesy-library.html>} and U{here <https://www.Movable-Type.co.UK/scripts/geodesy-library.html#latlon-ellipsoidal-referenceframe>}.
Note that I{ITRF solutions} do not directly use an ellipsoid, but are specified by Cartesian coordinates. The GRS80 ellipsoid is recommended for transformations to geographical coordinates.
Note WGS84(G730/G873/G1150) are coincident with ITRF at 10-centimetre level, see also U{here <ftp://ITRF.ENSG.IGN.FR/pub/itrf/WGS84.TXT>}. WGS84(G1674) and ITRF20014 / ITRF2008 I{"are likely to agree at the centimeter level"}, see also U{QPS/Qinsy<https://Confluence.QPS.NL/qinsy/ en/how-to-deal-with-etrs89-datum-and-time-dependent-transformation-parameters-45353274.html>}.
@var RefFrames.ETRF2000: RefFrame(name='ETRF2000', epoch=2005, ellipsoid=Ellipsoid(name='GRS80') @var RefFrames.GDA2020: RefFrame(name='GDA2020', epoch=2020, ellipsoid=Ellipsoid(name='GRS80') @var RefFrames.GDA94: RefFrame(name='GDA94', epoch=1994, ellipsoid=Ellipsoid(name='GRS80') @var RefFrames.ITRF2000: RefFrame(name='ITRF2000', epoch=1997, ellipsoid=Ellipsoid(name='GRS80') @var RefFrames.ITRF2005: RefFrame(name='ITRF2005', epoch=2000, ellipsoid=Ellipsoid(name='GRS80') @var RefFrames.ITRF2008: RefFrame(name='ITRF2008', epoch=2005, ellipsoid=Ellipsoid(name='GRS80') @var RefFrames.ITRF2014: RefFrame(name='ITRF2014', epoch=2010, ellipsoid=Ellipsoid(name='GRS80') @var RefFrames.ITRF91: RefFrame(name='ITRF91', epoch=1988, ellipsoid=Ellipsoid(name='GRS80') @var RefFrames.ITRF93: RefFrame(name='ITRF93', epoch=1988, ellipsoid=Ellipsoid(name='GRS80') @var RefFrames.NAD83: RefFrame(name='NAD83', epoch=1997, ellipsoid=Ellipsoid(name='GRS80') @var RefFrames.WGS84g1150: RefFrame(name='WGS84g1150', epoch=2001, ellipsoid=Ellipsoid(name='WGS84') @var RefFrames.WGS84g1674: RefFrame(name='WGS84g1674', epoch=2005, ellipsoid=Ellipsoid(name='WGS84') @var RefFrames.WGS84g1762: RefFrame(name='WGS84g1762', epoch=2005, ellipsoid=Ellipsoid(name='WGS84') '''
_epoch_, _exists_, _float as _F, _GRS80_, _NAD83_, \ _name_, _no_, _s_, _SPACE_, _sx_, _sy_, _sz_, \ _to_, _tx_, _ty_, _tz_, _WGS84_, _0_0, _0_001, \ _0_01, _0_1, _0_26, _0_5, _1_0 _NamedDict as _XD, _NamedEnum, _NamedEnumItem, \ _NamedTuple
'''Terrestrial Reference Frame (TRF) parameters. '''
'''New L{RefFrame}.
@arg epoch: Epoch, a fractional calendar year (C{scalar} or C{str}). @arg ellipsoid: The ellipsoid (L{Ellipsoid}, L{Ellipsoid2}, L{datum} or L{a_f2Tuple}). @kwarg name: Optional, unique name (C{str}).
@raise NameError: A L{RefFrame} with that B{C{name}} already exists.
@raise TRFError: Invalid B{C{epoch}}.
@raise TypeError: Invalid B{C{ellipsoid}}. '''
'''Get this reference frame's ellipsoid (L{Ellipsoid} or L{Ellipsoid2}). '''
'''Get this reference frame's epoch (C{Epoch}). '''
'''Return this reference frame as a text string.
@return: This L{RefFrame}'s attributes (C{str}). ''' Fmt.EQUAL(_epoch_, self.epoch), Fmt.PAREN(Fmt.EQUAL(_ellipsoid_, classname(e)), Fmt.EQUAL(_name_, repr(e.name))))
'''(INTERNAL) L{RefFrame} registry, I{must} be a sub-class to accommodate the L{_LazyNamedEnumItem} properties. ''' '''(INTERNAL) Instantiate the L{RefFrame}. '''
'''Some pre-defined L{RefFrame}s, all I{lazily} instantiated.''' # <https://GitHub.com/chrisveness/geodesy/blob/master/latlon-ellipsoidal-referenceframe.js> ETRF2000 = _lazy(_ETRF2000_, _F(2005), _GRS80_), # ETRF2000(R08) GDA2020 = _lazy(_GDA2020_, _F(2020), _GRS80_), # Australia GDA94 = _lazy(_GDA94_, _F(1994), _GRS80_), # Australia ITRF2000 = _lazy(_ITRF2000_, _F(1997), _GRS80_), ITRF2005 = _lazy(_ITRF2005_, _F(2000), _GRS80_), ITRF2008 = _lazy(_ITRF2008_, _F(2005), _GRS80_), # aks ITRF08 ITRF2014 = _lazy(_ITRF2014_, _F(2010), _GRS80_), ITRF91 = _lazy(_ITRF91_, _F(1988), _GRS80_), ITRF93 = _lazy(_ITRF93_, _F(1988), _GRS80_), NAD83 = _lazy(_NAD83_, _F(1997), _GRS80_), # CORS96 WGS84g1150 = _lazy(_WGS84g1150_, _F(2001), _WGS84_), WGS84g1674 = _lazy(_WGS84g1674_, _F(2005), _WGS84_), WGS84g1762 = _lazy(_WGS84g1762_, _F(2005), _WGS84_)) # same epoch
'''Return the reference frame C{epoch} for a calendar day.
@arg year: Year of the date (C{scalar}). @arg month: Month in the B{C{year}} (C{scalar}, 1..12). @arg day: Day in the B{C{month}} (C{scalar}, 1..31).
@return: Epoch, the fractional year (C{float}).
@raise TRFError: Invalid B{C{year}}, B{C{month}} or B{C{day}}.
@note: Any B{C{year}} is considered a leap year, i.e. having 29 days in February. '''
t = NN # _invalid_ raise TRFError(year=year, month=month, day=day, txt=t)
'''Return the date for a reference frame C{epoch}.
@arg epoch: Fractional year (C{scalar}).
@return: 3-Tuple C{(year, month, day)}.
@raise TRFError: Invalid B{C{epoch}}.
@note: Any B{C{year}} is considered a leap year, i.e. having 29 days in February. ''' else:
'''(INTERNAL) Find a trf* "in between" C{n1} and C{n2}. '''
'''(INTERNAL) Get 0, 1 or 2 Helmert L{Transform}s to convert reference frame B{C{rf}} observed at B{C{epoch}} into B{C{rf2}}. '''
or (n2.startswith(_ITRF_) and n1.startswith(_WGS84_)):
_2Transform((n, n2), e, _Forward))
_2Transform((n2, n), e, _Inverse))
t = _SPACE_(RefFrame.__name__, repr(n1), _to_, repr(n2)) raise TRFError(_no_(_conversion_), txt=t)
'''(INTERNAL) Combine the dual Helmert transforms from TRF conversion C{_trfXs[n1_n2]} into a into a single Helmert L{Transform} observed at B{C{epoch}}.
@note: Translations in C{millimeter} are converted to C{meter} and rotations in C{milliarcseconds} to C{arcseconds}. ''' n, x, r in zip(Transform7Tuple._Names_, X.xform, X.rates))
'''7-Tuple C{(tx, ty, tz, s, sx, sy, sz)} Helmert transformation with translations C{tx}, C{ty} and C{tz} in C{millimeter}, scale C{s} in C{ppb} and rotations C{sx}, C{sy} and C{sz} in C{milliarcseconds}.
@see: L{Transform}. '''
sx=_0_0, sy=_0_0, sz=_0_0, name=NN): '''New L{Transform7Tuple}.
@kwarg tx: Optional X translation (C{millimeter}). @kwarg ty: Optional Y translation (C{millimeter}). @kwarg tz: Optional Z translation (C{millimeter}). @kwarg s: Optional scale (C{float}), ppb. @kwarg sx: Optional X rotation (C{milliarcseconds}). @kwarg sy: Optional Y rotation (C{milliarcseconds}). @kwarg sz: Optional Z rotation (C{milliarcseconds}). @kwarg name: Optional name (C{str}). '''
'''Define a new Terrestrial Reference Frame (TRF) conversion.
@arg reframe1: Source reframe (L{RefFrame}), converting I{from}. @arg reframe2: Destination reframe (L{RefFrame}), converting I{to}. @kwarg epoch: Epoch, a fractional calendar year (C{scalar} or C{str}) or C{None} for C{B{reframe2}.epoch}. @kwarg xform: Helmert transform (C{Tranform7Tuple}). @kwarg rates: Helmert transform (C{Tranform7Tuple}).
@raise TRFError: Invalid B{C{epoch}} or TRF conversion already exists. ''' _xinstanceof(RefFrame, reframe1=reframe1, reframe2=reframe2) e = reframe2.epoch if epoch is None else Epoch(epoch=epoch, Error=TRFError) _xinstanceof(Transform7Tuple, xform=xform, rates=rates) _trfX(reframe1.name, reframe2.name, epoch=e, xform=xform, rates=rates)
'''(INTERNAL) New C{_trfXs} entry. ''' raise TRFError(trfX=n1_n2, txt=_exists_) # _NameError
# TRF conversions specified as an epoch and dual 7-parameter Helmert transforms. Most # from U{Transformation Parameters<http://ITRF.IGN.FR/trans_para.php>}, more at U{QPS # <https://Confluence.QPS.NL/qinsy/files/en/29856813/45482834/2/1453459502000/ITRF_Transformation_Parameters.xlsx>}. # see U{Transformation Parameters ITRF2014<http://ITRF.IGN.FR/doc_ITRF/Transfo-ITRF2014_ITRFs.txt>} xform=_T( 1.6, 1.9, 2.4, -0.02, _0_0, _0_0, _0_0), rates=_T( _0_0, _0_0, -_0_1, 0.03, _0_0, _0_0, _0_0)) xform=_T( 2.6, _1_0, -2.3, 0.92, _0_0, _0_0, _0_0), rates=_T( 0.3, _0_0, -_0_1, 0.03, _0_0, _0_0, _0_0)) xform=_T( 0.7, 1.2, -26.1, 2.12, _0_0, _0_0, _0_0), rates=_T( _0_1, _0_1, -1.9, 0.11, _0_0, _0_0, _0_0)) xform=_T( 7.4, -_0_5, -62.8, 3.8, _0_0, _0_0, _0_26), rates=_T( _0_1, -_0_5, -3.3, 0.12, _0_0, _0_0, _0_02)) xform=_T( 7.4, -_0_5, -62.8, 3.8, _0_0, _0_0, _0_26), rates=_T( _0_1, -_0_5, -3.3, 0.12, _0_0, _0_0, _0_02)) xform=_T( 7.4, -_0_5, -62.8, 3.8, _0_0, _0_0, _0_26), rates=_T( _0_1, -_0_5, -3.3, 0.12, _0_0, _0_0, _0_02)) xform=_T(-50.4, 3.3, -60.2, 4.29, -2.81, -3.38, 0.4), rates=_T( -2.8, -_0_1, -2.5, 0.12, -0.11, -0.19, 0.07)) xform=_T( 15.4, 1.5, -70.8, 3.09, _0_0, _0_0, _0_26), rates=_T( _0_1, -_0_5, -3.3, 0.12, _0_0, _0_0, _0_02)) xform=_T( 27.4, 15.5, -76.8, 4.49, _0_0, _0_0, _0_26), rates=_T( _0_1, -_0_5, -3.3, 0.12, _0_0, _0_0, _0_02)) xform=_T( 25.4, 11.5, -92.8, 4.79, _0_0, _0_0, _0_26), rates=_T( _0_1, -_0_5, -3.3, 0.12, _0_0, _0_0, _0_02)) xform=_T( 30.4, 35.5, -130.8, 8.19, _0_0, _0_0, _0_26), rates=_T( _0_1, -_0_5, -3.3, 0.12, _0_0, _0_0, _0_02)) xform=_T( 25.4, -_0_5, -154.8, 11.29, _0_1, _0_0, _0_26), rates=_T( _0_1, -_0_5, -3.3, 0.12, _0_0, _0_0, _0_02))
# see U{Transformation Parameters ITRF2008<http://ITRF.IGN.FR/doc_ITRF/Transfo-ITRF2008_ITRFs.txt>} # _trfX(_ITRF2008_, _ITRF2005_, epoch=_F(2005), # <http://ITRF.ENSG.IGN.FR/ITRF_solutions/2008/tp_08-05.php> # xform=_T(-_0_5, -0.9, -4.7, 0.94, _0_0, _0_0, _0_0), # rates=_T( 0.3, _0_0, _0_0, _0_0, _0_0, _0_0, _0_0)) xform=_T( -2.0, -0.9, -4.7, 0.94, _0_0, _0_0, _0_0), rates=_T( 0.3, _0_0, _0_0, _0_0, _0_0, _0_0, _0_0)) xform=_T( -1.9, -1.7, -10.5, 1.34, _0_0, _0_0, _0_0), rates=_T( _0_1, _0_1, -1.8, 0.08, _0_0, _0_0, _0_0)) xform=_T( 4.8, 2.6, -33.2, 2.92, _0_0, _0_0, _0_06), rates=_T( _0_1, -_0_5, -3.2, _0_09, _0_0, _0_0, _0_02)) xform=_T( 4.8, 2.6, -33.2, 2.92, _0_0, _0_0, _0_06), rates=_T( _0_1, -_0_5, -3.2, _0_09, _0_0, _0_0, _0_02)) xform=_T( 4.8, 2.6, -33.2, 2.92, _0_0, _0_0, _0_06), rates=_T( _0_1, -_0_5, -3.2, _0_09, _0_0, _0_0, _0_02)) xform=_T(-24.0, 2.4, -38.6, 3.41, -1.71, -1.48, -0.3), rates=_T( -2.8, -_0_1, -2.4, _0_09, -0.11, -0.19, 0.07)) xform=_T( 12.8, 4.6, -41.2, 2.21, _0_0, _0_0, _0_06), rates=_T( _0_1, -_0_5, -3.2, _0_09, _0_0, _0_0, _0_02)) xform=_T( 24.8, 18.6, -47.2, 3.61, _0_0, _0_0, _0_06), rates=_T( _0_1, -_0_5, -3.2, _0_09, _0_0, _0_0, _0_02)) xform=_T( 22.8, 14.6, -63.2, 3.91, _0_0, _0_0, _0_06), rates=_T( _0_1, -_0_5, -3.2, _0_09, _0_0, _0_0, _0_02)) xform=_T( 27.8, 38.6, -101.2, 7.31, _0_0, _0_0, _0_06), rates=_T( _0_1, -_0_5, -3.2, _0_09, _0_0, _0_0, _0_02)) xform=_T( 22.8, 2.6, -125.2, 10.41, _0_1, _0_0, _0_06), rates=_T( _0_1, -_0_5, -3.2, _0_09, _0_0, _0_0, _0_02))
xform=_T( _0_1, -0.8, -5.8, 0.4, _0_0, _0_0, _0_0), rates=_T( -0.2, _0_1, -1.8, 0.08, _0_0, _0_0, _0_0))
xform=_T( 0.67, 0.61, -1.85, 1.55, _0_0, _0_0, _0_0), rates=_T(_0_0, -0.06, -0.14, _0_01, _0_0, _0_0, _0_02)) xform=_T( 0.67, 0.61, -1.85, 1.55, _0_0, _0_0, _0_0), rates=_T(_0_0, -0.06, -0.14, _0_01, _0_0, _0_0, _0_02)) xform=_T( 0.67, 0.61, -1.85, 1.55, _0_0, _0_0, _0_0), rates=_T(_0_0, -0.06, -0.14, _0_01, _0_0, _0_0, _0_02)) xform=_T( 12.7, 6.5, -20.9, 1.95, -0.39, 0.8, -1.14), rates=_T( -2.9, -0.2, -0.6, _0_01, -0.11, -0.19, 0.07)) xform=_T( 1.47, 1.35, -1.39, 0.75, _0_0, _0_0, -0.18), rates=_T(_0_0, -0.06, -0.14, _0_01, _0_0, _0_0, _0_02)) xform=_T( 26.7, 27.5, -19.9, 2.15, _0_0, _0_0, -0.18), rates=_T( _0_0, -0.6, -1.4, _0_01, _0_0, _0_0, _0_02)) xform=_T( 2.47, 2.35, -3.59, 2.45, _0_0, _0_0, -0.18), rates=_T(_0_0, -0.06, -0.14, _0_01, _0_0, _0_0, _0_02)) xform=_T( 2.97, 4.75, -7.39, 5.85, _0_0, _0_0, -0.18), rates=_T(_0_0, -0.06, -0.14, _0_01, _0_0, _0_0, _0_02)) xform=_T( 2.47, 1.15, -9.79, 8.95, _0_1, _0_0, -0.18), rates=_T(_0_0, -0.06, -0.14, _0_01, _0_0, _0_0, _0_02))
# see U{Boucher, C. & Altamimi, Z. "Memo: Specifications for reference frame fixing in the # analysis of a EUREF GPS campaign" (2011) <https://ETRS89.ENSG.IGN.FR/memo-V8.pdf>} and # Altamimi, Z. U{"Key results of ITRF2014 and implication to ETRS89 realization", EUREF2016 # <https://www.EUREF.EU/symposia/2016SanSebastian/01-02-Altamimi.pdf>}. xform=_T( 53.7, 51.2, -55.1, 1.02, 0.891, 5.39, -8.712), rates=_T( _0_1, _0_1, -1.9, 0.11, 0.081, 0.49, -0.792)) xform=_T( 52.1, 49.3, -58.5, 1.34, 0.891, 5.39, -8.712), rates=_T( _0_1, _0_1, -1.8, 0.08, 0.081, 0.49, -0.792)) xform=_T( 54.1, 50.2, -53.8, 0.4, 0.891, 5.39, -8.712), rates=_T( -0.2, _0_1, -1.8, 0.08, 0.081, 0.49, -0.792)) xform=_T( 54.0, 51.0, -48.0, _0_0, 0.891, 5.39, -8.712), rates=_T( _0_0, _0_0, _0_0, _0_0, 0.081, 0.49, -0.792))
# see U{Solar, T. & Snay, R.A. "Transforming Positions and Velocities between the # International Terrestrial Reference Frame of 2000 and North American Datum of 1983" # (2004)<https://www.NGS.NOAA.gov/CORS/Articles/SolerSnayASCE.pdf>} xform=_T(995.6, -1901.3, -521.5, 0.62, 25.915, 9.426, 11.599), rates=_T( 0.7, -0.7, _0_5, -0.18, 0.067, -0.757, -0.051))
# GDA2020 "Geocentric Datum of Australia 2020 Technical Manual", v1.5, 2020-12-09, Table 3.3 and 3.4 # <https://www.ICSM.gov.AU/sites/default/files/2020-12/GDA2020%20Technical%20Manual%20V1.5_4.pdf> # (the GDA2020 xforms are different but the rates are the same as GDA94, further below) xform=_T( _0_0, _0_0, _0_0, _0_0, _0_0, _0_0, _0_0), rates=_T( _0_0, _0_0, _0_0, _0_0, 1.50379, 1.18346, 1.20716)) xform=_T( 13.79, 4.55, 15.22, 2.5, 0.2808, 0.2677, -0.4638), rates=_T( 1.42, 1.34, 0.9, 0.109, 1.5461, 1.182, 1.1551)) xform=_T( 40.32, -33.85, -16.72, 4.286, -1.2893, -0.8492, -0.3342), rates=_T( 2.25, -0.62, -0.56, 0.294, -1.4707, -1.1443, -1.1701)) xform=_T(-105.52, 51.58, 231.68, 3.55, 4.2175, 6.3941, 0.8617), rates=_T( -4.66, 3.55, 11.24, 0.249, 1.7454, 1.4868, 1.224))
# see Table 2 in U{Dawson, J. & Woods, A. "ITRF to GDA94 coordinate transformations", Journal of Applied # Geodesy 4 (2010), 189-199<https://www.ResearchGate.net/publication/258401581_ITRF_to_GDA94_coordinate_transformations>} # (note, sign of rotations for GDA94 reversed as "Australia assumes rotation to be of coordinate axes", # rather than the more conventional "position around the coordinate axes") xform=_T(-84.68, -19.42, 32.01, 9.71, -0.4254, 2.2578, 2.4015), rates=_T( 1.42, 1.34, 0.9, 0.109, 1.5461, 1.182, 1.1551)) xform=_T(-79.73, -6.86, 38.03, 6.636, 0.0351, -2.1211, -2.1411), rates=_T( 2.25, -0.62, -0.56, 0.294, -1.4707, -1.1443, -1.1701)) xform=_T(-45.91, -29.85, -20.37, 7.07, -1.6705, 0.4594, 1.9356), rates=_T( -4.66, 3.55, 11.24, 0.249, 1.7454, 1.4868, 1.224))
if __name__ == '__main__':
from pygeodesy.interns import _COMMA_, _NL_, _NL_var_, _STAR_
D = date2epoch.__name__ E = epoch2date.__name__ y = 2021 for m in range(1, 13): for d in (1, _mDays[m] - 1, _mDays[m]): f = '%s(%d,%3d,%3d)' % (D, y, m, d) e = date2epoch(y, m, d) t = epoch2date(e) x = NN if t == (y, m, d) else _STAR_ e = '%.3f' % (e,) e = '%s, %s(%s)' % (e, E, e) t = '%d,%3d,%3d' % t print('# %s = %s = %s %s' % (f, e, t, x))
# __doc__ of this file, force all into registery t = [NN] + RefFrames.toRepr(all=True).split(_NL_) print(_NL_var_.join(i.strip(_COMMA_) for i in t))
# **) MIT License # # Copyright (C) 2016-2021 -- mrJean1 at Gmail -- All Rights Reserved. # # Permission is hereby granted, free of charge, to any person obtaining a # copy of this software and associated documentation files (the "Software"), # to deal in the Software without restriction, including without limitation # the rights to use, copy, modify, merge, publish, distribute, sublicense, # and/or sell copies of the Software, and to permit persons to whom the # Software is furnished to do so, subject to the following conditions: # # The above copyright notice and this permission notice shall be included # in all copies or substantial portions of the Software. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS # OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, # FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL # THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR # OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, # ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR # OTHER DEALINGS IN THE SOFTWARE.
# % python -m pygeodesy.trf # # date2epoch(2021, 1, 1) = 2021.003, epoch2date(2021.003) = 2021, 1, 1 # date2epoch(2021, 1, 30) = 2021.082, epoch2date(2021.082) = 2021, 1, 30 # date2epoch(2021, 1, 31) = 2021.085, epoch2date(2021.085) = 2021, 1, 31 # date2epoch(2021, 2, 1) = 2021.087, epoch2date(2021.087) = 2021, 2, 2 * # date2epoch(2021, 2, 28) = 2021.161, epoch2date(2021.161) = 2021, 2, 28 # date2epoch(2021, 2, 29) = 2021.164, epoch2date(2021.164) = 2021, 3, 1 * # date2epoch(2021, 3, 1) = 2021.167, epoch2date(2021.167) = 2021, 3, 2 * # date2epoch(2021, 3, 30) = 2021.246, epoch2date(2021.246) = 2021, 3, 31 * # date2epoch(2021, 3, 31) = 2021.249, epoch2date(2021.249) = 2021, 4, 1 * # date2epoch(2021, 4, 1) = 2021.251, epoch2date(2021.251) = 2021, 4, 1 # date2epoch(2021, 4, 29) = 2021.328, epoch2date(2021.328) = 2021, 4, 29 # date2epoch(2021, 4, 30) = 2021.331, epoch2date(2021.331) = 2021, 4, 30 # date2epoch(2021, 5, 1) = 2021.333, epoch2date(2021.333) = 2021, 5, 1 # date2epoch(2021, 5, 30) = 2021.413, epoch2date(2021.413) = 2021, 5, 30 # date2epoch(2021, 5, 31) = 2021.415, epoch2date(2021.415) = 2021, 6, 1 * # date2epoch(2021, 6, 1) = 2021.418, epoch2date(2021.418) = 2021, 6, 2 * # date2epoch(2021, 6, 29) = 2021.495, epoch2date(2021.495) = 2021, 6, 30 * # date2epoch(2021, 6, 30) = 2021.497, epoch2date(2021.497) = 2021, 7, 1 * # date2epoch(2021, 7, 1) = 2021.500, epoch2date(2021.500) = 2021, 7, 1 # date2epoch(2021, 7, 30) = 2021.579, epoch2date(2021.579) = 2021, 7, 30 # date2epoch(2021, 7, 31) = 2021.582, epoch2date(2021.582) = 2021, 7, 31 # date2epoch(2021, 8, 1) = 2021.585, epoch2date(2021.585) = 2021, 8, 1 # date2epoch(2021, 8, 30) = 2021.664, epoch2date(2021.664) = 2021, 8, 31 * # date2epoch(2021, 8, 31) = 2021.667, epoch2date(2021.667) = 2021, 9, 1 * # date2epoch(2021, 9, 1) = 2021.669, epoch2date(2021.669) = 2021, 9, 2 * # date2epoch(2021, 9, 29) = 2021.746, epoch2date(2021.746) = 2021, 9, 30 * # date2epoch(2021, 9, 30) = 2021.749, epoch2date(2021.749) = 2021, 10, 1 * # date2epoch(2021, 10, 1) = 2021.751, epoch2date(2021.751) = 2021, 10, 1 # date2epoch(2021, 10, 30) = 2021.831, epoch2date(2021.831) = 2021, 10, 30 # date2epoch(2021, 10, 31) = 2021.833, epoch2date(2021.833) = 2021, 10, 31 # date2epoch(2021, 11, 1) = 2021.836, epoch2date(2021.836) = 2021, 11, 1 # date2epoch(2021, 11, 29) = 2021.913, epoch2date(2021.913) = 2021, 11, 29 # date2epoch(2021, 11, 30) = 2021.915, epoch2date(2021.915) = 2021, 12, 1 * # date2epoch(2021, 12, 1) = 2021.918, epoch2date(2021.918) = 2021, 12, 2 * # date2epoch(2021, 12, 30) = 2021.997, epoch2date(2021.997) = 2021, 12, 31 * # date2epoch(2021, 12, 31) = 2022.000, epoch2date(2022.000) = 2022, 1, 1 * |