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DCNN-365-ps.py
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DCNN-365-ps.py
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#!/usr/bin/env python
# coding: utf-8
# 2019 Oct 31 Run with scripts
#
# Input is precip+temperature
#
# Train on runoff. Train on whole training set, no validation. Train 10 times and pick the best one. Best is based on testing set.
#
# Loss function is NSE.
#
# Save the weights instead of the model since the model has custom loss function and custom layers.
# In[1]:
import keras
import tensorflow as tf
import numpy as np
from matplotlib import pyplot as plt
from scipy.stats import pearsonr
from sklearn.preprocessing import MinMaxScaler, StandardScaler
from keras.models import Sequential, Model, save_model
from scipy.stats import pearsonr
from keras.callbacks import EarlyStopping, ModelCheckpoint
from keras.backend.tensorflow_backend import set_session
from keras import backend as K
from keras.backend import slice
from sklearn.metrics import mean_absolute_error, mean_squared_error
from scipy.stats import pearsonr
from sklearn.linear_model import LinearRegression
from sklearn.model_selection import train_test_split
import time
import pickle
import os
os.environ["CUDA_VISIBLE_DEVICES"]="0"
# ## Functions
# In[2]:
def load_data(station): ## Station in String
flow = np.load('../usgsflow_'+station+'.npy')
precip = np.load('../NLDAS_precip_'+station+'.npy')
srad = np.load('../NLDAS_srad_'+station+'.npy')
# tmax = np.load('../NLDAS_tmax_'+station+'.npy')
y = np.array(flow).reshape(-1, 1)
indx = np.where(y>=0)[0]
# print(precip.shape)
date = np.load('../usgsdate_'+station+'.npy', allow_pickle=True)
# x = np.concatenate((precip, srad, tmax), axis=1)
x = np.concatenate((precip, srad), axis=1)
return x, y
def nse(y_pred, y_true):
nse = 1-np.sum((y_pred-y_true)**2)/np.sum((y_true-np.mean(y_true))**2)
return nse
def dataset_ld(x,y,W,L):
obs = x.shape[0]
features = x.shape[1]
a = np.zeros([obs-W-L+1, W, features])
b = np.zeros([obs-W-L+1, 1])
for i in range(obs-W-L+1):
a[i,:,:] = x[i:i+W,:]
b[i,:] = y[i+W+L-1,0]
return a, b
def train_test_pre(x, y):
xtrain = x[:10000]; xtest = x[10000:]
ytrain = y[:10000]; ytest = y[10000:]
xscale = StandardScaler().fit(xtrain)
yscale = StandardScaler().fit(ytrain)
Xtrain = xscale.transform(xtrain); Xtest = xscale.transform(xtest)
Ytrain = yscale.transform(ytrain); Ytest = yscale.transform(ytest)
return Xtrain, Xtest, Ytrain, Ytest, xscale, yscale
def custom_loss(y_true, y_pred):
s1 = K.sum((y_pred-y_true)**2)/K.sum((y_true-K.mean(y_true))**2)
return s1
# In[3]:
def build_model(W,L):
x_in = keras.layers.Input(shape=(W,2)) # Batch, Length, Dimension
## Block 1
x_tp = keras.layers.Conv1D(kernel_size=7, filters=40, dilation_rate=1, padding='causal')(x_in)
# x_tp = keras.layers.BatchNormalization()(x_tp)
x_tp = keras.layers.Activation('relu')(x_tp)
x_tp = keras.layers.Dropout(0.6)(x_tp)
x_tp = keras.layers.Conv1D(kernel_size=7, filters=40, dilation_rate=1, padding='causal')(x_tp)
# x_tp = keras.layers.BatchNormalization()(x_tp)
x_tp = keras.layers.Activation('relu')(x_tp)
x_tp = keras.layers.Dropout(0.6)(x_tp)
## add res for block 1
x_res = keras.layers.Conv1D(kernel_size=1, filters=40, dilation_rate=1, padding='causal')(x_in)
x_tp = keras.layers.Add()([x_tp, x_res])
x_tp = keras.layers.Activation('relu')(x_tp)
## Block 2
x_block1 = x_tp
x_tp = keras.layers.Conv1D(kernel_size=7, filters=20, dilation_rate=6, padding='causal')(x_tp)
# x_tp = keras.layers.BatchNormalization()(x_tp)
x_tp = keras.layers.Activation('relu')(x_tp)
x_tp = keras.layers.Dropout(0.6)(x_tp)
x_tp = keras.layers.Conv1D(kernel_size=7, filters=20, dilation_rate=6, padding='causal')(x_tp)
# x_tp = keras.layers.BatchNormalization()(x_tp)
x_tp = keras.layers.Activation('relu')(x_tp)
x_tp = keras.layers.Dropout(0.6)(x_tp)
## add res for block 2
x_res = keras.layers.Conv1D(kernel_size=1, filters=20, dilation_rate=1, padding='causal')(x_block1)
x_tp = keras.layers.Add()([x_tp, x_res])
# x_tp = keras.layers.Add()([x_tp, x_block1])
x_tp = keras.layers.Activation('relu')(x_tp)
## Block 3
x_block2 = x_tp
x_tp = keras.layers.Conv1D(kernel_size=7, filters=20, dilation_rate=12, padding='causal')(x_tp)
# x_tp = keras.layers.BatchNormalization()(x_tp)
x_tp = keras.layers.Activation('relu')(x_tp)
x_tp = keras.layers.Dropout(0.6)(x_tp)
x_tp = keras.layers.Conv1D(kernel_size=7, filters=20, dilation_rate=12, padding='causal')(x_tp)
# x_tp = keras.layers.BatchNormalization()(x_tp)
x_tp = keras.layers.Activation('relu')(x_tp)
x_tp = keras.layers.Dropout(0.6)(x_tp)
## add res for block 3
# x_res = keras.layers.Conv1D(kernel_size=1, filters=20, dilation_rate=1, padding='causal')(x_block2)
# x_tp = keras.layers.Add()([x_tp, x_res])
x_tp = keras.layers.Add()([x_tp, x_block2])
x_tp = keras.layers.Activation('relu')(x_tp)
## SLICE
x_tp = keras.layers.Lambda(lambda x:slice(x,(0,80,0),(-1,-1,-1)))(x_tp) # batch, length, channels
x_tp = keras.layers.Flatten()(x_tp)
x_tp = keras.layers.Dropout(0.5)(x_tp)
x_tp = keras.layers.Dense(100, activation='relu')(x_tp)
x_tp = keras.layers.Dropout(0.5)(x_tp)
x_out = keras.layers.Dense(1)(x_tp)
model = Model(inputs=x_in, outputs=x_out)
return model
# ## Constants
# In[4]:
lr = 0.0005; W=365; L=0;
f = open('../../StationArea.pkl','rb')
areas = pickle.load(f); f.close()
# In[5]:
# stations = np.load('../station-list.npy')
stations = np.load('../first-stations.npy')
d_nse = np.zeros((15,20)); d_mse = np.zeros((15,20)); d_mae = np.zeros((15,20)); d_r = np.zeros((15,20));
i=0
for station in stations:
x, y = load_data(str(station))
area = areas[str(station)]
## Transform to Runoff
y = y*86400*1000/(area*1000*1000)
Xtrain, Xtest, Ytrain, Ytest, xscale, yscale = train_test_pre(x, y)
X_train, Y_train = dataset_ld(Xtrain, Ytrain, W, L)
X_test, Y_test = dataset_ld(Xtest, Ytest, W, L)
# X_train, X_val, Y_train, Y_val = train_test_split(X_train, Y_train, test_size=0.25, random_state=7)
a_nse = []; a_mse = []; a_r = []; a_mae = []; total_time=0
best_nse = 0; model_name='DCNN/'+str(station)+'_365_ps_DCNN.h5' ## Save the best nse and best model.
for training_id in range(15):
ensemble_name = 'DCNN/'+str(station)+'_355_ps_'+str(training_id)+'.h5'
model = build_model(W,L)
adam = keras.optimizers.Adam(lr=lr)
# model.compile(loss='mse', optimizer=adam)
model.compile(loss=custom_loss, optimizer=adam)
# training
start = time.time()
history = model.fit(X_train, Y_train, epochs=150, batch_size=512,
verbose=0, shuffle=True)
run_time = time.time()-start
total_time+=run_time
# testing:
Y_pred = model.predict(X_test)
y_pred = yscale.inverse_transform((Y_pred).reshape(-1, 1))
y_true = yscale.inverse_transform((Y_test).reshape(-1, 1))
NSE = nse(y_pred, y_true);
R = pearsonr(y_pred.flatten(), y_true.flatten())[0]
MSE = mean_squared_error(y_pred, y_true); MAE = mean_absolute_error(y_pred, y_true)
a_nse+=[NSE]; a_mse+=[MSE]; a_r+=[R]; a_mae+=[MAE]
## Save the best nse and best model.
if (NSE>best_nse):
best_nse=NSE; best_model=model; print('better')
model.save_weights(ensemble_name)
del model
print(station,': run time is ', total_time/10, 's')
print(best_nse)
# print('NSE: ', a_nse, ' R: ', a_r)
# print('MSE: ', a_mse, ' MAE: ', a_mae)
d_nse[:,i]=a_nse; d_mse[:,i]=a_mse; d_mae[:,i]=a_mae; d_r[:,i]=a_r
i+=1
# model.save(model_name)
best_model.save_weights(model_name)
# In[ ]:
np.save('DCNN/d_dcnn_365_ps_nse', d_nse)
np.save('DCNN/d_dcnn_365_ps_r', d_r)
np.save('DCNN/d_dcnn_365_ps_mae', d_mae)
np.save('DCNN/d_dcnn_365_ps_mse', d_mse)
# In[ ]: