Start

In this guide, we’ll show how you can use EvalML to automatically find the best pipeline for predicting whether a patient has breast cancer. Along the way, we’ll highlight EvalML’s built-in tools and features for understanding and interacting with the search process.

[1]:
import evalml
from evalml import AutoMLSearch
from evalml.utils import infer_feature_types

First, we load in the features and outcomes we want to use to train our model.

[2]:
X, y = evalml.demos.load_fraud(n_rows=1000, return_pandas=True)
             Number of Features
Boolean                       1
Categorical                   6
Numeric                       5

Number of training examples: 1000
Targets
False    85.90%
True     14.10%
Name: fraud, dtype: object

First, we will clean the data. Since EvalML accepts a pandas input, it can run type inference on this data directly. Since we’d like to change the types inferred by EvalML, we can use the infer_feature_types utility method. Here’s what we’re going to do with the following dataset:

  • Reformat the expiration_date column so it reflects a more familiar date format.

  • Cast the lat and lng columns from float to str.

  • Use infer_feature_types to specify what types certain columns should be. For example, to avoid having the provider column be inferred as natural language text, we have specified it as a categorical column instead.

The infer_feature_types utility method takes a pandas or numpy input and converts it to a Woodwork data structure, providing us with flexibility to cast the data as necessary.

[3]:
X['expiration_date'] = X['expiration_date'].apply(lambda x: '20{}-01-{}'.format(x.split("/")[1], x.split("/")[0]))
X[['lat', 'lng']] = X[['lat', 'lng']].astype('str')
X = infer_feature_types(X, feature_types= {'store_id': 'categorical',
                                           'expiration_date': 'datetime',
                                           'lat': 'categorical',
                                           'lng': 'categorical',
                                           'provider': 'categorical'})
X
[3]:
Physical Type Logical Type Semantic Tag(s)
Data Column
card_id Int64 Integer ['numeric']
store_id category Categorical ['category']
datetime datetime64[ns] Datetime []
amount Int64 Integer ['numeric']
currency category Categorical ['category']
customer_present boolean Boolean []
expiration_date category Datetime []
provider category Categorical ['category']
lat category Categorical ['category']
lng category Categorical ['category']
region category Categorical ['category']
country category Categorical ['category']

In order to validate the results of the pipeline creation and optimization process, we will save some of our data as a holdout set.

[4]:
X_train, X_holdout, y_train, y_holdout = evalml.preprocessing.split_data(X, y, problem_type='binary', test_size=.2)

Note: To provide data to EvalML, it is recommended that you create a DataTable object using the Woodwork project. Here, split_data() returns Woodwork data structures.

EvalML also accepts and works well with pandas DataFrames. But using the DataTable makes it easy to control how EvalML will treat each feature, as a numeric feature, a categorical feature, a text feature or other type of feature. Woodwork’s DataTable includes features like inferring when a categorical feature should be treated as a text feature.

EvalML has many options to configure the pipeline search. At the minimum, we need to define an objective function. For simplicity, we will use the F1 score in this example. However, the real power of EvalML is in using domain-specific objective functions or building your own.

Below EvalML utilizes Bayesian optimization (EvalML’s default optimizer) to search and find the best pipeline defined by the given objective.

EvalML provides a number of parameters to control the search process. max_batches is one of the parameters which controls the stopping criterion for the AutoML search. It indicates the maximum number of rounds of AutoML to evaluate, where each round may train and score a variable number of pipelines. In this example, max_batches is set to 1.

** Graphing methods, like AutoMLSearch, on Jupyter Notebook and Jupyter Lab require ipywidgets to be installed.

** If graphing on Jupyter Lab, jupyterlab-plotly required. To download this, make sure you have npm installed.

[5]:
automl = AutoMLSearch(X_train=X_train, y_train=y_train,
                      problem_type='binary', objective='f1', max_batches=1)
Generating pipelines to search over...

When we call search(), the search for the best pipeline will begin. There is no need to wrangle with missing data or categorical variables as EvalML includes various preprocessing steps (like imputation, one-hot encoding, feature selection) to ensure you’re getting the best results. As long as your data is in a single table, EvalML can handle it. If not, you can reduce your data to a single table by utilizing Featuretools and its Entity Sets.

You can find more information on pipeline components and how to integrate your own custom pipelines into EvalML here.

[6]:
automl.search()

*****************************
* Beginning pipeline search *
*****************************

Optimizing for F1.
Greater score is better.

Using SequentialEngine to train and score pipelines.
Searching up to 1 batches for a total of 9 pipelines.
Allowed model families: lightgbm, extra_trees, random_forest, xgboost, decision_tree, catboost, linear_model

Evaluating Baseline Pipeline: Mode Baseline Binary Classification Pipeline
Mode Baseline Binary Classification Pipeline:
        Starting cross validation
        Finished cross validation - mean F1: 0.000

*****************************
* Evaluating Batch Number 1 *
*****************************

Elastic Net Classifier w/ Imputer + DateTime Featurization Component + One Hot Encoder + Undersampler + Standard Scaler:
        Starting cross validation
        Finished cross validation - mean F1: 0.248
Decision Tree Classifier w/ Imputer + DateTime Featurization Component + One Hot Encoder + Undersampler:
        Starting cross validation
        Finished cross validation - mean F1: 0.540
        High coefficient of variation (cv >= 0.2) within cross validation scores.
        Decision Tree Classifier w/ Imputer + DateTime Featurization Component + One Hot Encoder + Undersampler may not perform as estimated on unseen data.
Random Forest Classifier w/ Imputer + DateTime Featurization Component + One Hot Encoder + Undersampler:
        Starting cross validation
        Finished cross validation - mean F1: 0.736
LightGBM Classifier w/ Imputer + DateTime Featurization Component + One Hot Encoder + Undersampler:
        Starting cross validation
        Finished cross validation - mean F1: 0.726
Logistic Regression Classifier w/ Imputer + DateTime Featurization Component + One Hot Encoder + Undersampler + Standard Scaler:
        Starting cross validation
        Finished cross validation - mean F1: 0.326
XGBoost Classifier w/ Imputer + DateTime Featurization Component + One Hot Encoder + Undersampler:
        Starting cross validation
        Finished cross validation - mean F1: 0.724
Extra Trees Classifier w/ Imputer + DateTime Featurization Component + One Hot Encoder + Undersampler:
        Starting cross validation
        Finished cross validation - mean F1: 0.603
CatBoost Classifier w/ Imputer + DateTime Featurization Component + Undersampler:
        Starting cross validation
        Finished cross validation - mean F1: 0.683

Search finished after 00:34
Best pipeline: Random Forest Classifier w/ Imputer + DateTime Featurization Component + One Hot Encoder + Undersampler
Best pipeline F1: 0.735757

We also provide a standalone ``search` method <../generated/evalml.automl.search.html>`__ which does all of the above in a single line, and returns the AutoMLSearch instance and data check results. If there were data check errors, AutoML will not be run and no AutoMLSearch instance will be returned.

After the search is finished we can view all of the pipelines searched, ranked by score. Internally, EvalML performs cross validation to score the pipelines. If it notices a high variance across cross validation folds, it will warn you. EvalML also provides additional data checks to analyze your data to assist you in producing the best performing pipeline.

[7]:
automl.rankings
[7]:
id pipeline_name mean_cv_score standard_deviation_cv_score validation_score percent_better_than_baseline high_variance_cv parameters
0 3 Random Forest Classifier w/ Imputer + DateTime... 0.735757 0.050392 0.793651 73.575653 False {'Imputer': {'categorical_impute_strategy': 'm...
1 4 LightGBM Classifier w/ Imputer + DateTime Feat... 0.726177 0.012395 0.733333 72.617702 False {'Imputer': {'categorical_impute_strategy': 'm...
2 6 XGBoost Classifier w/ Imputer + DateTime Featu... 0.723516 0.059858 0.754098 72.351619 False {'Imputer': {'categorical_impute_strategy': 'm...
3 8 CatBoost Classifier w/ Imputer + DateTime Feat... 0.683355 0.078737 0.733333 68.335462 False {'Imputer': {'categorical_impute_strategy': 'm...
4 7 Extra Trees Classifier w/ Imputer + DateTime F... 0.603037 0.033231 0.637681 60.303658 False {'Imputer': {'categorical_impute_strategy': 'm...
5 2 Decision Tree Classifier w/ Imputer + DateTime... 0.539626 0.271816 0.787879 53.962577 True {'Imputer': {'categorical_impute_strategy': 'm...
6 5 Logistic Regression Classifier w/ Imputer + Da... 0.325626 0.041496 0.361111 32.562584 False {'Imputer': {'categorical_impute_strategy': 'm...
7 1 Elastic Net Classifier w/ Imputer + DateTime F... 0.247528 0.002861 0.249180 24.752836 False {'Imputer': {'categorical_impute_strategy': 'm...
8 0 Mode Baseline Binary Classification Pipeline 0.000000 0.000000 0.000000 0.000000 False {'Baseline Classifier': {'strategy': 'mode'}}

If we are interested in see more details about the pipeline, we can view a summary description using the id from the rankings table:

[8]:
automl.describe_pipeline(3)

***********************************************************************************************************
* Random Forest Classifier w/ Imputer + DateTime Featurization Component + One Hot Encoder + Undersampler *
***********************************************************************************************************

Problem Type: binary
Model Family: Random Forest

Pipeline Steps
==============
1. Imputer
         * categorical_impute_strategy : most_frequent
         * numeric_impute_strategy : mean
         * categorical_fill_value : None
         * numeric_fill_value : None
2. DateTime Featurization Component
         * features_to_extract : ['year', 'month', 'day_of_week', 'hour']
         * encode_as_categories : False
         * date_index : None
3. One Hot Encoder
         * top_n : 10
         * features_to_encode : None
         * categories : None
         * drop : if_binary
         * handle_unknown : ignore
         * handle_missing : error
4. Undersampler
         * sampling_ratio : 0.25
         * min_samples : 100
         * min_percentage : 0.1
5. Random Forest Classifier
         * n_estimators : 100
         * max_depth : 6
         * n_jobs : -1

Training
========
Training for binary problems.
Objective to optimize binary classification pipeline thresholds for: <evalml.objectives.standard_metrics.F1 object at 0x7fa0294d1cd0>
Total training time (including CV): 4.2 seconds

Cross Validation
----------------
               F1  MCC Binary  Log Loss Binary   AUC  Precision  Balanced Accuracy Binary  Accuracy Binary  Sensitivity at Low Alert Rates # Training # Validation
0           0.794       0.789            0.266 0.838      1.000                     0.829            0.951                           0.000        533          267
1           0.712       0.717            0.279 0.824      1.000                     0.776            0.936                           0.000        533          267
2           0.702       0.709            0.278 0.804      1.000                     0.770            0.936                           0.000        534          266
mean        0.736       0.739            0.274 0.822      1.000                     0.792            0.941                           0.000          -            -
std         0.050       0.044            0.007 0.017      0.000                     0.032            0.009                           0.000          -            -
coef of var 0.068       0.059            0.027 0.021      0.000                     0.041            0.009                             inf          -            -

We can also view the pipeline parameters directly:

[9]:
pipeline = automl.get_pipeline(3)
print(pipeline.parameters)
{'Imputer': {'categorical_impute_strategy': 'most_frequent', 'numeric_impute_strategy': 'mean', 'categorical_fill_value': None, 'numeric_fill_value': None}, 'DateTime Featurization Component': {'features_to_extract': ['year', 'month', 'day_of_week', 'hour'], 'encode_as_categories': False, 'date_index': None}, 'One Hot Encoder': {'top_n': 10, 'features_to_encode': None, 'categories': None, 'drop': 'if_binary', 'handle_unknown': 'ignore', 'handle_missing': 'error'}, 'Undersampler': {'sampling_ratio': 0.25, 'min_samples': 100, 'min_percentage': 0.1}, 'Random Forest Classifier': {'n_estimators': 100, 'max_depth': 6, 'n_jobs': -1}}

We can now select the best pipeline and score it on our holdout data:

[10]:
pipeline = automl.best_pipeline
pipeline.score(X_holdout, y_holdout, ["f1"])
[10]:
OrderedDict([('F1', 0.8085106382978724)])

We can also visualize the structure of the components contained by the pipeline:

[11]:
pipeline.graph()
[11]:
_images/start_24_0.svg