def test_fftim(self): self.m31image = create_test_image(cellsize=0.001, frequency=[1e8], canonical=True) m31_fft = fft_image(self.m31image) m31_fft_ifft = fft_image(m31_fft, self.m31image) numpy.testing.assert_array_almost_equal(self.m31image.data, m31_fft_ifft.data.real, 12) m31_fft.data = numpy.abs(m31_fft.data) export_image_to_fits(m31_fft, fitsfile='%s/test_m31_fft.fits' % (self.dir))
def test_tapering_Gaussian(self): self.actualSetUp() size_required = 0.010 self.componentvis = weight_visibility(self.componentvis, self.model, algoritm='uniform') self.componentvis = taper_visibility_gaussian(self.componentvis, beam=size_required) psf, sumwt = invert_2d(self.componentvis, self.model, dopsf=True) export_image_to_fits( psf, '%s/test_weighting_gaussian_taper_psf.fits' % self.dir) xfr = fft_image(psf) xfr.data = xfr.data.real.astype('float') export_image_to_fits( xfr, '%s/test_weighting_gaussian_taper_xfr.fits' % self.dir) npixel = psf.data.shape[3] sl = slice(npixel // 2 - 7, npixel // 2 + 8) fit = fit_2dgaussian(psf.data[0, 0, sl, sl]) # if fit.x_stddev <= 0.0 or fit.y_stddev <= 0.0: # raise ValueError('Error in fitting to psf') # fit_2dgaussian returns sqrt of variance. We need to convert that to FWHM. # https://en.wikipedia.org/wiki/Full_width_at_half_maximum scale_factor = numpy.sqrt(8 * numpy.log(2.0)) size = numpy.sqrt(fit.x_stddev * fit.y_stddev) * scale_factor # Now we need to convert to radians size *= numpy.pi * self.model.wcs.wcs.cdelt[1] / 180.0 # Very impressive! Desired 0.01 Acheived 0.0100006250829 assert numpy.abs(size - size_required) < 0.01 * size_required, \ "Fit should be %f, actually is %f" % (size_required, size)
def test_fftim_factors(self): for i in [3, 5, 7]: npixel = 256 * i m31image = create_test_image(cellsize=0.001, frequency=[1e8], canonical=True) padded = pad_image(m31image, [1, 1, npixel, npixel]) assert padded.shape == (1, 1, npixel, npixel) padded_fft = fft_image(padded) padded_fft_ifft = fft_image(padded_fft, m31image) numpy.testing.assert_array_almost_equal(padded.data, padded_fft_ifft.data.real, 12) padded_fft.data = numpy.abs(padded_fft.data) export_image_to_fits(padded_fft, fitsfile='%s/test_m31_fft_%d.fits' % (self.dir, npixel))
def test_convert_image_to_kernel(self): m31image = create_test_image(cellsize=0.001, frequency=[1e8], canonical=True) screen = create_w_term_like(m31image, w=20000.0, remove_shift=True) screen_fft = fft_image(screen) converted = convert_image_to_kernel(screen_fft, 8, 8) assert converted.shape == (1, 1, 8, 8, 8, 8) with self.assertRaises(AssertionError): converted = convert_image_to_kernel(m31image, 15, 1) with self.assertRaises(AssertionError): converted = convert_image_to_kernel(m31image, 15, 1000)
def test_tapering_Tukey(self): self.actualSetUp() self.componentvis = weight_visibility(self.componentvis, self.model, algoritm='uniform') self.componentvis = taper_visibility_tukey(self.componentvis, tukey=1.0) psf, sumwt = invert_2d(self.componentvis, self.model, dopsf=True) export_image_to_fits( psf, '%s/test_weighting_tukey_taper_psf.fits' % self.dir) xfr = fft_image(psf) xfr.data = xfr.data.real.astype('float') export_image_to_fits( xfr, '%s/test_weighting_tukey_taper_xfr.fits' % self.dir)