Metadata-Version: 2.1
Name: miceforest
Version: 2.0.2
Summary: Imputes missing data with MICE + random forests
Home-page: https://github.com/AnotherSamWilson/miceforest
Author: Samuel Wilson
Author-email: samwilson303@gmail.com
License: MIT
Keywords: MICE,Imputation,Missing Values,Missing,Random Forest
Platform: UNKNOWN
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Classifier: Operating System :: Microsoft :: Windows
Classifier: Programming Language :: Python :: 3.6
Classifier: Programming Language :: Python :: 3.7
Classifier: Programming Language :: Python :: 3.8
Classifier: License :: OSI Approved :: MIT License
Classifier: Operating System :: OS Independent
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Requires-Dist: sklearn
Requires-Dist: numpy
Requires-Dist: pandas
Requires-Dist: seaborn (>=0.11.0)
Requires-Dist: matplotlib (>=3.3.0)


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## miceforest: Fast Imputation with Random Forests in Python

<a href='https://github.com/AnotherSamWilson/miceforest'><img src='examples/icon.png' align="right" height="300" /></a>

Fast, memory efficient Multiple Imputation by Chained Equations (MICE)
with random forests. It can impute categorical and numeric data without
much setup, and has an array of diagnostic plots available. The R
version of this package may be found
[here](https://github.com/FarrellDay/miceRanger).

This document contains a thorough walkthrough of the package,
benchmarks, and an introduction to multiple imputation. More information
on MICE can be found in Stef van Buurenâ€™s excellent online book, which
you can find
[here](https://stefvanbuuren.name/fimd/ch-introduction.html).

#### Table of Contents:

  - [Package
    Meta](https://github.com/AnotherSamWilson/miceforest#Package-Meta)
  - [Using
    miceforest](https://github.com/AnotherSamWilson/miceforest#Using-miceforest)
      - [Single
        Imputation](https://github.com/AnotherSamWilson/miceforest#Imputing-A-Single-Dataset)
      - [Multiple
        Imputation](https://github.com/AnotherSamWilson/miceforest#Simple-Example-Of-Multiple-Imputation)
      - [Controlling Tree
        Growth](https://github.com/AnotherSamWilson/miceforest#Controlling-Tree-Growth)
      - [Custom Imputation
        Schemas](https://github.com/AnotherSamWilson/miceforest#Creating-a-Custom-Imputation-Schema)
      - [Imputing New Data with Existing
        Models](https://github.com/AnotherSamWilson/miceforest#Imputing-New-Data-with-Existing-Models)
  - [Diagnostic
    Plotting](https://github.com/AnotherSamWilson/miceforest#Diagnostic-Plotting)
      - [Imputed
        Distributions](https://github.com/AnotherSamWilson/miceforest#Distribution-of-Imputed-Values)
      - [Correlation
        Convergence](https://github.com/AnotherSamWilson/miceforest#Convergence-of-Correlation)
      - [Variable
        Importance](https://github.com/AnotherSamWilson/miceforest#Variable-Importance)
      - [Mean
        Convergence](https://github.com/AnotherSamWilson/miceforest#Variable-Importance)
  - [Using the Imputed
    Data](https://github.com/AnotherSamWilson/miceforest#Using-the-Imputed-Data)
  - [The MICE
    Algorithm](https://github.com/AnotherSamWilson/miceforest#The-MICE-Algorithm)
      - [Introduction](https://github.com/AnotherSamWilson/miceforest#The-MICE-Algorithm)
      - [Common Use
        Cases](https://github.com/AnotherSamWilson/miceforest#Common-Use-Cases)
      - [Predictive Mean
        Matching](https://github.com/AnotherSamWilson/miceforest#Predictive-Mean-Matching)
      - [Effects of Mean
        Matching](https://github.com/AnotherSamWilson/miceforest#Effects-of-Mean-Matching)

### Package Meta

miceforest has 4 main classes which the user will interact with:

  - `KernelDataSet` - a kernel data set is a dataset on which the mice
    algorithm is performed. Models are saved inside the instance, which
    can also be called on to impute new data. Several plotting methods
    are included to run diagnostics on the imputed data.  
  - `MultipleImputedKernel` - a collection of `KernelDataSet`s. Has
    additional methods for accessing and comparing multiple kernel
    datasets together.  
  - `ImputedDataSet` - a single dataset that has been imputed. These are
    returned after `impute_new_data()` is called.
  - `MultipleImputedDataSet` - A collection of datasets that have been
    imputed. Has additional methods for comparing the imputations
    between datasets.

You can download the latest stable version from PyPi:

``` bash
$ pip install miceforest
```

You can also download the latest development version from this
repository:

``` bash
$ pip install git+https://github.com/AnotherSamWilson/miceforest.git
```

## Using miceforest

In these examples we will be looking at a few simple examples of
imputation. We need to load the packages, and define the data:

``` python
import miceforest as mf
from sklearn.datasets import load_iris
import pandas as pd
import numpy as np

# Load data and introduce missing values
iris = pd.concat(load_iris(as_frame=True,return_X_y=True),axis=1)
iris['target'] = iris['target'].astype('category')
iris_amp = mf.ampute_data(iris,perc=0.25,random_state=1991)
```

### Imputing a Single Dataset

If you only want to create a single imputed dataset, you can use
`KernelDataSet`:

``` python
# Create kernel. 
kds = mf.KernelDataSet(
  iris_amp,
  save_all_iterations=True,
  random_state=1991
)

# Run the MICE algorithm for 3 iterations
kds.mice(3)

# Return the completed kernel data
completed_data = kds.complete_data()
```

There are also an array of plotting functions available, these are
discussed below in the section [Diagnostic
Plotting](https://github.com/AnotherSamWilson/miceforest#Diagnostic-Plotting).
The plotting behavior between single imputed datasets and multi-imputed
datasets is slightly different.

### Simple Example of Multiple Imputation

We can also create a class which contains multiple `KernelDataSet`s,
along with easy ways to compare them:

``` python
# Create kernel. 
kernel = mf.MultipleImputedKernel(
  iris_amp,
  datasets=4,
  save_all_iterations=True,
  random_state=1991
)

# Run the MICE algorithm for 3 iterations on each of the datasets
kernel.mice(3)
```

Printing the `MultipleImputedKernel` object will tell you some high
level information:

``` python
print(kernel)
```

    ##               Class: MultipleImputedKernel
    ##        Models Saved: Last Iteration
    ##            Datasets: 4
    ##          Iterations: 3
    ##   Imputed Variables: 5
    ## save_all_iterations: True

### Controlling Tree Growth

A *very* nice thing about random forests is that they are trivially
parallelizable. We can save a lot of time by setting the `n_jobs`
parameter in both the fit and predict methods for the random forests:

``` python
# Run the MICE algorithm for 2 more iterations on the kernel, 
kernel.mice(2,n_jobs=2)
```

Any other arguments may be passed to either class
(`RandomForestClassifier`,`RandomForestRegressor`). In our example, we
may not have saved much (if any) time. This is because there is overhead
with using multiple cores, and our data is very small.

### Creating a Custom Imputation Schema

It is possible to customize our imputation procedure by variable. By
passing a named list to `variable_schema`, you can specify the
predictors for each variable to impute. You can also select which
variables should be imputed using mean matching, as well as the mean
matching candidates, by passing a dict to`mean_match_candidates`:

``` python
var_sch = {
    'sepal width (cm)': ['target','petal width (cm)'],
    'petal width (cm)': ['target','sepal length (cm)']
}
var_mmc = {
    'sepal width (cm)': 5,
    'petal width (cm)': 0
}

cust_kernel = mf.MultipleImputedKernel(
    iris_amp,
    datasets=3,
    variable_schema=var_sch,
    mean_match_candidates=var_mmc
)
cust_kernel.mice(2)
```

### Imputing New Data with Existing Models

Multiple Imputation can take a long time. If you wish to impute a
dataset using the MICE algorithm, but donâ€™t have time to train new
models, it is possible to impute new datasets using a
`MultipleImputedKernel` object. The `impute_new_data()` function uses
the random forests collected by `MultipleImputedKernel` to perform
multiple imputation without updating the random forest at each
iteration:

``` python
# Our 'new data' is just the first 15 rows of iris_amp
new_data = iris_amp.iloc[range(15)]
new_data_imputed = kernel.impute_new_data(new_data=new_data)
print(new_data_imputed)
```

    ##               Class: MultipleImputedDataSet
    ##            Datasets: 4
    ##          Iterations: 5
    ##   Imputed Variables: 5
    ## save_all_iterations: False

All of the imputation parameters (variable\_schema,
mean\_match\_candidates, etc) will be carried over from the original
`MultipleImputedKernel` object. When mean matching, the candidate values
are pulled from the original kernel dataset. To impute new data, the
`save_models` parameter in `MultipleImputedKernel` must be \> 0. If
`save_models == 1`, the model from the latest iteration is saved for
each variable. If `save_models > 1`, the model from each iteration is
saved. This allows for new data to be imputed in a more similar fashion
to the original mice procedure.

## Diagnostic Plotting

As of now, miceforest has four diagnostic plots available.

### Distribution of Imputed-Values

We probably want to know how the imputed values are distributed. We can
plot the original distribution beside the imputed distributions in each
dataset by using the `plot_imputed_distributions` method of an
`MultipleImputedKernel` object:

``` python
kernel.plot_imputed_distributions(wspace=0.3,hspace=0.3)
```

<img src="examples/distributions.png" width="600px" />

The red line is the original data, and each black line are the imputed
values of each dataset.

### Convergence of Correlation

We are probably interested in knowing how our values between datasets
converged over the iterations. The `plot_correlations` method shows you
a boxplot of the correlations between imputed values in every
combination of datasets, at each iteration. This allows you to see how
correlated the imputations are between datasets, as well as the
convergence over iterations:

``` python
kernel.plot_correlations()
```

<img src="examples/plot_corr.png" width="600px" />

### Variable Importance

We also may be interested in which variables were used to impute each
variable. We can plot this information by using the
`plot_feature_importance` method.

``` python
kernel.plot_feature_importance(annot=True,cmap="YlGnBu",vmin=0, vmax=1)
```

<img src="examples/var_imp.png" width="600px" />

The numbers shown are returned from the sklearn random forest
`_feature_importance` attribute. Each square represents the importance
of the column variable in imputing the row variable.

### Mean Convergence

If our data is not missing completely at random, we may see that it
takes a few iterations for our models to get the distribution of
imputations right. We can plot the average value of our imputations to
see if this is occurring:

``` python
kernel.plot_mean_convergence(wspace=0.3, hspace=0.4)
```

<img src="examples/mean_convergence.png" width="600px" />

Our data was missing completely at random, so we donâ€™t see any
convergence occurring here.

## Using the Imputed Data

To return the imputed data simply use the `complete_data` method:

``` python
dataset_1 = kernel.complete_data(0)
```

This will return a single specified dataset. Multiple datasets are
typically created so that some measure of confidence around each
prediction can be created.

Since we know what the original data looked like, we can cheat and see
how well the imputations compare to the original data:

``` python
acclist = []
for iteration in range(kernel.iteration_count()+1):
    target_na_count = kernel.na_counts['target']
    compdat = kernel.complete_data(dataset=0,iteration=iteration)

    # Record the accuract of the imputations of target.
    acclist.append(
      round(1-sum(compdat['target'] != iris['target'])/target_na_count,2)
    )

# acclist shows the accuracy of the imputations
# over the iterations.
print(acclist)
```

    ## [0.32, 0.76, 0.78, 0.81, 0.86, 0.86]

In this instance, we went from a \~32% accuracy (which is expected with
random sampling) to an accuracy of \~86%. We managed to replace the
missing `target` values with a pretty high degree of accuracy\!

## The MICE Algorithm

Multiple Imputation by Chained Equations â€˜fills inâ€™ (imputes) missing
data in a dataset through an iterative series of predictive models. In
each iteration, each specified variable in the dataset is imputed using
the other variables in the dataset. These iterations should be run until
it appears that convergence has been met.

<img src="examples/MICEalgorithm.png" width="851" style="display: block; margin: auto;" />

This process is continued until all specified variables have been
imputed. Additional iterations can be run if it appears that the average
imputed values have not converged, although no more than 5 iterations
are usually necessary.

### Common Use Cases

##### **Data Leakage:**

MICE is particularly useful if missing values are associated with the
target variable in a way that introduces leakage. For instance, letâ€™s
say you wanted to model customer retention at the time of sign up. A
certain variable is collected at sign up or 1 month after sign up. The
absence of that variable is a data leak, since it tells you that the
customer did not retain for 1 month.

##### **Funnel Analysis:**

Information is often collected at different stages of a â€˜funnelâ€™. MICE
can be used to make educated guesses about the characteristics of
entities at different points in a funnel.

##### **Confidence Intervals:**

MICE can be used to impute missing values, however it is important to
keep in mind that these imputed values are a prediction. Creating
multiple datasets with different imputed values allows you to do two
types of inference:

  - Imputed Value Distribution: A profile can be built for each imputed
    value, allowing you to make statements about the likely distribution
    of that value.  
  - Model Prediction Distribution: With multiple datasets, you can build
    multiple models and create a distribution of predictions for each
    sample. Those samples with imputed values which were not able to be
    imputed with much confidence would have a larger variance in their
    predictions.

### Predictive Mean Matching

`miceforest` can make use of a procedure called predictive mean matching
(PMM) to select which values are imputed. PMM involves selecting a
datapoint from the original, nonmissing data which has a predicted value
close to the predicted value of the missing sample. The closest N
(`mean_match_candidates` parameter) values are chosen as candidates,
from which a value is chosen at random. This can be specified on a
column-by-column basis. Going into more detail from our example above,
we see how this works in practice:

<img src="examples/PMM.png" width="793" style="display: block; margin: auto;" />

This method is very useful if you have a variable which needs imputing
which has any of the following characteristics:

  - Multimodal  
  - Integer  
  - Skewed

### Effects of Mean Matching

As an example, letâ€™s construct a dataset with some of the above
characteristics:

``` python
randst = np.random.RandomState(1991)
# random uniform variable
nrws = 1000
uniform_vec = randst.uniform(size=nrws)

def make_bimodal(mean1,mean2,size):
    bimodal_1 = randst.normal(size=nrws, loc=mean1)
    bimodal_2 = randst.normal(size=nrws, loc=mean2)
    bimdvec = []
    for i in range(size):
        bimdvec.append(randst.choice([bimodal_1[i], bimodal_2[i]]))
    return np.array(bimdvec)

# Make 2 Bimodal Variables
close_bimodal_vec = make_bimodal(2,-2,nrws)
far_bimodal_vec = make_bimodal(3,-3,nrws)


# Highly skewed variable correlated with Uniform_Variable
skewed_vec = np.exp(uniform_vec*randst.uniform(size=nrws)*3) + randst.uniform(size=nrws)*3

# Integer variable correlated with Close_Bimodal_Variable and Uniform_Variable
integer_vec = np.round(uniform_vec + close_bimodal_vec/3 + randst.uniform(size=nrws)*2)

# Make a DataFrame
dat = pd.DataFrame(
    {
    'uniform_var':uniform_vec,
    'close_bimodal_var':close_bimodal_vec,
    'far_bimodal_var':far_bimodal_vec,
    'skewed_var':skewed_vec,
    'integer_var':integer_vec
    }
)

# Ampute the data.
ampdat = mf.ampute_data(dat,perc=0.25,random_state=randst)

# Plot the original data
import seaborn as sns
import matplotlib.pyplot as plt
g = sns.PairGrid(dat)
g.map(plt.scatter,s=5)
```

<img src="examples/dataset.png" width="600px" style="display: block; margin: auto;" />
We can see how our variables are distributed and correlated in the graph
above. Now letâ€™s run our imputation process twice, once using mean
matching, and once using the model prediction.

``` r
kernelmeanmatch <- mf.MultipleImputedKernel(ampdat,mean_match_candidates=5)
kernelmodeloutput <- mf.MultipleImputedKernel(ampdat,mean_match_candidates=0)

kernelmeanmatch.mice(5)
kernelmodeloutput.mice(5)
```

Letâ€™s look at the effect on the different variables.

##### With Mean Matching

``` python
kernelmeanmatch.plot_imputed_distributions(wspace=0.2,hspace=0.4)
```

<img src="examples/meanmatcheffects.png" width="600px" style="display: block; margin: auto;" />

##### Without Mean Matching

``` python
kernelmodeloutput.plot_imputed_distributions(wspace=0.2,hspace=0.4)
```

<img src="examples/nomeanmatching.png" width="600px" style="display: block; margin: auto;" />

You can see the effects that mean matching has, depending on the
distribution of the data. Simply returning the value from the model
prediction, while it may provide a better â€˜fitâ€™, will not provide
imputations with a similair distribution to the original. This may be
beneficial, depending on your goal.


