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- import numpy as np
- import time
- import matplotlib.pyplot as plt
- def emwnenmf_break(data, G, F, r, Tmax):
- tol = 1e-5
- delta_measure = 1
- em_iter_max = round(Tmax / delta_measure) + 1 #
- T = np.empty(shape=(em_iter_max + 1))
- T.fill(np.nan)
- RMSE = np.empty(shape=(2, em_iter_max + 1))
- RMSE.fill(np.nan)
- ITER_MAX = 200 # maximum inner iteration number (Default)
- ITER_MIN = 10 # minimum inner iteration number (Default)
- np.put(F, data.idxOF, data.sparsePhi_F)
- np.put(G, data.idxOG, data.sparsePhi_G)
- X = data.X + np.multiply(data.nW, np.dot(G, F))
- FXt = np.dot(F, X.T)
- FFt = np.dot(F, F.T)
- GtX = np.dot(G.T, X)
- GtG = np.dot(G.T, G)
- GradG = np.dot(G, FFt) - FXt.T
- GradF = np.dot(GtG, F) - GtX
- init_delta = stop_rule(np.hstack((G.T, F)), np.hstack((GradG.T, GradF)))
- tolF = tol * init_delta
- tolG = tolF # Stopping tolerance
- # Iterative updating
- G = G.T
- k = 0
- RMSE[:, k] = np.linalg.norm(F[:, 0:-1] - data.F[:, 0:-1], 2, axis=1) / np.sqrt(F.shape[1] - 1)
- T[k] = 0
- t = time.time()
- # Main loop
- while time.time() - t <= Tmax + delta_measure:
- # Estimation step
- X = data.X + np.multiply(data.nW, np.dot(G.T, F))
- # Maximisation step
- # Optimize F with fixed G
- np.put(F, data.idxOF, 0)
- F, iterF, _ = NNLS(F, GtG, GtX - GtG.dot(data.Phi_F), ITER_MIN, ITER_MAX, tolF, data.idxOF, False)
- np.put(F, data.idxOF, data.sparsePhi_F)
- # print(F[:,0:5])
- if iterF <= ITER_MIN:
- tolF = tolF / 10
- # print('Tweaked F tolerance to '+str(tolF))
- FFt = np.dot(F, F.T)
- FXt = np.dot(F, X.T)
- # Optimize G with fixed F
- np.put(G.T, data.idxOG, 0)
- G, iterG, _ = NNLS(G, FFt, FXt - FFt.dot(data.Phi_G.T), ITER_MIN, ITER_MAX, tolG, data.idxOG, True)
- np.put(G.T, data.idxOG, data.sparsePhi_G)
- if iterG <= ITER_MIN:
- tolG = tolG / 10
- # print('Tweaked G tolerance to '+str(tolG))
- GtG = np.dot(G, G.T)
- GtX = np.dot(G, X)
- if time.time() - t - k * delta_measure >= delta_measure:
- k = k + 1
- if k >= em_iter_max + 1:
- break
- RMSE[:, k] = np.linalg.norm(F[:, 0:-1] - data.F[:, 0:-1], 2, axis=1) / np.sqrt(F.shape[1] - 1)
- T[k] = time.time() - t
- # if k%100==0:
- # print(str(k)+' '+str(RMSE[0,k])+' '+str(RMSE[1,k]))
- return {'RMSE': RMSE, 'T': T}
- def stop_rule(X, GradX):
- # Stopping Criterions
- pGrad = GradX[np.any(np.dstack((X > 0, GradX < 0)), 2)]
- return np.linalg.norm(pGrad, 2)
- def NNLS(Z, GtG, GtX, iterMin, iterMax, tol, idxfixed, transposed):
- L = np.linalg.norm(GtG, 2) # Lipschitz constant
- H = Z # Initialization
- Grad = np.dot(GtG, Z) - GtX # Gradient
- alpha1 = np.ones(shape=(2, 1))
- for iter in range(1, iterMax + 1):
- H0 = H
- H = np.maximum(Z - Grad / L, 0) # Calculate squence 'Y'
- grad_scheme = np.greater(Grad.dot(H.T - H0.T), 0)
- if np.any(grad_scheme[:, 0]):
- break
- if np.any(grad_scheme[:, 1]):
- break
- if transposed: # If Z = G.T
- np.put(H.T, idxfixed, 0)
- else: # If Z = F
- np.put(H, idxfixed, 0)
- alpha2 = 0.5 * (1 + np.sqrt(1 + 4 * alpha1 ** 2))
- Z = H + ((alpha1 - 1) / alpha2) * (H - H0)
- alpha1 = alpha2
- Grad = np.dot(GtG, Z) - GtX
- # Stopping criteria
- if iter >= iterMin:
- # Lin's stopping criteria
- pgn = stop_rule(Z, Grad)
- if pgn <= tol:
- break
- return H, iter, Grad
- def nmf_norm_fro(X, G, F, *args):
- W = args
- if len(W) == 0:
- f = np.square(np.linalg.norm(X - np.dot(G, F), 'fro')) / np.square(np.linalg.norm(X, 'fro'))
- else:
- W = W[0]
- f = np.square(np.linalg.norm(X - np.multiply(W, np.dot(G, F)), 'fro')) / np.square(np.linalg.norm(X, 'fro'))
- return f
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