def strategy01(X_train, labels_train, X_test, labels_test):
'''
Estrategia número 1 para el primer clasificador
'''
print('\nEjecutando la estrategia número 1 del primer clasificador...')
# *** DEFINCION DE DATOS PARA EL TRAINING ***
# Paso 1: Cleaning de los datos
# > Training: 5040 x 82
s_clean = clean(X_train)
X_train = X_train[:, s_clean]
# Paso 2: Normalización Mean-Std de los datos
X_train, a, b = normalize(X_train)
# Paso 3: Selección de características
# Acá se utilizó el criterio de fisher
# > Training: 5040 x 50
s_sfs = sfs(X_train, labels_train, n_features=50, method="fisher")
X_train = X_train[:, s_sfs]
# Paso 4: PCA
# > Training: 5040 x 50
X_train, _, A, Xm, _ = pca(X_train, n_components=50)
# *** DEFINCION DE DATOS PARA EL TESTING ***
X_test = X_test[:, s_clean] # Paso 1: Clean
X_test = X_test * a + b # Paso 2: Normalizacion
X_test = X_test[:, s_sfs] # Paso 3: SFS
X_test = np.matmul(X_test - Xm, A) # Paso 4: PCA
return classifier_tests(X_train, labels_train, X_test, labels_test)
def strategy02(X_train, labels_train, X_test, labels_test):
'''
Estrategia número 2 para el primer clasificador
'''
print('\nEjecutando la estrategia número 2 del primer clasificador...')
# *** DEFINCION DE DATOS PARA EL TRAINING ***
# Paso 1: Clean
# > Training: 5040 x 82
s_clean = clean(X_train)
X_train = X_train[:, s_clean]
# Paso 2: PCA de 70 componentes
# > Training: 5040 x 70
X_train, _, A, Xm, _ = pca(X_train, n_components=70)
# Paso 3: Normalizacion
# > Training: 5040 x 70
X_train, a, b = normalize(X_train)
# Paso 4: SFS
# > Training: 5040 x 20
s_sfs = sfs(X_train, labels_train, n_features=20, method="fisher")
X_train = X_train[:, s_sfs]
# *** DEFINCION DE DATOS PARA EL TESTING ***
X_test = X_test[:, s_clean] # Paso 1: Clean
X_test = np.matmul(X_test - Xm, A) # Paso 2: PCA
X_test = X_test * a + b # Paso 3: Normalizacion
X_test = X_test[:, s_sfs] # Paso 4: SFS
return classifier_tests(X_train, labels_train, X_test, labels_test)
def strategy04(X_train, labels_train, X_test, labels_test):
'''
Estrategia número 4 para el primer clasificador
'''
print('\nEjecutando la estrategia número 4 del primer clasificador...')
# *** DEFINCION DE DATOS PARA EL TRAINING ***
# Paso 1: Cleaning de los datos
# > Training: 5040 x 82
s_clean = clean(X_train)
X_train = X_train[:, s_clean]
# Paso 2: Normalización Mean-Std de los datos
X_train, a, b = normalize(X_train)
# Paso 3: Selección de características
# Acá se utilizó el criterio de fisher
# > Training: 5040 x 26
s_sfs = sfs(X_train, labels_train, n_features=26, method="fisher")
X_train = X_train[:, s_sfs]
# *** DEFINCION DE DATOS PARA EL TESTING ***
X_test = X_test[:, s_clean] # Paso 3: clean
X_test = X_test * a + b # Paso 4: normalizacion
X_test = X_test[:, s_sfs] # Paso 5: SFS
return classifier_tests(X_train, labels_train, X_test, labels_test)
def strategy01(X_train, labels_train, X_test, labels_test, groups):
'''
Estrategia número 1 para el segundo clasificador
'''
print('\nEjecutando la estrategia número 1 del segundo clasificador...')
# Paso 3: Cleaning de los datos
# > Training: 8000 x 250
s_clean = clean(X_train)
X_train = X_train[:, s_clean]
# Paso 4: Normalización Mean-Std de los datos
X_train, a, b = normalize(X_train)
# Paso 5: Selección de características
# Acá se utilizó el criterio de fisher
# > Training: 8000 x 50
s_sfs = sfs(X_train, labels_train, n_features=50, method="fisher")
X_train = X_train[:, s_sfs]
# *** DEFINCION DE DATOS PARA EL TESTING ***
X_test = X_test[:, s_clean] # Paso 3: clean
X_test = X_test * a + b # Paso 4: normalizacion
X_test = X_test[:, s_sfs] # Paso 5: SFS
return classifier_tests(X_train, labels_train, X_test, labels_test, groups)
def WinnerStrategy(X_train, labels_train, X_test, labels_test, groups):
'''
Estrategia Número 1 con redes neuronales,
Reescrita para poder obtener estadísticas
'''
# Paso 3: Cleaning de los datos
# > Training: 8000 x 250
s_clean = clean(X_train)
X_train = X_train[:, s_clean]
# Paso 4: Normalización Mean-Std de los datos
X_train, a, b = normalize(X_train)
# Paso 5: Selección de características
# Acá se utilizó el criterio de fisher
# > Training: 8000 x 50
s_sfs = sfs(X_train, labels_train, n_features=50, method="fisher")
X_train = X_train[:, s_sfs]
# *** DEFINCION DE DATOS PARA EL TESTING ***
X_test = X_test[:, s_clean] # Paso 3: clean
X_test = X_test * a + b # Paso 4: normalizacion
X_test = X_test[:, s_sfs] # Paso 5: SFS
classifier = MLPClassifier(alpha=1, max_iter=1000, random_state=2)
results = {}
Y_pred = np.array([])
labels_test = np.array([])
# Probamos con los valores de testing
classifier.fit(X_train, labels_train)
for sample in groups['test']:
patch_data = np.array([])
for patch in groups['test'][sample]:
features = X_test[groups['test'][sample][patch], :].reshape(1, -1)
patch_data = np.append(patch_data, classifier.predict(features)[0])
# Clase clasificada
Y_pred = np.append(Y_pred, stats.mode(patch_data)[0][0])
labels_test = np.append(labels_test, get_class_by_name(sample))
results['Accuracy'] = performance(Y_pred, labels_test) * 100
results['Y_pred'] = Y_pred
results['labels_test'] = labels_test
return results
def strategy05(X_train, labels_train, X_test, labels_test, groups):
'''
Estrategia número 5 para el segundo clasificador
'''
print('\nEjecutando la estrategia número 5 del segundo clasificador...')
# *** DEFINCION DE DATOS PARA EL TRAINING ***
# Paso 1: Clean
# > Training: 5040 x 82
s_clean = clean(X_train)
X_train = X_train[:, s_clean]
# Paso 2: PCA
# > Training: 5040 x 82
X_train, _, A1, Xm1, _ = pca(X_train, n_components=X_train.shape[1])
# Paso 3: Normalizacion
# > Training: 5040 x 82
X_train, a, b = normalize(X_train)
# Paso 4: SFS
# > Training: 5040 x 80
s_sfs = sfs(X_train, labels_train, n_features=80, method="fisher")
X_train = X_train[:, s_sfs]
X_train_sfs80 = X_train.copy()
# Paso 5: PCA
# > Training: 5040 x 10
X_train, _, A2, Xm2, _ = pca(X_train, n_components=10)
#Paso 6: SFS
# > Trainning: 5040 x 20
X_train = np.concatenate((X_train, X_train_sfs80), axis=1)
s_sfs2 = sfs(X_train, labels_train, n_features=20, method="fisher")
X_train = X_train[:, s_sfs2]
# *** DEFINCION DE DATOS PARA EL TESTING ***
X_test = X_test[:, s_clean] # Paso 1: clean
X_test = np.matmul(X_test - Xm1, A1) # Paso 2: PCA
X_test = X_test * a + b # Paso 3: normalizacion
X_test = X_test[:, s_sfs] # Paso 4: SFS
X_test_sfs80 = X_test.copy()
X_test = np.matmul(X_test - Xm2, A2) # Paso 5: PCA
X_test = np.concatenate((X_test, X_test_sfs80), axis=1)
X_test = X_test[:, s_sfs2] # Paso 6: SFS
# *** ENTRENAMIENTO CON DATOS DE TRAINING Y PRUEBA CON DATOS DE TESTING ***
return classifier_tests(X_train, labels_train, X_test, labels_test, groups)
def WinnerStrategy(X_train, labels_train, X_test, labels_test):
'''
Estrategia Número 1 con redes neuronales,
Reescrita para poder obtener estadísticas
'''
# *** DEFINCION DE DATOS PARA EL TRAINING ***
# Paso 1: Cleaning de los datos
# > Training: 5040 x 82
s_clean = clean(X_train)
X_train = X_train[:, s_clean]
# Paso 2: Normalización Mean-Std de los datos
X_train, a, b = normalize(X_train)
# Paso 3: Selección de características
# Acá se utilizó el criterio de fisher
# > Training: 5040 x 50
s_sfs = sfs(X_train, labels_train, n_features=50, method="fisher")
X_train = X_train[:, s_sfs]
# Paso 4: PCA
# > Training: 5040 x 50
X_train, _, A, Xm, _ = pca(X_train, n_components=50)
# *** DEFINCION DE DATOS PARA EL TESTING ***
X_test = X_test[:, s_clean] # Paso 1: Clean
X_test = X_test * a + b # Paso 2: Normalizacion
X_test = X_test[:, s_sfs] # Paso 3: SFS
X_test = np.matmul(X_test - Xm, A) # Paso 4: PCA
classifier = MLPClassifier(alpha=1, max_iter=1000, random_state=2)
results = {}
# Clasificamos las muestras de Testing
classifier.fit(X_train, labels_train)
Y_pred = classifier.predict(X_test)
accuracy = performance(Y_pred, labels_test)
results['Accuracy'] = accuracy * 100
results['Y_pred'] = Y_pred
results['labels_test'] = labels_test
return results
def strategy03(X_train, labels_train, X_test, labels_test, groups):
'''
Estrategia número 3 para el segundo clasificador
'''
print('\nEjecutando la estrategia número 3 del segundo clasificador...')
# *** DEFINCION DE DATOS PARA EL TRAINING ***
# Paso 1: Clean
# > Training: 5040 x 82
s_clean = clean(X_train)
X_train = X_train[:, s_clean]
# Paso 2: Normalizacion
# > Training: 5040 x 82
X_train, a, b = normalize(X_train)
# Paso 3: SFS
# > Training: 5040 x 80
s_sfs = sfs(X_train, labels_train, n_features=80, method="fisher")
X_train = X_train[:, s_sfs]
# Paso 4: PCA
# > Training: 5040 x 20
X_train, _, A, Xm, _ = pca(X_train, n_components=20)
# Paso 5: SFS
# > Training: 5040 x 15
s_sfs2 = sfs(X_train, labels_train, n_features=15, method="fisher")
X_train = X_train[:, s_sfs2]
# *** DEFINCION DE DATOS PARA EL TESTING ***
X_test = X_test[:, s_clean] # Paso 1: Clean
X_test = X_test * a + b # Paso 2: Normalizacion
X_test = X_test[:, s_sfs] # Paso 3: SFS
X_test = np.matmul(X_test - Xm, A) # Paso 4: PCA
X_test = X_test[:, s_sfs2] # Paso 5: SFS
# *** ENTRENAMIENTO CON DATOS DE TRAINING Y PRUEBA CON DATOS DE TESTING ***
return classifier_tests(X_train, labels_train, X_test, labels_test, groups)
# > Testing : 53 x 1589
X_train, X_test, d_train, d_test = train_test_split(X,
d,
test_size=0.2,
shuffle=False)
# *** DEFINCION DE DATOS PARA EL TRAINING ***
# Paso 2-Training: Clean
# > Training: 211 x 387
s_clean = clean(X_train)
X_train = X_train[:, s_clean]
# Paso 3-Training: Normalizacion
# > Training: 211 x 387
X_train, a, b = normalize(X_train)
# Paso 4-Training: SFS
# > Training: 211 x 40
s_sfs = sfs(X_train, d_train, n_features=40, method="fisher", show=True)
X_train = X_train[:, s_sfs]
# Paso 5-Training: PCA
# > Training: 211 x 10
X_train, _, A, Xm, _ = pca(X_train, n_components=10)
# *** DEFINCION DE DATOS PARA EL TESTING ***
X_test = X_test[:, s_clean] # Paso 2: clean
X_test = X_test * a + b # Paso 3: normalizacion
X_test = X_test[:, s_sfs] # Paso 4: SFS
data = loadmat("realdata")
features = data["features"]
classes = data["classes"].squeeze()
# %%
from pybalu.data_selection import stratify
from pybalu.feature_transformation import normalize
# Training and Testing data (90% training, 10% testing)
idx_train, idx_test = stratify(classes, .90)
f_train = features[idx_train]
c_train = classes[idx_train]
f_test = features[idx_test]
c_test = classes[idx_test]
f_train_norm, a, b = normalize(f_train)
f_test_norm = f_test * a + b
# %%
from pybalu.feature_selection import sfs
N_FEATURES = 15
selected_feats = sfs(f_train_norm, c_train, n_features=N_FEATURES,
method="fisher", show=True)
# %%
from pybalu.classification import structure
from pybalu.performance_eval import performance
from sklearn.neighbors import KNeighborsClassifier
def main():
'''
Desarrollo de el flujo del programa de reconocimiento de paredes rayadas
La metodología utilizada es la que se describe en:
https://github.com/domingomery/patrones/blob/master/clases/Cap03_Seleccion_de_Caracteristicas/presentations/PAT03_GeneralSchema.pdf
La estructura del código se basó en el código de ejemplo de la actividad en clases:
https://github.com/domingomery/patrones/tree/master/clases/Cap03_Seleccion_de_Caracteristicas/ejercicios/PCA_SFS
'''
# Paso 1: Extracción de características
# > 4000 imágenes de training rayadas
# > 4000 imágenes de training no rayadas
# > 1000 imágenes de testing rayadas
# > 1000 imágenes de testing no rayadas
# > 357 características por imagen
features = FeatureExtractor(classes=CLASSES)
# Paso 2: Definición de datos training - testing
# > Training: 8000 x 357
# > Testing: 2000 x 357
X_train, labels_train = features['feature_values_train'], features[
'labels_train']
X_test, labels_test = features['feature_values_test'], features[
'labels_test']
X_train, labels_train = np.array(X_train), np.array(labels_train)
X_test, labels_test = np.array(X_test), np.array(labels_test)
# *** DEFINCION DE DATOS PARA EL TRAINING ***
# Paso 3: Cleaning de los datos
# > Training: 8000 x 250
s_clean = clean(X_train)
X_train = X_train[:, s_clean]
# Paso 4: Normalización Mean-Std de los datos
X_train, a, b = normalize(X_train)
# Paso 5: Selección de características
# Acá se utilizó el criterio de fisher
# > Training: 8000 x 50
s_sfs = sfs(X_train, labels_train, n_features=50)
X_train = X_train[:, s_sfs]
# *** DEFINCION DE DATOS PARA EL TESTING ***
X_test = X_test[:, s_clean] # Paso 3: clean
X_test = X_test * a + b # Paso 4: normalizacion
X_test = X_test[:, s_sfs] # Paso 5: SFS
# *** ENTRENAMIENTO CON DATOS DE TRAINING Y PRUEBA CON DATOS DE TESTING ***
knn = KNN(n_neighbors=3)
knn.fit(X_train, labels_train)
Y_pred = knn.predict(X_test)
# *** Estadísticas y desempeño del clasificador ***
accuracy = performance(Y_pred, labels_test)
print("Accuracy = " + str(accuracy))
confusionMatrix(Y_pred, labels_test)
printChoosenFeatures = True
if printChoosenFeatures:
feature_names = np.array(features['feature_names'])
feature_names = feature_names[s_sfs]
print('Las features seleccionadas por el sistema son:')
for name in feature_names:
print(name, end=' -- ')
# *** Guardado de las variables para el reconocedor externo ***
with open('data/reconocedor.json', 'w') as file:
file.write(
json.dumps({
's_clean': s_clean.tolist(),
'a': a.tolist(),
'b': b.tolist(),
's_sfs': s_sfs.tolist()
}))
print('Training Subset:')
X_train = np.concatenate((X0_train, X1_train), axis=0)
d0_train = np.zeros([X0_train.shape[0], 1], dtype=int)
d1_train = np.ones([X1_train.shape[0], 1], dtype=int)
d_train = np.concatenate((d0_train, d1_train), axis=0)
print('Original extracted features: ' + str(X_train.shape[1]) + '(' +
str(X_train.shape[0]) + ' samples)')
# Training: Cleaning
sclean = clean(X_train, show=True)
X_train_clean = X_train[:, sclean]
print(' cleaned features: ' + str(X_train_clean.shape[1]) + '(' +
str(X_train_clean.shape[0]) + ' samples)')
# Training: Normalization
X_train_norm, a, b = normalize(X_train_clean)
print(' normalized features: ' + str(X_train_norm.shape[1]) + '(' +
str(X_train_norm.shape[0]) + ' samples)')
# Training: Feature selection
ssfs = sfs(X_train_norm, d_train, n_features=20, method="fisher", show=True)
X_train_sfs = X_train_norm[:, ssfs]
print(' selected features: ' + str(X_train_sfs.shape[1]) + '(' +
str(X_train_sfs.shape[0]) + ' samples)')
# Testing dataset
print('Testing Subset:')
X_test = np.concatenate((X0_test, X1_test), axis=0)
d0_test = np.zeros([X0_test.shape[0], 1], dtype=int)
d1_test = np.ones([X1_test.shape[0], 1], dtype=int)
d_test = np.concatenate((d0_test, d1_test), axis=0)
def clean_norm(X):
sclean = clean(X, show=True)
X = X[:, sclean]
X, a, b = normalize(X)
return X, sclean, a, b
