Looking to visualize your forecasting data? The code snippet below illustrates how you can get an informative and aesthetically pleasing visual, like the one above! Note this uses the plot.ly library as well as the Python and R integration.The code requires a SQL ouptut with 2 columns:
- ds_aggregation: the date or datetime. name should be ds_hour, ds_day, ds_week, ds_month, ds_quarter, or ds_year. To make this dynamic with the Aggregation filter, you can name it ds_[aggregation]
- y_value: the value to forecast. name it whatever makes sense, e.g. y_signups, y$_revenue, etc. (Hint: add the dollar sign ($) to format in dollars!)
Code snippet below! Note that we create a dataframe that meets these conditions. However, you can comment this out and use your SQL output so long as it follows the 2 column format described above.
This code is in Python 3.6.
import pandas as pd
from fbprophet import Prophet
import plotly.plotly as py
import plotly.graph_objs as go
import datetime
from scipy.stats import boxcox
from scipy.special import inv_boxcox
from datetime import date
# Dummy Data
import numpy as np
dummy_df = pd.DataFrame()
dummy_df['ds_day'] = pd.date_range(start='1/1/2018', end='1/1/2019')
dummy_df['row_num'] = range(1, dummy_df.shape[0] + 1)
dummy_df['multiplier'] = np.random.randint(10,50, dummy_df.shape[0])
dummy_df['y$_revenue'] = dummy_df['row_num'] * dummy_df['multiplier']
df = dummy_df[['ds_day', 'y$_revenue']]
# Helper function that formats values as $ or %
def format(column):
if column.startswith('y$'):
return '$.3s'
elif column.startswith('y%'):
return '.0%'
else:
return '.3s'
# Helper Function that removes underscores
def column_name(column):
return column.split('_', 1)[1].replace('_',' ').title()
# Helper function that determines the intended aggregation based on column name
def aggregation(ds_col):
return ds_col.split('_', 1)[1].lower()
# Check for in progress data, will exclude later
def in_progress(dt, agg):
now = datetime.datetime.now()
if agg == 'hour':
return (now.year == dt.year and now.month == dt.month and now.day == dt.day and now.hour == dt.hour)
elif agg == 'day':
return (now.year == dt.year and now.month == dt.month and now.day == dt.day)
elif agg == 'week':
return (now.year == dt.year and now.isocalendar()[1] == dt.isocalendar()[1])
elif agg == 'month':
return (now.year == dt.year and now.month == dt.month)
elif agg == 'quarter':
return (now.year == dt.year and int(now.month / 4) == int(dt.month / 4))
elif agg == 'year':
return (now.year == dt.year)
# Lowercase the column names
df.columns = [c.lower() for c in df.columns]
# Determine which is Y axis
y_col = [c for c in df.columns if c.startswith('y')][0]
# Determine which is X axis
ds_col = [c for c in df.columns if c.startswith('ds')][0]
# Determine what the aggregation is
agg = aggregation(ds_col)
# Data cleanup and in-progress analysis
df['y'] = pd.to_numeric(df[y_col])
df['y'], lam = boxcox(df['y'])
df['ds'] = pd.to_datetime(df[ds_col])
df['in_progress'] = df.apply(lambda x: in_progress(x['ds'], agg), axis=1)
# Instantiate Prophet and fit the model
m = Prophet()
m.fit(df.query('in_progress == False')[['ds','y']])
# Create the predictions dataframe that includes future dates
if agg == 'hour':
future = m.make_future_dataframe(periods=72, freq='H')
elif agg == 'day':
future = m.make_future_dataframe(periods=30)
elif agg == 'week':
future = m.make_future_dataframe(periods=183)
future['day_diff'] = future.apply(lambda x: (df['ds'].max() - x['ds']).days, axis=1)
future = future[future['day_diff'] % 7 == 0]
elif agg == 'month':
future = m.make_future_dataframe(periods=365)
future = future[future['ds'].dt.day == 1]
elif agg == 'quarter':
future = m.make_future_dataframe(periods=365)
future = future[(future['ds'].dt.month % 3 == 1) & (future['ds'].dt.day == 1)]
elif agg == 'year':
future = m.make_future_dataframe(periods=731)
future = future[(future['ds'].dt.month == 1) & (future['ds'].dt.day == 1)]
# Predict the future
forecast = m.predict(future)
forecast[['yhat','yhat_upper','yhat_lower']] = forecast[['yhat','yhat_upper','yhat_lower']].apply(lambda x: inv_boxcox(x, lam))
# Create the plotly figure
yhat = go.Scatter(
x = forecast['ds'],
y = forecast['yhat'],
mode = 'lines',
marker = {
'color': '#3bbed7'
},
line = {
'width': 3
},
name = 'Forecast',
)
yhat_lower = go.Scatter(
x = forecast['ds'],
y = forecast['yhat_lower'],
marker = {
'color': 'rgba(0,0,0,0)'
},
showlegend = False,
hoverinfo = 'none',
)
yhat_upper = go.Scatter(
x = forecast['ds'],
y = forecast['yhat_upper'],
fill='tonexty',
fillcolor = 'rgba(231, 234, 241,.75)',
name = 'Confidence',
hoverinfo = 'none',
mode = 'none'
)
actual = go.Scatter(
x = df['ds'],
y = df[y_col],
mode = 'markers',
marker = {
'color': '#fffaef',
'size': 4,
'line': {
'color': '#000000',
'width': .75
}
},
name = 'Actual'
)
layout = go.Layout(
yaxis = {
'title': column_name(y_col),
'tickformat': format(y_col),
'hoverformat': format(y_col)
},
hovermode = 'x',
xaxis = {
'title': agg.title()
},
margin = {
't': 20,
'b': 50,
'l': 60,
'r': 10
},
legend = {
'bgcolor': 'rgba(0,0,0,0)'
}
)
data = [yhat_lower, yhat_upper, yhat, actual]
fig = dict(data = data, layout = layout)
periscope.plotly(fig)