Beispiel #1
0
def loadFAMEInput(path, moleculeDict=None):
    """
    Load the contents of a FAME input file into the MEASURE object. FAME
    is an early version of MEASURE written in Fortran and used by RMG-Java.
    This script enables importing FAME input files into MEASURE so we can
    use the additional functionality that MEASURE provides. Note that it
    is mostly designed to load the FAME input files generated automatically
    by RMG-Java, and may not load hand-crafted FAME input files. If you
    specify a `moleculeDict`, then this script will use it to associate
    the species with their structures.
    """
    
    def readMeaningfulLine(f):
        line = f.readline()
        while line != '':
            line = line.strip()
            if len(line) > 0 and line[0] != '#':
                return line
            else:
                line = f.readline()
        return ''

    moleculeDict = moleculeDict or {}

    logging.info('Loading file "{0}"...'.format(path))
    f = open(path)

    job = PressureDependenceJob(network=None)
    
    # Read method
    method = readMeaningfulLine(f).lower()
    if method == 'modifiedstrongcollision': 
        job.method = 'modified strong collision'
    elif method == 'reservoirstate': 
        job.method = 'reservoir state'

    # Read temperatures
    Tcount, Tunits, Tmin, Tmax = readMeaningfulLine(f).split()
    job.Tmin = Quantity(float(Tmin), Tunits) 
    job.Tmax = Quantity(float(Tmax), Tunits)
    job.Tcount = int(Tcount)
    Tlist = []
    for i in range(int(Tcount)):
        Tlist.append(float(readMeaningfulLine(f)))
    job.Tlist = Quantity(Tlist, Tunits)
    
    # Read pressures
    Pcount, Punits, Pmin, Pmax = readMeaningfulLine(f).split()
    job.Pmin = Quantity(float(Pmin), Punits) 
    job.Pmax = Quantity(float(Pmax), Punits)
    job.Pcount = int(Pcount)
    Plist = []
    for i in range(int(Pcount)):
        Plist.append(float(readMeaningfulLine(f)))
    job.Plist = Quantity(Plist, Punits)
    
    # Read interpolation model
    model = readMeaningfulLine(f).split()
    if model[0].lower() == 'chebyshev':
        job.interpolationModel = ('chebyshev', int(model[1]), int(model[2]))
    elif model[0].lower() == 'pdeparrhenius':
        job.interpolationModel = ('pdeparrhenius',)
    
    # Read grain size or number of grains
    job.minimumGrainCount = 0
    job.maximumGrainSize = None
    for i in range(2):
        data = readMeaningfulLine(f).split()
        if data[0].lower() == 'numgrains':
            job.minimumGrainCount = int(data[1])
        elif data[0].lower() == 'grainsize':
            job.maximumGrainSize = (float(data[2]), data[1])

    # A FAME file is almost certainly created during an RMG job, so use RMG mode
    job.rmgmode = True

    # Create the Network
    job.network = Network()

    # Read collision model
    data = readMeaningfulLine(f)
    assert data.lower() == 'singleexpdown'
    alpha0units, alpha0 = readMeaningfulLine(f).split()
    T0units, T0 = readMeaningfulLine(f).split()
    n = readMeaningfulLine(f)
    energyTransferModel = SingleExponentialDown(
        alpha0 = Quantity(float(alpha0), alpha0units),
        T0 = Quantity(float(T0), T0units),
        n = float(n),
    )
    
    speciesDict = {}

    # Read bath gas parameters
    bathGas = Species(label='bath_gas', energyTransferModel=energyTransferModel)
    molWtunits, molWt = readMeaningfulLine(f).split()
    if molWtunits == 'u': molWtunits = 'amu'
    bathGas.molecularWeight = Quantity(float(molWt), molWtunits)
    sigmaLJunits, sigmaLJ = readMeaningfulLine(f).split()
    epsilonLJunits, epsilonLJ = readMeaningfulLine(f).split()
    assert epsilonLJunits == 'J'
    bathGas.transportData = TransportData(
        sigma = Quantity(float(sigmaLJ), sigmaLJunits),
        epsilon = Quantity(float(epsilonLJ) / constants.kB, 'K'),
    )
    job.network.bathGas = {bathGas: 1.0}
    
    # Read species data
    Nspec = int(readMeaningfulLine(f))
    for i in range(Nspec):
        species = Species()
        species.conformer = Conformer()
        species.energyTransferModel = energyTransferModel
        
        # Read species label
        species.label = readMeaningfulLine(f)
        speciesDict[species.label] = species
        if species.label in moleculeDict:
            species.molecule = [moleculeDict[species.label]]
        
        # Read species E0
        E0units, E0 = readMeaningfulLine(f).split()
        species.conformer.E0 = Quantity(float(E0), E0units)
        species.conformer.E0.units = 'kJ/mol'
        
        # Read species thermo data
        H298units, H298 = readMeaningfulLine(f).split()
        S298units, S298 = readMeaningfulLine(f).split()
        Cpcount, Cpunits = readMeaningfulLine(f).split()
        Cpdata = []
        for i in range(int(Cpcount)):
            Cpdata.append(float(readMeaningfulLine(f)))
        if S298units == 'J/mol*K': S298units = 'J/(mol*K)'
        if Cpunits == 'J/mol*K': Cpunits = 'J/(mol*K)'
        species.thermo = ThermoData(
            H298 = Quantity(float(H298), H298units),
            S298 = Quantity(float(S298), S298units),
            Tdata = Quantity([300,400,500,600,800,1000,1500], "K"),
            Cpdata = Quantity(Cpdata, Cpunits),
            Cp0 = (Cpdata[0], Cpunits),
            CpInf = (Cpdata[-1], Cpunits),
        )
        
        # Read species collision parameters
        molWtunits, molWt = readMeaningfulLine(f).split()
        if molWtunits == 'u': molWtunits = 'amu'
        species.molecularWeight = Quantity(float(molWt), molWtunits)
        sigmaLJunits, sigmaLJ = readMeaningfulLine(f).split()
        epsilonLJunits, epsilonLJ = readMeaningfulLine(f).split()
        assert epsilonLJunits == 'J'
        species.transportData = TransportData(
            sigma = Quantity(float(sigmaLJ), sigmaLJunits),
            epsilon = Quantity(float(epsilonLJ) / constants.kB, 'K'),
        )
        
        # Read species vibrational frequencies
        freqCount, freqUnits = readMeaningfulLine(f).split()
        frequencies = []
        for j in range(int(freqCount)):
            frequencies.append(float(readMeaningfulLine(f)))
        species.conformer.modes.append(HarmonicOscillator(
            frequencies = Quantity(frequencies, freqUnits),
        ))
        
        # Read species external rotors
        rotCount, rotUnits = readMeaningfulLine(f).split()
        if int(rotCount) > 0:
            raise NotImplementedError('Cannot handle external rotational modes in FAME input.')
        
        # Read species internal rotors
        freqCount, freqUnits = readMeaningfulLine(f).split()
        frequencies = []
        for j in range(int(freqCount)):
            frequencies.append(float(readMeaningfulLine(f)))
        barrCount, barrUnits = readMeaningfulLine(f).split()
        barriers = []
        for j in range(int(barrCount)):
            barriers.append(float(readMeaningfulLine(f)))
        if barrUnits == 'cm^-1':
            barrUnits = 'J/mol'
            barriers = [barr * constants.h * constants.c * constants.Na * 100. for barr in barriers]
        elif barrUnits in ['Hz', 's^-1']:
            barrUnits = 'J/mol'
            barriers = [barr * constants.h * constants.Na for barr in barriers]
        elif barrUnits != 'J/mol':
            raise Exception('Unexpected units "{0}" for hindered rotor barrier height.'.format(barrUnits))
        inertia = [V0 / 2.0 / (nu * constants.c * 100.)**2 / constants.Na for nu, V0 in zip(frequencies, barriers)]
        for I, V0 in zip(inertia, barriers):
            species.conformer.modes.append(HinderedRotor(
                inertia = Quantity(I,"kg*m^2"), 
                barrier = Quantity(V0,barrUnits), 
                symmetry = 1,
                semiclassical = False,
            ))
            
        # Read overall symmetry number
        species.conformer.spinMultiplicity = int(readMeaningfulLine(f))
        
    # Read isomer, reactant channel, and product channel data
    Nisom = int(readMeaningfulLine(f))
    Nreac = int(readMeaningfulLine(f))
    Nprod = int(readMeaningfulLine(f))
    for i in range(Nisom):
        data = readMeaningfulLine(f).split()
        assert data[0] == '1'
        job.network.isomers.append(speciesDict[data[1]])
    for i in range(Nreac):
        data = readMeaningfulLine(f).split()
        assert data[0] == '2'
        job.network.reactants.append([speciesDict[data[1]], speciesDict[data[2]]])
    for i in range(Nprod):
        data = readMeaningfulLine(f).split()
        if data[0] == '1':
            job.network.products.append([speciesDict[data[1]]])
        elif data[0] == '2':
            job.network.products.append([speciesDict[data[1]], speciesDict[data[2]]])

    # Read path reactions
    Nrxn = int(readMeaningfulLine(f))
    for i in range(Nrxn):
        
        # Read and ignore reaction equation
        equation = readMeaningfulLine(f)
        reaction = Reaction(transitionState=TransitionState(), reversible=True)
        job.network.pathReactions.append(reaction)
        reaction.transitionState.conformer = Conformer()
        
        # Read reactant and product indices
        data = readMeaningfulLine(f).split()
        reac = int(data[0]) - 1
        prod = int(data[1]) - 1
        if reac < Nisom:
            reaction.reactants = [job.network.isomers[reac]]
        elif reac < Nisom+Nreac:
            reaction.reactants = job.network.reactants[reac-Nisom]
        else:
            reaction.reactants = job.network.products[reac-Nisom-Nreac]
        if prod < Nisom:
            reaction.products = [job.network.isomers[prod]]
        elif prod < Nisom+Nreac:
            reaction.products = job.network.reactants[prod-Nisom]
        else:
            reaction.products = job.network.products[prod-Nisom-Nreac]
        
        # Read reaction E0
        E0units, E0 = readMeaningfulLine(f).split()
        reaction.transitionState.conformer.E0 = Quantity(float(E0), E0units)
        reaction.transitionState.conformer.E0.units = 'kJ/mol'
        
        # Read high-pressure limit kinetics
        data = readMeaningfulLine(f)
        assert data.lower() == 'arrhenius'
        Aunits, A = readMeaningfulLine(f).split()
        if '/' in Aunits:
            index = Aunits.find('/')
            Aunits = '{0}/({1})'.format(Aunits[0:index], Aunits[index+1:])
        Eaunits, Ea = readMeaningfulLine(f).split()
        n = readMeaningfulLine(f)
        reaction.kinetics = Arrhenius(
            A = Quantity(float(A), Aunits),
            Ea = Quantity(float(Ea), Eaunits),
            n = Quantity(float(n)),
        )
        reaction.kinetics.Ea.units = 'kJ/mol'

    f.close()
    
    job.network.isomers = [Configuration(isomer) for isomer in job.network.isomers]
    job.network.reactants = [Configuration(*reactants) for reactants in job.network.reactants]
    job.network.products = [Configuration(*products) for products in job.network.products]

    return job
Beispiel #2
0
    def update_configurations(self, reaction_model):
        """
        Sort the reactants and products of each of the network's path reactions
        into isomers, reactant channels, and product channels. You must pass 
        the current `reaction_model` because some decisions on sorting are made
        based on which species are in the model core. 
        """
        reactants = []
        products = []

        # All explored species are isomers
        isomers = self.explored[:]

        # The source configuration is an isomer (if unimolecular) or a reactant channel (if bimolecular)
        if len(self.source) == 1:
            # The source is a unimolecular isomer
            if self.source[0] not in isomers: isomers.insert(0, self.source[0])
        else:
            # The source is a bimolecular reactant channel
            self.source.sort()
            reactants.append(self.source)

        # Iterate over path reactions and make sure each set of reactants and products is classified
        for rxn in self.path_reactions:
            # Sort bimolecular configurations so that we always encounter them in the
            # same order
            # The actual order doesn't matter, as long as it is consistent
            rxn.reactants.sort()
            rxn.products.sort()
            # Reactants of the path reaction
            if len(rxn.reactants) == 1 and rxn.reactants[
                    0] not in isomers and rxn.reactants not in products:
                # We've encountered a unimolecular reactant that is not classified
                # These are always product channels (since they would be in source or explored otherwise)
                products.append(rxn.reactants)
            elif len(
                    rxn.reactants
            ) > 1 and rxn.reactants not in reactants and rxn.reactants not in products:
                # We've encountered bimolecular reactants that are not classified
                if all([
                        reactant in reaction_model.core.species
                        for reactant in rxn.reactants
                ]):
                    # Both reactants are in the core, so treat as reactant channel
                    reactants.append(rxn.reactants)
                else:
                    # One or more reactants is an edge species, so treat as product channel
                    products.append(rxn.reactants)
            # Products of the path reaction
            if len(rxn.products) == 1 and rxn.products[
                    0] not in isomers and rxn.products not in products:
                # We've encountered a unimolecular product that is not classified
                # These are always product channels (since they would be in source or explored otherwise)
                products.append(rxn.products)
            elif len(
                    rxn.products
            ) > 1 and rxn.products not in reactants and rxn.products not in products:
                # We've encountered bimolecular products that are not classified
                if all([
                        product in reaction_model.core.species
                        for product in rxn.products
                ]):
                    # Both products are in the core, so treat as reactant channel
                    reactants.append(rxn.products)
                else:
                    # One or more reactants is an edge species, so treat as product channel
                    products.append(rxn.products)

        # Clear existing configurations
        self.isomers = []
        self.reactants = []
        self.products = []

        # Make a configuration object for each
        for isomer in isomers:
            self.isomers.append(Configuration(isomer))
        for reactant in reactants:
            self.reactants.append(Configuration(*reactant))
        for product in products:
            self.products.append(Configuration(*product))