提升算法的理论参考《统计学习方法》,本文的部分代码参考《机器学习实战》实现的。《机器学习实战》这本书上的代码很多时候是跑不通的,而且某些算法关键部分来得莫名其妙,也没说明是怎么来的,为什么那么写。本人自己实现的代码关键部分是按照《统计学习方法》这本书的理论实现的,并且通俗易懂,完全对照算法的思路和公式就可看懂。好了,废话少说,直接开始吧!
简单训练数据
def load_simple_data(): data_mat = matrix([[1.0, 2.1], [2.0, 1.1], [1.3, 1.0], [1.0, 1.0], [2.0, 1.0]]) class_labels = [1.0, 1.0, -1.0, -1.0, 1.0] return data_mat,class_labels
根据阈值判断每个特征的输出值,其中ret_array初始化时不能全-1或全1,其他任何值都可以。但是《机器学习实战》ret_array初始化为全1,我也跑过这本书上的算法,很遗憾没有得到正确的输出。
def stump_classify(data_matrix, dimen, threshval, thresh_ineq): ret_array = zeros((shape(data_matrix)[0], 1)) if(thresh_ineq == "lt"): ret_array[data_matrix[:, dimen] <= threshval] = -1.0 else: ret_array[data_matrix[:, dimen] > threshval] = 1.0 return ret_array
单层决策树的实现:lt_predicted_arr存储小于等于阈值的输出值,gt_predicted_arr存储大于阈值的输出值,最后再综合起来得到该阈值下的输出值,最后计算权重和,用字典保存相关信息。在这里《机器学习实战》和本人实现的方式很不一样,仔细看了这本书上不同的那部分实现方式,第一:不懂为什么那样写,第二:感觉书上的实现方式错的,得不到正确的输出。哪位大神能否解答我的疑惑?
def build_stump(data_arr, class_labels, D): data_matrix = mat(data_arr) label_mat = mat(class_labels).T m,n = shape(data_matrix) num_steps = 10.0 best_stump = {} best_class_est = mat(zeros((m, 1))) min_error = inf for i in range(n): range_min = data_matrix[:, i].min() range_max = data_matrix[:, i].max() step_size = (range_max - range_min) * 1.0 / num_steps for j in range(-1, int(num_steps) + 1): thresh_val = (range_min + float(j) * step_size) lt_predicted_arr = zeros((m, 1)) #获得小于不等号的值 gt_predicted_arr = zeros((m, 1)) #获得大于不等号的值 predicted_arr = zeros((m, 1)) #最终的预测值 for inequal in ["lt", "gt"]: predicted_vals = stump_classify(data_matrix, i, thresh_val, inequal) if(inequal == "lt"): lt_predicted_arr = predicted_vals else: gt_predicted_arr = predicted_vals for k in range(m): predicted_arr[k] = lt_predicted_arr[k] if(gt_predicted_arr[k] != 0): predicted_arr[k] = gt_predicted_arr[k] err_arr = mat(ones((m, 1))) err_arr[predicted_arr == label_mat] = 0 weight_error = D.T * err_arr print("min_error = %0.5f, split: dim %d, thresh %0.2f,\ the weighted error is %0.3f" %\ (min_error, i, thresh_val, weight_error)) if(weight_error < min_error): min_error = weight_error best_class_est = predicted_arr.copy() best_stump["dim"] = i best_stump["thresh"] = thresh_val best_stump["class_est"] = best_class_est return best_stump,min_error,best_class_est
根据单层决策树得到一个弱分类器保存在列表中,根据得到的弱分类器输出的预测值和原始值修改权重,减小误差小的点的权重,增大误差大的点的权重。最后误差率等于0则停止迭代。
def adaboost_train_DS(data_arr, class_labels, num_it = 40): weak_class_arr = [] m = shape(data_arr)[0] D = mat(ones((m, 1)) / m) agg_class_est = mat(zeros((m, 1))) counts = 0 for i in range(num_it): best_stump,error,class_est = build_stump(data_arr, class_labels, D) print("D: ", D.T) alpha = float(0.5 * log((1.0 - error) / error)) best_stump["alpha"] = alpha weak_class_arr.append(best_stump) print("class_est: ", class_est.T) expon = multiply(-1 * alpha * mat(class_labels).T, class_est) D = multiply(D, exp(expon)) D = D / D.sum() agg_class_est += alpha * class_est #预测值 print("agg_class_est: ", agg_class_est.T) agg_errors = multiply(sign(agg_class_est) != mat(class_labels).T, ones((m, 1))) error_rate = agg_errors.sum() / m print("total error: ", error_rate) counts += 1 if(error_rate == 0.0): break return weak_class_arr,counts
弱分类器:根据每一个弱分类器阈值,输出每个特征的输出值。
def Gx(data_matrix, reshval): m = shape(data_matrix)[0] result_data = mat(ones((m, 1))) result_data[data_matrix[:, 0] <= reshval] = -1.0 result_data[data_matrix[:, 0] > reshval] = 1.0 return result_data
根据输出数据,输出实际预测值。
def ada_classfiy(input_data, weak_class_arr, counts): data_matrix = mat(input_data) m,n = shape(data_matrix) agg_class_est = mat(zeros((m, 1))) for j in range(n): for i in range(len(weak_class_arr)): agg_class_est += (weak_class_arr[i]["alpha"] * (Gx(input_data[:, j], weak_class_arr[i]["thresh"])).T).T print(agg_class_est) return sign(agg_class_est)
画出实验结果图函数
def experiment_plot(data_matrix, agg_class_est): data_arr_in = data_matrix.getA() label_arr_in = agg_class_est.getA() m,n = shape(data_matrix) for i in range(m): if(label_arr_in[i, 0] == -1): plt.plot(data_arr_in[i, 0], data_arr_in[i, 1], "ob") elif(label_arr_in[i, 0] == 1): plt.plot(data_arr_in[i, 0], data_arr_in[i, 1], "or") plt.xlabel("X") plt.ylabel("Y") plt.show()
主函数
def main(): #D = mat(ones((5, 1)) / 5.0) data_mat,class_labels = load_simple_data() #build_stump(data_mat, class_labels, D) weak_class_arr,counts = adaboost_train_DS(data_mat, class_labels) print("**************************") data_mat2 = matrix([[1.2, 2.0], [1.0, 1.0], [0.6, 1.2], [0.8, 1.1], [1.8, 1.0], [2.0, 0.4], [1.7, 0.8], [3.5, 0.2], [2.5, 0.8], [2.8, 0.9]]) agg_class_est = ada_classfiy(data_mat2, weak_class_arr, counts) print("--------------------------") print(agg_class_est) experiment_plot(data_mat2, agg_class_est) main()
实验结果:
本文的实验结果
4.PNG
《机器学习实战》这本书的结果
5.PNG
两者对比可知,结果是一样的,但是本文的实现方法是完全不同的。
完整代码如下:
from numpy import *import numpy as npimport matplotlib.pyplot as pltdef load_simple_data(): data_mat = matrix([[1.0, 2.1], [2.0, 1.1], [1.3, 1.0], [1.0, 1.0], [2.0, 1.0]]) class_labels = [1.0, 1.0, -1.0, -1.0, 1.0] return data_mat,class_labelsdef stump_classify(data_matrix, dimen, threshval, thresh_ineq): ret_array = zeros((shape(data_matrix)[0], 1)) if(thresh_ineq == "lt"): ret_array[data_matrix[:, dimen] <= threshval] = -1.0 else: ret_array[data_matrix[:, dimen] > threshval] = 1.0 return ret_arraydef build_stump(data_arr, class_labels, D): data_matrix = mat(data_arr) label_mat = mat(class_labels).T m,n = shape(data_matrix) num_steps = 10.0 best_stump = {} best_class_est = mat(zeros((m, 1))) min_error = inf for i in range(n): range_min = data_matrix[:, i].min() range_max = data_matrix[:, i].max() step_size = (range_max - range_min) * 1.0 / num_steps for j in range(-1, int(num_steps) + 1): thresh_val = (range_min + float(j) * step_size) lt_predicted_arr = zeros((m, 1)) #获得小于不等号的值 gt_predicted_arr = zeros((m, 1)) #获得大于不等号的值 predicted_arr = zeros((m, 1)) #最终的预测值 for inequal in ["lt", "gt"]: predicted_vals = stump_classify(data_matrix, i, thresh_val, inequal) if(inequal == "lt"): lt_predicted_arr = predicted_vals else: gt_predicted_arr = predicted_vals for k in range(m): predicted_arr[k] = lt_predicted_arr[k] if(gt_predicted_arr[k] != 0): predicted_arr[k] = gt_predicted_arr[k] err_arr = mat(ones((m, 1))) err_arr[predicted_arr == label_mat] = 0 weight_error = D.T * err_arr print("min_error = %0.5f, split: dim %d, thresh %0.2f,\ the weighted error is %0.3f" %\ (min_error, i, thresh_val, weight_error)) if(weight_error < min_error): min_error = weight_error best_class_est = predicted_arr.copy() best_stump["dim"] = i best_stump["thresh"] = thresh_val best_stump["class_est"] = best_class_est return best_stump,min_error,best_class_estdef adaboost_train_DS(data_arr, class_labels, num_it = 40): weak_class_arr = [] m = shape(data_arr)[0] D = mat(ones((m, 1)) / m) agg_class_est = mat(zeros((m, 1))) counts = 0 for i in range(num_it): best_stump,error,class_est = build_stump(data_arr, class_labels, D) print("D: ", D.T) alpha = float(0.5 * log((1.0 - error) / error)) best_stump["alpha"] = alpha weak_class_arr.append(best_stump) print("class_est: ", class_est.T) expon = multiply(-1 * alpha * mat(class_labels).T, class_est) D = multiply(D, exp(expon)) D = D / D.sum() agg_class_est += alpha * class_est #预测值 print("agg_class_est: ", agg_class_est.T) agg_errors = multiply(sign(agg_class_est) != mat(class_labels).T, ones((m, 1))) error_rate = agg_errors.sum() / m print("total error: ", error_rate) counts += 1 if(error_rate == 0.0): break return weak_class_arr,countsdef Gx(data_matrix, reshval): m = shape(data_matrix)[0] result_data = mat(ones((m, 1))) result_data[data_matrix[:, 0] <= reshval] = -1.0 result_data[data_matrix[:, 0] > reshval] = 1.0 return result_datadef ada_classfiy(input_data, weak_class_arr, counts): data_matrix = mat(input_data) m,n = shape(data_matrix) agg_class_est = mat(zeros((m, 1))) for j in range(n): for i in range(len(weak_class_arr)): agg_class_est += (weak_class_arr[i]["alpha"] * (Gx(input_data[:, j], weak_class_arr[i]["thresh"])).T).T print(agg_class_est) return sign(agg_class_est)def experiment_plot(data_matrix, agg_class_est): data_arr_in = data_matrix.getA() label_arr_in = agg_class_est.getA() m,n = shape(data_matrix) for i in range(m): if(label_arr_in[i, 0] == -1): plt.plot(data_arr_in[i, 0], data_arr_in[i, 1], "ob") elif(label_arr_in[i, 0] == 1): plt.plot(data_arr_in[i, 0], data_arr_in[i, 1], "or") plt.xlabel("X") plt.ylabel("Y") plt.show()def main(): #D = mat(ones((5, 1)) / 5.0) data_mat,class_labels = load_simple_data() #build_stump(data_mat, class_labels, D) weak_class_arr,counts = adaboost_train_DS(data_mat, class_labels) print("**************************") data_mat2 = matrix([[1.2, 2.0], [1.0, 1.0], [0.6, 1.2], [0.8, 1.1], [1.8, 1.0], [2.0, 0.4], [1.7, 0.8], [3.5, 0.2], [2.5, 0.8], [2.8, 0.9]]) agg_class_est = ada_classfiy(data_mat2, weak_class_arr, counts) print("--------------------------") print(agg_class_est) experiment_plot(data_mat2, agg_class_est) main()
总结:在学习机器学习算法的过程中,先自己分析理论,看懂书上的代码为什么那么写,一步一步对照算法的思路理解代码。如果遇到无法运行的代码,自己根据算法的思路和理论修改代码,调试。有时间的话,可以自己把算法实现一遍。
作者:幸福洋溢的季节
链接:https://www.jianshu.com/p/2ea2f4ec121c