def __init__(self, **kwargs): self.conf = kwargs self.REncoder = None self.bias = True self.W_i = None self.N_i = None self.N_o = None self.N_f = 0 self.beta = 1e-6 self.method = 'ridge' self.skip_con = kwargs.get('skip_con', 0) self.N_h = 0 self.reservoirConf = kwargs.get('reservoirConf') self.REncoder = ReservoirEncoder(self.reservoirConf) self.encoder_func = self.REncoder.echostate \ if kwargs.get('encoder', 'echostate') == 'echostate' \ else self.REncoder.transform
def __init__(self, **kwargs): self.conf = kwargs self.sigmas = None self.bias = True self.W_i = None self.N_i = None self.N_o = None self.N_f = 0 self.beta = 1e-6 self.method = 'ridge' self.skip_con = kwargs.get('skip_con', 0) self.activation = kwargs.get('activation', 'rbf') self.N_h = kwargs.get('N_h') self.sigma = kwargs.get('sigma', 1) self.reservoirConf = kwargs.get('reservoirConf') self.REncoder = ReservoirEncoder(self.reservoirConf) self.encoder_func = self.REncoder.transform \ if kwargs.get('encoder', 'transform') == 'transform' \ else self.REncoder.echostate
class ESN_ATTN_simple: def __init__(self, **kwargs): self.conf = kwargs self.sigmas = None self.bias = True self.W_i = None self.N_i = None self.N_o = None self.N_f = 0 self.beta = 1e-6 self.method = 'ridge' self.skip_con = kwargs.get('skip_con', 0) self.activation = kwargs.get('activation', 'rbf') self.N_h = kwargs.get('N_h') self.sigma = kwargs.get('sigma', 1) self.reservoirConf = kwargs.get('reservoirConf') self.REncoder = ReservoirEncoder(self.reservoirConf) self.encoder_func = self.REncoder.transform \ if kwargs.get('encoder', 'transform') == 'transform' \ else self.REncoder.echostate @staticmethod def pairwise_distances(X, Y): D = -2 * X @ Y.T + np.sum(Y ** 2, axis=1) + np.sum(X ** 2, axis=1)[:, np.newaxis] D[D < 0] = 0 return D @staticmethod def col_normalize(x, f=None): if x.shape[0] == 0: return x fx = f(x) if f else x fx_sum = fx.sum(axis=0).reshape([1, fx.shape[1]]) return fx / fx_sum def _pre_output(self, X, Z=None): """ :param X: (N_i, N_samples) :param Z: (nz, N_samples) :param W_i: ((N_h, nz) :return: H: (..., N_samples) """ assert(self.N_h > 0) H = np.exp( -self.pairwise_distances(self.W_i, Z.T) / (2 * self.sigma ** 2 * self.sigmas.reshape((-1, 1))) ) # (N_h, N_samples) H = np.vstack([H, Z]) self.N_f = self.N_h + Z.shape[0] if self.skip_con: H = np.vstack([H, X[-self.skip_con:]]) self.N_f += len(X[-self.skip_con:]) if self.bias: ones = np.ones((1, H.shape[1])) H = np.vstack([H, ones]) self.N_f += 1 return H def train(self, X, Y, **kwargs): num_prepare = kwargs.get('num_prepare', 0) self.N_i = X.shape[0] self.N_o = Y.shape[0] Z = self.encoder_func(X) if self.REncoder else X X, Z = X[:, num_prepare:], Z[:, num_prepare:] if self.N_h <= 0: self.W_i = np.empty((0, self.N_i)) else: # self.W_i, _ = kmeans2(X.T, self.N_h, minit='points') if self.activation == 'rbf': if self.W_i is None: self.W_i, self.sigmas = fcm(Z.T, self.N_h) elif self.activation == 'rbf-random': self.W_i = np.random.uniform(-1, 1, (self.N_h, self.N_i)) # self.W_i = X.T[np.random.choice(X.shape[1],self.N_h,replace=False)] H = self._pre_output(X, Z) self.W_o = ridge_regressor(H, Y, self.beta) def predict(self, X, **kwargs): num_prepare = kwargs.get('num_prepare', 0) Z = self.encoder_func(X) if self.REncoder else X X, Z = X[:, num_prepare:], Z[:, num_prepare:] H = self._pre_output(X, Z) return self.W_o.dot(H) def predict_multistep(self, X, horizon): Y = np.empty((self.N_o * horizon, X.shape[1])) Z = np.vstack([X, Y]) start = X.shape[0] Z[start:start + self.N_o, :] = self.predict(X) for i in range(1, horizon): Z[start + i * self.N_o: start + (i + 1) * self.N_o, :] = self.predict(Z[i * self.N_o: start + i * self.N_o, :]) return Z[start:, :] def predict_multistep_esn(self, X, horizon): Y = np.empty((self.N_o * horizon, 1)) Z = self.encoder_func(X) z = Z[:, -1:] x = X[:, -1:] for i in range(horizon): H = self._pre_output(x, z) y = self.W_o.dot(H) Y[i * self.N_o: (i + 1) * self.N_o] = y x = np.vstack([x, y])[-self.N_i:] z = self.REncoder.state_transition(z, y) return Y
class ESN: def __init__(self, **kwargs): self.conf = kwargs self.REncoder = None self.bias = True self.W_i = None self.N_i = None self.N_o = None self.N_f = 0 self.beta = 1e-6 self.method = 'ridge' self.skip_con = kwargs.get('skip_con', 0) self.N_h = 0 self.reservoirConf = kwargs.get('reservoirConf') self.REncoder = ReservoirEncoder(self.reservoirConf) self.encoder_func = self.REncoder.echostate \ if kwargs.get('encoder', 'echostate') == 'echostate' \ else self.REncoder.transform def _pre_output(self, X, Z=None): """ :param X: (N_i, N_samples) :param Z: (nz, N_samples) :param W_i: ((N_h, nz) :return: H: (..., N_samples) """ H = Z self.N_f = Z.shape[0] if self.skip_con: H = np.vstack([H, X[-self.skip_con:]]) self.N_f += len(X[-self.skip_con:]) if self.bias: ones = np.ones((1, H.shape[1])) H = np.vstack([H, ones]) self.N_f += 1 return H def train(self, X, Y, **kwargs): num_prepare = kwargs.get('num_prepare', 0) self.N_i = X.shape[0] self.N_o = Y.shape[0] Z = self.encoder_func(X) if self.REncoder else X X, Z = X[:, num_prepare:], Z[:, num_prepare:] H = self._pre_output(X, Z) self.W_o = ridge_regressor(H, Y, self.beta) def predict(self, X, **kwargs): num_prepare = kwargs.get('num_prepare', 0) Z = self.encoder_func(X) if self.REncoder else X X, Z = X[:, num_prepare:], Z[:, num_prepare:] H = self._pre_output(X, Z) return self.W_o.dot(H) def predict_multistep(self, X, horizon): Y = np.empty((self.N_o * horizon, X.shape[1])) Z = np.vstack([X, Y]) start = X.shape[0] Z[start:start + self.N_o, :] = self.predict(X) for i in range(1, horizon): # print(Z[i * self.N_o: start + i * self.N_o, :]) Z[start + i * self.N_o:start + (i + 1) * self.N_o, :] = self.predict(Z[i * self.N_o:start + i * self.N_o, :]) return Z[start:, :] def predict_multistep_esn(self, X, horizon): Y = np.empty((self.N_o * horizon, 1)) Z = self.encoder_func(X) z = Z[:, -1:] x = X[:, -1:] for i in range(horizon): H = self._pre_output(x, z) y = self.W_o.dot(H) Y[i * self.N_o:(i + 1) * self.N_o] = y x = np.vstack([x, y])[-self.N_i:] z = self.REncoder.state_transition(z, y) # print(np.min(z), np.max(z)) return Y