def calc_hapi(): ''' Calc spectrum under HAPI ''' clean_after_run = not exists(HAPIdb) and False try: db_begin(HAPIdb) if not molecule in tableList(): # only if data not downloaded already fetch(molecule, mol_id, iso, wmin-broadening_max_width / 2, wmax+broadening_max_width/2) # HAPI doesnt correct for side effects # Calculate with HAPI nu, coef = absorptionCoefficient_Voigt(SourceTables='CO2', Environment={'T': T, # K 'p': p/1.01325, # atm }, WavenumberStep=dnu, HITRAN_units=False, GammaL='gamma_self') nu, trans = transmittanceSpectrum(nu, coef, Environment={'l': L, # cm }) s_hapi = Spectrum.from_array(nu, trans, 'transmittance_noslit', 'cm-1', 'I/I0', conditions={'Tgas': T}, name='HAPI') except: raise finally: if clean_after_run: shutil.rmtree(HAPIdb) return s_hapi
def calc_hapi(): """ Calc spectrum under HAPI """ clean_after_run = not exists(HAPIdb) and False try: db_begin(HAPIdb) if not molecule in tableList( ): # only if data not downloaded already fetch( molecule, mol_id, iso, wmin - broadening_max_width / 2, wmax + broadening_max_width / 2, ) # HAPI doesnt correct for side effects # Calculate with HAPI nu, coef = absorptionCoefficient_Voigt( SourceTables="CO2", Environment={ "T": T, "p": p / 1.01325, }, # K # atm WavenumberStep=dnu, HITRAN_units=False, GammaL="gamma_self", ) nu, trans = transmittanceSpectrum( nu, coef, Environment={ "l": L, }, ) # cm s_hapi = Spectrum.from_array( nu, trans, "transmittance_noslit", "cm-1", "1", conditions={"Tgas": T}, name="HAPI", ) except: raise finally: if clean_after_run: shutil.rmtree(HAPIdb) return s_hapi
def test_broadening(rtol=1e-2, verbose=True, plot=False, *args, **kwargs): ''' Test broadening against HAPI and tabulated data We're looking at CO(0->1) line 'R1' at 2150.86 cm-1 ''' from radis.io.hapi import db_begin, fetch, tableList, absorptionCoefficient_Voigt if plot: # Make sure matplotlib is interactive so that test are not stuck in pytest plt.ion() setup_test_line_databases() # add HITRAN-CO-TEST in ~/.radis if not there # Conditions T = 3000 p = 0.0001 wstep = 0.001 wmin = 2150 # cm-1 wmax = 2152 # cm-1 broadening_max_width = 10 # cm-1 # %% HITRAN calculation # ----------- # Generate HAPI database locally db_begin(join(dirname(__file__), __file__.replace('.py', '_HAPIdata'))) if not 'CO' in tableList(): # only if data not downloaded already fetch('CO', 5, 1, wmin - broadening_max_width / 2, wmax + broadening_max_width / 2) # HAPI doesnt correct for side effects # Calculate with HAPI nu, coef = absorptionCoefficient_Voigt( SourceTables='CO', Environment={ 'T': T, # K 'p': p / 1.01325, # atm }, WavenumberStep=wstep, HITRAN_units=False) s_hapi = Spectrum.from_array(nu, coef, 'abscoeff', 'cm-1', 'cm_1', conditions={'Tgas': T}, name='HAPI') # %% Calculate with RADIS # ---------- sf = SpectrumFactory( wavenum_min=wmin, wavenum_max=wmax, mole_fraction=1, path_length=1, # doesnt change anything wstep=wstep, pressure=p, broadening_max_width=broadening_max_width, isotope=[1], warnings={ 'MissingSelfBroadeningWarning': 'ignore', 'NegativeEnergiesWarning': 'ignore', 'HighTemperatureWarning': 'ignore', 'GaussianBroadeningWarning': 'ignore' }) # 0.2) sf.load_databank('HITRAN-CO-TEST') # s = pl.non_eq_spectrum(Tvib=T, Trot=T, Ttrans=T) s = sf.eq_spectrum(Tgas=T, name='RADIS') if plot: # plot broadening of line of largest linestrength sf.plot_broadening(i=sf.df1.S.idxmax()) # Plot and compare res = abs(get_residual_integral(s, s_hapi, 'abscoeff')) if plot: plot_diff(s, s_hapi, var='abscoeff', title='{0} bar, {1} K (residual {2:.2g}%)'.format( p, T, res * 100), show_points=False) plt.xlim((wmin, wmax)) if verbose: printm('residual:', res) assert res < rtol