What is automated machine learning (AutoML)?
Automated machine learning, also referred to as automated ML or AutoML, is the process of automating the time-consuming, iterative tasks of machine learning model development. It allows data scientists, analysts, and developers to build ML models with high scale, efficiency, and productivity all while sustaining model quality. Automated ML in Azure Machine Learning is based on a breakthrough from our Microsoft Research division.
Traditional machine learning model development is resource-intensive, requiring significant domain knowledge and time to produce and compare dozens of models. With automated machine learning, you'll accelerate the time it takes to get production-ready ML models with great ease and efficiency.
Ways to use AutoML in Azure Machine Learning
Azure Machine Learning offers the following two experiences for working with automated ML. See the following sections to understand feature availability in each experience.
For code-experienced customers, Azure Machine Learning Python SDK. Get started with Tutorial: Use automated machine learning to predict taxi fares.
For limited/no-code experience customers, Azure Machine Learning studio at https://ml.azure.com. Get started with these tutorials:
AutoML settings and configuration
The following settings allow you to configure your automated ML experiment.
|The Python SDK||The studio web experience|
|Split data into train/validation sets||✓||✓|
|Supports ML tasks: classification, regression, and forecasting||✓||✓|
|Optimizes based on primary metric||✓||✓|
|Supports Azure ML compute as compute target||✓||✓|
|Configure forecast horizon, target lags & rolling window||✓||✓|
|Set exit criteria||✓||✓|
|Set concurrent iterations||✓||✓|
|Supports training on Azure Databricks clusters||✓|
|View engineered feature names||✓|
|Featurization for holidays||✓|
|Log file verbosity levels||✓|
These settings can be applied to the best model as a result of your automated ML experiment.
|The Python SDK||The studio web experience|
|Best model registration, deployment, explainability||✓||✓|
|Enable voting ensemble & stack ensemble models||✓||✓|
|Show best model based on non-primary metric||✓|
|Enable/disable ONNX model compatibility||✓|
|Test the model||✓|
Run control settings
These settings allow you to review and control your experiment runs and its child runs.
|The Python SDK||The studio web experience|
|Run summary table||✓||✓|
|Cancel runs & child runs||✓||✓|
|Pause & resume runs||✓|
When to use AutoML: classification, regression, & forecasting
Apply automated ML when you want Azure Machine Learning to train and tune a model for you using the target metric you specify. Automated ML democratizes the machine learning model development process, and empowers its users, no matter their data science expertise, to identify an end-to-end machine learning pipeline for any problem.
Data scientists, analysts, and developers across industries can use automated ML to:
- Implement ML solutions without extensive programming knowledge
- Save time and resources
- Leverage data science best practices
- Provide agile problem-solving
Classification is a common machine learning task. Classification is a type of supervised learning in which models learn using training data, and apply those learnings to new data. Azure Machine Learning offers featurizations specifically for these tasks, such as deep neural network text featurizers for classification. Learn more about featurization options.
The main goal of classification models is to predict which categories new data will fall into based on learnings from its training data. Common classification examples include fraud detection, handwriting recognition, and object detection. Learn more and see an example at Create a classification model with automated ML.
Similar to classification, regression tasks are also a common supervised learning task. Azure Machine Learning offers featurizations specifically for these tasks.
Different from classification where predicted output values are categorical, regression models predict numerical output values based on independent predictors. In regression, the objective is to help establish the relationship among those independent predictor variables by estimating how one variable impacts the others. For example, automobile price based on features like, gas mileage, safety rating, etc. Learn more and see an example of regression with automated machine learning.
See examples of regression and automated machine learning for predictions in these Python notebooks: CPU Performance Prediction,
Building forecasts is an integral part of any business, whether it's revenue, inventory, sales, or customer demand. You can use automated ML to combine techniques and approaches and get a recommended, high-quality time-series forecast. Learn more with this how-to: automated machine learning for time series forecasting.
An automated time-series experiment is treated as a multivariate regression problem. Past time-series values are "pivoted" to become additional dimensions for the regressor together with other predictors. This approach, unlike classical time series methods, has an advantage of naturally incorporating multiple contextual variables and their relationship to one another during training. Automated ML learns a single, but often internally branched model for all items in the dataset and prediction horizons. More data is thus available to estimate model parameters and generalization to unseen series becomes possible.
Advanced forecasting configuration includes:
- holiday detection and featurization
- time-series and DNN learners (Auto-ARIMA, Prophet, ForecastTCN)
- many models support through grouping
- rolling-origin cross validation
- configurable lags
- rolling window aggregate features
How automated ML works
During training, Azure Machine Learning creates a number of pipelines in parallel that try different algorithms and parameters for you. The service iterates through ML algorithms paired with feature selections, where each iteration produces a model with a training score. The higher the score, the better the model is considered to "fit" your data. It will stop once it hits the exit criteria defined in the experiment.
Using Azure Machine Learning, you can design and run your automated ML training experiments with these steps:
Identify the ML problem to be solved: classification, forecasting, or regression
Choose whether you want to use the Python SDK or the studio web experience: Learn about the parity between the Python SDK and studio web experience.
Specify the source and format of the labeled training data: Numpy arrays or Pandas dataframe
Configure the compute target for model training, such as your local computer, Azure Machine Learning Computes, remote VMs, or Azure Databricks.
Configure the automated machine learning parameters that determine how many iterations over different models, hyperparameter settings, advanced preprocessing/featurization, and what metrics to look at when determining the best model.
Submit the training run.
Review the results
The following diagram illustrates this process.
You can also inspect the logged run information, which contains metrics gathered during the run. The training run produces a Python serialized object (
.pkl file) that contains the model and data preprocessing.
While model building is automated, you can also learn how important or relevant features are to the generated models.
Feature engineering is the process of using domain knowledge of the data to create features that help ML algorithms learn better. In Azure Machine Learning, scaling and normalization techniques are applied to facilitate feature engineering. Collectively, these techniques and feature engineering are referred to as featurization.
For automated machine learning experiments, featurization is applied automatically, but can also be customized based on your data. Learn more about what featurization is included.
Automated machine learning featurization steps (feature normalization, handling missing data, converting text to numeric, etc.) become part of the underlying model. When using the model for predictions, the same featurization steps applied during training are applied to your input data automatically.
Automatic featurization (standard)
In every automated machine learning experiment, your data is automatically scaled or normalized to help algorithms perform well. During model training, one of the following scaling or normalization techniques will be applied to each model. Learn how AutoML helps prevent over-fitting and imbalanced data in your models.
|Scaling & processing||Description|
|StandardScaleWrapper||Standardize features by removing the mean and scaling to unit variance|
|MinMaxScalar||Transforms features by scaling each feature by that column's minimum and maximum|
|MaxAbsScaler||Scale each feature by its maximum absolute value|
|RobustScalar||Scales features by their quantile range|
|PCA||Linear dimensionality reduction using Singular Value Decomposition of the data to project it to a lower dimensional space|
|TruncatedSVDWrapper||This transformer performs linear dimensionality reduction by means of truncated singular value decomposition (SVD). Contrary to PCA, this estimator does not center the data before computing the singular value decomposition, which means it can work with scipy.sparse matrices efficiently|
|SparseNormalizer||Each sample (that is, each row of the data matrix) with at least one non-zero component is rescaled independently of other samples so that its norm (l1 or l2) equals one|
Additional feature engineering techniques such as, encoding and transforms are also available.
Enable this setting with:
Azure Machine Learning studio: Enable Automatic featurization in the View additional configuration section with these steps.
Automated machine learning supports ensemble models, which are enabled by default. Ensemble learning improves machine learning results and predictive performance by combining multiple models as opposed to using single models. The ensemble iterations appear as the final iterations of your run. Automated machine learning uses both voting and stacking ensemble methods for combining models:
- Voting: predicts based on the weighted average of predicted class probabilities (for classification tasks) or predicted regression targets (for regression tasks).
- Stacking: stacking combines heterogenous models and trains a meta-model based on the output from the individual models. The current default meta-models are LogisticRegression for classification tasks and ElasticNet for regression/forecasting tasks.
The Caruana ensemble selection algorithm with sorted ensemble initialization is used to decide which models to use within the ensemble. At a high level, this algorithm initializes the ensemble with up to five models with the best individual scores, and verifies that these models are within 5% threshold of the best score to avoid a poor initial ensemble. Then for each ensemble iteration, a new model is added to the existing ensemble and the resulting score is calculated. If a new model improved the existing ensemble score, the ensemble is updated to include the new model.
See the how-to for changing default ensemble settings in automated machine learning.
Guidance on local vs. remote managed ML compute targets
The web interface for automated ML always uses a remote compute target. But when you use the Python SDK, you will choose either a local compute or a remote compute target for automated ML training.
- Local compute: Training occurs on your local laptop or VM compute.
- Remote compute: Training occurs on Machine Learning compute clusters.
Choose compute target
Consider these factors when choosing your compute target:
- Choose a local compute: If your scenario is about initial explorations or demos using small data and short trains (i.e. seconds or a couple of minutes per child run), training on your local computer might be a better choice. There is no setup time, the infrastructure resources (your PC or VM) are directly available.
- Choose a remote ML compute cluster: If you are training with larger datasets like in production training creating models which need longer trains, remote compute will provide much better end-to-end time performance because
AutoMLwill parallelize trains across the cluster's nodes. On a remote compute, the start-up time for the internal infrastructure will add around 1.5 minutes per child run, plus additional minutes for the cluster infrastructure if the VMs are not yet up and running.
Pros and cons
Consider these pros and cons when choosing to use local vs. remote.
|Pros (Advantages)||Cons (Handicaps)|
|Local compute target|
|Remote ML compute clusters|
More features are available when you use the remote compute, as shown in the table below.
|Data streaming (Large data support, up to 100 GB)||✓|
|DNN-BERT-based text featurization and training||✓|
|Out-of-the-box GPU support (training and inference)||✓|
|Image Classification and Labeling support||✓|
|Auto-ARIMA, Prophet and ForecastTCN models for forecasting||✓|
|Multiple runs/iterations in parallel||✓|
|Create models with interpretability in AutoML studio web experience UI||✓|
|Feature engineering customization in studio web experience UI||✓|
|Azure ML hyperparameter tuning||✓|
|Azure ML Pipeline workflow support||✓|
|Continue a run||✓|
|Create and run experiments in notebooks||✓||✓|
|Register and visualize experiment's info and metrics in UI||✓||✓|
AutoML & ONNX
With Azure Machine Learning, you can use automated ML to build a Python model and have it converted to the ONNX format. Once the models are in the ONNX format, they can be run on a variety of platforms and devices. Learn more about accelerating ML models with ONNX.
The ONNX runtime also supports C#, so you can use the model built automatically in your C# apps without any need for recoding or any of the network latencies that REST endpoints introduce. Learn more about using an AutoML ONNX model in a .NET application with ML.NET and inferencing ONNX models with the ONNX runtime C# API.
There are multiple resources to get you up and running with AutoML.
Tutorials are end-to-end introductory examples of AutoML scenarios.
For a code first experience, follow the Tutorial: Train a regression model with AutoML and Python.
For a low or no-code experience, see the Tutorial: Train a classification model with no-code AutoML in Azure Machine Learning studio.
How-to articles provide additional detail into what functionality automated ML offers. For example,
Configure the settings for automatic training experiments
Learn how to train forecasting models with time series data.
Jupyter notebook samples
Review detailed code examples and use cases in the GitHub notebook repository for automated machine learning samples.
Python SDK reference
Deepen your expertise of SDK design patterns and class specifications with the AutoML class reference documentation.