snowflake.ml.modeling.linear_model.TweedieRegressor¶

class snowflake.ml.modeling.linear_model.TweedieRegressor(*, power=0.0, alpha=1.0, fit_intercept=True, link='auto', solver='lbfgs', max_iter=100, tol=0.0001, warm_start=False, verbose=0, input_cols: Optional[Union[str, Iterable[str]]] = None, output_cols: Optional[Union[str, Iterable[str]]] = None, label_cols: Optional[Union[str, Iterable[str]]] = None, passthrough_cols: Optional[Union[str, Iterable[str]]] = None, drop_input_cols: Optional[bool] = False, sample_weight_col: Optional[str] = None)¶

Bases: BaseTransformer

Generalized Linear Model with a Tweedie distribution For more details on this class, see sklearn.linear_model.TweedieRegressor

input_cols: Optional[Union[str, List[str]]]

A string or list of strings representing column names that contain features. If this parameter is not specified, all columns in the input DataFrame except the columns specified by label_cols, sample_weight_col, and passthrough_cols parameters are considered input columns. Input columns can also be set after initialization with the set_input_cols method.

label_cols: Optional[Union[str, List[str]]]

A string or list of strings representing column names that contain labels. Label columns must be specified with this parameter during initialization or with the set_label_cols method before fitting.

output_cols: Optional[Union[str, List[str]]]

A string or list of strings representing column names that will store the output of predict and transform operations. The length of output_cols must match the expected number of output columns from the specific predictor or transformer class used. If you omit this parameter, output column names are derived by adding an OUTPUT_ prefix to the label column names for supervised estimators, or OUTPUT_<IDX>for unsupervised estimators. These inferred output column names work for predictors, but output_cols must be set explicitly for transformers. In general, explicitly specifying output column names is clearer, especially if you don’t specify the input column names. To transform in place, pass the same names for input_cols and output_cols. be set explicitly for transformers. Output columns can also be set after initialization with the set_output_cols method.

sample_weight_col: Optional[str]

A string representing the column name containing the sample weights. This argument is only required when working with weighted datasets. Sample weight column can also be set after initialization with the set_sample_weight_col method.

passthrough_cols: Optional[Union[str, List[str]]]

A string or a list of strings indicating column names to be excluded from any operations (such as train, transform, or inference). These specified column(s) will remain untouched throughout the process. This option is helpful in scenarios requiring automatic input_cols inference, but need to avoid using specific columns, like index columns, during training or inference. Passthrough columns can also be set after initialization with the set_passthrough_cols method.

drop_input_cols: Optional[bool], default=False

If set, the response of predict(), transform() methods will not contain input columns.

power: float, default=0

The power determines the underlying target distribution according to the following table:

Power	Distribution
0	Normal
1	Poisson
(1,2)	Compound Poisson Gamma
2	Gamma
3	Inverse Gaussian

For 0 < power < 1, no distribution exists.

alpha: float, default=1

Constant that multiplies the L2 penalty term and determines the regularization strength. alpha = 0 is equivalent to unpenalized GLMs. In this case, the design matrix X must have full column rank (no collinearities). Values of alpha must be in the range [0.0, inf).

fit_intercept: bool, default=True

Specifies if a constant (a.k.a. bias or intercept) should be added to the linear predictor (X @ coef + intercept).

link: {‘auto’, ‘identity’, ‘log’}, default=’auto’

The link function of the GLM, i.e. mapping from linear predictor X @ coeff + intercept to prediction y_pred. Option ‘auto’ sets the link depending on the chosen power parameter as follows:

‘identity’ for power <= 0, e.g. for the Normal distribution
‘log’ for power > 0, e.g. for Poisson, Gamma and Inverse Gaussian distributions

solver: {‘lbfgs’, ‘newton-cholesky’}, default=’lbfgs’

Algorithm to use in the optimization problem:

‘lbfgs’: Calls scipy’s L-BFGS-B optimizer.
‘newton-cholesky’: Uses Newton-Raphson steps (in arbitrary precision arithmetic equivalent to iterated reweighted least squares) with an inner Cholesky based solver. This solver is a good choice for n_samples >> n_features, especially with one-hot encoded categorical features with rare categories. Be aware that the memory usage of this solver has a quadratic dependency on n_features because it explicitly computes the Hessian matrix.

max_iter: int, default=100

The maximal number of iterations for the solver. Values must be in the range [1, inf).

tol: float, default=1e-4

Stopping criterion. For the lbfgs solver, the iteration will stop when max{|g_j|, j = 1, ..., d} <= tol where g_j is the j-th component of the gradient (derivative) of the objective function. Values must be in the range (0.0, inf).

warm_start: bool, default=False

If set to True, reuse the solution of the previous call to fit as initialization for coef_ and intercept_ .

verbose: int, default=0

For the lbfgs solver set verbose to any positive number for verbosity. Values must be in the range [0, inf).

Methods

`fit`(dataset)	Fit a Generalized Linear Model For more details on this function, see sklearn.linear_model.TweedieRegressor.fit
`get_input_cols`()	Input columns getter.
`get_label_cols`()	Label column getter.
`get_output_cols`()	Output columns getter.
`get_params`([deep])	Get parameters for this transformer.
`get_passthrough_cols`()	Passthrough columns getter.
`get_sample_weight_col`()	Sample weight column getter.
`get_sklearn_args`([default_sklearn_obj, ...])	Get sklearn keyword arguments.
`predict`(dataset)	Predict using GLM with feature matrix X For more details on this function, see sklearn.linear_model.TweedieRegressor.predict
`score`(dataset)	Compute D^2, the percentage of deviance explained For more details on this function, see sklearn.linear_model.TweedieRegressor.score
`set_drop_input_cols`([drop_input_cols])
`set_input_cols`(input_cols)	Input columns setter.
`set_label_cols`(label_cols)	Label column setter.
`set_output_cols`(output_cols)	Output columns setter.
`set_params`(**params)	Set the parameters of this transformer.
`set_passthrough_cols`(passthrough_cols)	Passthrough columns setter.
`set_sample_weight_col`(sample_weight_col)	Sample weight column setter.
`to_sklearn`()	Get sklearn.linear_model.TweedieRegressor object.

Attributes

model_signatures

Returns model signature of current class.