k-近邻算法(KNN)
将一个32x32的二进制图像矩阵转化为1x1024的向量。
函数img2vector,将图像转化为向量,该函数创建1x1024的数组,然后打开给定的文件,循环读出文件的前32行,并将每行的头32个字值存储在NumPy数组种,最后返回数组。
#将图像文本数据转换为向量 def img2vector(filename): returnVect = zeros((1,1024)) fr = open(filename) for i in range(32): lineStr = fr.readline() for j in range(32): returnVect[0,32*i+j] = int(lineStr[j]) return returnVect
将这些数据输入到分类器,检测分类器的执行效果。
#测试算法 def handwritingClassTest(): hwLabels = [] trainingFileList = listdir('trainingDigits') #加载训练集 m = len(trainingFileList) trainingMat = zeros((m,1024)) for i in range(m): fileNameStr = trainingFileList[i] fileStr = fileNameStr.split('.')[0] classNumStr = int(fileStr.split('_')[0]) hwLabels.append(classNumStr) trainingMat[i,:] = img2vector('trainingDigits/%s' % fileNameStr) testFileList = listdir('testDigits') #遍历 errorCount = 0.0 mTest = len(testFileList) for i in range(mTest): fileNameStr = testFileList[i] fileStr = fileNameStr.split('.')[0] classNumStr = int(fileStr.split('_')[0]) vectorUnderTest = img2vector('testDigits/%s' % fileNameStr) classifierResult = classify0(vectorUnderTest, trainingMat, hwLabels, 3) print "the classifier came back with: %d, the real answer is: %d" % (classifierResult, classNumStr) if (classifierResult != classNumStr): errorCount += 1.0 print "\nthe total number of errors is: %d" % errorCount print "\nthe total error rate is: %f" % (errorCount/float(mTest))
classify0)()函数有4个参数:用于分类的输入向量是inX,训练集为dataSet,标签向量为labels,,k表示用于选择最近邻居的数目,其中标签向量的元素数目和矩阵dataSet的行数相同。
def classify0(inX, dataSet, labels, k): dataSetSize = dataSet.shape[0] diffMat = tile(inX, (dataSetSize,1)) - dataSet #把inX二维数组化,dataSetSize表示生成数组后的行数,1表示列的倍数。实现了矩阵之间的减法。 sqDiffMat = diffMat**2 sqDistances = sqDiffMat.sum(axis=1)。#axis=1:参数等于1,矩阵中行之间的数的求和 distances = sqDistances**0.5 sortedDistIndicies = distances.argsort() #argsort():对一个数组进行非降序排序 classCount={} for i in range(k): voteIlabel = labels[sortedDistIndicies[i]] #访问下标键为voteIlabel的项 classCount[voteIlabel] = classCount.get(voteIlabel,0) + 1 sortedClassCount = sorted(classCount.iteritems(), key=operator.itemgetter(1), reverse=True) return sortedClassCount[0][0]
代码
from numpy import * import operator from os import listdir def classify0(inX, dataSet, labels, k): dataSetSize = dataSet.shape[0] diffMat = tile(inX, (dataSetSize,1)) - dataSet #把inX二维数组化,dataSetSize表示生成数组后的行数,1表示列的倍数。实现了矩阵之间的减法。 sqDiffMat = diffMat**2 sqDistances = sqDiffMat.sum(axis=1)。#axis=1:参数等于1,矩阵中行之间的数的求和 distances = sqDistances**0.5 sortedDistIndicies = distances.argsort() #argsort():对一个数组进行非降序排序 classCount={} for i in range(k): voteIlabel = labels[sortedDistIndicies[i]] #访问下标键为voteIlabel的项 classCount[voteIlabel] = classCount.get(voteIlabel,0) + 1 sortedClassCount = sorted(classCount.iteritems(), key=operator.itemgetter(1), reverse=True) return sortedClassCount[0][0] #将图像文本数据转换为向量 def img2vector(filename): returnVect = zeros((1,1024)) fr = open(filename) for i in range(32): lineStr = fr.readline() for j in range(32): returnVect[0,32*i+j] = int(lineStr[j]) return returnVect #测试算法 def handwritingClassTest(): hwLabels = [] trainingFileList = listdir('trainingDigits') #加载训练集 m = len(trainingFileList) trainingMat = zeros((m,1024)) for i in range(m): fileNameStr = trainingFileList[i] fileStr = fileNameStr.split('.')[0] classNumStr = int(fileStr.split('_')[0]) hwLabels.append(classNumStr) trainingMat[i,:] = img2vector('trainingDigits/%s' % fileNameStr) testFileList = listdir('testDigits') #遍历 errorCount = 0.0 mTest = len(testFileList) for i in range(mTest): fileNameStr = testFileList[i] fileStr = fileNameStr.split('.')[0] classNumStr = int(fileStr.split('_')[0]) vectorUnderTest = img2vector('testDigits/%s' % fileNameStr) classifierResult = classify0(vectorUnderTest, trainingMat, hwLabels, 3) print "the classifier came back with: %d, the real answer is: %d" % (classifierResult, classNumStr) if (classifierResult != classNumStr): errorCount += 1.0 print "\nthe total number of errors is: %d" % errorCount print "\nthe total error rate is: %f" % (errorCount/float(mTest))