"""
Differentiating Kernel GRLVQ (DKGRLVQ).
Combines per-feature relevance weighting with per-prototype kernel bandwidth:
.. math::
d_\\kappa^2(x, w_k) = 2\\left(1 - \\exp\\left(
-\\frac{\\sum_j \\lambda_j (x_j - w_{kj})^2}{2\\sigma_k^2}
\\right)\\right)
where :math:`\\lambda = \\text{softmax}(\\text{relevances})`.
References
----------
.. [1] Villmann, T., Haase, S., & Kaden, M. (2015). Kernelized vector
quantization in gradient-descent learning. Neurocomputing.
"""
import jax
import jax.numpy as jnp
from jax import jit
import numpy as np
from prosemble.models.prototype_base import SupervisedPrototypeModel
from prosemble.core.competitions import wtac
from prosemble.core.kernel import kernel_distance_squared_relevance
@jit
def _predict_dkgrlvq_jit(X, prototypes, sigmas, relevances, proto_labels,
sigma_min):
"""JIT-compiled DKGRLVQ prediction."""
sigmas = jnp.maximum(sigmas, sigma_min)
lam = jax.nn.softmax(relevances)
distances = kernel_distance_squared_relevance(X, prototypes, sigmas, lam)
return wtac(distances, proto_labels)
[docs]
class DKGRLVQ(SupervisedPrototypeModel):
"""Differentiating Kernel GRLVQ.
Combines GRLVQ per-feature relevance weighting with Gaussian kernel
distance and per-prototype bandwidth adaptation.
.. math::
d_\\kappa^2(x, w_k) = 2\\left(1 - \\exp\\left(
-\\frac{\\sum_j \\lambda_j (x_j - w_{kj})^2}{2\\sigma_k^2}
\\right)\\right)
Parameters
----------
sigma_init : str or float
Initialization strategy for per-prototype bandwidths.
'median' (default): per-class median distance from prototype to class members.
'mean': per-class mean distance.
float: fixed value for all prototypes.
sigma_min : float
Lower bound for sigma to prevent bandwidth collapse. Default: 1e-3.
beta : float
Transfer function steepness parameter.
n_prototypes_per_class : int
Number of prototypes per class.
max_iter : int
Maximum training iterations.
lr : float
Learning rate.
epsilon : float
Convergence threshold on loss change.
random_seed : int
Random seed for reproducibility.
optimizer : str or optax optimizer, optional
Optimizer name ('adam', 'sgd') or optax GradientTransformation.
transfer_fn : callable, optional
Transfer function for loss shaping (default: identity).
margin : float
Margin for loss computation.
callbacks : list, optional
List of Callback objects.
use_scan : bool
If True (default), use jax.lax.scan for training.
batch_size : int, optional
Mini-batch size. If None, use full-batch training.
lr_scheduler : str or optax.Schedule, optional
Learning rate schedule.
lr_scheduler_kwargs : dict, optional
Keyword arguments for the learning rate scheduler.
prototypes_initializer : str or callable, optional
How to initialize prototypes.
patience : int, optional
Epochs with no improvement before stopping.
restore_best : bool
If True, restore best parameters after training.
class_weight : dict or 'balanced', optional
Weights for each class.
gradient_accumulation_steps : int, optional
Accumulate gradients over this many steps.
ema_decay : float, optional
Exponential moving average decay for parameters.
freeze_params : list of str, optional
Parameter group names to freeze.
lookahead : dict, optional
Lookahead optimizer wrapper configuration.
mixed_precision : str or None, optional
Compute dtype for mixed precision training.
References
----------
.. [1] Villmann, T., Haase, S., & Kaden, M. (2015). Kernelized vector
quantization in gradient-descent learning. Neurocomputing.
See Also
--------
SupervisedPrototypeModel : Full list of base parameters.
"""
def __init__(self, sigma_init='median', sigma_min=1e-3, beta=10.0,
n_prototypes_per_class=1, max_iter=100,
lr=0.01, epsilon=1e-6, random_seed=42, distance_fn=None,
optimizer='adam', transfer_fn=None, margin=0.0,
callbacks=None, use_scan=True, batch_size=None,
lr_scheduler=None, lr_scheduler_kwargs=None,
prototypes_initializer=None, patience=None,
restore_best=False, class_weight=None,
gradient_accumulation_steps=None, ema_decay=None,
freeze_params=None, lookahead=None, mixed_precision=None,
**kwargs):
super().__init__(
n_prototypes_per_class=n_prototypes_per_class,
max_iter=max_iter, lr=lr, epsilon=epsilon,
random_seed=random_seed, distance_fn=distance_fn,
optimizer=optimizer, transfer_fn=transfer_fn, margin=margin,
callbacks=callbacks, use_scan=use_scan, batch_size=batch_size,
lr_scheduler=lr_scheduler,
lr_scheduler_kwargs=lr_scheduler_kwargs,
prototypes_initializer=prototypes_initializer,
patience=patience, restore_best=restore_best,
class_weight=class_weight,
gradient_accumulation_steps=gradient_accumulation_steps,
ema_decay=ema_decay, freeze_params=freeze_params,
lookahead=lookahead, mixed_precision=mixed_precision,
**kwargs,
)
self.sigma_init = sigma_init
self.sigma_min = sigma_min
self.beta = beta
self.sigmas_ = None
self.relevances_ = None
def _estimate_sigmas(self, X, y, prototypes, proto_labels):
"""Estimate per-prototype bandwidths from data."""
if isinstance(self.sigma_init, (int, float)):
return jnp.full(prototypes.shape[0], float(self.sigma_init))
sigmas = []
for k in range(prototypes.shape[0]):
label_k = proto_labels[k]
class_mask = (y == label_k)
X_class = X[class_mask]
dists = jnp.sqrt(jnp.sum((X_class - prototypes[k]) ** 2, axis=1))
if self.sigma_init == 'median':
sigma_k = jnp.median(dists)
else: # 'mean'
sigma_k = jnp.mean(dists)
sigmas.append(jnp.maximum(sigma_k, self.sigma_min))
return jnp.array(sigmas)
def _get_resume_params(self, params):
params['sigmas'] = self.sigmas_
params['relevances'] = self.relevances_
return params
def _init_state(self, X, y, key):
n_features = X.shape[1]
key1, key2 = jax.random.split(key)
prototypes, proto_labels = self._init_prototypes(
X, y, self.n_prototypes_per_class, key1
)
sigmas = self._estimate_sigmas(X, y, prototypes, proto_labels)
relevances = jnp.ones(n_features) / n_features
params = {
'prototypes': prototypes,
'relevances': relevances,
'sigmas': sigmas,
}
opt_state = self._optimizer.init(params)
from prosemble.models.prototype_base import SupervisedState
state = SupervisedState(
prototypes=prototypes,
opt_state=opt_state,
loss=jnp.array(float('inf')),
iteration=0,
converged=False,
)
return state, params, proto_labels
def _compute_loss(self, params, X, y, proto_labels):
prototypes = params['prototypes']
relevances = params['relevances']
sigmas = jnp.maximum(params['sigmas'], self.sigma_min)
lam = jax.nn.softmax(relevances)
distances = kernel_distance_squared_relevance(
X, prototypes, sigmas, lam
)
from prosemble.core.losses import glvq_loss_with_transfer
return glvq_loss_with_transfer(
distances, y, proto_labels,
transfer_fn=self.transfer_fn,
margin=self.margin,
beta=self.beta,
)
def _post_update(self, params):
params['sigmas'] = jnp.maximum(params['sigmas'], self.sigma_min)
return params
def _extract_results(self, params, proto_labels, loss_history, n_iter, **kwargs):
super()._extract_results(params, proto_labels, loss_history, n_iter, **kwargs)
self.sigmas_ = params['sigmas']
self.relevances_ = params['relevances']
@property
def relevance_profile(self):
"""Return the learned relevance weights (normalized via softmax)."""
if self.relevances_ is None:
raise ValueError("Model not fitted. Call fit() first.")
return jax.nn.softmax(self.relevances_)
@property
def kernel_bandwidths(self):
"""Return the learned per-prototype bandwidths."""
if self.sigmas_ is None:
raise ValueError("Model not fitted. Call fit() first.")
return self.sigmas_
def _compute_distances_for_rejection(self, X):
"""Relevance kernel distances for reject option."""
sigmas = jnp.maximum(self.sigmas_, self.sigma_min)
lam = jax.nn.softmax(self.relevances_)
return kernel_distance_squared_relevance(X, self.prototypes_, sigmas, lam)
[docs]
def predict(self, X):
"""Predict using learned kernel distance with relevance weighting."""
self._check_fitted()
X = jnp.asarray(X, dtype=jnp.float32)
return _predict_dkgrlvq_jit(
X, self.prototypes_, self.sigmas_, self.relevances_,
self.prototype_labels_, self.sigma_min,
)
def _get_quantizable_attrs(self):
attrs = super()._get_quantizable_attrs()
if self.sigmas_ is not None:
attrs.append('sigmas_')
if self.relevances_ is not None:
attrs.append('relevances_')
return attrs
def _get_fitted_arrays(self):
arrays = super()._get_fitted_arrays()
if self.sigmas_ is not None:
arrays['sigmas_'] = np.asarray(self.sigmas_)
if self.relevances_ is not None:
arrays['relevances_'] = np.asarray(self.relevances_)
return arrays
def _set_fitted_arrays(self, arrays):
super()._set_fitted_arrays(arrays)
if 'sigmas_' in arrays:
self.sigmas_ = jnp.asarray(arrays['sigmas_'])
if 'relevances_' in arrays:
self.relevances_ = jnp.asarray(arrays['relevances_'])
def _get_hyperparams(self):
hp = super()._get_hyperparams()
hp['beta'] = self.beta
hp['sigma_init'] = self.sigma_init
hp['sigma_min'] = self.sigma_min
return hp