Python 共享x轴子批次对数正态分布直方图的拟合
我有三个不同长度的数组,比如Python 共享x轴子批次对数正态分布直方图的拟合,python,matplotlib,gaussian,data-fitting,Python,Matplotlib,Gaussian,Data Fitting,我有三个不同长度的数组,比如standx、standy和standz,它们只包含正值。 我想以与共享x轴类似的方式绘制它们的直方图分布(请参见编辑后的下图)。 但我希望x轴的比例为log,三个图中的箱子大小相同(后一种情况暂时可以放宽) 然后我想在log空间中用高斯函数拟合这些分布(即对数正态分布)。我总是把拟合弄得一团糟,而高斯分布实际上并不再现分布(它通常比实际分布或其他奇怪的行为平坦得多) 上次更新 以下是我设法得到的结果:拟合曲线没有按预期进行 import pyfits import
standxstandystandzloglogimport pyfits
import numpy as np
import matplotlib.pyplot as plt
from scipy import stats
from scipy.optimize import curve_fit
import pylab as py
def gaussian(x, a, mean, sigma):
return a * np.exp(-((x - mean)**2 / (2 * sigma**2)))
f, (ax1, ax2, ax3) = plt.subplots(3, sharex=True)
bins = np.histogram(standx, bins = 100)[1]
num_1, bins_1 = np.histogram(standx, np.histogram(standx, bins = 100)[1])
bins_01 = np.logspace( np.log10( standx.min() ), np.log10(standx.max() ), 100 )
x_fit = py.linspace(bins_01[0], bins_01[-1], 100)
popt, pcov = curve_fit(gaussian, x_fit, num_1, p0=[1, np.mean(standx), np.std(standx)])
y_fit = gaussian(bins_01, *popt)
counts, edges, patches = ax1.hist(standx, bins_01, facecolor='blue', alpha=0.5) # bins=100
area = sum(np.diff(edges)*counts)
# calculate length of each bin (required for scaling PDF to histogram)
bins_log_len = np.zeros( x_fit.size )
for ii in range( counts.size):
bins_log_len[ii] = edges[ii+1]-edges[ii]
# Create an array of length num_bins containing the center of each bin.
centers = 0.5*(edges[:-1] + edges[1:])
# Make a fit to the samples.
shape, loc, scale = stats.lognorm.fit(standx, floc=0)
# get pdf-values for same intervals as histogram
samples_fit_log = stats.lognorm.pdf( bins_01, shape, loc=loc, scale=scale )
# oplot fitted and scaled PDF into histogram
new_x = np.linspace(np.min(standx), np.max(standx), 100)
pdf = stats.norm.pdf(new_x, loc=np.log(scale), scale=shape)
ax1.plot(new_x, pdf*sum(counts), 'k-')
ax1.plot(bins_01, np.multiply(samples_fit_log, bins_log_len)*sum(counts), 'g--', label='PDF using histogram bins', linewidth=2 )
ax1.set_xscale('log')
ax1.plot(x_fit, stats.norm.pdf(x_fit, popt[1], popt[2])*area,'r--',linewidth=2,label='Fit: $\mu$=%.3f , $\sigma$=%.3f'%(popt[1],popt[2]) )
ax1.legend(loc='best', frameon=False, prop={'size':15})
# And similar for the ax2, ax3 plots
[ 101.51694114 118.85313212 91.69531845 90.26532237 90.28341631 105.12906896 262.7891152 486.49418076 161.05389372 163.73690191 166.77302778 222.02090477 126.19058434 86.05609479 88.91853857 193.97923929 239.15533093 106.52112332 60.84555301 88.45753752 123.02881537 124.81366349 27.19285691 104.71247832 146.07595491 106.56780994 118.54743181 182.01683537 155.86798209 212.47778143 154.97126376 91.52202431 112.49359451 164.37672439 173.27686471 209.55033453 224.81250249 117.96784525 241.48515315 90.20163858 242.82090455 195.16391416 157.28399949 236.17969925 52.60286058 153.19747048 220.8835675 160.28413028 183.82540253 78.87306634 87.7934009 29.2185999 129.05052788 105.9416127 104.47906222 303.81976836 231.82568094 234.7277374 133.87567039 84.21624497 83.77612409 100.3160127 66.60196186 93.82032598 98.88012693 235.07139859 44.74506772 90.43154857 97.83903455 56.6958664 87.39357325 80.4975729 44.50914276 80.04352253 122.69702279 181.73622079 114.35305809 72.8500753 92.97985176 167.82181244 23.89170096 277.56842175 120.27960673 188.24283156 87.85287841 104.65666064 55.56738985 113.74158901 160.78501265 144.7793944 146.26352811 72.42916164 81.58934891 82.03941082 140.62209553 98.12528712 27.80664138 60.33766399 69.16640959 76.58721414 129.2027075 92.0469369 58.65284569 74.47532813 272.38073082 25.6830871 120.49394762 153.67903201 108.99329823 73.31596785 158.44313205 108.06319404 149.67655877 100.98970685 183.89276773 259.99372599 146.67345963 151.87414015 56.50412433 68.30454916 87.91449416 136.98367718 85.89559447 146.20528695 137.48987622 119.43868024 127.65423602 95.12679396 74.19057758 37.78992221 124.93823546 76.83988791 156.26098736 52.77456371 74.56009299 72.83196226 126.33366119 114.75476007 71.07015661 203.58334989 115.37482779 112.41575426 52.67146874 34.41173382 91.43309873 84.56022527 97.52863818 64.69175291 98.82649613 110.33549604 88.73162329 63.33406042 67.50249703 51.80125226 93.77331898 134.86070329 104.78906904 180.36527776 96.10291219 73.86951609 61.85057464 85.4873267 19.49122558 94.90673405 54.70439619 44.11875268 77.00669426 106.03192447 72.14576138 32.88507942 43.71636039 69.09934896 164.33347129 184.71203014 91.85472367 112.8524319 130.65249146 93.07362972 82.04078274 77.55368682 37.01401147 95.27927068 45.84825324 78.97197286 56.51405138 55.6592834 123.75173665 146.25507348 100.94836797 148.27354976 75.66748311 249.42155118 103.90381969 96.81010983 94.77583435 68.77485119 23.38673989 88.64533289 67.76195191 177.0339476 103.49888373 101.77976527 121.43646273 150.67473968 134.80596161 110.43357052 109.31380389 46.4057108 202.95885552 368.77902191 151.79275675 84.19636911 72.80008013 46.03038795 57.46082639 53.41813204 178.14381109 135.27764511 76.58440241 71.31719469 60.19553618 27.25850013 32.44469416 22.57373214 36.81684014 27.31495127 70.17993686 142.8763359 135.88971259 72.97332852 86.41262044 64.57571923 143.87039206 155.27256205 110.78974448 151.27678795 147.15253312 52.58800732 104.08482961 79.94199525 122.04554796 110.58938546 50.32322361 77.34908774 111.69467931 166.33807553 72.91820982 79.81368763 57.5947018 103.52493188 163.77297985 144.02647916 113.26699317 147.49539845 85.72692319 30.22168157 116.74761705 74.51974655 80.10030241 75.37240728 63.55822184 243.37524675 231.9249136 113.26550804 72.43832113 55.14416523 120.54661712 147.10974035 72.92975739 69.32965749 120.95141745 37.68729105 66.24036939 203.91863535 55.8913402 95.73112443 96.24012717 176.62058262 79.31680757 162.42756296 78.39239957 169.11233776 100.20872299 62.93332374 30.91932801 38.07484721 54.18812526 172.53322492 89.52425567 84.25552157 130.99786509 94.25222458 60.10524134 62.86851886 76.52525125 59.58721735 92.13854969 174.06688353 138.10744182 194.01223744 151.1429943 140.01681885 47.14387464 11.84490967 6.96245414 47.70510341 101.54753328 108.36307095 157.82389186 166.39075768 151.60755493 65.70209698 143.84160067 126.19604257 102.22278009 45.26080872 108.46101698 158.36097588 141.08731145 83.69653695 118.36827104 118.32749524 143.7909344 37.68873242 115.57921476 139.13432742 138.44656014 94.29691791 94.18191872 85.85732773 51.69086583 66.97353588 59.40691006 95.74665069 92.3880327 75.95646049 18.87321191 54.9681136 114.54996764 131.89699216 123.48381482 72.87593216 139.98739954 122.6154045 143.29503576 271.88908663 262.73039299 155.66868313 101.36700756 216.940961 84.36613486 74.54262361 170.46092396 74.96294713 80.65423117 123.18869993 90.12445866 63.49877742 118.44434098 308.95279788 255.71401823 162.75657523 153.1426693 18.39821795 13.24170647 112.97427259 220.2135291 102.58993152 43.24075783 54.34572251 106.78667036 113.02930818 84.60049337 125.86238265 37.77423088 59.49255685 118.06299299 113.96271631 24.43862174 57.94269235 50.87677692 116.38177017 177.47487286 110.86615691 108.23451165 170.39527188 326.17663873 183.0187635 91.91273324 101.3131493 35.39369149 122.47551828 148.65749349 95.25557961 57.29064772 70.35810775 69.1915958 81.80452845 125.35745323 71.86708276 109.91184751 93.73739808 98.42700723 76.31195397 95.91546147 177.6087925 170.84268012 82.02914243 93.76613621 78.39962097 104.58703334 36.59546855 116.05663747 116.3494942 68.79781642 109.93397594 151.25008586 172.46504215 85.93646199 51.43955677 42.28647472 66.93113746 60.77211697 96.28259636 82.22735049 49.54423262 178.94159839 93.76859479 45.54744672 94.4599803 71.19930623 104.09904187 75.79761794 69.93849545 130.88921733 126.67404755 81.1833829 62.33448081 84.5987729 152.13563736 96.85621001 276.75452386 139.3158367 171.07567204 173.5501148 148.58205472 43.75713099 80.5508343 51.58395044 95.91107361 129.91845099 124.15592207 137.38840679 92.28611414 120.2618697 187.74571371 22.86841981 119.45375294 105.22286286 80.31061238 62.40199987 167.05483245 47.33392878 166.50472376 153.6375309 88.34718903 135.61514556 119.43909776 128.71538875 140.71852651 169.89867936 219.83340846 143.79419523 47.90655796 179.50489278 146.87141422 52.42075947 57.91783746 68.93906889 37.94645557 88.17616503 112.79640294 103.59258333 134.18698633 116.95667835 70.14118921 56.32427154 125.85321223 61.04903197 43.4000049 87.08489101 40.89691119 79.42038892 106.29486574 74.89994892 104.88572333 152.7553574 172.16266051 117.84344965 89.89983418 73.36633027 101.8498084 71.1734305 63.86839788 52.28033569 87.30368207 58.4308207 54.05836602 149.96873987 54.83900084 64.84848435 309.27088231 138.21289193 122.33905816 89.70053273 39.84886492 98.53375932 95.2274298 92.20005886 90.92608997 81.77090328 104.50069549 78.80647072 131.17258666 163.53527862]
我认为您需要适应日志转换的存储箱,并通过在每个存储箱上进行乘法来纠正缩放,就像上面所做的那样
您能给出一些重现您问题的示例数据吗?@DavidG,我在编辑中添加了一些数据。请将相关的导入语句添加到您的代码示例中,即py和curve_fit-它们来自何处?@jlarsch,好的,完成!你已经看过seaborn了吗?谢谢你的努力。你为什么把乘法因子设为18?拟合似乎并不符合分布。18的乘法因子只是一个猜测。我编辑了答案以便精确计算。拟合现在看起来很好,我以前忘了应用拟合参数的pdf校正,方法是将每个箱子的箱子宽度乘以,就像对样本的拟合日志一样。现在好多了?
def gaussian(x, a, mean, sigma):
return a * np.exp(-((x - mean)**2 / (2 * sigma**2)))
f, (ax1, ax2, ax3) = plt.subplots(3, sharex=True)
bins = np.histogram(standx, bins = 100)[1]
from scipy.optimize import curve_fit
from scipy import stats
num_1, bins_1 = np.histogram(standx, np.histogram(standx, bins = 100)[1])
#log transform the bins!
bins_log=np.log10(bins_1[:-1])
bins_01 = np.logspace( np.log10( standx.min() ), np.log10(standx.max() ), 100 )
x_fit = np.linspace(bins_01[0], bins_01[-1], 100)
#popt, pcov = curve_fit(gaussian, x_fit, num_1, p0=[1, np.mean(standx), np.std(standx)])
popt, pcov = curve_fit(gaussian, bins_log, num_1, p0=[1, np.mean(standx), np.std(standx)])
#y_fit = gaussian(bins_01, *popt)
y_fit = gaussian(bins_log, *popt)
counts, edges, patches = ax1.hist(standx, bins_01, facecolor='blue', alpha=0.5) # bins=100
area = sum(np.diff(edges)*counts)
# calculate length of each bin (required for scaling PDF to histogram)
bins_log_len = np.zeros( x_fit.size )
for ii in range( counts.size):
bins_log_len[ii] = edges[ii+1]-edges[ii]
# Create an array of length num_bins containing the center of each bin.
centers = 0.5*(edges[:-1] + edges[1:])
# Make a fit to the samples.
shape, loc, scale = stats.lognorm.fit(standx, floc=0)
# get pdf-values for same intervals as histogram
samples_fit_log = stats.lognorm.pdf( bins_01, shape, loc=loc, scale=scale )
# oplot fitted and scaled PDF into histogram
new_x = np.linspace(np.min(standx), np.max(standx), 100)
pdf = stats.norm.pdf(new_x, loc=np.log(scale), scale=shape)
ax1.plot(new_x, pdf*sum(counts), 'k-')
ax1.plot(bins_01, np.multiply(samples_fit_log, bins_log_len)*sum(counts), 'g--', label='PDF using histogram bins', linewidth=2 )
#ax1.plot(x_fit, stats.norm.pdf(x_fit, popt[1], popt[2])*area,'r--',linewidth=2,label='Fit: $\mu$=%.3f , $\sigma$=%.3f'%(popt[1],popt[2]) )
log_adjusted_pdf=np.multiply(bins_log_len,stats.norm.pdf(bins_log, popt[1], popt[2]))
scale_factor=len(standx)/sum(log_adjusted_pdf)
ax1.plot(bins_1[:-1], scale_factor*log_adjusted_pdf,'r--',linewidth=2,label='Fit: $\mu$=%.3f , $\sigma$=%.3f'%(popt[1],popt[2]) )
ax1.set_xscale('log')
ax1.legend(loc='best', frameon=False, prop={'size':15})
# And similar for the ax2, ax3 plots