def synth_8542(atmos, backgroundProvider=None): atmos.convert_scales() atmos.quadrature(5) aSet = lw.RadiativeSet([ H_6_atom(), C_atom(), O_atom(), Si_atom(), Al_atom(), CaII_atom(), Fe_atom(), He_9_atom(), MgII_atom(), N_atom(), Na_atom(), S_atom() ]) aSet.set_active('Ca') spect = aSet.compute_wavelength_grid() eqPops = aSet.compute_eq_pops(atmos) ctx = lw.Context(atmos, spect, eqPops, Nthreads=8, backgroundProvider=backgroundProvider) iterate_ctx(ctx) eqPops.update_lte_atoms_Hmin_pops(atmos) Iwave = ctx.compute_rays(wave, [atmos.muz[-1]], stokes=False) return ctx, Iwave
def make_fal_context(velShift=0.0): atmos = Falc82() atmos.vlos[:] = velShift atmos.convert_scales() atmos.quadrature(5) aSet = lw.RadiativeSet([H_6_atom(), C_atom(), O_atom(), Si_atom(), Al_atom(), CaII_atom(), Fe_atom(), He_9_atom(), MgII_atom(), N_atom(), Na_atom(), S_atom()]) aSet.set_active('H', 'Ca') spect = aSet.compute_wavelength_grid() eqPops = aSet.compute_eq_pops(atmos) ctx = lw.Context(atmos, spect, eqPops, ngOptions=NgOptions(0,0,0), Nthreads=1) return ctx
def inner(): atmos = Atmosphere(ScaleType.Geometric, depthScale=atmosData['height'], temperature=atmosData['temp'], vlos=atmosData['vlos'], vturb=4000 * np.ones_like(atmosData['height'])) aSet = RadiativeSet([ H_3_atom(), C_atom(), O_atom(), Si_atom(), Al_atom(), CaII_atom(), Fe_atom(), He_atom(), MgII_atom(), N_atom(), Na_atom(), S_atom() ]) aSet.set_active('Ca') spect = aSet.compute_wavelength_grid() atmos.convert_scales(Pgas=atmosData['pgas']) atmos.quadrature(5) mols = MolecularTable() eqPops = aSet.iterate_lte_ne_eq_pops(mols, atmos) ctx = LwContext(atmos, spect, eqPops, conserveCharge=True, initSol=InitialSolution.Lte) iterate_ctx(ctx, prd=False) aSet.set_active('H') spect = aSet.compute_wavelength_grid() ctx2 = LwContext(atmos, spect, eqPops, conserveCharge=True, initSol=InitialSolution.Lte) iterate_ctx(ctx2, prd=False) eqPops.update_lte_atoms_Hmin_pops(atmos) Iwave = ctx.compute_rays(wave, [1.0]) return Iwave
def cmo_synth(atmosData, crsw=None): with open(os.devnull, 'w') as f: with redirect_stdout(f): if crsw is not None: crsw = crsw() atmos = Atmosphere(ScaleType.Geometric, depthScale=atmosData['height'], temperature=atmosData['temp'], vlos=atmosData['vlos'], vturb=4000 * np.ones_like(atmosData['height'])) aSet = RadiativeSet([ H_3_atom(), C_atom(), O_atom(), Si_atom(), Al_atom(), CaII_atom(), Fe_atom(), He_atom(), MgII_atom(), N_atom(), Na_atom(), S_atom() ]) aSet.set_active('H', 'Ca') spect = aSet.compute_wavelength_grid() atmos.convert_scales(Pgas=atmosData['pgas']) atmos.quadrature(5) mols = MolecularTable() eqPops = aSet.iterate_lte_ne_eq_pops(mols, atmos) ctx = LwContext(atmos, spect, eqPops, conserveCharge=True, initSol=InitialSolution.Lte, crswCallback=crsw) iterate_ctx(ctx, prd=False) eqPops.update_lte_atoms_Hmin_pops(atmos) Iwave = ctx.compute_rays(wave, [1.0]) return Iwave
def synth_line(atmos, conserve, useNe=True, prd=False): atmos.convert_scales() atmos.quadrature(5) aSet = lw.RadiativeSet([ H_6_atom(), C_atom(), O_atom(), Si_atom(), Al_atom(), CaII_atom(), Fe_atom(), He_9_atom(), MgII_atom(), N_atom(), Na_atom(), S_atom() ]) aSet.set_active('H', 'Ca', 'Mg') spect = aSet.compute_wavelength_grid() molPaths = [get_default_molecule_path() + m + '.molecule' for m in ['H2']] mols = lw.MolecularTable(molPaths) if useNe: eqPops = aSet.compute_eq_pops(atmos, mols) else: eqPops = aSet.iterate_lte_ne_eq_pops(atmos, mols) ctx = lw.Context(atmos, spect, eqPops, ngOptions=NgOptions(0, 0, 0), hprd=False, conserveCharge=conserve, Nthreads=8) ctx.depthData.fill = True start = time.time() iterate_ctx(ctx, atmos, eqPops, prd=prd, updateLte=False) end = time.time() print('%.2f s' % (end - start)) eqPops.update_lte_atoms_Hmin_pops(atmos) Iwave = ctx.compute_rays(wave, [atmos.muz[-1]], stokes=False) return ctx, Iwave
def cmo_synth_given(atmosData): with open(os.devnull, 'w') as f: with redirect_stdout(f): at = get_global_atomic_table() atmos = Atmosphere(ScaleType.Geometric, depthScale=atmosData['height'], temperature=atmosData['temp'], vlos=atmosData['vlos'], vturb=4000 * np.ones_like(atmosData['height']), ne=atmosData['ne'], nHTot=(atmosData['density'] / (at.weightPerH * Const.Amu))) aSet = RadiativeSet([ H_3_atom(), C_atom(), O_atom(), Si_atom(), Al_atom(), CaII_atom(), Fe_atom(), He_atom(), MgII_atom(), N_atom(), Na_atom(), S_atom() ]) aSet.set_active('Ca') spect = aSet.compute_wavelength_grid() atmos.convert_scales() atmos.quadrature(5) mols = MolecularTable() eqPops = aSet.iterate_lte_ne_eq_pops(mols, atmos) ctx = LwContext(atmos, spect, eqPops, conserveCharge=False) iterate_ctx(ctx, prd=False) Iwave = ctx.compute_rays(wave, [1.0]) return Iwave
def cmo_synth(atmosData, crsw=None, NmaxIter=1000): with open(os.devnull, 'w') as f: with redirect_stdout(f): if crsw is not None: crsw = crsw() atmos = Atmosphere(ScaleType.Geometric, depthScale=atmosData['height'], temperature=atmosData['temp'], vlos=atmosData['vlos'], vturb=4000 * np.ones_like(atmosData['height'])) aSet = RadiativeSet([ H_6_atom(), C_atom(), O_atom(), Si_atom(), Al_atom(), CaII_atom(), Fe_atom(), He_atom(), MgII_atom(), N_atom(), Na_atom(), S_atom() ]) aSet.set_active('H', 'Ca') spect = aSet.compute_wavelength_grid() atmos.convert_scales(Pgas=atmosData['pgas']) atmos.quadrature(5) eqPops = aSet.iterate_lte_ne_eq_pops(atmos) ctx = lw.Context(atmos, spect, eqPops, conserveCharge=False, initSol=InitialSolution.Lte, crswCallback=crsw) converged = True exploding = False try: nIter = iterate_ctx(ctx, eqPops, prd=False, NmaxIter=NmaxIter, nr=True) except ConvergenceError: converged = False nIter = NmaxIter except ExplodingMatrixError: converged = False exploding = True nIter = NmaxIter if converged: eqPops.update_lte_atoms_Hmin_pops(atmos) Iwave = ctx.compute_rays(wave, [1.0]) return { 'Iwave': Iwave, 'eqPops': eqPops, 'converged': converged, 'nIter': nIter, 'atmosData': atmosData, 'exploding': exploding } else: return { 'converged': converged, 'nIter': nIter, 'atmosData': atmosData, 'exploding': exploding }
coarse[:, 0] = fine[:, 0] coarse[:, -1] = fine[:, -1] fal_sampler = fal_height_upsampler() coarse = fal_sampler(2, outer=True) fine = fal_sampler(4) coarse.quadrature(5) fine.quadrature(5) aSet = lw.RadiativeSet([ H_6_atom(), C_atom(), O_atom(), Si_atom(), Al_atom(), CaII_atom(), Fe_atom(), He_9_atom(), MgII_atom(), N_atom(), Na_atom(), S_atom() ]) aSet.set_active('Ca') spect = aSet.compute_wavelength_grid() coarseEqPops = aSet.compute_eq_pops(coarse) fineEqPops = aSet.compute_eq_pops(fine) trueEqPops = aSet.compute_eq_pops(fine) coarseCtx = lw.Context(coarse,
def synth_8542(atmos, conserve, useNe, wave): ''' Synthesise a spectral line for given atmosphere with different conditions. Parameters ---------- atmos : lw.Atmosphere The atmospheric model in which to synthesise the line. conserve : bool Whether to start from LTE electron density and conserve charge, or simply use from the electron density present in the atomic model. useNe : bool Whether to use the electron density present in the model as the starting solution, or compute the LTE electron density. wave : np.ndarray Array of wavelengths over which to resynthesise the final line profile for muz=1. Returns ------- ctx : lw.Context The Context object that was used to compute the equilibrium populations. Iwave : np.ndarray The intensity at muz=1 for each wavelength in `wave`. ''' # Configure the atmospheric angular quadrature atmos.quadrature(5) # Configure the set of atomic models to use. aSet = lw.RadiativeSet([ H_6_atom(), C_atom(), O_atom(), Si_atom(), Al_atom(), CaII_atom(), Fe_atom(), He_9_atom(), MgII_atom(), N_atom(), Na_atom(), S_atom() ]) # Set H and Ca to "active" i.e. NLTE, everything else participates as an # LTE background. aSet.set_active('H', 'Ca') # Compute the necessary wavelength dependent information (SpectrumConfiguration). spect = aSet.compute_wavelength_grid() # Either compute the equilibrium populations at the fixed electron density # provided in the model, or iterate an LTE electron density and compute the # corresponding equilibrium populations (SpeciesStateTable). if useNe: eqPops = aSet.compute_eq_pops(atmos) else: eqPops = aSet.iterate_lte_ne_eq_pops(atmos) # Configure the Context which holds the state of the simulation for the # backend, and provides the python interface to the backend. # Feel free to increase Nthreads to increase the number of threads the # program will use. ctx = lw.Context(atmos, spect, eqPops, conserveCharge=conserve, Nthreads=1) start = time.time() # Iterate the Context to convergence iterate_ctx(ctx) end = time.time() print('%.2f s' % (end - start)) # Update the background populations based on the converged solution and # compute the final intensity for mu=1 on the provided wavelength grid. eqPops.update_lte_atoms_Hmin_pops(atmos) Iwave = ctx.compute_rays(wave, [atmos.muz[-1]], stokes=False) return ctx, Iwave