In order to obtain your desired output, I think you need to use a model that can return the standard deviation in the predicted value. Therefore, I adopt Gaussian process regression. From the code you provided in your post, I don't see how this is a time series forecasting task, so in my solution below, I also treat this task as a usual regression task.
First, prepare the data
import pandas
from sklearn.preprocessing import StandardScaler
from sklearn.gaussian_process import GaussianProcessRegressor
url = "https://gist.githubusercontent.com/jerry-shad/36912907ba8660e11cd27be0d3e30639/raw/424f0891dc46d96cd5f867f3d2697777ac984f68/pollution.csv"
df = pd.read_csv(url,parse_dates=['date'])
df.drop(columns=['Unnamed: 0'],axis=1,inplace=True)
# sort the dataframe by date and reset the index
df = df.sort_values(by='date').reset_index(drop=True)
# after sorting the dataframe, split the dataframe
split_date ='2017-12-01'
df_training = df.loc[(df.date <= split_date).values]
df_test = df.loc[(df.date > split_date).values]
# drop the date column
df_training.drop(columns=['date'],axis=1,inplace=True)
df_test.drop(columns=['date'],axis=1,inplace=True)
y_train = df_training['pollution_index']
y_test = df_test['pollution_index']
df_training.drop(['pollution_index'],axis=1)
df_test.drop(['pollution_index'],axis=1)
scaler = StandardScaler()
scaler.fit(df_training)
X_train = scaler.transform(df_training)
X_test = scaler.transform(df_test)
X_train_df = pd.DataFrame(X_train,columns=df_training.columns)
X_test_df = pd.DataFrame(X_test,columns=df_test.columns)
with the dataframes prepared above, you can train a GaussianProcessRegressor
and make predictions by
gpr = GaussianProcessRegressor(normalize_y=True).fit(X_train_df,y_train)
pred,std = gpr.predict(X_test_df,return_std=True)
in which std
is an array of standard deviations in the predicted values. Then, you can plot the data by
import numpy as np
from matplotlib import pyplot as plt
fig,ax = plt.subplots(figsize=(12,8))
plot_start = 225
# plot the training data
ax.plot(y_train.index[plot_start:],y_train.values[plot_start:],'navy',marker='o',label='observed')
# plot the test data
ax.plot(y_test.index,y_test.values,'navy',marker='o')
ax.plot(y_test.index,pred,'darkgreen',marker='o',label='pred')
sigma = np.sqrt(std)
ax.fill(np.concatenate([y_test.index,y_test.index[::-1]]),
np.concatenate([pred-1.960*sigma,(pred+1.9600*sigma)[::-1]]),
alpha=.5,fc='silver',ec='tomato',label='95% confidence interval')
ax.legend(loc='upper left',prop={'size':16})
the output plot looks like
UPDATE
I thought pollution_index
is something that can be predicted by 'dew', 'temp', 'press', 'wnd_spd', 'rain'
. If you want a one-step ahead forecasting, here is what you can do
import numpy as np
import pandas as pd
from statsmodels.tsa.arima_model import ARIMA
from matplotlib import pyplot as plt
import matplotlib.dates as mdates
url = "https://gist.githubusercontent.com/jerry-shad/36912907ba8660e11cd27be0d3e30639/raw/424f0891dc46d96cd5f867f3d2697777ac984f68/pollution.csv"
df = pd.read_csv(url,parse_dates=['date'])
df.drop(columns=['Unnamed: 0'],axis=1,inplace=True)
# sort the dataframe by date and reset the index
df = df.sort_values(by='date').reset_index(drop=True)
# after sorting the dataframe, split the dataframe
split_date ='2017-12-01'
df_training = df.loc[(df.date <= split_date).values]
df_test = df.loc[(df.date > split_date).values]
# extract the relevant info
train_date,train_polltidx = df_training['date'].values,df_training['pollution_index'].values
test_date,test_polltidx = df_test['date'].values,df_test['pollution_index'].values
# train an ARIMA model
model = ARIMA(train_polltidx,order=(1,1,1))
model_fit = model.fit(disp=0)
# you can predict as many as you want, here I only predict len(test_dat.index) days
forecast,stderr,conf = model_fit.forecast(len(test_date))
# plot the result
fig,ax = plt.subplots(figsize=(12,8))
plot_start = 225
# plot the training data
plt.plot(train_date[plot_start:],train_polltidx[plot_start:],'navy',marker='o',label='observed')
# plot the test data
plt.plot(test_date,test_polltidx,'navy',marker='o')
plt.plot(test_date,forecast,'darkgreen',marker='o',label='pred')
# ax.errorbar(np.arange(len(pred)),pred,std,fmt='r')
plt.fill(np.concatenate([test_date,test_date[::-1]]),
np.concatenate((conf[:,0],conf[:,1][::-1])),
alpha=.5,fc='silver',ec='tomato',label='95% confidence interval')
plt.legend(loc='upper left',prop={'size':16})
ax = plt.gca()
ax.set_xlim([df_training['date'].values[plot_start],df_test['date'].values[-1]])
ax.xaxis.set_major_locator(mdates.MonthLocator(interval=6))
ax.xaxis.set_major_formatter(mdates.DateFormatter('%Y-%m-%d'))
plt.gcf().autofmt_xdate()
plt.show()
The output figure is
Clearly, the prediction is very bad, because I haven't done any preprocessing to the training data.
UPDATE 2
Since I'm not familiar with ARIMA
, I implement one-step forecasting using GaussianProcessRegressor
with the help of this wonderful post.
import numpy as np
import pandas as pd
from matplotlib import pyplot as plt
import matplotlib.dates as mdates
from sklearn.gaussian_process import GaussianProcessRegressor
from sklearn.preprocessing import StandardScaler
url = "https://gist.githubusercontent.com/jerry-shad/36912907ba8660e11cd27be0d3e30639/raw/424f0891dc46d96cd5f867f3d2697777ac984f68/pollution.csv"
df = pd.read_csv(url,parse_dates=['date'])
df.drop(columns=['Unnamed: 0'],axis=1,inplace=True)
# sort the dataframe by date and reset the index
df = df.sort_values(by='date').reset_index(drop=True)
# after sorting the dataframe, split the dataframe
split_date ='2017-12-01'
df_training = df.loc[(df.date <= split_date).values]
df_test = df.loc[(df.date > split_date).values]
# extract the relevant info
train_date,train_polltidx = df_training['date'].values,df_training['pollution_index'].values[:,None]
test_date,test_polltidx = df_test['date'].values,df_test['pollution_index'].values[:,None]
# preprocessing
scalar = StandardScaler()
scalar.fit(train_polltidx)
train_polltidx = scalar.transform(train_polltidx)
test_polltidx = scalar.transform(test_polltidx)
def series_to_supervised(data,n_in,n_out):
df = pd.DataFrame(data)
cols = list()
for i in range(n_in,0,-1): cols.append(df.shift(i))
for i in range(0, n_out): cols.append(df.shift(-i))
agg = pd.concat(cols,axis=1)
agg.dropna(inplace=True)
return agg.values
months_look_back = 1
# train
pollt_series = series_to_supervised(train_polltidx,months_look_back,1)
x_train,y_train = pollt_series[:,:months_look_back],pollt_series[:,-1]
# test
pollt_series = series_to_supervised(test_polltidx,months_look_back,1)
x_test,y_test = pollt_series[:,:months_look_back],pollt_series[:,-1]
print("The first %i months in the test set won't be predicted." % months_look_back)
def walk_forward_validation(x_train,y_train,x_test,y_test):
predictions = []
history_x = x_train.tolist()
history_y = y_train.tolist()
for rep,target in zip(x_test,y_test):
# train model
gpr = GaussianProcessRegressor(alpha=1e-4,normalize_y=False).fit(history_x,history_y)
pred,std = gpr.predict([rep],return_std=True)
predictions.append([pred,std])
history_x.append(rep)
history_y.append(target)
return predictions
predictions = walk_forward_validation(x_train,y_train,x_test,y_test)
pred_test,pred_std = zip(*predictions)
# put back
pred_test = scalar.inverse_transform(pred_test)
pred_std = scalar.inverse_transform(pred_std)
train_polltidx = scalar.inverse_transform(train_polltidx)
test_polltidx = scalar.inverse_transform(test_polltidx)
# plot the result
fig,ax = plt.subplots(figsize=(12,8))
plot_start = 100
# plot the training data
plt.plot(train_date[plot_start:],train_polltidx[plot_start:],'navy',marker='o',label='observed')
# plot the test data
plt.plot(test_date[months_look_back:],test_polltidx[months_look_back:],'navy',marker='o')
plt.plot(test_date[months_look_back:],pred_test,'darkgreen',marker='o',label='pred')
sigma = np.sqrt(pred_std)
ax.fill(np.concatenate([test_date[months_look_back:],test_date[months_look_back:][::-1]]),
np.concatenate([pred_test-1.960*sigma,(pred_test+1.9600*sigma)[::-1]]),
alpha=.5,fc='silver',ec='tomato',label='95% confidence interval')
plt.legend(loc='upper left',prop={'size':16})
ax = plt.gca()
ax.set_xlim([df_training['date'].values[plot_start],df_test['date'].values[-1]])
ax.xaxis.set_major_locator(mdates.MonthLocator(interval=6))
ax.xaxis.set_major_formatter(mdates.DateFormatter('%Y-%m-%d'))
plt.gcf().autofmt_xdate()
plt.show()
The idea of this script is to cast the time series forecasting task into a supervised regression task. The plot_start
is a parameter that controls from which year we want to plot, clearly plot_start
cannot be greater than the length of the training data. The output figure of the script is
as you can see, the first month in the test dataset is not predicted, because we need to look back one month to make a prediction.
In order to further make predictions about unseen data, based on this post on CV site, you can train a new model using the predicted value from the last step, therefore, here is how you can do it
unseen_dates = pd.date_range(test_date[-1],periods=180,freq='D').values
all_data = series_to_supervised(df['pollution_index'].values,months_look_back,months_to_predict)
def predict_unseen(unseen_dates,all_data,days_look_back):
predictions = []
history_x = all_data[:,:days_look_back].tolist()
history_y = all_data[:,-1].tolist()
inds = np.arange(unseen_dates.shape[0])
for ind in inds:
# train model
gpr = GaussianProcessRegressor(alpha=1e-2,normalize_y=False).fit(history_x,history_y)
rep = np.array(history_y[-days_look_back:]).reshape(days_look_back,1)
pred,std = gpr.predict(rep,return_std=True)
predictions.append([pred,std])
history_x.append(history_y[-days_look_back:])
history_y.append(pred)
return predictions
predictions = predict_unseen(unseen_dates,all_data,days_look_back=1)
pred_test,pred_std = zip(*predictions)
fig,ax = plt.subplots(figsize=(12,8))
plot_start = 100
# plot the test data
plt.plot(unseen_dates,pred_test,'navy',marker='o')
sigma = np.sqrt(pred_std)
ax.fill(np.concatenate([unseen_dates,unseen_dates[::-1]]),
np.concatenate([pred_test-1.960*sigma,(pred_test+1.9600*sigma)[::-1]]),
alpha=.5,fc='silver',ec='tomato',label='95% confidence interval')
plt.legend(loc='upper left',prop={'size':16})
ax = plt.gca()
ax.xaxis.set_major_locator(mdates.DayLocator(interval=7))
ax.xaxis.set_major_formatter(mdates.DateFormatter('%Y-%m-%d'))
plt.gcf().autofmt_xdate()
plt.show()
One very important thing to note: The timestep of the real data is a month, using such data to make predictions about days may not be correct.