Pyspark中的过采样或SMOTE

也许这个项目对你的目标很有用：Spark SMOTE

但我认为115条记录对于随机森林来说是不够的。您可以使用其他最简单的技术，如决策树

你可以查看这个答案：

Is Random Forest suitable for very small data sets?

这是我过去使用的Pyspark和Scala smote的另一个实现。我已经将代码和referenced the source进行了对比，因为它非常小：

Pyspark：

import random
import numpy as np
from pyspark.sql import Row
from sklearn import neighbors
from pyspark.ml.feature import VectorAssembler

def vectorizerFunction(dataInput, TargetFieldName):
    if(dataInput.select(TargetFieldName).distinct().count() != 2):
        raise ValueError("Target field must have only 2 distinct classes")
    columnNames = list(dataInput.columns)
    columnNames.remove(TargetFieldName)
    dataInput = dataInput.select((','.join(columnNames)+','+TargetFieldName).split(','))
    assembler=VectorAssembler(inputCols = columnNames, outputCol = 'features')
    pos_vectorized = assembler.transform(dataInput)
    vectorized = pos_vectorized.select('features',TargetFieldName).withColumn('label',pos_vectorized[TargetFieldName]).drop(TargetFieldName)
    return vectorized

def SmoteSampling(vectorized, k = 5, minorityClass = 1, majorityClass = 0, percentageOver = 200, percentageUnder = 100):
    if(percentageUnder > 100|percentageUnder < 10):
        raise ValueError("Percentage Under must be in range 10 - 100");
    if(percentageOver < 100):
        raise ValueError("Percentage Over must be in at least 100");
    dataInput_min = vectorized[vectorized['label'] == minorityClass]
    dataInput_maj = vectorized[vectorized['label'] == majorityClass]
    feature = dataInput_min.select('features')
    feature = feature.rdd
    feature = feature.map(lambda x: x[0])
    feature = feature.collect()
    feature = np.asarray(feature)
    nbrs = neighbors.NearestNeighbors(n_neighbors=k, algorithm='auto').fit(feature)
    neighbours =  nbrs.kneighbors(feature)
    gap = neighbours[0]
    neighbours = neighbours[1]
    min_rdd = dataInput_min.drop('label').rdd
    pos_rddArray = min_rdd.map(lambda x : list(x))
    pos_ListArray = pos_rddArray.collect()
    min_Array = list(pos_ListArray)
    newRows = []
    nt = len(min_Array)
    nexs = percentageOver/100
    for i in range(nt):
        for j in range(nexs):
            neigh = random.randint(1,k)
            difs = min_Array[neigh][0] - min_Array[i][0]
            newRec = (min_Array[i][0]+random.random()*difs)
            newRows.insert(0,(newRec))
    newData_rdd = sc.parallelize(newRows)
    newData_rdd_new = newData_rdd.map(lambda x: Row(features = x, label = 1))
    new_data = newData_rdd_new.toDF()
    new_data_minor = dataInput_min.unionAll(new_data)
    new_data_major = dataInput_maj.sample(False, (float(percentageUnder)/float(100)))
    return new_data_major.unionAll(new_data_minor)

dataInput = spark.read.format('csv').options(header='true',inferSchema='true').load("sam.csv").dropna()
SmoteSampling(vectorizerFunction(dataInput, 'Y'), k = 2, minorityClass = 1, majorityClass = 0, percentageOver = 90, percentageUnder = 5)

规模：

// Import the necessary packages
import org.apache.spark.ml.feature.BucketedRandomProjectionLSH
import org.apache.spark.ml.feature.VectorAssembler
import org.apache.spark.sql.expressions.Window
import org.apache.spark.mllib.linalg.Vectors
import org.apache.spark.sql.functions.rand
import org.apache.spark.sql.functions._

object smoteClass{
  def KNNCalculation(
    dataFinal:org.apache.spark.sql.DataFrame,
    feature:String,
    reqrows:Int,
    BucketLength:Int,
    NumHashTables:Int):org.apache.spark.sql.DataFrame = {
      val b1 = dataFinal.withColumn("index", row_number().over(Window.partitionBy("label").orderBy("label")))
      val brp = new BucketedRandomProjectionLSH().setBucketLength(BucketLength).setNumHashTables(NumHashTables).setInputCol(feature).setOutputCol("values")
      val model = brp.fit(b1)
      val transformedA = model.transform(b1)
      val transformedB = model.transform(b1)
      val b2 = model.approxSimilarityJoin(transformedA, transformedB, 2000000000.0)
      require(b2.count > reqrows, println("Change bucket lenght or reduce the percentageOver"))
      val b3 = b2.selectExpr("datasetA.index as id1",
        "datasetA.feature as k1",
        "datasetB.index as id2",
        "datasetB.feature as k2",
        "distCol").filter("distCol>0.0").orderBy("id1", "distCol").dropDuplicates().limit(reqrows)
      return b3
  }

  def smoteCalc(key1: org.apache.spark.ml.linalg.Vector, key2: org.apache.spark.ml.linalg.Vector)={
    val resArray = Array(key1, key2)
    val res = key1.toArray.zip(key2.toArray.zip(key1.toArray).map(x => x._1 - x._2).map(_*0.2)).map(x => x._1 + x._2)
    resArray :+ org.apache.spark.ml.linalg.Vectors.dense(res)}

  def Smote(
    inputFrame:org.apache.spark.sql.DataFrame,
    feature:String,
    label:String,
    percentOver:Int,
    BucketLength:Int,
    NumHashTables:Int):org.apache.spark.sql.DataFrame = {
      val groupedData = inputFrame.groupBy(label).count
      require(groupedData.count == 2, println("Only 2 labels allowed"))
      val classAll = groupedData.collect()
      val minorityclass = if (classAll(0)(1).toString.toInt > classAll(1)(1).toString.toInt) classAll(1)(0).toString else classAll(0)(0).toString
      val frame = inputFrame.select(feature,label).where(label + " == " + minorityclass)
      val rowCount = frame.count
      val reqrows = (rowCount * (percentOver/100)).toInt
      val md = udf(smoteCalc _)
      val b1 = KNNCalculation(frame, feature, reqrows, BucketLength, NumHashTables)
      val b2 = b1.withColumn("ndtata", md($"k1", $"k2")).select("ndtata")
      val b3 = b2.withColumn("AllFeatures", explode($"ndtata")).select("AllFeatures").dropDuplicates
      val b4 = b3.withColumn(label, lit(minorityclass).cast(frame.schema(1).dataType))
      return inputFrame.union(b4).dropDuplicates
  }
}

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