ReferenceState.pyx

#!python
# cython: boundscheck=False
# cython: wraparound=True
# cython: initializedcheck=False
# cython: cdivision=True

cimport Grid
cimport Restart
cimport numpy as np
import numpy as np
from NetCDFIO cimport NetCDFIO_Stats
cimport ParallelMPI
from scipy.integrate import odeint
include 'parameters.pxi'

cdef extern from "thermodynamic_functions.h":
    inline double qt_from_pv(double p0, double pv)

cdef class ReferenceState:
    def __init__(self, Grid.Grid Gr ):

        self.p0 = np.zeros(Gr.dims.nlg[2], dtype=np.double, order='c')
        self.p0_half = np.zeros(Gr.dims.nlg[2], dtype=np.double, order='c')
        self.alpha0 = np.zeros(Gr.dims.nlg[2], dtype=np.double, order='c')
        self.alpha0_half = np.zeros(Gr.dims.nlg[2], dtype=np.double, order='c')
        self.rho0 = np.zeros(Gr.dims.nlg[2], dtype=np.double, order='c')
        self.rho0_half = np.zeros(Gr.dims.nlg[2], dtype=np.double, order='c')

        return

    def initialize(self, Grid.Grid Gr, Thermodynamics, NetCDFIO_Stats NS, ParallelMPI.ParallelMPI Pa):
        '''
        Initilize the reference profiles. The function is typically called from the case specific initialization
        fucntion defined in Initialization.pyx
        :param Gr: Grid class
        :param Thermodynamics: Thermodynamics class
        :param NS: StatsIO class
        :param Pa:  ParallelMPI class
        :return:
        '''




        self.sg = Thermodynamics.entropy(self.Pg, self.Tg, self.qtg, 0.0, 0.0)

        # Form a right hand side for integrating the hydrostatic equation to
        # determine the reference pressure
        def rhs(p, z):
            T, ql, qi = Thermodynamics.eos(np.exp(p), self.sg, self.qtg)
            return -g / (Rd * T * (1.0 - self.qtg + eps_vi * (self.qtg - ql - qi)))

        # Construct arrays for integration points
        z = np.array(Gr.z[Gr.dims.gw - 1:-Gr.dims.gw + 1])
        z_half = np.append([0.0], np.array(Gr.z_half[Gr.dims.gw:-Gr.dims.gw]))

        # We are integrating the log pressure so need to take the log of the
        # surface pressure
        p0 = np.log(self.Pg)

        p = np.zeros(Gr.dims.ng[2], dtype=np.double, order='c')
        p_half = np.zeros(Gr.dims.ng[2], dtype=np.double, order='c')

        # Perform the integration
        p[Gr.dims.gw - 1:-Gr.dims.gw +1] = odeint(rhs, p0, z, hmax=1.0)[:, 0]
        p_half[Gr.dims.gw:-Gr.dims.gw] = odeint(rhs, p0, z_half, hmax=1.0)[1:, 0]

        # Set boundary conditions
        p[:Gr.dims.gw - 1] = p[2 * Gr.dims.gw - 2:Gr.dims.gw - 1:-1]
        p[-Gr.dims.gw + 1:] = p[-Gr.dims.gw - 1:-2 * Gr.dims.gw:-1]

        p_half[:Gr.dims.gw] = p_half[2 * Gr.dims.gw - 1:Gr.dims.gw - 1:-1]
        p_half[-Gr.dims.gw:] = p_half[-Gr.dims.gw - 1:-2 * Gr.dims.gw - 1:-1]

        p = np.exp(p)
        p_half = np.exp(p_half)

        cdef double[:] p_ = p
        cdef double[:] p_half_ = p_half
        cdef double[:] temperature = np.zeros(Gr.dims.ng[2], dtype=np.double, order='c')
        cdef double[:] temperature_half = np.zeros(Gr.dims.ng[2], dtype=np.double, order='c')
        cdef double[:] alpha = np.zeros(Gr.dims.ng[2], dtype=np.double, order='c')
        cdef double[:] alpha_half = np.zeros(Gr.dims.ng[2], dtype=np.double, order='c')

        cdef double[:] ql = np.zeros(Gr.dims.ng[2], dtype=np.double, order='c')
        cdef double[:] qi = np.zeros(Gr.dims.ng[2], dtype=np.double, order='c')
        cdef double[:] qv = np.zeros(Gr.dims.ng[2], dtype=np.double, order='c')

        cdef double[:] ql_half = np.zeros(Gr.dims.ng[2], dtype=np.double, order='c')
        cdef double[:] qi_half = np.zeros(Gr.dims.ng[2], dtype=np.double, order='c')
        cdef double[:] qv_half = np.zeros(Gr.dims.ng[2], dtype=np.double, order='c')

        # Compute reference state thermodynamic profiles
        for k in xrange(Gr.dims.ng[2]):
            temperature[k], ql[k], qi[k] = Thermodynamics.eos(p_[k], self.sg, self.qtg)
            qv[k] = self.qtg - (ql[k] + qi[k])
            alpha[k] = Thermodynamics.alpha(p_[k], temperature[k], self.qtg, qv[k])

            temperature_half[k], ql_half[k], qi_half[k] = Thermodynamics.eos(p_half_[k], self.sg, self.qtg)
            qv_half[k] = self.qtg - (ql_half[k] + qi_half[k])
            alpha_half[k] = Thermodynamics.alpha(p_half_[k], temperature_half[k], self.qtg, qv_half[k])

        # Now do a sanity check to make sure that the Reference State entropy profile is uniform following
        # saturation adjustment
        cdef double s
        for k in xrange(Gr.dims.ng[2]):
            s = Thermodynamics.entropy(p_half[k],temperature_half[k],self.qtg,ql_half[k],qi_half[k])
            if np.abs(s - self.sg)/self.sg > 0.01:
                Pa.root_print('Error in reference profiles entropy not constant !')
                Pa.root_print('Likely error in saturation adjustment')
                Pa.root_print('Kill Simulation Now!')
                Pa.kill()


        # print(np.array(Gr.extract_local_ghosted(alpha_half,2)))
        self.alpha0_half = Gr.extract_local_ghosted(alpha_half, 2)
        self.alpha0 = Gr.extract_local_ghosted(alpha, 2)
        self.p0 = Gr.extract_local_ghosted(p_, 2)
        self.p0_half = Gr.extract_local_ghosted(p_half, 2)
        self.rho0 = 1.0 / np.array(self.alpha0)
        self.rho0_half = 1.0 / np.array(self.alpha0_half)

        # Write reference profiles to StatsIO
        NS.add_reference_profile('alpha0', Gr, Pa)
        NS.write_reference_profile('alpha0', alpha_half[Gr.dims.gw:-Gr.dims.gw], Pa)
        NS.add_reference_profile('p0', Gr, Pa)
        NS.write_reference_profile('p0', p_half[Gr.dims.gw:-Gr.dims.gw], Pa)
        NS.add_reference_profile('rho0', Gr, Pa)
        NS.write_reference_profile('rho0', 1.0 / np.array(alpha_half[Gr.dims.gw:-Gr.dims.gw]), Pa)
        NS.add_reference_profile('temperature0', Gr, Pa)
        NS.write_reference_profile('temperature0', temperature_half[Gr.dims.gw:-Gr.dims.gw], Pa)
        NS.add_reference_profile('ql0', Gr, Pa)
        NS.write_reference_profile('ql0', ql_half[Gr.dims.gw:-Gr.dims.gw], Pa)
        NS.add_reference_profile('qv0', Gr, Pa)
        NS.write_reference_profile('qv0', qv_half[Gr.dims.gw:-Gr.dims.gw], Pa)
        NS.add_reference_profile('qi0', Gr, Pa)
        NS.write_reference_profile('qi0', qi_half[Gr.dims.gw:-Gr.dims.gw], Pa)

        return

    cpdef restart(self, Grid.Grid Gr, Restart.Restart Re):
        Re.restart_data['Ref'] = {}

        Re.restart_data['Ref']['p0'] = np.array(self.p0)
        Re.restart_data['Ref']['p0_half'] = np.array(self.p0_half)
        Re.restart_data['Ref']['alpha0'] = np.array(self.alpha0)
        Re.restart_data['Ref']['alpha0_half'] = np.array(self.alpha0_half)

        Re.restart_data['Ref']['Tg'] = self.Tg
        Re.restart_data['Ref']['Pg'] = self.Pg
        Re.restart_data['Ref']['sg'] = self.sg
        Re.restart_data['Ref']['qtg'] = self.qtg
        Re.restart_data['Ref']['u0'] = self.u0
        Re.restart_data['Ref']['v0'] = self.v0

        return


    cpdef init_from_restart(self, Grid.Grid Gr, Restart.Restart Re):

        self.Tg = Re.restart_data['Ref']['Tg']
        self.Pg = Re.restart_data['Ref']['Pg']
        self.sg = Re.restart_data['Ref']['sg']
        self.qtg = Re.restart_data['Ref']['qtg']
        self.u0 = Re.restart_data['Ref']['u0']
        self.v0 = Re.restart_data['Ref']['v0']

        self.p0 = Re.restart_data['Ref']['p0']
        self.p0_half = Re.restart_data['Ref']['p0_half']
        self.alpha0 = Re.restart_data['Ref']['alpha0']
        self.alpha0_half = Re.restart_data['Ref']['alpha0_half']
        self.rho0 = 1.0 / Re.restart_data['Ref']['alpha0']
        self.rho0_half = 1.0 / Re.restart_data['Ref']['alpha0_half']

        return