pyPDAF.PDAF.omi_put_state_en3dvar_lestkf_nondiagR

pyPDAF.PDAF.omi_put_state_en3dvar_lestkf_nondiagR()

It is recommended to use pyPDAF.PDAF.localomi_put_state_en3dvar_lestkf_nondiagR() or pyPDAF.PDAF.localomi_put_state_en3dvar_lestkf().

PDAFlocal-OMI modules require fewer user-supplied functions and improved efficiency.

3DEnVar for a single DA step without post-processing, distributing analysis, and setting next observation step,

where the ensemble anomaly is generated by LESTKF using non-diagnoal observation error covariance matrix.

Compared to pyPDAF.PDAF.omi_assimilate_en3dvar_lestkf_nondiagR(), this function has no get_state() call. This means that the analysis is not post-processed, and distributed to the model forecast by user-supplied functions. The next DA step will not be assigned by user-supplied functions as well. This function is typically used when there are not enough CPUs to run the ensemble in parallel, and some ensemble members have to be run serially. The pyPDAF.PDAF.get_state() function follows this function call to ensure the sequential DA.

The background error covariance matrix is estimated by ensemble. The 3DEnVar only calculates the analysis of the ensemble mean. An LESTKF is used to generate ensemble perturbations. This function should be called at each model time step.

The user-supplied function are executed in the following sequence:

1. py__collect_state_pdaf

2. py__prepoststep_state_pdaf

3. py__init_dim_obs_pdaf

4. py__obs_op_pdaf

5. Starting the iterative optimisation:

   1. py__cvt_ens_pdaf

   2. py__obs_op_lin_pdaf

   3. py__prodRinvA_pdaf

   4. py__obs_op_adj_pdaf

   5. py__cvt_adj_ens_pdaf

   6. core DA algorithm

6. py__cvt_ens_pdaf

7. Perform LESTKF:

   1. py__init_n_domains_p_pdaf

   2. py__init_dim_obs_pdaf

   3. py__obs_op_pdaf (for each ensemble member)

   4. loop over each local domain:

      1. py__init_dim_l_pdaf

      2. py__init_dim_obs_l_pdaf

      3. py__g2l_state_pdaf

      4. py__prodRinvA_l_pdaf

      5. core DA algorithm

      6. py__l2g_state_pdaf

Deprecated since version 1.0.0: This function is replaced by pyPDAF.PDAF.localomi_put_state_en3dvar_lestkf_nondiagR() and pyPDAF.PDAF.localomi_put_state_en3dvar_lestkf()

Parameters:

• py__collect_state_pdaf (Callable[dim_p:int, state_p : ndarray[tuple[dim_p], np.float64]]) –

  Routine to collect a state vector

  Callback Parameters

  • dim_pint

    • pe-local state dimension

  • state_pndarray[tuple[dim_p], np.float64]

    • local state vector

  Callback Returns

  • state_pndarray[tuple[dim_p], np.float64]

    • local state vector

• py__init_dim_obs_pdaf (Callable[step:int, dim_obs_p:int]) –

  Initialize dimension of full observation vector

  Callback Parameters

  • stepint

    • current time step

  • dim_obs_pint

    • dimension of observation vector

  Callback Returns

  • dim_obs_pint

    • dimension of observation vector

• py__obs_op_pdaf (Callable[step:int, dim_p:int, dim_obs_p:int, state_p : ndarray[tuple[dim_p], np.float64], m_state_p : ndarray[tuple[dim_obs_p], np.float64]]) –

  Full observation operator

  Callback Parameters

  • stepint

    • Current time step

  • dim_pint

    • Size of state vector (local part in case of parallel decomposed state)

  • dim_obs_pint

    • Size of observation vector

  • state_pndarray[tuple[dim_p], np.float64]

    • Model state vector

  • m_state_pndarray[tuple[dim_obs_p], np.float64]

    • Observed state vector (i.e. the result after applying the observation operator to state_p)

  Callback Returns

  • m_state_pndarray[tuple[dim_obs_p], np.float64]

    • Observed state vector (i.e. the result after applying the observation operator to state_p)

• py__prodRinvA_pdaf (Callable[step:int, dim_obs_p:int, rank:int, obs_p : ndarray[tuple[dim_obs_p], np.float64], A_p : ndarray[tuple[dim_obs_p, rank], np.float64], C_p : ndarray[tuple[dim_obs_p, rank], np.float64]]) –

  Provide product R^-1 A

  Callback Parameters

  • stepint

    • Current time step

  • dim_obs_pint

    • Number of observations at current time step (i.e. the size of the observation vector)

  • rankint

    • Number of the columns in the matrix processes here. This is usually the ensemble size minus one (or the rank of the initial covariance matrix)

  • obs_pndarray[tuple[dim_obs_p], np.float64]

    • Vector of observations

  • A_pndarray[tuple[dim_obs_p, rank], np.float64]

    • Input matrix provided by PDAF

  • C_pndarray[tuple[dim_obs_p, rank], np.float64]

    • Output matrix

  Callback Returns

  • C_pndarray[tuple[dim_obs_p, rank], np.float64]

    • Output matrix

• py__cvt_ens_pdaf (Callable[iter:int, dim_p:int, dim_ens:int, dim_cvec_ens:int, ens_p : ndarray[tuple[dim_p, dim_ens], np.float64], v_p : ndarray[tuple[dim_cvec_ens], np.float64], Vv_p : ndarray[tuple[dim_p], np.float64]]) –

  Apply control vector transform matrix to control vector

  Callback Parameters

  • iterint

    • Iteration of optimization

  • dim_pint

    • PE-local dimension of state

  • dim_ensint

    • Ensemble size

  • dim_cvec_ensint

    • Dimension of control vector

  • ens_pndarray[tuple[dim_p, dim_ens], np.float64]

    • PE-local ensemble

  • v_pndarray[tuple[dim_cvec_ens], np.float64]

    • PE-local control vector

  • Vv_pndarray[tuple[dim_p], np.float64]

    • PE-local state increment

  Callback Returns

  • Vv_pndarray[tuple[dim_p], np.float64]

    • PE-local state increment

• py__cvt_adj_ens_pdaf (Callable[iter:int, dim_p:int, dim_ens:int, dim_cv_ens_p:int, ens_p : ndarray[tuple[dim_p, dim_ens], np.float64], Vcv_p : ndarray[tuple[dim_p], np.float64], cv_p : ndarray[tuple[dim_cv_ens_p], np.float64]]) –

  Apply adjoint control vector transform matrix

  Callback Parameters

  • iterint

    • Iteration of optimization

  • dim_pint

    • PE-local observation dimension

  • dim_ensint

    • Ensemble size

  • dim_cv_ens_pint

    • PE-local dimension of control vector

  • ens_pndarray[tuple[dim_p, dim_ens], np.float64]

    • PE-local ensemble

  • Vcv_pndarray[tuple[dim_p], np.float64]

    • PE-local input vector

  • cv_pndarray[tuple[dim_cv_ens_p], np.float64]

    • PE-local result vector

  Callback Returns

  • cv_pndarray[tuple[dim_cv_ens_p], np.float64]

    • PE-local result vector

• py__obs_op_lin_pdaf (Callable[step:int, dim_p:int, dim_obs_p:int, state_p : ndarray[tuple[dim_p], np.float64], m_state_p : ndarray[tuple[dim_obs_p], np.float64]]) –

  Linearized observation operator

  Callback Parameters

  • stepint

    • Current time step

  • dim_pint

    • PE-local dimension of state

  • dim_obs_pint

    • Dimension of observed state

  • state_pndarray[tuple[dim_p], np.float64]

    • PE-local model state

  • m_state_pndarray[tuple[dim_obs_p], np.float64]

    • PE-local observed state

  Callback Returns

  • m_state_pndarray[tuple[dim_obs_p], np.float64]

    • PE-local observed state

• py__obs_op_adj_pdaf (Callable[step:int, dim_p:int, dim_obs_p:int, state_p : ndarray[tuple[dim_p], np.float64], m_state_p : ndarray[tuple[dim_obs_p], np.float64]]) –

  Adjoint observation operator

  Callback Parameters

  • stepint

    • Current time step

  • dim_pint

    • PE-local dimension of state

  • dim_obs_pint

    • Dimension of observed state

  • state_pndarray[tuple[dim_p], np.float64]

    • PE-local model state

  • m_state_pndarray[tuple[dim_obs_p], np.float64]

    • PE-local observed state

  Callback Returns

  • state_pndarray[tuple[dim_p], np.float64]

    • PE-local model state

• py__prodRinvA_l_pdaf (Callable[domain_p:int, step:int, dim_obs_l:int, rank:int, obs_l : ndarray[tuple[dim_obs_l], np.float64], A_l : ndarray[tuple[dim_obs_l, rank], np.float64], C_l : ndarray[tuple[dim_obs_l, rank], np.float64]]) –

  Provide product R^-1 A for local analysis domain

  Callback Parameters

  • domain_pint

    • Index of current local analysis domain

  • stepint

    • Current time step

  • dim_obs_lint

    • Number of local observations at current time step (i.e. the size of the local observation vector)

  • rankint

    • Number of the columns in the matrix processes here. This is usually the ensemble size minus one (or the rank of the initial covariance matrix)

  • obs_lndarray[tuple[dim_obs_l], np.float64]

    • Local vector of observations

  • A_lndarray[tuple[dim_obs_l, rank], np.float64]

    • Input matrix provided by PDAF

  • C_lndarray[tuple[dim_obs_l, rank], np.float64]

    • Output matrix

  Callback Returns

  • C_lndarray[tuple[dim_obs_l, rank], np.float64]

    • Output matrix

• py__init_n_domains_p_pdaf (Callable[step:int, n_domains_p:int]) –

  Provide number of local analysis domains

  Callback Parameters

  • stepint

    • current time step

  • n_domains_pint

    • pe-local number of analysis domains

  Callback Returns

  • n_domains_pint

    • pe-local number of analysis domains

• py__init_dim_l_pdaf (Callable[step:int, domain_p:int, dim_l:int]) –

  Init state dimension for local ana. domain

  Callback Parameters

  • stepint

    • current time step

  • domain_pint

    • current local analysis domain

  • dim_lint

    • local state dimension

  Callback Returns

  • dim_lint

    • local state dimension

• py__init_dim_obs_l_pdaf (Callable[domain_p:int, step:int, dim_obs_f:int, dim_obs_l:int]) –

  Initialize local dimimension of obs. vector

  Callback Parameters

  • domain_pint

    • index of current local analysis domain

  • stepint

    • current time step

  • dim_obs_fint

    • full dimension of observation vector

  • dim_obs_lint

    • local dimension of observation vector

  Callback Returns

  • dim_obs_lint

    • local dimension of observation vector

• py__g2l_state_pdaf (Callable[step:int, domain_p:int, dim_p:int, state_p : ndarray[tuple[dim_p], np.float64], dim_l:int, state_l : ndarray[tuple[dim_l], np.float64]]) –

  Get state on local ana. domain from full state

  Callback Parameters

  • stepint

    • current time step

  • domain_pint

    • current local analysis domain

  • dim_pint

    • pe-local full state dimension

  • state_pndarray[tuple[dim_p], np.float64]

    • pe-local full state vector

  • dim_lint

    • local state dimension

  • state_lndarray[tuple[dim_l], np.float64]

    • state vector on local analysis domain

  Callback Returns

  • state_lndarray[tuple[dim_l], np.float64]

    • state vector on local analysis domain

• py__l2g_state_pdaf (Callable[step:int, domain_p:int, dim_l:int, state_l : ndarray[tuple[dim_l], np.float64], dim_p:int, state_p : ndarray[tuple[dim_p], np.float64]]) –

  Init full state from local state

  Callback Parameters

  • stepint

    • current time step

  • domain_pint

    • current local analysis domain

  • dim_lint

    • local state dimension

  • state_lndarray[tuple[dim_l], np.float64]

    • state vector on local analysis domain

  • dim_pint

    • pe-local full state dimension

  • state_pndarray[tuple[dim_p], np.float64]

    • pe-local full state vector

  Callback Returns

  • state_pndarray[tuple[dim_p], np.float64]

    • pe-local full state vector

• py__prepoststep_pdaf (Callable[step:int, dim_p:int, dim_ens:int, dim_ens_p:int, dim_obs_p:int, state_p : ndarray[tuple[dim_p], np.float64], uinv : ndarray[tuple[dim_ens-1, dim_ens-1], np.float64], ens_p : ndarray[tuple[dim_p, dim_ens], np.float64], flag:int]) –

  User supplied pre/poststep routine

  Callback Parameters

  • stepint

    • current time step (negative for call after forecast)

  • dim_pint

    • pe-local state dimension

  • dim_ensint

    • size of state ensemble

  • dim_ens_pint

    • pe-local size of ensemble

  • dim_obs_pint

    • pe-local dimension of observation vector

  • state_pndarray[tuple[dim_p], np.float64]

    • pe-local forecast/analysis state (the array ‘state_p’ is not generally not initialized in the case of seik. it can be used freely here.)

  • uinvndarray[tuple[dim_ens-1, dim_ens-1], np.float64]

    • inverse of matrix u

  • ens_pndarray[tuple[dim_p, dim_ens], np.float64]

    • pe-local state ensemble

  • flagint

    • pdaf status flag

  Callback Returns

  • state_pndarray[tuple[dim_p], np.float64]

    • pe-local forecast/analysis state (the array ‘state_p’ is not generally not initialized in the case of seik. it can be used freely here.)

  • uinvndarray[tuple[dim_ens-1, dim_ens-1], np.float64]

    • inverse of matrix u

  • ens_pndarray[tuple[dim_p, dim_ens], np.float64]

    • pe-local state ensemble

• outflag (int) – Status flag

Returns:

outflag – Status flag

Return type:

int