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Surface NMR processing and inversion GUI
Nevar pievienot vairāk kā 25 tēmas Tēmai ir jāsākas ar burtu vai ciparu, tā var saturēt domu zīmes ('-') un var būt līdz 35 simboliem gara.
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Atzars: master
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Akvo/akvo/terminal/plotKernel.py

plotKernel.py 2.3KB
Patstāvīgā saite Vēsture Neapstrādāts

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  1. import matplotlib.pyplot as plt

  2. import sys,os

  3. from pylab import meshgrid

  4. from matplotlib.colors import LightSource

  5. from matplotlib.ticker import ScalarFormatter

  6. from matplotlib.ticker import MaxNLocator

  7. from matplotlib.ticker import AutoMinorLocator

  8. from matplotlib.ticker import LogLocator

  9. from matplotlib.ticker import FormatStrFormatter

  10. import numpy as np

  11. import yaml

  12. from  akvo.tressel.lemma_yaml import *

  13. from akvo.tressel.SlidesPlot import *

  14. import cmocean 

  15. 

  16. def catLayers(K0):

  17.     K = np.zeros( (len(K0.keys()), len(K0["layer-0"].data)) , dtype=complex )

  18.     for lay in range(len(K0.keys())):

  19.         #print(K0["layer-"+str(lay)].data) #    print (lay)

  20.         K[lay] = K0["layer-"+str(lay)].data #    print (lay)

  21.     return K

  22. 

  23. if __name__ == "__main__":

  24. 

  25.     with open(sys.argv[1]) as f:

  26.         # use safe_load instead load

  27.         K0 = yaml.load(f, Loader=yaml.Loader)

  28. 

  29.     K = 1e9*catLayers(K0.K0)

  30.     q = np.array(K0.PulseI.data)* (float)(K0.Taup)

  31. 

  32.     centres = (np.array(K0.Interfaces.data[0:-1]) + np.array(K0.Interfaces.data[1::])) / 2

  33. 

  34.     fig = plt.figure( figsize=(pc2in(20),pc2in(20)) )

  35.     fig.add_axes((.2,.2,.65,.7))

  36.     #plt.pcolor(K0.Interfaces.data, K0.PulseI.data, np.abs(K))

  37.     #plt.pcolor(q, K0.Interfaces.data, np.abs(K), cmap=cmocean.cm.gray_r)

  38.     #plt.contourf(q, K0.Interfaces.data[0:-1], np.abs(K), cmap=cmocean.cm.tempo)

  39.     #plt.pcolormesh(q, K0.Interfaces.data, np.abs(K), cmap=cmocean.cm.tempo, shading='nearest')

  40.     plt.pcolormesh(q, centres, np.abs(K), cmap=cmocean.cm.tempo, shading='nearest')

  41.     plt.colorbar(label=r"$\left| \overline{\mathcal{V}_N}(0) \right|$ (nV)")

  42. 

  43.     ax1 = plt.gca()

  44.     ax1.set_ylim( ax1.get_ylim()[1], ax1.get_ylim()[0]  )

  45.     #ax1.set_xscale('log')

  46.     #ax1.set_yscale('log')

  47.     #ax1.xaxis.set_major_formatter(ScalarFormatter())

  48.     ax1.set_xticks([ax1.get_xlim()[0], 1, ax1.get_xlim()[1],])

  49.     ax1.xaxis.set_major_formatter(FormatStrFormatter('%.1f'))

  50.     #print(yaml.dump(K0.K0))

  51.     #print( K0.K0["layer-0"].data )

  52.     #print( type(  np.array(K0.K0["layer-0"].data) ) )

  53.     #plt.plot( np.real( K0.K0["layer-0"].data ) )

  54.     #plt.plot( K0.K0["layer-0"].data )

  55.     plt.gca().set_xlabel("q (A $\cdot$ s)")

  56.     plt.gca().set_ylabel("depth (m)")

  57.     plt.savefig("kernel.pdf")

  58. 

  59.     #sound = np.sum(K, axis=0)

  60.     #plt.figure()

  61.     #plt.plot(q, np.abs(sound))

  62.     #plt.savefig("sound.pdf")

  63. 

  64.     plt.show()

  65.     #print(yaml.dump(K0))