pyPDAF.PDAF.omi_assimilate_lnetf_nondiagR¶

pyPDAF.PDAF.omi_assimilate_lnetf_nondiagR()¶

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

LNETF [1] for a single DA step using non-diagnoal observation error covariance matrix. See pyPDAF.PDAF.localomi_assimilate() for using diagnoal observation error covariance matrix. The filter type is set in pyPDAF.PDAF.init(). This function should be called at each model time step. The function is a combination of pyPDAF.PDAF.omi_put_state_lnetf_nondiagR() and pyPDAF.PDAF.get_state().

User-supplied functions are executed in the following sequence:

py__collect_state_pdaf
py__prepoststep_state_pdaf
py__init_n_domains_p_pdaf
py__init_dim_obs_pdaf
py__obs_op_pdaf (for each ensemble member)
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__likelihood_l_pdaf
5. core DA algorithm
6. py__l2g_state_pdaf
py__prepoststep_state_pdaf
py__distribute_state_pdaf
py__next_observation_pdaf

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

References

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__distribute_state_pdaf (Callable[dim_p:int, state_p : ndarray[tuple[dim_p], np.float64]]) –
Routine to distribute 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 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]]) –
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__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
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 dim. of obs. vector for local ana. domain
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__likelihood_l_pdaf (Callable[domain_p:int, step:int, dim_obs_l:int, obs_l : ndarray[tuple[dim_obs_l], np.float64], resid_l : ndarray[tuple[dim_obs_l], np.float64], likely_l:float]) –
Compute observation likelihood for an ensemble member
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)
- obs_lndarray[tuple[dim_obs_l], np.float64]
  
  Local vector of observations
- resid_lndarray[tuple[dim_obs_l], np.float64]
  
  nput vector holding the local residual
- likely_lfloat
  
  Output value of the local likelihood
Callback Returns
- likely_lfloat
  
  Output value of the local likelihood
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 state on local analysis domain
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__next_observation_pdaf (Callable[stepnow:int, nsteps:int, doexit:int, time:float]) –
Provide time step and time of next observation
Callback Parameters
- stepnowint
  
  number of the current time step
- nstepsint
  
  number of time steps until next obs
- doexitint
  
  whether to exit forecasting (1 for exit)
- timefloat
  
  current model (physical) time
Callback Returns
- nstepsint
  
  number of time steps until next obs
- doexitint
  
  whether to exit forecasting (1 for exit)
- timefloat
  
  current model (physical) time

Returns:

outflag – Status flag

Return type:

int

pyPDAF.PDAF.omi_assimilate_lnetf_nondiagR¶

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