コード例 #1
0
    def test_soil_moisture_potential(self):

        eps = 0.01
        nhru = 100
        nsoil = 5
        model = richards.richards(nhru, nsoil)
        #define parameters
        model.theta[:] = np.random.uniform(low=0.05, high=0.5,
                                           size=nhru)[:, np.newaxis]
        model.thetar[:] = 0.1
        model.thetas[:] = 0.5
        model.b[:] = np.random.uniform(low=3, high=8, size=nhru)
        model.satpsi[:] = 0.1
        #choose layer
        psi = []
        bpsi = []
        for il in xrange(nsoil):
            psi.append(model.calculate_soil_moisture_potential(il))
            tmp = model.theta[:, il]
            m = (tmp <= (1 + eps) * model.thetar)
            tmp[m] = (1 + eps) * model.thetar[m]
            bpsi.append(model.satpsi *
                        ((model.theta[:, il] - model.thetar) /
                         (model.thetas - model.thetar))**(-model.b))
        psi = np.array(psi)
        bpsi = np.array(bpsi)
        self.assertTrue(np.allclose(psi, bpsi))
コード例 #2
0
    def initialize_richards(self, ):

        from pyRichards import richards

        #Initialize richards
        self.richards = richards.richards(self.nhru, self.nsoil)

        #Set other parameters
        self.richards.dx = self.dx
        self.richards.nhru = self.nhru
        #print(self.nhru)
        self.richards.m[:] = self.input_fp.groups['parameters'].variables[
            'm'][:]
        #self.richards.dem[:] = self.input_fp.groups['parameters'].variables['dem'][:]
        self.richards.dem[:] = self.input_fp.groups['parameters'].variables[
            'hand'][:]
        self.richards.slope[:] = self.input_fp.groups['parameters'].variables[
            'slope'][:]
        #self.richards.hand[:] = self.input_fp.groups['parameters'].variables['hand'][:]
        self.richards.area[:] = self.input_fp.groups['parameters'].variables[
            'area'][:]
        self.richards.width = sparse.csr_matrix(
            (self.input_fp.groups['wmatrix'].variables['data'][:],
             self.input_fp.groups['wmatrix'].variables['indices'][:],
             self.input_fp.groups['wmatrix'].variables['indptr'][:]),
            shape=(self.nhru, self.nhru),
            dtype=np.float64)
        #dtype=np.float64)[0:self.nhru,0:self.nhru]
        #print(self.richards.width.shape)
        self.richards.I = self.richards.width.copy()
        self.richards.I[self.richards.I != 0] = 1

        return
コード例 #3
0
ファイル: HydroBlocks.py プロジェクト: chaneyn/HydroBlocks
 def initialize_richards(self,):
   
  from pyRichards import richards
  
  #Initialize richards
  self.richards = richards.richards(self.nhru,self.nsoil)

  #Set other parameters
  self.richards.dx = self.dx
  self.richards.nhru = self.nhru
  #print(self.nhru)
  self.richards.m[:] = self.input_fp.groups['parameters'].variables['m'][:]
  #self.richards.dem[:] = self.input_fp.groups['parameters'].variables['dem'][:]
  self.richards.dem[:] = self.input_fp.groups['parameters'].variables['hand'][:]
  self.richards.slope[:] = self.input_fp.groups['parameters'].variables['slope'][:]
  #self.richards.hand[:] = self.input_fp.groups['parameters'].variables['hand'][:]
  self.richards.area[:] = self.input_fp.groups['parameters'].variables['area'][:]
  self.richards.width = sparse.csr_matrix((self.input_fp.groups['wmatrix'].variables['data'][:],
                                  self.input_fp.groups['wmatrix'].variables['indices'][:],
                                  self.input_fp.groups['wmatrix'].variables['indptr'][:]),
                                  shape=(self.nhru,self.nhru),dtype=np.float64)
                                  #dtype=np.float64)[0:self.nhru,0:self.nhru]
  #print(self.richards.width.shape)
  self.richards.I = self.richards.width.copy()
  self.richards.I[self.richards.I != 0] = 1
  
  return
コード例 #4
0
ファイル: unittests.py プロジェクト: chaneyn/HydroBlocks
  def test_hydraulic_conductivity(self):

   nhru = 100
   nsoil = 5
   model = richards.richards(nhru,1)
   model.ksat[:] = 10**-3*np.random.uniform(low=10**-6,high=1,size=nhru) #mm/s
   model.satpsi[:] = np.random.uniform(low=0.01,high=1.0,size=nhru)
   model.b[:] = np.random.uniform(low=3,high=8,size=nhru)
   psi = np.random.uniform(low=0.001,high=10**10,size=nhru)
   #model
   kx = model.calculate_hydraulic_conductivity(psi)
   #baseline
   bkx = 10*model.ksat*(psi/model.satpsi)**(-2-3/model.b)
   self.assertTrue(np.allclose(kx,bkx,rtol=1e-10, atol=1e-50))
コード例 #5
0
    def test_hydraulic_conductivity(self):

        nhru = 100
        nsoil = 5
        model = richards.richards(nhru, 1)
        model.ksat[:] = 10**-3 * np.random.uniform(
            low=10**-6, high=1, size=nhru)  #mm/s
        model.satpsi[:] = np.random.uniform(low=0.01, high=1.0, size=nhru)
        model.b[:] = np.random.uniform(low=3, high=8, size=nhru)
        psi = np.random.uniform(low=0.001, high=10**10, size=nhru)
        #model
        kx = model.calculate_hydraulic_conductivity(psi)
        #baseline
        bkx = 10 * model.ksat * (psi / model.satpsi)**(-2 - 3 / model.b)
        self.assertTrue(np.allclose(kx, bkx, rtol=1e-10, atol=1e-50))
コード例 #6
0
    def test_dense_sparse_comparison(self):

        nhru = 5000
        nsoil = 1
        model = richards.richards(nhru, nsoil)
        #define parameters
        model.nhru = nhru
        model.theta[:] = np.random.uniform(low=0.1,
                                           high=0.5,
                                           size=(nhru, nsoil))
        model.thetar[:] = 0.1
        model.thetas[:] = 0.5
        model.b[:] = np.random.uniform(low=0.1, high=0.5, size=nhru)
        model.satpsi[:] = np.random.uniform(low=0.001, high=1.0, size=nhru)
        model.ksat[:] = 10**-3 * np.random.uniform(
            low=10**-6, high=1, size=nhru)  #mm/s
        model.dz[:] = np.random.uniform(low=0.01, high=100.0, size=nsoil)
        model.dx = 30.0
        model.area[:] = np.random.uniform(low=900, high=90000, size=nhru)
        model.dem[:] = np.random.uniform(low=0.0, high=1000.0, size=nhru)
        tmp = np.random.randint(low=-1000, high=2, size=(nhru, nhru))
        tmp[tmp <= 0] = 0
        tmp[range(nhru), range(nhru)] = 1
        tsymm = 30 * (tmp + tmp.T) / 2
        model.width = scipy.sparse.csr_matrix(tsymm)
        model.I = model.width.copy()
        model.I[model.I != 0] = 1
        print '%d connections out of %d possible connections' % (np.sum(
            model.width != 0), nhru * nhru)
        #update (dense)
        tic = time.time()
        model.update(type='dense')
        print 'dense', time.time() - tic
        hdiv = np.copy(model.hdiv)
        #update (sparse)
        tic = time.time()
        model.update(type='sparse')
        print 'sparse', time.time() - tic
        bhdiv = np.copy(model.hdiv)
        #compare
        self.assertTrue(np.allclose(hdiv, bhdiv, rtol=1e-10, atol=1e-50))
コード例 #7
0
ファイル: unittests.py プロジェクト: chaneyn/HydroBlocks
  def test_dense_sparse_comparison(self):

   nhru = 5000
   nsoil = 1
   model = richards.richards(nhru,nsoil)
   #define parameters
   model.nhru = nhru
   model.theta[:] = np.random.uniform(low=0.1,high=0.5,size=(nhru,nsoil))
   model.thetar[:] = 0.1
   model.thetas[:] = 0.5
   model.b[:] = np.random.uniform(low=0.1,high=0.5,size=nhru)
   model.satpsi[:] = np.random.uniform(low=0.001,high=1.0,size=nhru)
   model.ksat[:] = 10**-3*np.random.uniform(low=10**-6,high=1,size=nhru) #mm/s
   model.dz[:] = np.random.uniform(low=0.01,high=100.0,size=nsoil)
   model.dx = 30.0
   model.area[:] = np.random.uniform(low=900,high=90000,size=nhru)
   model.dem[:] = np.random.uniform(low=0.0,high=1000.0,size=nhru)
   tmp = np.random.randint(low=-1000,high=2,size=(nhru,nhru))
   tmp[tmp <= 0] = 0
   tmp[range(nhru),range(nhru)] = 1
   tsymm = 30*(tmp + tmp.T)/2
   model.width = scipy.sparse.csr_matrix(tsymm)
   model.I = model.width.copy()
   model.I[model.I != 0] = 1
   print '%d connections out of %d possible connections' % (np.sum(model.width != 0),nhru*nhru)
   #update (dense)
   tic = time.time()
   model.update(type='dense')
   print 'dense',time.time()-tic
   hdiv = np.copy(model.hdiv)
   #update (sparse)
   tic = time.time()
   model.update(type='sparse')
   print 'sparse',time.time()-tic
   bhdiv = np.copy(model.hdiv)
   #compare
   self.assertTrue(np.allclose(hdiv,bhdiv,rtol=1e-10, atol=1e-50))
コード例 #8
0
ファイル: unittests.py プロジェクト: chaneyn/HydroBlocks
  def test_soil_moisture_potential(self):

   eps = 0.01
   nhru = 100
   nsoil = 5
   model = richards.richards(nhru,nsoil)
   #define parameters
   model.theta[:] = np.random.uniform(low=0.05,high=0.5,size=nhru)[:,np.newaxis]
   model.thetar[:] = 0.1
   model.thetas[:] = 0.5 
   model.b[:] = np.random.uniform(low=3,high=8,size=nhru)
   model.satpsi[:] = 0.1
   #choose layer
   psi = []
   bpsi = []
   for il in xrange(nsoil):
    psi.append(model.calculate_soil_moisture_potential(il))
    tmp = model.theta[:,il]
    m = (tmp <= (1+eps)*model.thetar)
    tmp[m] = (1+eps)*model.thetar[m]
    bpsi.append(model.satpsi*((model.theta[:,il]-model.thetar)/(model.thetas-model.thetar))**(-model.b))
   psi = np.array(psi)
   bpsi = np.array(bpsi)
   self.assertTrue(np.allclose(psi,bpsi))