def produce(self, spectrum): bin_boundaries = spectrum.binning() n_bins = len(bin_boundaries) - 1 row = newtables.BaseRow() row.append(newtables.CellString(spectrum.latex_title)) i_left = self.binning.index(bin_boundaries[0]) i_right = self.binning.index(bin_boundaries[-1]) for i in xrange(i_left): row.append(newtables.CellString('-')) if self.normalize: incl_xs = self.get_incl_xs(spectrum) for i_scan, scan in enumerate(spectrum.scans): left = bin_boundaries[i_scan] right = bin_boundaries[i_scan + 1] up = scan.unc.right_error down = scan.unc.left_error cell = CellSymmRelativeUncs(-abs(down), up) cell.span = self.binning.index(right) - self.binning.index(left) row.append(cell) for i in xrange(i_right, n_bins): row.append(newtables.CellString('-')) return row
def produce_binning_row(self, title=''): self.int_binning_where_possible() row = newtables.BaseRow() row.append(newtables.CellString(title)) for left, right in zip(self.binning[:-1], self.binning[1:]): if right == 10000. or (self.last_bin_is_overflow and right == self.binning[-1]): row.append(newtables.CellString('$>${0}'.format(left))) else: row.append(newtables.CellString('{0}-{1}'.format(left, right))) return row
def produce(self, spectrum): bin_boundaries = spectrum.binning() n_bins = len(bin_boundaries) - 1 row = newtables.BaseRow() row.append(newtables.CellString(spectrum.latex_title)) if self.do_xs: CellAsymmUncCrossSection.scientific_notation = True CellAsymmUncCrossSection.n_decimals = 3 i_left = self.binning.index(bin_boundaries[0]) i_right = self.binning.index(bin_boundaries[-1]) for i in xrange(i_left): row.append(newtables.CellString('-')) if self.normalize: incl_xs = self.get_incl_xs(spectrum) for i_scan, scan in enumerate(spectrum.scans): left = bin_boundaries[i_scan] right = bin_boundaries[i_scan + 1] center = scan.unc.x_min up = scan.unc.right_error down = scan.unc.left_error if self.do_xs: xs = spectrum.smxs[i_scan] bin_width = right - left if self.normalize: center *= xs * bin_width / incl_xs up *= xs * bin_width / incl_xs down *= xs * bin_width / incl_xs else: center *= xs up *= xs down *= xs cell = CellAsymmUncCrossSection(center, up, -abs(down)) cell.span = self.binning.index(right) - self.binning.index(left) row.append(cell) for i in xrange(i_right, n_bins): row.append(newtables.CellString('-')) return row
def produce_from_hist(self, H): row = newtables.BaseRow() row.append(newtables.CellString(H.title)) for i in xrange(H.n_bins): cell = CellSymmRelativeUncs(-abs(H.errs_down[i]), H.errs_up[i]) row.append(cell) return row
def produce_row_given_labels(self, labels): row = newtables.BaseRow() for label in labels: row.append(newtables.CellString(label)) return row