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Imputation of missing values with knn.
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import numpy as np | |
import pandas as pd | |
from collections import defaultdict | |
from scipy.stats import hmean | |
from scipy.spatial.distance import cdist | |
from scipy import stats | |
import numbers | |
def weighted_hamming(data): | |
""" Compute weighted hamming distance on categorical variables. For one variable, it is equal to 1 if | |
the values between point A and point B are different, else it is equal the relative frequency of the | |
distribution of the value across the variable. For multiple variables, the harmonic mean is computed | |
up to a constant factor. | |
@params: | |
- data = a pandas data frame of categorical variables | |
@returns: | |
- distance_matrix = a distance matrix with pairwise distance for all attributes | |
""" | |
categories_dist = [] | |
for category in data: | |
X = pd.get_dummies(data[category]) | |
X_mean = X * X.mean() | |
X_dot = X_mean.dot(X.transpose()) | |
X_np = np.asarray(X_dot.replace(0,1,inplace=False)) | |
categories_dist.append(X_np) | |
categories_dist = np.array(categories_dist) | |
distances = hmean(categories_dist, axis=0) | |
return distances | |
def distance_matrix(data, numeric_distance = "euclidean", categorical_distance = "jaccard"): | |
""" Compute the pairwise distance attribute by attribute in order to account for different variables type: | |
- Continuous | |
- Categorical | |
For ordinal values, provide a numerical representation taking the order into account. | |
Categorical variables are transformed into a set of binary ones. | |
If both continuous and categorical distance are provided, a Gower-like distance is computed and the numeric | |
variables are all normalized in the process. | |
If there are missing values, the mean is computed for numerical attributes and the mode for categorical ones. | |
Note: If weighted-hamming distance is chosen, the computation time increases a lot since it is not coded in C | |
like other distance metrics provided by scipy. | |
@params: | |
- data = pandas dataframe to compute distances on. | |
- numeric_distances = the metric to apply to continuous attributes. | |
"euclidean" and "cityblock" available. | |
Default = "euclidean" | |
- categorical_distances = the metric to apply to binary attributes. | |
"jaccard", "hamming", "weighted-hamming" and "euclidean" | |
available. Default = "jaccard" | |
@returns: | |
- the distance matrix | |
""" | |
possible_continuous_distances = ["euclidean", "cityblock"] | |
possible_binary_distances = ["euclidean", "jaccard", "hamming", "weighted-hamming"] | |
number_of_variables = data.shape[1] | |
number_of_observations = data.shape[0] | |
# Get the type of each attribute (Numeric or categorical) | |
is_numeric = [all(isinstance(n, numbers.Number) for n in data.iloc[:, i]) for i, x in enumerate(data)] | |
is_all_numeric = sum(is_numeric) == len(is_numeric) | |
is_all_categorical = sum(is_numeric) == 0 | |
is_mixed_type = not is_all_categorical and not is_all_numeric | |
# Check the content of the distances parameter | |
if numeric_distance not in possible_continuous_distances: | |
print "The continuous distance " + numeric_distance + " is not supported." | |
return None | |
elif categorical_distance not in possible_binary_distances: | |
print "The binary distance " + categorical_distance + " is not supported." | |
return None | |
# Separate the data frame into categorical and numeric attributes and normalize numeric data | |
if is_mixed_type: | |
number_of_numeric_var = sum(is_numeric) | |
number_of_categorical_var = number_of_variables - number_of_numeric_var | |
data_numeric = data.iloc[:, is_numeric] | |
data_numeric = (data_numeric - data_numeric.mean()) / (data_numeric.max() - data_numeric.min()) | |
data_categorical = data.iloc[:, [not x for x in is_numeric]] | |
# Replace missing values with column mean for numeric values and mode for categorical ones. With the mode, it | |
# triggers a warning: "SettingWithCopyWarning: A value is trying to be set on a copy of a slice from a DataFrame" | |
# but the value are properly replaced | |
if is_mixed_type: | |
data_numeric.fillna(data_numeric.mean(), inplace=True) | |
for x in data_categorical: | |
data_categorical[x].fillna(data_categorical[x].mode()[0], inplace=True) | |
elif is_all_numeric: | |
data.fillna(data.mean(), inplace=True) | |
else: | |
for x in data: | |
data[x].fillna(data[x].mode()[0], inplace=True) | |
# "Dummifies" categorical variables in place | |
if not is_all_numeric and not (categorical_distance == 'hamming' or categorical_distance == 'weighted-hamming'): | |
if is_mixed_type: | |
data_categorical = pd.get_dummies(data_categorical) | |
else: | |
data = pd.get_dummies(data) | |
elif not is_all_numeric and categorical_distance == 'hamming': | |
if is_mixed_type: | |
data_categorical = pd.DataFrame([pd.factorize(data_categorical[x])[0] for x in data_categorical]).transpose() | |
else: | |
data = pd.DataFrame([pd.factorize(data[x])[0] for x in data]).transpose() | |
if is_all_numeric: | |
result_matrix = cdist(data, data, metric=numeric_distance) | |
elif is_all_categorical: | |
if categorical_distance == "weighted-hamming": | |
result_matrix = weighted_hamming(data) | |
else: | |
result_matrix = cdist(data, data, metric=categorical_distance) | |
else: | |
result_numeric = cdist(data_numeric, data_numeric, metric=numeric_distance) | |
if categorical_distance == "weighted-hamming": | |
result_categorical = weighted_hamming(data_categorical) | |
else: | |
result_categorical = cdist(data_categorical, data_categorical, metric=categorical_distance) | |
result_matrix = np.array([[1.0*(result_numeric[i, j] * number_of_numeric_var + result_categorical[i, j] * | |
number_of_categorical_var) / number_of_variables for j in range(number_of_observations)] for i in range(number_of_observations)]) | |
# Fill the diagonal with NaN values | |
np.fill_diagonal(result_matrix, np.nan) | |
return pd.DataFrame(result_matrix) | |
def knn_impute(target, attributes, k_neighbors, aggregation_method="mean", numeric_distance="euclidean", | |
categorical_distance="jaccard", missing_neighbors_threshold = 0.5): | |
""" Replace the missing values within the target variable based on its k nearest neighbors identified with the | |
attributes variables. If more than 50% of its neighbors are also missing values, the value is not modified and | |
remains missing. If there is a problem in the parameters provided, returns None. | |
If to many neighbors also have missing values, leave the missing value of interest unchanged. | |
@params: | |
- target = a vector of n values with missing values that you want to impute. The length has | |
to be at least n = 3. | |
- attributes = a data frame of attributes with n rows to match the target variable | |
- k_neighbors = the number of neighbors to look at to impute the missing values. It has to be a | |
value between 1 and n. | |
- aggregation_method = how to aggregate the values from the nearest neighbors (mean, median, mode) | |
Default = "mean" | |
- numeric_distances = the metric to apply to continuous attributes. | |
"euclidean" and "cityblock" available. | |
Default = "euclidean" | |
- categorical_distances = the metric to apply to binary attributes. | |
"jaccard", "hamming", "weighted-hamming" and "euclidean" | |
available. Default = "jaccard" | |
- missing_neighbors_threshold = minimum of neighbors among the k ones that are not also missing to infer | |
the correct value. Default = 0.5 | |
@returns: | |
target_completed = the vector of target values with missing value replaced. If there is a problem | |
in the parameters, return None | |
""" | |
# Get useful variables | |
possible_aggregation_method = ["mean", "median", "mode"] | |
number_observations = len(target) | |
is_target_numeric = all(isinstance(n, numbers.Number) for n in target) | |
# Check for possible errors | |
if number_observations < 3: | |
print "Not enough observations." | |
return None | |
if attributes.shape[0] != number_observations: | |
print "The number of observations in the attributes variable is not matching the target variable length." | |
return None | |
if k_neighbors > number_observations or k_neighbors < 1: | |
print "The range of the number of neighbors is incorrect." | |
return None | |
if aggregation_method not in possible_aggregation_method: | |
print "The aggregation method is incorrect." | |
return None | |
if not is_target_numeric and aggregation_method != "mode": | |
print "The only method allowed for categorical target variable is the mode." | |
return None | |
# Make sure the data are in the right format | |
target = pd.DataFrame(target) | |
attributes = pd.DataFrame(attributes) | |
# Get the distance matrix and check whether no error was triggered when computing it | |
distances = distance_matrix(attributes, numeric_distance, categorical_distance) | |
if distances is None: | |
return None | |
# Get the closest points and compute the correct aggregation method | |
for i, value in enumerate(target.iloc[:, 0]): | |
if pd.isnull(value): | |
order = distances.iloc[i,:].values.argsort()[:k_neighbors] | |
closest_to_target = target.iloc[order, :] | |
missing_neighbors = [x for x in closest_to_target.isnull().iloc[:, 0]] | |
# Compute the right aggregation method if at least more than 50% of the closest neighbors are not missing | |
if sum(missing_neighbors) >= missing_neighbors_threshold * k_neighbors: | |
continue | |
elif aggregation_method == "mean": | |
target.iloc[i] = np.ma.mean(np.ma.masked_array(closest_to_target,np.isnan(closest_to_target))) | |
elif aggregation_method == "median": | |
target.iloc[i] = np.ma.median(np.ma.masked_array(closest_to_target,np.isnan(closest_to_target))) | |
else: | |
target.iloc[i] = stats.mode(closest_to_target, nan_policy='omit')[0][0] | |
return target |
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