Implementation in Python
Having become familiar with the models that will allow us to predict time series, you probably have a question, which Python libraries will be used?
Firstly, in order to better understand the mathematical mechanism - you can implement one of the models yourself in Python.
While we will load the rest of the models through libraries such as statsmodels:
import matplotlib.pyplot as plt
import pandas as pd
import seaborn as sns
from statsmodels.tsa.api import acf, graphics, pacf
from statsmodels.tsa.ar_model import AutoReg, ar_select_order
sns.set_style("darkgrid")
pd.plotting.register_matplotlib_converters()
sns.mpl.rc("figure", figsize=(16, 6))
sns.mpl.rc("font", size=14)
data = pd.read_csv("HOUSTNSA.csv")
data = data.set_index("DATE")
housing = data.pct_change().dropna()
housing = 100 * housing.asfreq("MS")
fig, ax = plt.subplots()
ax = housing.plot(ax=ax)
mod = AutoReg(housing, 4, old_names=False)
res = mod.fit()
sel = ar_select_order(housing, 18, old_names=False)
sel.ar_lags
res = sel.model.fit()
fig = res.plot_predict(700, 840)
We have formed a prediction for the next hundred months in the plot above.
The above code uses a model that captures the last "pattern" of seasonality, i.e., the same repeating segment.
Bedankt voor je feedback!
Vraag AI
Vraag AI
Vraag wat u wilt of probeer een van de voorgestelde vragen om onze chat te starten.
Awesome!
Completion rate improved to 3.85Implementation in Python
Veeg om het menu te tonen
Having become familiar with the models that will allow us to predict time series, you probably have a question, which Python libraries will be used?
Firstly, in order to better understand the mathematical mechanism - you can implement one of the models yourself in Python.
While we will load the rest of the models through libraries such as statsmodels:
import matplotlib.pyplot as plt
import pandas as pd
import seaborn as sns
from statsmodels.tsa.api import acf, graphics, pacf
from statsmodels.tsa.ar_model import AutoReg, ar_select_order
sns.set_style("darkgrid")
pd.plotting.register_matplotlib_converters()
sns.mpl.rc("figure", figsize=(16, 6))
sns.mpl.rc("font", size=14)
data = pd.read_csv("HOUSTNSA.csv")
data = data.set_index("DATE")
housing = data.pct_change().dropna()
housing = 100 * housing.asfreq("MS")
fig, ax = plt.subplots()
ax = housing.plot(ax=ax)
mod = AutoReg(housing, 4, old_names=False)
res = mod.fit()
sel = ar_select_order(housing, 18, old_names=False)
sel.ar_lags
res = sel.model.fit()
fig = res.plot_predict(700, 840)
We have formed a prediction for the next hundred months in the plot above.
The above code uses a model that captures the last "pattern" of seasonality, i.e., the same repeating segment.
Bedankt voor je feedback!
