def plotIsoFreqNStipper(ax,freq,array,flag,par='abs',colorbar=True,colorNorm='SymLog',cLevel=True,contour=True):
indUniFreq = np.where(freq==array['freq'])
x, y = array['x'][indUniFreq],array['y'][indUniFreq]
if par == 'abs':
cmap = plt.get_cmap('OrRd_r')#seismic')
zPlot = np.abs(array[flag][indUniFreq])
if cLevel:
level = np.logspace(-4,0,33)
clevel = np.logspace(-4,0,5)
else:
level = np.linspace(zPlot.min(),zPlot.max(),100)
clevel = np.linspace(zPlot.min(),zPlot.max(),10)
if colorNorm=='SymLog':
plotNorm = colors.LogNorm()
else:
plotNorm = colors.Normalize()
elif par == 'real':
cmap = plt.get_cmap('RdYlBu')
zPlot = np.real(array[flag][indUniFreq])
if cLevel:
level = np.concatenate((-np.logspace(0,-4,33),np.logspace(-4,0,33)))
clevel = np.concatenate((-np.logspace(0,-4,5),np.logspace(-4,0,5)))
else:
level = np.linspace(zPlot.min(),zPlot.max(),100)
clevel = np.linspace(zPlot.min(),zPlot.max(),10)
if colorNorm=='SymLog':
plotNorm = colors.SymLogNorm(1e-4,linscale=2)
else:
plotNorm = colors.Normalize()
elif par == 'imag':
cmap = plt.get_cmap('RdYlBu')
zPlot = np.imag(array[flag][indUniFreq])
if cLevel:
level = np.concatenate((-np.logspace(0,-4,33),np.logspace(-4,0,33)))
clevel = np.concatenate((-np.logspace(0,-4,5),np.logspace(-4,0,5)))
else:
level = np.linspace(zPlot.min(),zPlot.max(),100)
clevel = np.linspace(zPlot.min(),zPlot.max(),10)
if colorNorm=='SymLog':
plotNorm = colors.SymLogNorm(1e-4,linscale=2)
else:
plotNorm = colors.Normalize()
if contour:
cs = ax.tricontourf(x,y,zPlot,levels=level,cmap=cmap,norm=plotNorm)#,extend='both')
else:
uniX,uniY = np.unique(x),np.unique(y)
X,Y = np.meshgrid(np.append(uniX-25,uniX[-1]+25),np.append(uniY-25,uniY[-1]+25))
cs = ax.pcolor(X,Y,np.reshape(zPlot,(len(uniY),len(uniX))),levels=level,cmap=cmap,norm=plotNorm,edgecolors='k', linewidths=0.5)
if colorbar:
plt.colorbar(cs,cax=ax.cax,ticks=clevel,format='%1.2e')
ax.set_title(flag+' '+par,fontsize=8)
def plotIsoFreqNSimpedance(
ax,
freq,
array,
flag,
par="abs",
colorbar=True,
colorNorm="SymLog",
cLevel=True,
contour=True,
):
indUniFreq = np.where(freq == array["freq"])
x, y = array["x"][indUniFreq], array["y"][indUniFreq]
if par == "abs":
zPlot = np.abs(array[flag][indUniFreq])
cmap = plt.get_cmap("OrRd_r") # seismic')
level = np.logspace(0, -5, 31)
clevel = np.logspace(0, -4, 5)
plotNorm = colors.LogNorm()
elif par == "real":
zPlot = np.real(array[flag][indUniFreq])
cmap = plt.get_cmap("RdYlBu")
if cLevel:
level = np.concatenate(
(-np.logspace(0, -10, 31), np.logspace(-10, 0, 31)))
clevel = np.concatenate(
(-np.logspace(0, -8, 5), np.logspace(-8, 0, 5)))
else:
level = np.linspace(zPlot.min(), zPlot.max(), 100)
clevel = np.linspace(zPlot.min(), zPlot.max(), 10)
if colorNorm == "SymLog":
plotNorm = colors.SymLogNorm(1e-10, linscale=2)
else:
plotNorm = colors.Normalize()
elif par == "imag":
zPlot = np.imag(array[flag][indUniFreq])
cmap = plt.get_cmap("RdYlBu")
level = np.concatenate(
(-np.logspace(0, -10, 31), np.logspace(-10, 0, 31)))
clevel = np.concatenate((-np.logspace(0, -8, 5), np.logspace(-8, 0,
5)))
plotNorm = colors.SymLogNorm(1e-10, linscale=2)
if cLevel:
level = np.concatenate(
(-np.logspace(0, -10, 31), np.logspace(-10, 0, 31)))
clevel = np.concatenate(
(-np.logspace(0, -8, 5), np.logspace(-8, 0, 5)))
else:
level = np.linspace(zPlot.min(), zPlot.max(), 100)
clevel = np.linspace(zPlot.min(), zPlot.max(), 10)
if colorNorm == "SymLog":
plotNorm = colors.SymLogNorm(1e-10, linscale=2)
elif colorNorm == "Lin":
plotNorm = colors.Normalize()
if contour:
cs = ax.tricontourf(x,
y,
zPlot,
levels=level,
cmap=cmap,
norm=plotNorm) # ,extend='both')
else:
uniX, uniY = np.unique(x), np.unique(y)
X, Y = np.meshgrid(np.append(uniX - 25, uniX[-1] + 25),
np.append(uniY - 25, uniY[-1] + 25))
cs = ax.pcolor(X,
Y,
np.reshape(zPlot, (len(uniY), len(uniX))),
cmap=cmap,
norm=plotNorm)
if colorbar:
plt.colorbar(cs, cax=ax.cax, ticks=clevel, format="%1.2e")
ax.set_title(flag + " " + par, fontsize=8)
return cs
def plotPsudoSectNSDiff(
ax,
sectDict,
arrayList,
flag,
par="abs",
colorbar=True,
colorNorm="SymLog",
cLevel=None,
contour=True,
mask=None,
useLog=False,
):
def sortInArr(arr):
return np.sort(arr, order=["freq", "x", "y", "z"])
# Find the index for the slice
indSect0 = np.where(
sectDict.values()[0] == arrayList[0][sectDict.keys()[0]])
indSect1 = np.where(
sectDict.values()[0] == arrayList[1][sectDict.keys()[0]])
# Extract and sort the mats
arr0 = sortInArr(arrayList[0][indSect0])
arr1 = sortInArr(arrayList[1][indSect1])
# Define the plot axes
if "x" in sectDict.keys()[0]:
x0 = arr0["y"]
x1 = arr1["y"]
else:
x0 = arr0["x"]
x1 = arr1["x"]
y0 = arr0["freq"]
y1 = arr1["freq"]
if par == "abs":
if useLog:
zPlot = (np.log10(np.abs(arr0[flag])) - np.log10(np.abs(
arr1[flag]))) / np.log10(np.abs(arr1[flag]))
else:
zPlot = (np.abs(arr0[flag]) - np.abs(arr1[flag])) / np.abs(
arr1[flag])
if mask:
maskInd = np.logical_or(
np.abs(arr0[flag]) < 1e-3,
np.abs(arr1[flag]) < 1e-3)
zPlot = np.ma.array(zPlot)
zPlot[maskInd] = mask
cmap = plt.get_cmap("RdYlBu") # seismic)
elif par == "ares":
arF = 1 / (8 * np.pi**2 * 10**(-7))
if useLog:
zPlot = (np.log10(
(arF / arr0["freq"]) * np.abs(arr0[flag])**2) - np.log10(
(arF / arr1["freq"]) * np.abs(arr1[flag])**2)) / np.log10(
(arF / arr1["freq"]) * np.abs(arr1[flag])**2)
else:
zPlot = ((arF / arr0["freq"]) * np.abs(arr0[flag])**2 -
(arF / arr1["freq"]) * np.abs(arr1[flag])**2) / (
(arF / arr1["freq"]) * np.abs(arr1[flag])**2)
if mask:
maskInd = np.logical_or(
np.abs(arr0[flag]) < 1e-3,
np.abs(arr1[flag]) < 1e-3)
zPlot = np.ma.array(zPlot)
zPlot[maskInd] = mask
cmap = plt.get_cmap("Spectral") # seismic)
elif par == "aphs":
if useLog:
zPlot = (np.log10(
np.arctan2(arr0[flag].imag, arr0[flag].real) *
(180 / np.pi)) - np.log10(
np.arctan2(arr1[flag].imag, arr1[flag].real) *
(180 / np.pi))) / np.log10(
np.arctan2(arr1[flag].imag, arr1[flag].real) *
(180 / np.pi))
else:
zPlot = (np.arctan2(arr0[flag].imag, arr0[flag].real) *
(180 / np.pi) -
np.arctan2(arr1[flag].imag, arr1[flag].real) *
(180 / np.pi)) / (
np.arctan2(arr1[flag].imag, arr1[flag].real) *
(180 / np.pi))
if mask:
maskInd = np.logical_or(
np.abs(arr0[flag]) < 1e-3,
np.abs(arr1[flag]) < 1e-3)
zPlot = np.ma.array(zPlot)
zPlot[maskInd] = mask
cmap = plt.get_cmap("Spectral") # seismic)
elif par == "real":
if useLog:
zPlot = (np.log10(arr0[flag].real) -
np.log10(arr1[flag].real)) / np.log10(arr1[flag].real)
else:
zPlot = (arr0[flag].real - arr1[flag].real) / arr1[flag].real
if mask:
maskInd = np.logical_or(arr0[flag].real < 1e-3,
arr1[flag].real < 1e-3)
zPlot = np.ma.array(zPlot)
zPlot[maskInd] = mask
cmap = plt.get_cmap("Spectral") # ('Spectral')
elif par == "imag":
if useLog:
zPlot = (np.log10(arr0[flag].imag) -
np.log10(arr1[flag].imag)) / np.log10(arr1[flag].imag)
else:
zPlot = (arr0[flag].imag - arr1[flag].imag) / arr1[flag].imag
if mask:
maskInd = np.logical_or(arr0[flag].imag < 1e-3,
arr1[flag].imag < 1e-3)
zPlot = np.ma.array(zPlot)
zPlot[maskInd] = mask
cmap = plt.get_cmap("Spectral") # ('RdYlBu')
if cLevel:
zMax = np.log10(cLevel[1])
zMin = np.log10(cLevel[0])
else:
zMax = np.ceil(np.log10(np.abs(zPlot).max()))
zMin = np.floor(np.log10(np.abs(zPlot).min()))
if colorNorm == "SymLog":
level = np.concatenate((
-np.logspace(
zMax, zMin - 0.125, (zMax - zMin) * 8 + 1, endpoint=True),
np.logspace(zMin - 0.125,
zMax, (zMax - zMin) * 8 + 1,
endpoint=True),
))
clevel = np.concatenate((
-np.logspace(zMax, zMin, (zMax - zMin) * 1 + 1, endpoint=True),
np.logspace(zMin, zMax, (zMax - zMin) * 1 + 1, endpoint=True),
))
plotNorm = colors.SymLogNorm(np.abs(level).min(), linscale=0.1)
elif colorNorm == "Lin":
if cLevel:
level = np.arange(cLevel[0], cLevel[1] + 0.1,
(cLevel[1] - cLevel[0]) / 50.0)
clevel = np.arange(cLevel[0], cLevel[1] + 0.1,
(cLevel[1] - cLevel[0]) / 10.0)
else:
level = np.arange(zPlot.min(), zPlot.max(),
(zPlot.max() - zPlot.min()) / 50.0)
clevel = np.arange(zPlot.min(), zPlot.max(),
(zPlot.max() - zPlot.min()) / 10.0)
plotNorm = colors.Normalize()
elif colorNorm == "Log":
level = np.logspace(zMin - 0.125,
zMax, (zMax - zMin) * 8 + 1,
endpoint=True)
clevel = np.logspace(zMin, zMax, (zMax - zMin) * 2 + 1, endpoint=True)
plotNorm = colors.LogNorm()
if contour:
cs = ax.tricontourf(
x0,
y0,
zPlot * 100,
levels=level * 100,
cmap=cmap,
norm=plotNorm,
extend="both",
) # ,extend='both')
else:
uniX, uniY = np.unique(x0), np.unique(y0)
X, Y = np.meshgrid(np.append(uniX - 25, uniX[-1] + 25),
np.append(uniY - 25, uniY[-1] + 25))
cs = ax.pcolor(X,
Y,
np.reshape(zPlot, (len(uniY), len(uniX))),
cmap=cmap,
norm=plotNorm)
if colorbar:
csB = plt.colorbar(cs, cax=ax.cax, ticks=clevel * 100, format="%1.2e")
# csB.on_mappable_changed(cs)
ax.set_title(flag + " " + par + " diff", fontsize=8)
return cs, csB
return cs, None
def plotPsudoSectNSimpedance(
ax,
sectDict,
array,
flag,
par="abs",
colorbar=True,
colorNorm="None",
cLevel=None,
contour=True,
):
indSect = np.where(sectDict.values()[0] == array[sectDict.keys()[0]])
# Define the plot axes
if "x" in sectDict.keys()[0]:
x = array["y"][indSect]
else:
x = array["x"][indSect]
y = array["freq"][indSect]
if par == "abs":
zPlot = np.abs(array[flag][indSect])
cmap = plt.get_cmap("OrRd_r") # seismic')
if cLevel:
level = np.logspace(0, -5, 31, endpoint=True)
clevel = np.logspace(0, -4, 5, endpoint=True)
else:
level = np.linspace(zPlot.min(), zPlot.max(), 100, endpoint=True)
clevel = np.linspace(zPlot.min(), zPlot.max(), 10, endpoint=True)
elif par == "ares":
zPlot = np.abs(array[flag][indSect])**2 / (8 * np.pi**2 * 10**(-7) *
array["freq"][indSect])
cmap = plt.get_cmap("RdYlBu") # seismic)
if cLevel:
zMax = np.log10(cLevel[1])
zMin = np.log10(cLevel[0])
else:
zMax = np.ceil(np.log10(np.abs(zPlot).max()))
zMin = np.floor(np.log10(np.abs(zPlot).min()))
level = np.logspace(zMin, zMax, (zMax - zMin) * 8 + 1, endpoint=True)
clevel = np.logspace(zMin, zMax, (zMax - zMin) * 2 + 1, endpoint=True)
plotNorm = colors.LogNorm()
elif par == "aphs":
zPlot = np.arctan2(array[flag][indSect].imag,
array[flag][indSect].real) * (180 / np.pi)
cmap = plt.get_cmap("RdYlBu") # seismic)
if cLevel:
zMax = cLevel[1]
zMin = cLevel[0]
else:
zMax = np.ceil(zPlot).max()
zMin = np.floor(zPlot).min()
level = np.arange(zMin, zMax + 0.1, 1)
clevel = np.arange(zMin, zMax + 0.1, 10)
plotNorm = colors.Normalize()
elif par == "real":
zPlot = np.real(array[flag][indSect])
cmap = plt.get_cmap("Spectral") # ('RdYlBu')
if cLevel:
zMax = np.log10(cLevel[1])
zMin = np.log10(cLevel[0])
else:
zMax = np.ceil(np.log10(np.abs(zPlot).max()))
zMin = np.floor(np.log10(np.abs(zPlot).min()))
level = np.concatenate((
-np.logspace(
zMax, zMin - 0.125, (zMax - zMin) * 8 + 1, endpoint=True),
np.logspace(zMin - 0.125,
zMax, (zMax - zMin) * 8 + 1,
endpoint=True),
))
clevel = np.concatenate((
-np.logspace(zMax, zMin, (zMax - zMin) * 1 + 1, endpoint=True),
np.logspace(zMin, zMax, (zMax - zMin) * 1 + 1, endpoint=True),
))
plotNorm = colors.SymLogNorm(np.abs(level).min(), linscale=0.1)
elif par == "imag":
zPlot = np.imag(array[flag][indSect])
cmap = plt.get_cmap("Spectral") # ('RdYlBu')
if cLevel:
zMax = np.log10(cLevel[1])
zMin = np.log10(cLevel[0])
else:
zMax = np.ceil(np.log10(np.abs(zPlot).max()))
zMin = np.floor(np.log10(np.abs(zPlot).min()))
level = np.concatenate((
-np.logspace(
zMax, zMin - 0.125, (zMax - zMin) * 8 + 1, endpoint=True),
np.logspace(zMin - 0.125,
zMax, (zMax - zMin) * 8 + 1,
endpoint=True),
))
clevel = np.concatenate((
-np.logspace(zMax, zMin, (zMax - zMin) * 1 + 1, endpoint=True),
np.logspace(zMin, zMax, (zMax - zMin) * 1 + 1, endpoint=True),
))
plotNorm = colors.SymLogNorm(np.abs(level).min(), linscale=0.1)
if colorNorm == "SymLog":
plotNorm = colors.SymLogNorm(np.abs(level).min(), linscale=0.1)
elif colorNorm == "Lin":
plotNorm = colors.Normalize()
elif colorNorm == "Log":
plotNorm = colors.LogNorm()
if contour:
cs = ax.tricontourf(x,
y,
zPlot,
levels=level,
cmap=cmap,
norm=plotNorm) # ,extend='both')
else:
uniX, uniY = np.unique(x), np.unique(y)
X, Y = np.meshgrid(np.append(uniX - 25, uniX[-1] + 25),
np.append(uniY - 25, uniY[-1] + 25))
cs = ax.pcolor(X,
Y,
np.reshape(zPlot, (len(uniY), len(uniX))),
cmap=cmap,
norm=plotNorm)
if colorbar:
csB = plt.colorbar(cs, cax=ax.cax, ticks=clevel, format="%1.2e")
# csB.on_mappable_changed(cs)
ax.set_title(flag + " " + par, fontsize=8)
return cs, csB
return cs, None
def plotIsoFreqNStipper(ax,
freq,
array,
flag,
par='abs',
colorbar=True,
colorNorm='SymLog',
cLevel=True,
contour=True):
indUniFreq = np.where(freq == array['freq'])
x, y = array['x'][indUniFreq], array['y'][indUniFreq]
if par == 'abs':
cmap = plt.get_cmap('OrRd_r') #seismic')
zPlot = np.abs(array[flag][indUniFreq])
if cLevel:
level = np.logspace(-4, 0, 33)
clevel = np.logspace(-4, 0, 5)
else:
level = np.linspace(zPlot.min(), zPlot.max(), 100)
clevel = np.linspace(zPlot.min(), zPlot.max(), 10)
if colorNorm == 'SymLog':
plotNorm = colors.LogNorm()
else:
plotNorm = colors.Normalize()
elif par == 'real':
cmap = plt.get_cmap('RdYlBu')
zPlot = np.real(array[flag][indUniFreq])
if cLevel:
level = np.concatenate(
(-np.logspace(0, -4, 33), np.logspace(-4, 0, 33)))
clevel = np.concatenate(
(-np.logspace(0, -4, 5), np.logspace(-4, 0, 5)))
else:
level = np.linspace(zPlot.min(), zPlot.max(), 100)
clevel = np.linspace(zPlot.min(), zPlot.max(), 10)
if colorNorm == 'SymLog':
plotNorm = colors.SymLogNorm(1e-4, linscale=2)
else:
plotNorm = colors.Normalize()
elif par == 'imag':
cmap = plt.get_cmap('RdYlBu')
zPlot = np.imag(array[flag][indUniFreq])
if cLevel:
level = np.concatenate(
(-np.logspace(0, -4, 33), np.logspace(-4, 0, 33)))
clevel = np.concatenate(
(-np.logspace(0, -4, 5), np.logspace(-4, 0, 5)))
else:
level = np.linspace(zPlot.min(), zPlot.max(), 100)
clevel = np.linspace(zPlot.min(), zPlot.max(), 10)
if colorNorm == 'SymLog':
plotNorm = colors.SymLogNorm(1e-4, linscale=2)
else:
plotNorm = colors.Normalize()
if contour:
cs = ax.tricontourf(x,
y,
zPlot,
levels=level,
cmap=cmap,
norm=plotNorm) #,extend='both')
else:
uniX, uniY = np.unique(x), np.unique(y)
X, Y = np.meshgrid(np.append(uniX - 25, uniX[-1] + 25),
np.append(uniY - 25, uniY[-1] + 25))
cs = ax.pcolor(X,
Y,
np.reshape(zPlot, (len(uniY), len(uniX))),
levels=level,
cmap=cmap,
norm=plotNorm,
edgecolors='k',
linewidths=0.5)
if colorbar:
plt.colorbar(cs, cax=ax.cax, ticks=clevel, format='%1.2e')
ax.set_title(flag + ' ' + par, fontsize=8)
def plotPsudoSectNSDiff(ax,sectDict,arrayList,flag,par='abs',colorbar=True,colorNorm='SymLog',cLevel=None,contour=True,mask=None,useLog=False):
def sortInArr(arr):
return np.sort(arr,order=['freq','x','y','z'])
# Find the index for the slice
indSect0 = np.where(sectDict.values()[0]==arrayList[0][sectDict.keys()[0]])
indSect1 = np.where(sectDict.values()[0]==arrayList[1][sectDict.keys()[0]])
# Extract and sort the mats
arr0 = sortInArr(arrayList[0][indSect0])
arr1 = sortInArr(arrayList[1][indSect1])
# Define the plot axes
if 'x' in sectDict.keys()[0]:
x0 = arr0['y']
x1 = arr1['y']
else:
x0 = arr0['x']
x1 = arr1['x']
y0 = arr0['freq']
y1 = arr1['freq']
if par == 'abs':
if useLog:
zPlot = (np.log10(np.abs(arr0[flag])) - np.log10(np.abs(arr1[flag])))/np.log10(np.abs(arr1[flag]))
else:
zPlot = (np.abs(arr0[flag]) - np.abs(arr1[flag]))/np.abs(arr1[flag])
if mask:
maskInd = np.logical_or(np.abs(arr0[flag])< 1e-3,np.abs(arr1[flag]) < 1e-3)
zPlot = np.ma.array(zPlot)
zPlot[maskInd] = mask
cmap = plt.get_cmap('RdYlBu')#seismic)
elif par == 'ares':
arF = 1/(8*np.pi**2*10**(-7))
if useLog:
zPlot = (np.log10((arF/arr0['freq'])*np.abs(arr0[flag])**2) - np.log10((arF/arr1['freq'])*np.abs(arr1[flag])**2))/np.log10((arF/arr1['freq'])*np.abs(arr1[flag])**2)
else:
zPlot = ((arF/arr0['freq'])*np.abs(arr0[flag])**2 - (arF/arr1['freq'])*np.abs(arr1[flag])**2)/((arF/arr1['freq'])*np.abs(arr1[flag])**2)
if mask:
maskInd = np.logical_or(np.abs(arr0[flag])< 1e-3,np.abs(arr1[flag]) < 1e-3)
zPlot = np.ma.array(zPlot)
zPlot[maskInd] = mask
cmap = plt.get_cmap('Spectral')#seismic)
elif par == 'aphs':
if useLog:
zPlot = (np.log10(np.arctan2(arr0[flag].imag,arr0[flag].real)*(180/np.pi)) - np.log10(np.arctan2(arr1[flag].imag,arr1[flag].real)*(180/np.pi)) )/np.log10(np.arctan2(arr1[flag].imag,arr1[flag].real)*(180/np.pi))
else:
zPlot = ( np.arctan2(arr0[flag].imag,arr0[flag].real)*(180/np.pi) - np.arctan2(arr1[flag].imag,arr1[flag].real)*(180/np.pi) )/(np.arctan2(arr1[flag].imag,arr1[flag].real)*(180/np.pi))
if mask:
maskInd = np.logical_or(np.abs(arr0[flag])< 1e-3,np.abs(arr1[flag]) < 1e-3)
zPlot = np.ma.array(zPlot)
zPlot[maskInd] = mask
cmap = plt.get_cmap('Spectral')#seismic)
elif par == 'real':
if useLog:
zPlot = (np.log10(arr0[flag].real) - np.log10(arr1[flag].real))/np.log10(arr1[flag].real)
else:
zPlot = (arr0[flag].real - arr1[flag].real)/arr1[flag].real
if mask:
maskInd = np.logical_or(arr0[flag].real< 1e-3,arr1[flag].real < 1e-3)
zPlot = np.ma.array(zPlot)
zPlot[maskInd] = mask
cmap = plt.get_cmap('Spectral') #('Spectral')
elif par == 'imag':
if useLog:
zPlot = (np.log10(arr0[flag].imag) - np.log10(arr1[flag].imag))/np.log10(arr1[flag].imag)
else:
zPlot = (arr0[flag].imag - arr1[flag].imag)/arr1[flag].imag
if mask:
maskInd = np.logical_or(arr0[flag].imag< 1e-3,arr1[flag].imag < 1e-3)
zPlot = np.ma.array(zPlot)
zPlot[maskInd] = mask
cmap = plt.get_cmap('Spectral') #('RdYlBu')
if cLevel:
zMax = np.log10(cLevel[1])
zMin = np.log10(cLevel[0])
else:
zMax = (np.ceil(np.log10(np.abs(zPlot).max())))
zMin = (np.floor(np.log10(np.abs(zPlot).min())))
if colorNorm=='SymLog':
level = np.concatenate((-np.logspace(zMax,zMin-.125,(zMax-zMin)*8+1,endpoint=True),np.logspace(zMin-.125,zMax,(zMax-zMin)*8+1,endpoint=True)))
clevel = np.concatenate((-np.logspace(zMax,zMin,(zMax-zMin)*1+1,endpoint=True),np.logspace(zMin,zMax,(zMax-zMin)*1+1,endpoint=True)))
plotNorm = colors.SymLogNorm(np.abs(level).min(),linscale=0.1)
elif colorNorm=='Lin':
if cLevel:
level = np.arange(cLevel[0],cLevel[1]+.1,(cLevel[1] - cLevel[0])/50.)
clevel = np.arange(cLevel[0],cLevel[1]+.1,(cLevel[1] - cLevel[0])/10.)
else:
level = np.arange(zPlot.min(),zPlot.max(),(zPlot.max() - zPlot.min())/50.)
clevel = np.arange(zPlot.min(),zPlot.max(),(zPlot.max() - zPlot.min())/10.)
plotNorm = colors.Normalize()
elif colorNorm=='Log':
level = np.logspace(zMin-.125,zMax,(zMax-zMin)*8+1,endpoint=True)
clevel = np.logspace(zMin,zMax,(zMax-zMin)*2+1,endpoint=True)
plotNorm = colors.LogNorm()
if contour:
cs = ax.tricontourf(x0,y0,zPlot*100,levels=level*100,cmap=cmap,norm=plotNorm,extend='both')#,extend='both')
else:
uniX,uniY = np.unique(x0),np.unique(y0)
X,Y = np.meshgrid(np.append(uniX-25,uniX[-1]+25),np.append(uniY-25,uniY[-1]+25))
cs = ax.pcolor(X,Y,np.reshape(zPlot,(len(uniY),len(uniX))),cmap=cmap,norm=plotNorm)
if colorbar:
csB = plt.colorbar(cs,cax=ax.cax,ticks=clevel*100,format='%1.2e')
# csB.on_mappable_changed(cs)
ax.set_title(flag+' '+par + ' diff',fontsize=8)
return cs, csB
return cs,None
def plotPsudoSectNSimpedance(ax,sectDict,array,flag,par='abs',colorbar=True,colorNorm='None',cLevel=None,contour=True):
indSect = np.where(sectDict.values()[0]==array[sectDict.keys()[0]])
# Define the plot axes
if 'x' in sectDict.keys()[0]:
x = array['y'][indSect]
else:
x = array['x'][indSect]
y = array['freq'][indSect]
if par == 'abs':
zPlot = np.abs(array[flag][indSect])
cmap = plt.get_cmap('OrRd_r')#seismic')
if cLevel:
level = np.logspace(0,-5,31,endpoint=True)
clevel = np.logspace(0,-4,5,endpoint=True)
else:
level = np.linspace(zPlot.min(),zPlot.max(),100,endpoint=True)
clevel = np.linspace(zPlot.min(),zPlot.max(),10,endpoint=True)
elif par == 'ares':
zPlot = np.abs(array[flag][indSect])**2/(8*np.pi**2*10**(-7)*array['freq'][indSect])
cmap = plt.get_cmap('RdYlBu')#seismic)
if cLevel:
zMax = np.log10(cLevel[1])
zMin = np.log10(cLevel[0])
else:
zMax = (np.ceil(np.log10(np.abs(zPlot).max())))
zMin = (np.floor(np.log10(np.abs(zPlot).min())))
level = np.logspace(zMin,zMax,(zMax-zMin)*8+1,endpoint=True)
clevel = np.logspace(zMin,zMax,(zMax-zMin)*2+1,endpoint=True)
plotNorm = colors.LogNorm()
elif par == 'aphs':
zPlot = np.arctan2(array[flag][indSect].imag,array[flag][indSect].real)*(180/np.pi)
cmap = plt.get_cmap('RdYlBu')#seismic)
if cLevel:
zMax = cLevel[1]
zMin = cLevel[0]
else:
zMax = (np.ceil(zPlot).max())
zMin = (np.floor(zPlot).min())
level = np.arange(zMin,zMax+.1,1)
clevel = np.arange(zMin,zMax+.1,10)
plotNorm = colors.Normalize()
elif par == 'real':
zPlot = np.real(array[flag][indSect])
cmap = plt.get_cmap('Spectral') #('RdYlBu')
if cLevel:
zMax = np.log10(cLevel[1])
zMin = np.log10(cLevel[0])
else:
zMax = (np.ceil(np.log10(np.abs(zPlot).max())))
zMin = (np.floor(np.log10(np.abs(zPlot).min())))
level = np.concatenate((-np.logspace(zMax,zMin-.125,(zMax-zMin)*8+1,endpoint=True),np.logspace(zMin-.125,zMax,(zMax-zMin)*8+1,endpoint=True)))
clevel = np.concatenate((-np.logspace(zMax,zMin,(zMax-zMin)*1+1,endpoint=True),np.logspace(zMin,zMax,(zMax-zMin)*1+1,endpoint=True)))
plotNorm = colors.SymLogNorm(np.abs(level).min(),linscale=0.1)
elif par == 'imag':
zPlot = np.imag(array[flag][indSect])
cmap = plt.get_cmap('Spectral') #('RdYlBu')
if cLevel:
zMax = np.log10(cLevel[1])
zMin = np.log10(cLevel[0])
else:
zMax = (np.ceil(np.log10(np.abs(zPlot).max())))
zMin = (np.floor(np.log10(np.abs(zPlot).min())))
level = np.concatenate((-np.logspace(zMax,zMin-.125,(zMax-zMin)*8+1,endpoint=True),np.logspace(zMin-.125,zMax,(zMax-zMin)*8+1,endpoint=True)))
clevel = np.concatenate((-np.logspace(zMax,zMin,(zMax-zMin)*1+1,endpoint=True),np.logspace(zMin,zMax,(zMax-zMin)*1+1,endpoint=True)))
plotNorm = colors.SymLogNorm(np.abs(level).min(),linscale=0.1)
if colorNorm=='SymLog':
plotNorm = colors.SymLogNorm(np.abs(level).min(),linscale=0.1)
elif colorNorm=='Lin':
plotNorm = colors.Normalize()
elif colorNorm=='Log':
plotNorm = colors.LogNorm()
if contour:
cs = ax.tricontourf(x,y,zPlot,levels=level,cmap=cmap,norm=plotNorm)#,extend='both')
else:
uniX,uniY = np.unique(x),np.unique(y)
X,Y = np.meshgrid(np.append(uniX-25,uniX[-1]+25),np.append(uniY-25,uniY[-1]+25))
cs = ax.pcolor(X,Y,np.reshape(zPlot,(len(uniY),len(uniX))),cmap=cmap,norm=plotNorm)
if colorbar:
csB = plt.colorbar(cs,cax=ax.cax,ticks=clevel,format='%1.2e')
# csB.on_mappable_changed(cs)
ax.set_title(flag+' '+par,fontsize=8)
return cs, csB
return cs,None