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这篇文章将为大家详细讲解有关如何利用python做数据拟合,小编觉得挺实用的,因此分享给大家做个参考,希望大家阅读完这篇文章后可以有所收获。
出处:
SciPy v1.1.0 Reference Guide
#Header import numpy as np import matplotlib.pyplot as plt from scipy.optimize import curve_fit #Define a function(here a exponential function is used) def func(x, a, b, c): return a * np.exp(-b * x) + c #Create the data to be fit with some noise xdata = np.linspace(0, 4, 50) y = func(xdata, 2.5, 1.3, 0.5) np.random.seed(1729) y_noise = 0.2 * np.random.normal(size=xdata.size) ydata = y + y_noise plt.plot(xdata, ydata, 'bo', label='data') #Fit for the parameters a, b, c of the function func: popt, pcov = curve_fit(func, xdata, ydata) popt #output: array([ 2.55423706, 1.35190947, 0.47450618]) plt.plot(xdata, func(xdata, *popt), 'r-', label='fit: a=%5.3f, b=%5.3f, c=%5.3f' % tuple(popt)) #In the case of parameters a,b,c need be constrainted #Constrain the optimization to the region of #0 <= a <= 3, 0 <= b <= 1 and 0 <= c <= 0.5 popt, pcov = curve_fit(func, xdata, ydata, bounds=(0, [3., 1., 0.5])) popt #output: array([ 2.43708906, 1. , 0.35015434]) plt.plot(xdata, func(xdata, *popt), 'g--', label='fit: a=%5.3f, b=%5.3f, c=%5.3f' % tuple(popt)) #Labels plt.title("Exponential Function Fitting") plt.xlabel('x coordinate') plt.ylabel('y coordinate') plt.legend() leg = plt.legend() # remove the frame of Legend, personal choice leg.get_frame().set_linewidth(0.0) # remove the frame of Legend, personal choice #leg.get_frame().set_edgecolor('b') # change the color of Legend frame #plt.show() #Export figure #plt.savefig('fit1.eps', format='eps', dpi=1000) plt.savefig('fit1.pdf', format='pdf', dpi=1000, figsize=(8, 6), facecolor='w', edgecolor='k') plt.savefig('fit1.jpg', format='jpg', dpi=1000, figsize=(8, 6), facecolor='w', edgecolor='k')
上面一段代码可以直接在spyder中运行。得到的JPG导出图如下:
出处:LMFIT: Non-Linear Least-Squares Minimization and Curve-Fitting for Python
#Header import numpy as np import matplotlib.pyplot as plt from numpy import exp, linspace, random from scipy.optimize import curve_fit #Define the Gaussian function def gaussian(x, amp, cen, wid): return amp * exp(-(x-cen)**2 / wid) #Create the data to be fitted x = linspace(-10, 10, 101) y = gaussian(x, 2.33, 0.21, 1.51) + random.normal(0, 0.2, len(x)) np.savetxt ('data.dat',[x,y]) #[x,y] is is saved as a matrix of 2 lines #Set the initial(init) values of parameters need to optimize(best) init_vals = [1, 0, 1] # for [amp, cen, wid] #Define the optimized values of parameters best_vals, covar = curve_fit(gaussian, x, y, p0=init_vals) print(best_vals) # output: array [2.27317256 0.20682276 1.64512305] #Plot the curve with initial parameters and optimized parameters y1 = gaussian(x, *best_vals) #best_vals, '*'is used to read-out the values in the array y2 = gaussian(x, *init_vals) #init_vals plt.plot(x, y, 'bo',label='raw data') plt.plot(x, y1, 'r-',label='best_vals') plt.plot(x, y2, 'k--',label='init_vals') #plt.show() #Labels plt.title("Gaussian Function Fitting") plt.xlabel('x coordinate') plt.ylabel('y coordinate') plt.legend() leg = plt.legend() # remove the frame of Legend, personal choice leg.get_frame().set_linewidth(0.0) # remove the frame of Legend, personal choice #leg.get_frame().set_edgecolor('b') # change the color of Legend frame #plt.show() #Export figure #plt.savefig('fit2.eps', format='eps', dpi=1000) plt.savefig('fit2.pdf', format='pdf', dpi=1000, figsize=(8, 6), facecolor='w', edgecolor='k') plt.savefig('fit2.jpg', format='jpg', dpi=1000, figsize=(8, 6), facecolor='w', edgecolor='k')
上面一段代码可以直接在spyder中运行。得到的JPG导出图如下:
需要下载lmfit这个包,下载地址:
https://pypi.org/project/lmfit/#files
下载下来的文件是.tar.gz格式,在MacOS及Linux命令行中解压,指令:
将其中的lmfit文件夹复制到当前project目录下。
上述例子2中生成了data.dat,用来作为接下来的方法中的原始数据。
出处:
Modeling Data and Curve Fitting
#Header import numpy as np import matplotlib.pyplot as plt from numpy import exp, loadtxt, pi, sqrt from lmfit import Model #Import the data and define x, y and the function data = loadtxt('data.dat') x = data[0, :] y = data[1, :] def gaussian1(x, amp, cen, wid): return (amp / (sqrt(2*pi) * wid)) * exp(-(x-cen)**2 / (2*wid**2)) #Fitting gmodel = Model(gaussian1) result = gmodel.fit(y, x=x, amp=5, cen=5, wid=1) #Fit from initial values (5,5,1) print(result.fit_report()) #Plot plt.plot(x, y, 'bo',label='raw data') plt.plot(x, result.init_fit, 'k--',label='init_fit') plt.plot(x, result.best_fit, 'r-',label='best_fit') #plt.show() #Labels plt.title("Gaussian Function Fitting") plt.xlabel('x coordinate') plt.ylabel('y coordinate') plt.legend() leg = plt.legend() # remove the frame of Legend, personal choice leg.get_frame().set_linewidth(0.0) # remove the frame of Legend, personal choice #leg.get_frame().set_edgecolor('b') # change the color of Legend frame #plt.show() #Export figure #plt.savefig('fit3.eps', format='eps', dpi=1000) plt.savefig('fit3.pdf', format='pdf', dpi=1000, figsize=(8, 6), facecolor='w', edgecolor='k') plt.savefig('fit3.jpg', format='jpg', dpi=1000, figsize=(8, 6), facecolor='w', edgecolor='k')
上面这一段代码需要按指示下载lmfit包,并且读取例子2中生成的data.dat
。
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