现给出一个算例:
如果人工直接求解:
现给出Python求解过程:
import numpy as np from sympy import * import math import matplotlib.pyplot as plt import mpl_toolkits.axisartist as axisartist # 定义符号 x1, x2, t = symbols(\'x1, x2, t\') def func(): # 自定义一个函数 return pow(x1, 2) + 2 * pow(x2, 2) - 2 * x1 * x2 - 2 * x2 def grad(data): # 求梯度向量,data=[data1, data2] f = func() grad_vec = [diff(f, x1), diff(f, x2)] # 求偏导数,梯度向量 grad = [] for item in grad_vec: grad.append(item.subs(x1, data[0]).subs(x2, data[1])) return grad def grad_len(grad): # 梯度向量的模长 vec_len = math.sqrt(pow(grad[0], 2) + pow(grad[1], 2)) return vec_len def zhudian(f): # 求得min(t)的驻点 t_diff = diff(f) t_min = solve(t_diff) return t_min def main(X0, theta): f = func() grad_vec = grad(X0) grad_length = grad_len(grad_vec) # 梯度向量的模长 k = 0 data_x = [0] data_y = [0] while grad_length > theta: # 迭代的终止条件 k += 1 p = -np.array(grad_vec) # 迭代 X = np.array(X0) + t*p t_func = f.subs(x1, X[0]).subs(x2, X[1]) t_min = zhudian(t_func) X0 = np.array(X0) + t_min*p grad_vec = grad(X0) grad_length = grad_len(grad_vec) print(\'grad_length\', grad_length) print(\'坐标\', X0[0], X0[1]) data_x.append(X0[0]) data_y.append(X0[1]) print(k) # 绘图 fig = plt.figure() ax = axisartist.Subplot(fig, 111) fig.add_axes(ax) ax.axis[\"bottom\"].set_axisline_style(\"-|>\", size=1.5) ax.axis[\"left\"].set_axisline_style(\"->\", size=1.5) ax.axis[\"top\"].set_visible(False) ax.axis[\"right\"].set_visible(False) plt.title(r\'$Gradient \\ method - steepest \\ descent \\ method$\') plt.plot(data_x, data_y, label=r\'$f(x_1,x_2)=x_1^2+2 \\cdot x_2^2-2 \\cdot x_1 \\cdot x_2-2 \\cdot x_2$\') plt.legend() plt.scatter(1, 1, marker=(5, 1), c=5, s=1000) plt.grid() plt.xlabel(r\'$x_1$\', fontsize=20) plt.ylabel(r\'$x_2$\', fontsize=20) plt.show() if __name__ == \'__main__\': # 给定初始迭代点和阈值 main([0, 0], 0.00001)
最终结果图如下所示:
以上就是本文的全部内容,希望对大家的学习有所帮助,也希望大家多多支持自学编程网。
