Prediction engineering methods for Draco.
Project description
A project from Data to AI Lab at MIT.
Zephyr
A machine learning library for assisting in the generation of machine learning problems for wind farms operations data by analyzing past occurrences of events.
Important Links | |
---|---|
:computer: Website | Check out the Sintel Website for more information about the project. |
:book: Documentation | Quickstarts, User and Development Guides, and API Reference. |
:star: Tutorials | Checkout our notebooks |
:octocat: Repository | The link to the Github Repository of this library. |
:scroll: License | The repository is published under the MIT License. |
:keyboard: Development Status | This software is in its Pre-Alpha stage. |
Community | Join our Slack Workspace for announcements and discussions. |
- Homepage: https://github.com/signals-dev/zephyr
Overview
The Zephyr library is a framework designed to assist in the generation of machine learning problems for wind farms operations data by analyzing past occurrences of events.
The main features of Zephyr are:
- EntitySet creation: tools designed to represent wind farm data and the relationship between different tables. We have functions to create EntitySets for datasets with PI data and datasets using SCADA data.
- Labeling Functions: a collection of functions, as well as tools to create custom versions of them, ready to be used to analyze past operations data in the search for occurrences of specific types of events in the past.
- Prediction Engineering: a flexible framework designed to apply labeling functions on wind turbine operations data in a number of different ways to create labels for custom Machine Learning problems.
- Feature Engineering: a guide to using Featuretools to apply automated feature engineerinig to wind farm data.
Install
Requirements
Zephyr has been developed and runs on Python 3.6 and 3.7.
Also, although it is not strictly required, the usage of a virtualenv is highly recommended in order to avoid interfering with other software installed in the system where you are trying to run Zephyr.
Download and Install
Zephyr can be installed locally using pip with the following command:
pip install zephyr-ml
If you want to install from source or contribute to the project please read the Contributing Guide.
Quickstart
In this short tutorial we will guide you through a series of steps that will help you getting started with Zephyr.
1. Loading the data
The first step we will be to use preprocessed data to create an EntitySet. Depending on the
type of data, we will either the zephyr_ml.create_pidata_entityset
or zephyr_ml.create_scada_entityset
functions.
NOTE: if you cloned the Zephyr repository, you will find some demo data inside the
notebooks/data
folder which has been preprocessed to fit the create_entityset
data
requirements.
import os
import pandas as pd
from zephyr_ml import create_scada_entityset
data_path = 'notebooks/data'
data = {
'turbines': pd.read_csv(os.path.join(data_path, 'turbines.csv')),
'alarms': pd.read_csv(os.path.join(data_path, 'alarms.csv')),
'work_orders': pd.read_csv(os.path.join(data_path, 'work_orders.csv')),
'stoppages': pd.read_csv(os.path.join(data_path, 'stoppages.csv')),
'notifications': pd.read_csv(os.path.join(data_path, 'notifications.csv')),
'scada': pd.read_csv(os.path.join(data_path, 'scada.csv'))
}
scada_es = create_scada_entityset(data)
This will load the turbine, alarms, stoppages, work order, notifications, and SCADA data, and return it as an EntitySet.
Entityset: SCADA data
DataFrames:
turbines [Rows: 1, Columns: 10]
alarms [Rows: 2, Columns: 9]
work_orders [Rows: 2, Columns: 20]
stoppages [Rows: 2, Columns: 16]
notifications [Rows: 2, Columns: 15]
scada [Rows: 2, Columns: 5]
Relationships:
alarms.COD_ELEMENT -> turbines.COD_ELEMENT
stoppages.COD_ELEMENT -> turbines.COD_ELEMENT
work_orders.COD_ELEMENT -> turbines.COD_ELEMENT
scada.COD_ELEMENT -> turbines.COD_ELEMENT
notifications.COD_ORDER -> work_orders.COD_ORDER
2. Selecting a Labeling Function
The second step will be to choose an adequate Labeling Function.
We can see the list of available labeling functions using the zephyr_ml.labeling.get_labeling_functions
function.
from zephyr_ml import labeling
labeling.get_labeling_functions()
This will return us a dictionary with the name and a short description of each available function.
{'brake_pad_presence': 'Calculates the total power loss over the data slice.',
'converter_replacement_presence': 'Calculates the converter replacement presence.',
'total_power_loss': 'Calculates the total power loss over the data slice.'}
In this case, we will choose the total_power_loss
function, which calculates the total
amount of power lost over a slice of time.
3. Generate Target Times
Once we have loaded the data and the Labeling Function, we are ready to start using
the zephyr_ml.generate_labels
function to generate a Target Times table.
from zephyr_ml import DataLabeler
data_labeler = DataLabeler(labeling.labeling_functions.total_power_loss)
target_times, metadata = data_labeler.generate_label_times(scada_es)
This will return us a compose.LabelTimes
containing the three columns required to start
working on a Machine Learning problem: the turbine ID (COD_ELEMENT), the cutoff time (time) and the label.
COD_ELEMENT time label
0 0 2022-01-01 45801.0
4. Feature Engineering
Using EntitySets and LabelTimes allows us to easily use Featuretools for automatic feature generation.
import featuretools as ft
feature_matrix, features = ft.dfs(
entityset=scada_es,
target_dataframe_name='turbines',
cutoff_time_in_index=True,
cutoff_time=target_times,
max_features=20
)
Then we get a list of features and the computed feature_matrix
.
TURBINE_PI_ID TURBINE_LOCAL_ID TURBINE_SAP_COD DES_CORE_ELEMENT SITE DES_CORE_PLANT ... MODE(alarms.COD_STATUS) MODE(alarms.DES_NAME) MODE(alarms.DES_TITLE) NUM_UNIQUE(alarms.COD_ALARM) NUM_UNIQUE(alarms.COD_ALARM_INT) label
COD_ELEMENT time ...
0 2022-01-01 TA00 A0 LOC000 T00 LOCATION LOC ... Alarm1 Alarm1 Description of alarm 1 1 1 45801.0
[1 rows x 21 columns]
5. Modeling
Once we have the feature matrix, we can train a model using the Zephyr interface where you can train, infer, and evaluate a pipeline.
First, we need to prepare our dataset for training by creating X
and y
variables and one-hot encoding features.
y = list(feature_matrix.pop('label'))
X = pd.get_dummies(feature_matrix).values
In this example, we will use an 'xgb' regression pipeline to predict total power loss.
from zephyr_ml import Zephyr
pipeline_name = 'xgb_regressor'
zephyr = Zephyr(pipeline_name)
To train the pipeline, we simply use the fit
function.
zephyr.fit(X, y)
After it finished training, we can make prediciton using predict
y_pred = zephyr.predict(X)
We can also use zephyr.evaluate
to obtain the performance of the pipeline.
What's Next?
If you want to continue learning about Zephyr and all its features please have a look at the tutorials found inside the notebooks folder.
History
0.0.3 - 2024-03-12
SigPro supporting python 3.9, 3.10, and 3.11
- add gearbox_replace_presence labeling function - Issue #21 by @SaraPido
- Update python versions - Issue #20 by @SaraPido
0.0.2 - 2023-05-09
SigPro integration for processing signals
- Integrating SigPro - Issue #7 by @frances-h @sarahmish
- Add options to xgb pipeline - Issue #5 by @sarahmish
0.0.1 - 2023-03-02
New modeling module using Zephyr class
0.0.0 - 2022-11-17
First full release
- Prediction Engineering Framework by @frances-h
- EntitySet creation by @frances-h
- DataLabeler and initial labeling functions by @frances-h
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