sklearn.gaussian_process.kernels
.WhiteKernel¶
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class
sklearn.gaussian_process.kernels.
WhiteKernel
(noise_level=1.0, noise_level_bounds=(1e-05, 100000.0))[source]¶ White kernel.
The main use-case of this kernel is as part of a sum-kernel where it explains the noise-component of the signal. Tuning its parameter corresponds to estimating the noise-level.
k(x_1, x_2) = noise_level if x_1 == x_2 else 0
New in version 0.18.
Parameters: - noise_level : float, default: 1.0
Parameter controlling the noise level
- noise_level_bounds : pair of floats >= 0, default: (1e-5, 1e5)
The lower and upper bound on noise_level
Attributes: bounds
Returns the log-transformed bounds on the theta.
- hyperparameter_noise_level
hyperparameters
Returns a list of all hyperparameter specifications.
n_dims
Returns the number of non-fixed hyperparameters of the kernel.
theta
Returns the (flattened, log-transformed) non-fixed hyperparameters.
Methods
__call__
(X[, Y, eval_gradient])Return the kernel k(X, Y) and optionally its gradient. clone_with_theta
(theta)Returns a clone of self with given hyperparameters theta. diag
(X)Returns the diagonal of the kernel k(X, X). get_params
([deep])Get parameters of this kernel. is_stationary
()Returns whether the kernel is stationary. set_params
(**params)Set the parameters of this kernel. -
__init__
(noise_level=1.0, noise_level_bounds=(1e-05, 100000.0))[source]¶ Initialize self. See help(type(self)) for accurate signature.
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__call__
(X, Y=None, eval_gradient=False)[source]¶ Return the kernel k(X, Y) and optionally its gradient.
Parameters: - X : array, shape (n_samples_X, n_features)
Left argument of the returned kernel k(X, Y)
- Y : array, shape (n_samples_Y, n_features), (optional, default=None)
Right argument of the returned kernel k(X, Y). If None, k(X, X) if evaluated instead.
- eval_gradient : bool (optional, default=False)
Determines whether the gradient with respect to the kernel hyperparameter is determined. Only supported when Y is None.
Returns: - K : array, shape (n_samples_X, n_samples_Y)
Kernel k(X, Y)
- K_gradient : array (opt.), shape (n_samples_X, n_samples_X, n_dims)
The gradient of the kernel k(X, X) with respect to the hyperparameter of the kernel. Only returned when eval_gradient is True.
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bounds
¶ Returns the log-transformed bounds on the theta.
Returns: - bounds : array, shape (n_dims, 2)
The log-transformed bounds on the kernel’s hyperparameters theta
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clone_with_theta
(theta)[source]¶ Returns a clone of self with given hyperparameters theta.
Parameters: - theta : array, shape (n_dims,)
The hyperparameters
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diag
(X)[source]¶ Returns the diagonal of the kernel k(X, X).
The result of this method is identical to np.diag(self(X)); however, it can be evaluated more efficiently since only the diagonal is evaluated.
Parameters: - X : array, shape (n_samples_X, n_features)
Left argument of the returned kernel k(X, Y)
Returns: - K_diag : array, shape (n_samples_X,)
Diagonal of kernel k(X, X)
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get_params
(deep=True)[source]¶ Get parameters of this kernel.
Parameters: - deep : boolean, optional
If True, will return the parameters for this estimator and contained subobjects that are estimators.
Returns: - params : mapping of string to any
Parameter names mapped to their values.
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hyperparameters
¶ Returns a list of all hyperparameter specifications.
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n_dims
¶ Returns the number of non-fixed hyperparameters of the kernel.
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set_params
(**params)[source]¶ Set the parameters of this kernel.
The method works on simple kernels as well as on nested kernels. The latter have parameters of the form
<component>__<parameter>
so that it’s possible to update each component of a nested object.Returns: - self
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theta
¶ Returns the (flattened, log-transformed) non-fixed hyperparameters.
Note that theta are typically the log-transformed values of the kernel’s hyperparameters as this representation of the search space is more amenable for hyperparameter search, as hyperparameters like length-scales naturally live on a log-scale.
Returns: - theta : array, shape (n_dims,)
The non-fixed, log-transformed hyperparameters of the kernel