Esempio n. 1
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    def get_reflectance(self, tb11, sun_zenith=None, tb13_4=None):
        """Get the reflectance part of an NIR channel"""

        try:
            from pyspectral.near_infrared_reflectance import Calculator
        except ImportError:
            LOG.info("Couldn't load pyspectral")

        # Check the wavelength, and if outside 3-4 microns this functionality
        # doesn't give any meaning and should not be supported
        if (self.wavelength_range[1] < 3.0 or self.wavelength_range[1] > 4.0):
            LOG.warning("Deriving the near infrared reflectance" +
                        " of a band that is outside the 3-4 micron range" +
                        " is not supported!\n\tWill do nothing...")
            return

        # Check if the sun-zenith angle was provided:
        if sun_zenith is None:
            lonlats = self.area.get_lonlats()
            sun_zenith = sza(self.info['time'], lonlats[0], lonlats[1])

        try:
            refl39 = Calculator(self.info['satname'] + self.info['satnumber'],
                                self.info['instrument_name'], self.name)
        except NameError:
            LOG.warning("pyspectral missing!")
            return

        return refl39.reflectance_from_tbs(sun_zenith,
                                           self.data,
                                           tb11,
                                           tb_ir_co2=tb13_4)
Esempio n. 2
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    def get_reflectance(self, tb11, sun_zenith=None, tb13_4=None):
        """Get the reflectance part of an NIR channel"""

        try:
            from pyspectral.near_infrared_reflectance import Calculator
        except ImportError:
            LOG.info("Couldn't load pyspectral")

        # Check the wavelength, and if outside 3-4 microns this functionality
        # doesn't give any meaning and should not be supported
        if (self.wavelength_range[1] < 3.0 or self.wavelength_range[1] > 4.0):
            LOG.warning("Deriving the near infrared reflectance" +
                        " of a band that is outside the 3-4 micron range" +
                        " is not supported!\n\tWill do nothing...")
            return

        # Check if the sun-zenith angle was provided:
        if sun_zenith is None:
            lonlats = self.area.get_lonlats()
            sun_zenith = sza(self.info['time'], lonlats[0], lonlats[1])

        try:
            refl39 = Calculator(self.info['satname'] + self.info['satnumber'],
                                self.info['instrument_name'], self.name)
        except NameError:
            LOG.warning("pyspectral missing!")
            return

        return refl39.reflectance_from_tbs(sun_zenith, self.data, tb11, tb_ir_co2=tb13_4)
Esempio n. 3
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    def test_rsr_integral(self):
        """Test calculating the integral of the relative spectral response
        function. 
        """
        with patch('pyspectral.radiance_tb_conversion.RelativeSpectralResponse'
                   ) as mymock:
            instance = mymock.return_value
            instance.rsr = TEST_RSR
            instance.unit = '1e-6 m'
            instance.si_scale = 1e-6

            refl37 = Calculator('EOS-Aqua', 'modis', '20')

        expected = 1.8563451e-07  # unit = 'm' (meter)
        self.assertAlmostEqual(refl37.rsr_integral, expected)

        with patch('pyspectral.radiance_tb_conversion.RelativeSpectralResponse'
                   ) as mymock:
            instance = mymock.return_value
            instance.rsr = TEST_RSR_WN
            instance.unit = 'cm-1'
            instance.si_scale = 100.

            refl37 = Calculator('EOS-Aqua',
                                'modis',
                                '20',
                                wavespace='wavenumber')

        expected = 13000.385  # SI units = 'm-1' (1/meter)
        res = refl37.rsr_integral
        self.assertAlmostEqual(res / expected, 1.0, 6)
Esempio n. 4
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    def _init_refl3x(self, projectables):
        """Initiate the 3.x reflectance derivations
        """
        try:
            from pyspectral.near_infrared_reflectance import Calculator
        except ImportError:
            LOG.info("Couldn't load pyspectral")
            raise

        _nir, _tb11 = projectables
        self._refl3x = Calculator(_nir.attrs['platform_name'], _nir.attrs['sensor'], _nir.attrs['name'])
Esempio n. 5
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class NIRReflectance(CompositeBase):
    # TODO: Daskify

    def __call__(self, projectables, optional_datasets=None, **info):
        """Get the reflectance part of an NIR channel. Not supposed to be used
        for wavelength outside [3, 4] µm.
        """
        self._init_refl3x(projectables)
        _nir, _ = projectables
        refl = self._get_reflectance(projectables, optional_datasets) * 100
        proj = xr.DataArray(refl.filled(np.nan),
                            dims=_nir.dims,
                            coords=_nir.coords,
                            attrs=_nir.attrs)

        proj.attrs['units'] = '%'
        self.apply_modifier_info(_nir, proj)

        return proj

    def _init_refl3x(self, projectables):
        """Initiate the 3.x reflectance derivations
        """
        try:
            from pyspectral.near_infrared_reflectance import Calculator
        except ImportError:
            LOG.info("Couldn't load pyspectral")
            raise

        _nir, _tb11 = projectables
        self._refl3x = Calculator(_nir.attrs['platform_name'],
                                  _nir.attrs['sensor'], _nir.attrs['name'])

    def _get_reflectance(self, projectables, optional_datasets):
        """Calculate 3.x reflectance with pyspectral"""
        _nir, _tb11 = projectables
        LOG.info('Getting reflective part of %s', _nir.attrs['name'])

        sun_zenith = None
        tb13_4 = None

        for dataset in optional_datasets:
            if (dataset.attrs['units'] == 'K' and "wavelengh" in dataset.attrs
                    and dataset.attrs["wavelength"][0] <= 13.4 <=
                    dataset.attrs["wavelength"][2]):
                tb13_4 = dataset
            elif dataset.attrs["standard_name"] == "solar_zenith_angle":
                sun_zenith = dataset

        # Check if the sun-zenith angle was provided:
        if sun_zenith is None:
            from pyorbital.astronomy import sun_zenith_angle as sza
            lons, lats = _nir.attrs["area"].get_lonlats_dask(CHUNK_SIZE)
            sun_zenith = sza(_nir.attrs['start_time'], lons, lats)

        return self._refl3x.reflectance_from_tbs(sun_zenith,
                                                 _nir,
                                                 _tb11,
                                                 tb_ir_co2=tb13_4)
Esempio n. 6
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    def _init_refl3x(self, projectables):
        """Initiate the 3.x reflectance derivations
        """
        try:
            from pyspectral.near_infrared_reflectance import Calculator
        except ImportError:
            LOG.info("Couldn't load pyspectral")
            raise

        _nir, _tb11 = projectables
        self._refl3x = Calculator(_nir.attrs['platform_name'], _nir.attrs['sensor'], _nir.attrs['name'])
Esempio n. 7
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class NIRReflectance(CompositeBase):
    # TODO: Daskify

    def __call__(self, projectables, optional_datasets=None, **info):
        """Get the reflectance part of an NIR channel. Not supposed to be used
        for wavelength outside [3, 4] µm.
        """
        self._init_refl3x(projectables)
        _nir, _ = projectables
        refl = self._get_reflectance(projectables, optional_datasets) * 100
        proj = xr.DataArray(refl.filled(np.nan), dims=_nir.dims,
                            coords=_nir.coords, attrs=_nir.attrs)

        proj.attrs['units'] = '%'
        self.apply_modifier_info(_nir, proj)

        return proj

    def _init_refl3x(self, projectables):
        """Initiate the 3.x reflectance derivations
        """
        try:
            from pyspectral.near_infrared_reflectance import Calculator
        except ImportError:
            LOG.info("Couldn't load pyspectral")
            raise

        _nir, _tb11 = projectables
        self._refl3x = Calculator(_nir.attrs['platform_name'], _nir.attrs['sensor'], _nir.attrs['name'])

    def _get_reflectance(self, projectables, optional_datasets):
        """Calculate 3.x reflectance with pyspectral"""
        _nir, _tb11 = projectables
        LOG.info('Getting reflective part of %s', _nir.attrs['name'])

        sun_zenith = None
        tb13_4 = None

        for dataset in optional_datasets:
            if (dataset.attrs['units'] == 'K' and
                    "wavelengh" in dataset.attrs and
                    dataset.attrs["wavelength"][0] <= 13.4 <= dataset.attrs["wavelength"][2]):
                tb13_4 = dataset
            elif dataset.attrs["standard_name"] == "solar_zenith_angle":
                sun_zenith = dataset

        # Check if the sun-zenith angle was provided:
        if sun_zenith is None:
            from pyorbital.astronomy import sun_zenith_angle as sza
            lons, lats = _nir.attrs["area"].get_lonlats_dask(CHUNK_SIZE)
            sun_zenith = sza(_nir.attrs['start_time'], lons, lats)

        return self._refl3x.reflectance_from_tbs(sun_zenith, _nir, _tb11, tb_ir_co2=tb13_4)
Esempio n. 8
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    def __call__(self, projectables, optional_datasets=None, **info):
        """Get the reflectance part of an NIR channel. Not supposed to be used
        for wavelength outside [3, 4] µm.
        """
        try:
            from pyspectral.near_infrared_reflectance import Calculator
        except ImportError:
            LOG.info("Couldn't load pyspectral")
            raise

        nir, tb11 = projectables
        LOG.info('Getting reflective part of %s', nir.info['name'])

        sun_zenith = None
        tb13_4 = None

        for dataset in optional_datasets:
            if (dataset.info['units'] == 'K' and "wavelengh" in dataset.info
                    and dataset.info["wavelength"][0] <= 13.4 <=
                    dataset.info["wavelength"][2]):
                tb13_4 = dataset
            elif dataset.info["standard_name"] == "solar_zenith_angle":
                sun_zenith = dataset

        # Check if the sun-zenith angle was provided:
        if sun_zenith is None:
            from pyorbital.astronomy import sun_zenith_angle as sza
            lons, lats = nir.info["area"].get_lonlats()
            sun_zenith = sza(nir.info['start_time'], lons, lats)

        refl39 = Calculator(nir.info['platform_name'], nir.info['sensor'],
                            nir.id.wavelength[1])

        proj = Dataset(
            refl39.reflectance_from_tbs(sun_zenith, nir, tb11, tb13_4) * 100,
            **nir.info)
        proj.info['units'] = '%'
        self.apply_modifier_info(nir, proj)

        return proj
Esempio n. 9
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    def __call__(self, projectables, optional_datasets=None, **info):
        """Get the reflectance part of an NIR channel. Not supposed to be used
        for wavelength outside [3, 4] µm.
        """
        try:
            from pyspectral.near_infrared_reflectance import Calculator
        except ImportError:
            LOG.info("Couldn't load pyspectral")
            raise

        nir, tb11 = projectables
        LOG.info('Getting reflective part of %s', nir.info['name'])

        sun_zenith = None
        tb13_4 = None

        for dataset in optional_datasets:
            if dataset.info["standard_name"] == "solar_zenith_angle":
                sun_zenith = dataset
            elif (dataset.info['units'] == 'K' and
                  "wavelengh" in dataset.info and
                  dataset.info["wavelength"][0] <= 13.4 <= dataset.info["wavelength"][2]):
                tb13_4 = dataset

        # Check if the sun-zenith angle was provided:
        if sun_zenith is None:
            from pyorbital.astronomy import sun_zenith_angle as sza
            lons, lats = nir.info["area"].get_lonlats()
            sun_zenith = sza(nir.info['start_time'], lons, lats)

        refl39 = Calculator(nir.info['platform_name'],
                            nir.info['sensor'], nir.info['name'])

        proj = Projectable(refl39.reflectance_from_tbs(sun_zenith, nir,
                                                       tb11, tb13_4),
                           **nir.info)
        self.apply_modifier_info(nir, proj)

        return proj
Esempio n. 10
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    def _init_reflectance_calculator(self, metadata):
        """Initialize the 3.x reflectance derivations."""
        if not Calculator:
            logger.info("Couldn't load pyspectral")
            raise ImportError(
                "No module named pyspectral.near_infrared_reflectance")

        reflectance_3x_calculator = Calculator(
            metadata['platform_name'],
            metadata['sensor'],
            metadata['name'],
            sunz_threshold=self.sun_zenith_threshold,
            masking_limit=self.masking_limit)
        return reflectance_3x_calculator
Esempio n. 11
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class CycloneCellFast:
    __slots__ = [
        "image", "i4_reflectance", "gts", "xmin", "xmax", "ymin", "ymax"
    ]
    A = 2 / (np.log(0.6 / 0.72))
    B = 2 - A * np.log(0.72)
    from pyspectral.near_infrared_reflectance import Calculator
    calc = Calculator("Suomi-NPP", "viirs", "I4")

    def __init__(self, image: "CycloneImageFast", xmin, xmax, ymin, ymax):
        self.image = image
        self.xmin = xmin
        self.xmax = xmax
        self.ymin = ymin
        self.ymax = ymax
        self.i4_reflectance = self.calc.reflectance_from_tbs(
            self.zenith, self.i4, self.i5)
        assert not np.isnan(self.i4).all() and not np.isnan(self.i5).all()
        self.gts = self.glaciation_temperature_percentile()

    @property
    def i4(self):
        return self.image.raw_grid_I4[self.ymin:self.ymax, self.xmin:self.xmax]

    @property
    def i5(self):
        return self.image.raw_grid_I5[self.ymin:self.ymax, self.xmin:self.xmax]

    @property
    def zenith(self):
        return self.image.zenith[self.ymin:self.ymax, self.xmin:self.xmax]

    @property
    def satz(self):
        return self.image.satz[self.ymin:self.ymax, self.xmin:self.xmax]

    @property
    def raz(self):
        return self.image.raz[self.ymin:self.ymax, self.xmin:self.xmax]

    @property
    def i5_c(self):
        return self.i5 - ABSOLUTE_ZERO

    @property
    def i5_flat_c(self):
        return self.i5_flat - ABSOLUTE_ZERO

    @property
    def BTD(self):
        return self.i4_flat - (self.i5_flat)

    @property
    def BTD_ratio(self):
        return (self.i4_flat - (self.i5_flat)) / (self.i5_flat)

    @property
    def i4i5ratio(self):
        return (self.i4_flat) / (self.i5_flat)

    @property
    def good_gt(self):
        return (ABSOLUTE_ZERO - 45 < self.gt.value <
                ABSOLUTE_ZERO) and self.gt.error < 5

    def bin_data_percentiles(self, percentiles, i4_band=None):
        i4_list, i5_list = [], []
        if i4_band is None:
            i4_band = self.i4_flat
        gt_fit = GTFit(i4_band, self.i5_flat)
        for p in percentiles:
            i5, i4 = gt_fit.bin_data(np.percentile, 1, (p, ))
            i4_list.append(i4)
            i5_list.append(i5)
        return i4_list, i5_list

    def intersects(self, cell: "CycloneCellFast"):
        if cell is self:
            return True
        return cell.xmax > self.xmin and self.xmax > cell.xmin and self.ymax > cell.ymin and cell.ymax > self.ymin

    def plot(self, fig, ax, show=True):
        ax.imshow(self.i5)
        if show:
            plt.show()

    def plot_profile(self):
        fig, ax = plt.subplots(1, 2)
        self.plot(fig, ax[0], show=False)
        gt_fit = GTFit(self.i4_flat, self.i5_flat)
        gt_fit.piecewise_percentile(5, fig, ax[1])
        plt.show()

    @property
    def gt(self):
        return self.gts[0][0]

    @property
    def gt_i4(self):
        return self.gts[0][1]

    @property
    def r2(self):
        return self.gts[0][2]

    @property
    def i4_flat(self):
        return self.i4[~np.isnan(self.i4)].flatten()

    @property
    def i4_reflectance_flat(self):
        return self.i4_reflectance[~np.isnan(self.i4_reflectance)].flatten()

    @property
    def i5_flat(self):
        return self.i5[~np.isnan(self.i5)].flatten()

    def glaciation_temperature_percentile(self, percentiles=(5, 50, 95)):
        gt_fit = GTFit(self.i4_reflectance_flat, self.i5_flat)
        return gt_fit.piecewise_percentile_multiple(percentiles,
                                                    units="kelvin",
                                                    i4_units="reflectance")

    def re(self, nan_out_of_range=False):
        from inspect_nc import get_re
        return np.array([[
            get_re(self.i4_reflectance[y, x],
                   self.satz[y, x],
                   self.zenith[y, x],
                   np.abs(self.raz[y, x]),
                   nan_out_of_range=nan_out_of_range)
            for x in range(self.xmax - self.xmin)
        ] for y in range(self.ymax - self.ymin)])
Esempio n. 12
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    def test_reflectance(self):
        """Test the derivation of the reflective part of a 3.7 micron band"""

        with patch('pyspectral.radiance_tb_conversion.RelativeSpectralResponse'
                   ) as mymock:
            instance = mymock.return_value
            instance.rsr = TEST_RSR
            instance.unit = '1e-6 m'
            instance.si_scale = 1e-6

            with self.assertRaises(NotImplementedError):
                dummy = Calculator('Suomi-NPP', 'viirs', 10.8)

            refl37 = Calculator('Suomi-NPP', 'viirs', 3.7)
            self.assertEqual(refl37.bandwavelength, 3.7)
            self.assertEqual(refl37.bandname, '20')

        with patch('pyspectral.radiance_tb_conversion.RelativeSpectralResponse'
                   ) as mymock:
            instance = mymock.return_value
            instance.rsr = TEST_RSR
            instance.unit = '1e-6 m'
            instance.si_scale = 1e-6

            refl37 = Calculator('EOS-Aqua', 'modis', '20')

        sunz = np.array([80.])
        tb3 = np.array([290.])
        tb4 = np.array([282.])
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        self.assertAlmostEqual(refl.data[0], 0.251245010648, 6)

        tb3x = refl37.emissive_part_3x()
        self.assertAlmostEqual(tb3x, 276.213054, 6)

        sunz = np.array([80.])
        tb3 = np.array([295.])
        tb4 = np.array([282.])
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        self.assertAlmostEqual(refl.data[0], 0.452497961, 6)

        tb3x = refl37.emissive_part_3x()
        self.assertAlmostEqual(tb3x, 270.077268, 6)

        sunz = np.array([50.])
        tb3 = np.array([300.])
        tb4 = np.array([285.])
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        self.assertAlmostEqual(refl.data[0], 0.1189217, 6)

        tb3x = refl37.emissive_part_3x()
        self.assertAlmostEqual(tb3x, 282.455426, 6)
Esempio n. 13
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    def test_reflectance(self):
        """Test the derivation of the reflective part of a 3.7 micron band."""
        with patch('pyspectral.radiance_tb_conversion.RelativeSpectralResponse') as mymock:
            instance = mymock.return_value
            # VIIRS doesn't have a channel '20' like MODIS so the generic
            # mapping this test will end up using will find 'ch20' for VIIRS
            viirs_rsr = {'ch20': TEST_RSR['20'], '99': TEST_RSR['99']}
            instance.rsr = viirs_rsr
            instance.unit = '1e-6 m'
            instance.si_scale = 1e-6

            with self.assertRaises(NotImplementedError):
                dummy = Calculator('Suomi-NPP', 'viirs', 10.8)
                del dummy

            refl37 = Calculator('Suomi-NPP', 'viirs', 3.7)
            self.assertEqual(refl37.bandwavelength, 3.7)
            self.assertEqual(refl37.bandname, 'ch20')
            # Default sunz-threshold used to stay on day side and away from terminator:
            self.assertEqual(refl37.sunz_threshold, 85.0)

        with patch('pyspectral.radiance_tb_conversion.RelativeSpectralResponse') as mymock:
            instance = mymock.return_value
            instance.rsr = TEST_RSR
            instance.unit = '1e-6 m'
            instance.si_scale = 1e-6

            refl37 = Calculator('EOS-Aqua', 'modis', '20')
            self.assertEqual(refl37.sunz_threshold, TERMINATOR_LIMIT)
            self.assertEqual(refl37.masking_limit, TERMINATOR_LIMIT)

            refl37_sz88 = Calculator('EOS-Aqua', 'modis', '20', sunz_threshold=88.0, masking_limit=None)
            self.assertEqual(refl37_sz88.sunz_threshold, 88.0)
            self.assertIsNone(refl37_sz88.masking_limit)
            self.assertAlmostEqual(refl37_sz88.bandwavelength, 3.780282, 5)
            self.assertEqual(refl37_sz88.bandname, '20')

        sunz = 80.
        tb3 = 290.
        tb4 = 282.
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        np.testing.assert_allclose(refl[0], 0.251245010648, 6)

        sunz = 85.
        tb3 = 290.
        tb4 = 282.
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        np.testing.assert_allclose(refl[0], 1.12236884, 6)

        sunz = np.array([85.1])
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        self.assertTrue(np.isnan(refl[0]))

        refl_sz88 = refl37_sz88.reflectance_from_tbs(sunz, tb3, tb4)
        np.testing.assert_allclose(refl_sz88[0], 1.2064644, 6)
        sunz = np.array([86.0])
        self.assertTrue(np.isnan(refl[0]))

        tb3x = refl37.emissive_part_3x()
        np.testing.assert_allclose(tb3x, 276.213054, 6)

        sunz = np.array([80.])
        tb3 = np.array([295.])
        tb4 = np.array([282.])
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        np.testing.assert_allclose(refl[0], 0.452497961, 6)

        tb3x = refl37.emissive_part_3x()
        np.testing.assert_allclose(tb3x, 270.077268, 6)

        sunz = np.array([50.])
        tb3 = np.array([300.])
        tb4 = np.array([285.])
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        np.testing.assert_allclose(refl[0], 0.1189217, 6)

        tb3x = refl37.emissive_part_3x()
        np.testing.assert_allclose(tb3x, 282.455426, 6)

        sunz = np.array([50.])
        tb3 = np.ma.masked_array([300.], mask=False)
        tb4 = np.ma.masked_array([285.], mask=False)
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        self.assertTrue(hasattr(refl, 'mask'))

        try:
            import dask.array as da
            sunz = da.from_array([50.], chunks=10)
            tb3 = da.from_array([300.], chunks=10)
            tb4 = da.from_array([285.], chunks=10)
            refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
            self.assertTrue(hasattr(refl, 'compute'))
        except ImportError:
            pass
Esempio n. 14
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p = Proj(proj='geos', h=sat_h, lon_0=sat_lon, sweep=sat_sweep, a=6378137.0)
# Convert map points to latitude and longitude with the magic provided by Pyproj
XX, YY = np.meshgrid(X, Y)
lons, lats = p(XX, YY, inverse=True)

# Get the year month day hour and minute to apply the zenith correction
utc_time = datetime(int(year), int(month), int(day), int(hour), int(minutes))
sun_zenith = np.zeros((data1.shape[0], data1.shape[1]))
sun_zenith = astronomy.sun_zenith_angle(utc_time, lons, lats)

print("Solar Zenith Angle calculus finished")

# Calculate the solar component (band 3.7 um)
from pyspectral.near_infrared_reflectance import Calculator

refl39 = Calculator('GOES-16', 'abi', 'ch7')
data1b = refl39.reflectance_from_tbs(sun_zenith, data1, data2)
print("Solar Component calculus finished")
#------------------------------------------------------------------------------------------------------
#------------------------------------------------------------------------------------------------------
# RGB Components
R = data3
G = data4
B = data1b

# Minimuns and Maximuns
Rmin = 0
Rmax = 1

Gmin = 0
Gmax = 0.7
Esempio n. 15
0
    def test_reflectance(self):
        """Test the derivation of the reflective part of a 3.7 micron band"""

        with patch('pyspectral.radiance_tb_conversion.RelativeSpectralResponse') as mymock:
            instance = mymock.return_value
            instance.rsr = TEST_RSR
            instance.unit = '1e-6 m'
            instance.si_scale = 1e-6

            with self.assertRaises(NotImplementedError):
                dummy = Calculator('Suomi-NPP', 'viirs', 10.8)

            refl37 = Calculator('Suomi-NPP', 'viirs', 3.7)
            self.assertEqual(refl37.bandwavelength, 3.7)
            self.assertEqual(refl37.bandname, '20')

        with patch('pyspectral.radiance_tb_conversion.RelativeSpectralResponse') as mymock:
            instance = mymock.return_value
            instance.rsr = TEST_RSR
            instance.unit = '1e-6 m'
            instance.si_scale = 1e-6

            refl37 = Calculator('EOS-Aqua', 'modis', '20')

        sunz = np.array([80.])
        tb3 = np.array([290.])
        tb4 = np.array([282.])
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        np.testing.assert_allclose(refl[0], 0.251245010648, 6)

        tb3x = refl37.emissive_part_3x()
        np.testing.assert_allclose(tb3x, 276.213054, 6)

        sunz = np.array([80.])
        tb3 = np.array([295.])
        tb4 = np.array([282.])
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        np.testing.assert_allclose(refl[0], 0.452497961, 6)

        tb3x = refl37.emissive_part_3x()
        np.testing.assert_allclose(tb3x, 270.077268, 6)

        sunz = np.array([50.])
        tb3 = np.array([300.])
        tb4 = np.array([285.])
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        np.testing.assert_allclose(refl[0], 0.1189217, 6)

        tb3x = refl37.emissive_part_3x()
        np.testing.assert_allclose(tb3x, 282.455426, 6)

        sunz = np.array([50.])
        tb3 = np.ma.masked_array([300.], mask=False)
        tb4 = np.ma.masked_array([285.], mask=False)
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        self.assertTrue(hasattr(refl, 'mask'))

        try:
            import dask.array as da
            sunz = da.from_array([50.], chunks=10)
            tb3 = da.from_array([300.], chunks=10)
            tb4 = da.from_array([285.], chunks=10)
            refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
            self.assertTrue(hasattr(refl, 'compute'))
        except ImportError:
            pass
Esempio n. 16
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solar_irr = SolarIrradianceSpectrum(TOTAL_IRRADIANCE_SPECTRUM_2000ASTM, dlambda=0.0005)
from pyspectral.rsr_reader import RelativeSpectralResponse
seviri = RelativeSpectralResponse('Meteosat-10', 'seviri')
sflux = solar_irr.inband_solarflux(seviri.rsr['IR3.9'])

ch39 = local_data['IR_039']
ch11 = local_data['IR_108']
ch13 = local_data['IR_134']
lonlats = ch39.area.get_lonlats()

from pyorbital.astronomy import sun_zenith_angle
sunz = sun_zenith_angle(tslot, lonlats[0], lonlats[1])

print("... create look-up-table")
#refl37 = Calculator(rsr)
refl37 = Calculator('Meteosat-9', 'seviri', 'IR3.9', solar_flux=sflux)
#refl37.make_tb2rad_lut('/tmp/seviri_37_tb2rad_lut.npz')
# new syntax -> 
#refl37.make_tb2rad_lut('IR3.9','/data/COALITION2/database/meteosat/SEVIRI/seviri_tb2rad_lut/')

print("... calculate reflectance")
r39 = refl37.reflectance_from_tbs(sunz, ch39.data, ch11.data, ch13.data) # , lookuptable='/tmp/seviri_37_tb2rad_lut.npz'

import numpy as np
r39 = np.ma.masked_array(r39, mask = np.logical_or(np.less(r39, -0.1), 
                                                   np.greater(r39, 3.0)))
print("... show new RGB image")
from mpop.imageo.geo_image import GeoImage
img = GeoImage((local_data[0.8].data, local_data[1.6].data, r39 * 100), area, 
               tslot, crange=((0, 100), (0, 70), (0, 30)), 
               fill_value=(0, 0, 0), mode="RGB")
Esempio n. 17
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logging.getLogger("").setLevel(logging.DEBUG)
LOG.addHandler(handler)

ahi = RelativeSpectralResponse('Himawari-8', 'ahi')
solar_irr = SolarIrradianceSpectrum(TOTAL_IRRADIANCE_SPECTRUM_2000ASTM,
                                    dlambda=0.005)
sflux = solar_irr.inband_solarflux(ahi.rsr['ch7'])
LOG.info("Solar flux over Band: " + str(sflux))

# sunz = [80., 80.5]
# tb7 = [288.0, 390.0]
# tb14 = [282.0, 272.0]
# tb16 = [275.0, 269.0]

sunz = np.random.rand(5500, 550) * 120.
tb7 = np.random.rand(5500, 550) * 120. + 260.0
tb14 = np.random.rand(5500, 550) * 30. + 260.0
tb16 = np.random.rand(5500, 550) * 30. + 250.0

refl38 = Calculator(
    'Himawari-8',
    'ahi',
    'ch7',
    detector='det-1',
    solar_flux=sflux,
    tb2rad_lut_filename='/tmp/tb2rad_lut_himawari_ahi_ir3.9.npz')
x = refl38.reflectance_from_tbs(sunz, tb7, tb14)
LOG.info("Reflectance: " + str(x[0, 0]))
y = refl38.reflectance_from_tbs(sunz, tb7, tb14, tb16)
LOG.info("Reflectance - co2 corrected: " + str(y[0, 0]))
Esempio n. 18
0
    def test_reflectance(self):
        """Test the derivation of the reflective part of a 3.7 micron band."""
        with patch('pyspectral.radiance_tb_conversion.RelativeSpectralResponse') as mymock:
            instance = mymock.return_value
            # VIIRS doesn't have a channel '20' like MODIS so the generic
            # mapping this test will end up using will find 'ch20' for VIIRS
            viirs_rsr = {'ch20': TEST_RSR['20'], '99': TEST_RSR['99']}
            instance.rsr = viirs_rsr
            instance.unit = '1e-6 m'
            instance.si_scale = 1e-6

            with self.assertRaises(NotImplementedError):
                dummy = Calculator('Suomi-NPP', 'viirs', 10.8)
                del dummy

            refl37 = Calculator('Suomi-NPP', 'viirs', 3.7)
            self.assertEqual(refl37.bandwavelength, 3.7)
            self.assertEqual(refl37.bandname, 'ch20')

        with patch('pyspectral.radiance_tb_conversion.RelativeSpectralResponse') as mymock:
            instance = mymock.return_value
            instance.rsr = TEST_RSR
            instance.unit = '1e-6 m'
            instance.si_scale = 1e-6

            refl37 = Calculator('EOS-Aqua', 'modis', '20')

        sunz = np.array([80.])
        tb3 = np.array([290.])
        tb4 = np.array([282.])
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        np.testing.assert_allclose(refl[0], 0.251245010648, 6)

        tb3x = refl37.emissive_part_3x()
        np.testing.assert_allclose(tb3x, 276.213054, 6)

        sunz = np.array([80.])
        tb3 = np.array([295.])
        tb4 = np.array([282.])
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        np.testing.assert_allclose(refl[0], 0.452497961, 6)

        tb3x = refl37.emissive_part_3x()
        np.testing.assert_allclose(tb3x, 270.077268, 6)

        sunz = np.array([50.])
        tb3 = np.array([300.])
        tb4 = np.array([285.])
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        np.testing.assert_allclose(refl[0], 0.1189217, 6)

        tb3x = refl37.emissive_part_3x()
        np.testing.assert_allclose(tb3x, 282.455426, 6)

        sunz = np.array([50.])
        tb3 = np.ma.masked_array([300.], mask=False)
        tb4 = np.ma.masked_array([285.], mask=False)
        refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
        self.assertTrue(hasattr(refl, 'mask'))

        try:
            import dask.array as da
            sunz = da.from_array([50.], chunks=10)
            tb3 = da.from_array([300.], chunks=10)
            tb4 = da.from_array([285.], chunks=10)
            refl = refl37.reflectance_from_tbs(sunz, tb3, tb4)
            self.assertTrue(hasattr(refl, 'compute'))
        except ImportError:
            pass