moscot.problems.time.TemporalProblem.prepare¶
- TemporalProblem.prepare(time_key, joint_attr=None, policy='sequential', cost='sq_euclidean', cost_kwargs=mappingproxy({}), a=None, b=None, marginal_kwargs=mappingproxy({}), subset=None, reference=None, xy_callback=None, x_callback=None, y_callback=None, xy_callback_kwargs=mappingproxy({}), x_callback_kwargs=mappingproxy({}), y_callback_kwargs=mappingproxy({}), x=mappingproxy({}), y=mappingproxy({}), xy=mappingproxy({}))[source]¶
Prepare the temporal problem problem.
See also
See Disentangling lineage relationships of delta and epsilon cells in pancreatic development with the TemporalProblem on how to prepare and solve the
TemporalProblem.
- Parameters:
time_key (
str) – Key inobswhere the time points are stored.joint_attr (
Union[str,Mapping[str,Any],None]) –How to get the data that defines the linear problem:
dict- it should contain'attr'and'key', the attribute and key inAnnData, and optionally'tag'from thetags.
By default,
tag = 'point_cloud'is used.policy (
Literal['sequential','triu','tril','explicit']) –Rule which defines how to construct the subproblems using
obs['{time_key}']. Valid options are:'sequential'- align subsequent time points[(t0, t1), (t1, t2), ...].'triu'- upper triangular matrix[(t0, t1), (t0, t2), ..., (t1, t2), ...].'tril'- lower triangular matrix[(t_n, t_n-1), (t_n, t0), ..., (t_n-1, t_n-2), ...].'explicit'- explicit sequence of subsets passed viasubset = [(b3, b0), ...].
cost (
Literal['euclidean','sq_euclidean','cosine','pnorm_p','sq_pnorm','geodesic']) –Cost function to use. Valid options are:
str- name of the cost function, seeget_available_costs().dict- a dictionary with the following keys and values:'xy'- cost function for the linear term, same as above.
cost_kwargs (
Union[Mapping[str,Any],Mapping[Literal['x','y','xy'],Mapping[str,Any]]]) – Keyword arguments for theBaseCostor any backend-specific cost.Source marginals. Valid options are:
bool- ifTrue,estimate the marginals, otherwise use uniform marginals.None- set toTrueifproliferation_keyorapoptosis_keyis notNone.
Target marginals. Valid options are:
bool- ifTrue,estimate the marginals, otherwise use uniform marginals.None- set toTrueifproliferation_keyorapoptosis_keyis notNone.
marginal_kwargs (
Mapping[str,Any]) – Keyword arguments forestimate_marginals(). It always containsproliferation_keyandapoptosis_key, seescore_genes_for_marginals()for more information.subset (
Optional[Sequence[Tuple[Union[int,float],Union[int,float]]]]) – Subset ofobs['{key}']for theExplicitPolicy. Only used whenpolicy = 'explicit'.reference (
Optional[Any]) – Reference for theSubsetPolicy. Only used whenpolicy = 'star'.xy_callback (
Union[Literal['local-pca'],Callable[[Literal['xy','x','y'],AnnData,Optional[AnnData]],Optional[TaggedArray]],None]) – Callback function used to prepare the data in the linear term.x_callback (
Union[Literal['local-pca'],Callable[[Literal['xy','x','y'],AnnData,Optional[AnnData]],Optional[TaggedArray]],None]) – Callback function used to prepare the data in the source quadratic term.y_callback (
Union[Literal['local-pca'],Callable[[Literal['xy','x','y'],AnnData,Optional[AnnData]],Optional[TaggedArray]],None]) – Callback function used to prepare the data in the target quadratic term.xy_callback_kwargs (
Mapping[str,Any]) – Keyword arguments for thexy_callback.x_callback_kwargs (
Mapping[str,Any]) – Keyword arguments for thex_callback.y_callback_kwargs (
Mapping[str,Any]) – Keyword arguments for they_callback.x (
Mapping[str,Any]) – Data for the source quadratic term.y (
Mapping[str,Any]) – Data for the target quadratic term.xy (
Mapping[str,Any]) – Data for the linear term.
- Return type:
- Returns:
: Returns self and updates the following fields:
problems- the prepared subproblems.temporal_key- key inobswhere time points are stored.stage- set to'prepared'.problem_kind- set to'linear'.