Here's fully working code that will produce plots so you can fully visualize the varying of up to 3 parameters using GridSearchCV. This is what you will see when running the code:

- Parameter1 (x-axis)
- Cross Validaton Mean Score (y-axis)
- Parameter2 (extra line plotted for each different Parameter2 value, with a legend for reference)
- Parameter3 (extra charts will pop up for each different Parameter3 value, allowing you to view differences between these different charts)

For each line plotted, also shown is a standard deviation of what you can expect the Cross Validation Mean Score to do based on the multiple CV's you're running. Enjoy!

```
from sklearn import tree
from sklearn import model_selection
import pandas as pd
import numpy as np
import matplotlib.pyplot as plt
from sklearn.preprocessing import LabelEncoder
from sklearn.model_selection import train_test_split, GridSearchCV
from sklearn.datasets import load_digits
digits = load_digits()
X, y = digits.data, digits.target
Algo = [['DecisionTreeClassifier', tree.DecisionTreeClassifier(), # algorithm
'max_depth', [1, 2, 4, 6, 8, 10, 12, 14, 18, 20, 22, 24, 26, 28, 30], # Parameter1
'max_features', ['sqrt', 'log2', None], # Parameter2
'criterion', ['gini', 'entropy']]] # Parameter3
def plot_grid_search(cv_results, grid_param_1, grid_param_2, name_param_1, name_param_2, title):
# Get Test Scores Mean and std for each grid search
grid_param_1 = list(str(e) for e in grid_param_1)
grid_param_2 = list(str(e) for e in grid_param_2)
scores_mean = cv_results['mean_test_score']
scores_std = cv_results['std_test_score']
params_set = cv_results['params']
scores_organized = {}
std_organized = {}
std_upper = {}
std_lower = {}
for p2 in grid_param_2:
scores_organized[p2] = []
std_organized[p2] = []
std_upper[p2] = []
std_lower[p2] = []
for p1 in grid_param_1:
for i in range(len(params_set)):
if str(params_set[i][name_param_1]) == str(p1) and str(params_set[i][name_param_2]) == str(p2):
mean = scores_mean[i]
std = scores_std[i]
scores_organized[p2].append(mean)
std_organized[p2].append(std)
std_upper[p2].append(mean + std)
std_lower[p2].append(mean - std)
_, ax = plt.subplots(1, 1)
# Param1 is the X-axis, Param 2 is represented as a different curve (color line)
# plot means
for key in scores_organized.keys():
ax.plot(grid_param_1, scores_organized[key], '-o', label= name_param_2 + ': ' + str(key))
ax.fill_between(grid_param_1, std_lower[key], std_upper[key], alpha=0.1)
ax.set_title(title)
ax.set_xlabel(name_param_1)
ax.set_ylabel('CV Average Score')
ax.legend(loc="best")
ax.grid('on')
plt.show()
dataset = 'Titanic'
X_train, X_test, y_train, y_test = train_test_split(X, y, test_size=0.2)
cv_split = model_selection.KFold(n_splits=10, random_state=2)
for i in range(len(Algo)):
name = Algo[0][0]
alg = Algo[0][1]
param_1_name = Algo[0][2]
param_1_range = Algo[0][3]
param_2_name = Algo[0][4]
param_2_range = Algo[0][5]
param_3_name = Algo[0][6]
param_3_range = Algo[0][7]
for p in param_3_range:
# grid search
param = {
param_1_name: param_1_range,
param_2_name: param_2_range,
param_3_name: [p]
}
grid_test = GridSearchCV(alg, param_grid=param, scoring='accuracy', cv=cv_split)
grid_test.fit(X_train, y_train)
plot_grid_search(grid_test.cv_results_, param[param_1_name], param[param_2_name], param_1_name, param_2_name, dataset + ' GridSearch Scores: ' + name + ', ' + param_3_name + '=' + str(p))
param = {
param_1_name: param_1_range,
param_2_name: param_2_range,
param_3_name: param_3_range
}
grid_final = GridSearchCV(alg, param_grid=param, scoring='accuracy', cv=cv_split)
grid_final.fit(X_train, y_train)
best_params = grid_final.best_params_
alg.set_params(**best_params)
```