data_frame = principalDf.copy()
for name, model in models:
principalDf= data_frame.copy()
model.fit(principalDf)
labels = model.labels_
n_clusters_ = len(set(labels)) - (1 if -1 in labels else 0)
n_noise_ = list(labels).count(-1)
print("CLUSTERS:", n_clusters_)
principalDf["Clusters"] = labels
principalDf["Koppen_labels"]= koppen_labels
principalDf = principalDf[principalDf['Clusters'] != -1]
k = max(unique(principalDf["Clusters"]))
df = principalDf.copy()
plot_map('OPTICS',k,df,lonSeries,latSeries)
principalDf['veg_type'] = mapped_dataset['veg_type']
principalDf = principalDf.loc[~(principalDf.veg_type == '0')]
sil_df = principalDf.drop(['Clusters', 'veg_type','Koppen_labels'], axis=1)
sil_pred = principalDf['Clusters']
label_encoder = LabelEncoder()
y = label_encoder.fit_transform(principalDf['veg_type'])
principalDf['veg_encoded'] = y
principalDf = principalDf[principalDf['Clusters'] != -1]
k1 = max(principalDf['veg_encoded']) + 1
I1 = principalDf['veg_encoded'].replace({0: k1})
k2 = max(principalDf['Koppen_labels']) + 1
I2 = principalDf["Clusters"]
data_frame = principalDf.copy()
for name, model in models:
principalDf= data_frame.copy()
model.fit(principalDf)
labels = model.labels_
n_clusters_ = len(set(labels)) - (1 if -1 in labels else 0)
n_noise_ = list(labels).count(-1)
print("CLUSTERS:", n_clusters_)
principalDf["Clusters"] = labels
principalDf["Koppen_labels"]= koppen_labels
principalDf = principalDf[principalDf['Clusters'] != -1]
k = max(unique(principalDf["Clusters"]))
df = principalDf.copy()
plot_map('AffinityPropagation',k,df,lonSeries,latSeries)
principalDf['veg_type'] = mapped_dataset['veg_type']
principalDf = principalDf.loc[~(principalDf.veg_type == '0')]
sil_df = principalDf.drop(['Clusters', 'veg_type','Koppen_labels'], axis=1)
sil_pred = principalDf['Clusters']
label_encoder = LabelEncoder()
y = label_encoder.fit_transform(principalDf['veg_type'])
principalDf['veg_encoded'] = y
principalDf = principalDf[principalDf['Clusters'] != -1]
k1 = max(principalDf['veg_encoded']) + 1
I1 = principalDf['veg_encoded'].replace({0: k1})
k2 = max(principalDf['Koppen_labels']) + 1
I2 = principalDf["Clusters"]
('Agglomerative Clustering29', AgglomerativeClustering(n_clusters=29), 29))
models.append(
('Agglomerative Clustering30', AgglomerativeClustering(n_clusters=30), 30))
data_frame = principalDf.copy()
for name, model, k in models:
principalDf = data_frame.copy()
model.fit(principalDf)
labels = model.labels_
principalDf["Clusters"] = labels
principalDf["Koppen_labels"] = koppen_labels
df = principalDf.copy()
plot_map('Agglomerative', k, df, lonSeries, latSeries)
if k == 29:
plot_maps('Agglomerative', k, df, lonSeries, latSeries)
principalDf['veg_type'] = mapped_dataset['veg_type']
principalDf = principalDf.loc[~(principalDf.veg_type == '0')]
sil_df = principalDf.drop(['Clusters', 'veg_type', 'Koppen_labels'],
axis=1)
sil_pred = principalDf['Clusters']
label_encoder = LabelEncoder()
y = label_encoder.fit_transform(principalDf['veg_type'])
principalDf['veg_encoded'] = y
I1 = principalDf['veg_encoded']
models.append(('BIRCH26', Birch(n_clusters=26), 26))
models.append(('BIRCH29', Birch(n_clusters=29), 29))
models.append(('BIRCH30', Birch(n_clusters=30), 30))
data_frame = principalDf.copy()
for name, model, k in models:
principalDf = data_frame.copy()
model.fit(principalDf)
labels = model.predict(principalDf)
principalDf["Clusters"] = labels
principalDf["Koppen_labels"] = koppen_labels
df = principalDf.copy()
plot_map('BIRCH', k, df, lonSeries, latSeries)
if k == 29:
plot_maps('BIRCH', k, df, lonSeries, latSeries)
principalDf['veg_type'] = mapped_dataset['veg_type']
principalDf = principalDf.loc[~(principalDf.veg_type == '0')]
sil_df = principalDf.drop(['Clusters', 'veg_type', 'Koppen_labels'],
axis=1)
sil_pred = principalDf['Clusters']
label_encoder = LabelEncoder()
y = label_encoder.fit_transform(principalDf['veg_type'])
principalDf['veg_encoded'] = y
k1 = max(principalDf['veg_encoded']) + 1
models.append(
('Gaussian Mixture30', GaussianMixture(n_components=30,
random_state=1), 30))
data_frame = principalDf.copy()
for name, model, k in models:
principalDf = data_frame.copy()
model.fit(principalDf)
labels = model.predict(principalDf)
principalDf["Clusters"] = labels
principalDf["Koppen_labels"] = koppen_labels
df = principalDf.copy()
plot_map('Gaussian Mixture', k, df, lonSeries, latSeries)
if k == 29:
plot_maps('Gaussian Mixture', k, df, lonSeries, latSeries)
principalDf['veg_type'] = mapped_dataset['veg_type']
principalDf = principalDf.loc[~(principalDf.veg_type == '0')]
sil_df = principalDf.drop(['Clusters', 'veg_type', 'Koppen_labels'],
axis=1)
sil_pred = principalDf['Clusters']
label_encoder = LabelEncoder()
y = label_encoder.fit_transform(principalDf['veg_type'])
principalDf['veg_encoded'] = y
k1 = max(principalDf['veg_encoded']) + 1
models.append(('Kmeans30', KMeans(n_clusters=30, random_state=1), 30))
data_frame = principalDf.copy()
for name, model, k in models:
principalDf = data_frame.copy()
model.fit(principalDf)
labels = model.labels_
principalDf["Clusters"] = labels
principalDf.to_csv('/Users/bilalhussain/Downloads/Plotly CSV/kmeans.csv',
index=False)
principalDf["Koppen_labels"] = koppen_labels
df = principalDf.copy()
plot_map('KMeans', k, df, lonSeries, latSeries)
if k == 29:
plot_maps('KMeans', k, df, lonSeries, latSeries)
principalDf['veg_type'] = mapped_dataset['veg_type']
principalDf = principalDf.loc[~(principalDf.veg_type == '0')]
sil_df = principalDf.drop(['Clusters', 'veg_type', 'Koppen_labels'],
axis=1)
sil_pred = principalDf['Clusters']
label_encoder = LabelEncoder()
y = label_encoder.fit_transform(principalDf['veg_type'])
principalDf['veg_encoded'] = y
I1 = principalDf['veg_encoded']
models.append(('MiniBatchKMeans26', MiniBatchKMeans(n_clusters=26), 26))
models.append(('MiniBatchKMeans29', MiniBatchKMeans(n_clusters=29), 29))
models.append(('MiniBatchKMeans30', MiniBatchKMeans(n_clusters=30), 30))
data_frame = principalDf.copy()
for name, model, k in models:
principalDf = data_frame.copy()
model.fit(principalDf)
labels = model.predict(principalDf)
principalDf["Clusters"] = labels
principalDf["Koppen_labels"] = koppen_labels
df = principalDf.copy()
plot_map('MinBKmeans', k, df, lonSeries, latSeries)
if k == 29:
plot_maps('MinBKmeans', k, df, lonSeries, latSeries)
principalDf['veg_type'] = mapped_dataset['veg_type']
principalDf = principalDf.loc[~(principalDf.veg_type == '0')]
sil_df = principalDf.drop(['Clusters', 'veg_type', 'Koppen_labels'],
axis=1)
sil_pred = principalDf['Clusters']
label_encoder = LabelEncoder()
y = label_encoder.fit_transform(principalDf['veg_type'])
principalDf['veg_encoded'] = y
k1 = max(principalDf['veg_encoded']) + 1
