a.flux_axis,
a.pwr - 40 - 60,
absolute(a.MagcomFilt[50, :, :]).transpose(),
auto_xlim=False,
x_min=0.33,
x_max=0.40,
auto_ylim=False,
y_min=-30 - 110,
y_max=10 - 110,
)
ax = pl.axes
ax.set_yticks(linspace(-30.0 - 110, 10.0 - 110, 3))
ax.set_xticks(linspace(0.34, 0.38, 3))
onres = 20 * log10(absolute(a.MagcomFilt[50, :, :])) + 10 - bg_A1(
a.frequency[50])
colormesh(a.flux_axis,
a.pwr - 40 - 60,
absolute(10**(onres / 20.0)).transpose(),
pl=pl,
auto_xlim=False,
x_min=0.33,
x_max=0.40,
auto_ylim=False,
y_min=-30 - 100,
y_max=10 - 100,
ylabel="Power (dBm) ",
xlabel=r"$\Phi/\Phi_0$")
#b.save_plots([pl1])
print a.pwr
print a.flux_axis.shape
b.filt.center=14
b.filt.halfwidth=5
b.fitter.fit_type="lorentzian"
b.fitter.gamma=0.05 #0.01
b.flux_axis_type="fq" #"flux"
b.end_skip=10
b.save_folder.main_dir=b.name
if __name__=="__main__":
if 1:
b.read_data()
scatter(absolute(b.MagcomFilt[50, 370, :]))
colormesh(absolute(b.MagcomFilt[50, :, :]))#.show()
onres=20*log10(absolute(b.MagcomFilt[50, 362, :]))-bg_A1(b.frequency[50])
offres=20*log10(absolute(a.MagcomFilt[50, 0, :]))-bg_A1(b.frequency[50])
scatter(b.pwr-30-60, absolute(onres-offres))
scatter(b.pwr-30-60, absolute(10**(onres/20.0)-10**(offres/20.0)))
b.magabs_colormesh()
b.ifft_plot()
b.filter_type="FFT"
#b.ifft_plot()
b.pwr_ind=0
b.magabs_colormesh()
b.pwr_ind=3
b.magabs_colormesh()
b.pwr_ind=6
b.magabs_colormesh()
line(a.frequency, angle(magfilt))
X=idt.Np*pi*(a.frequency-idt.f0)/idt.f0
#line(a.frequency, 20*log10(0.5*(sin(X)/(X))**2), pl=pl)
ifft_plot(a)#.show()
from D0317_S4A1_frq_pulse_flux import a as c
from numpy import mean
c.read_data()
print c.comment
cdata=10.0**((20.0*log10(mean(absolute(c.MagcomData[64:76, :, 0]), axis=0))-c.probe_pwr)/20.0)
pl=scatter(c.frequency, 20*log10(cdata)+10-1.0-bg_A1(c.frequency),
pl=pl, color="purple", marker="x")
#pl=scatter(c.frequency, 20*log10(mean(absolute(c.MagcomData[64:76, :, 0]), axis=0))+0*8.5-bg(c.frequency),
# pl=pl, color="purple", marker="x")
#a.save_plots([pl,])
pl.show()
if __name__=="__main__":
#b.filt_compare(a.on_res_ind)
print a.net_loss, a.rt_atten
#pl=a.magabs_colormesh()#magabs_colormesh3(s3a4_wg)
#pl=a.hann_ifft_plot()
pl=a.ifft_plot()#.show()
#cbr.set_label("$|S_{21}|$", size=8, labelpad=-10)
#cbr.set_ticks(linspace(0.0, 0.12, 2))
#plbg.axes.set_xticks(linspace(0.7, 1.5, 3))
#plbg.axes.set_yticks(linspace(4.35, 4.55, 5))
#plbg.axes.set_ylabel("Frequency (GHz)")
#plbg.axes.set_xlabel("$\Phi/\Phi_0$")
if 0:
frq1 = c.freq_axis[595]
pl.nplot = 3
flux_axis = c.flux_axis[c.flat_flux_indices]
freq_axis = c.freq_axis[c.indices]
c.filter_type = "Fit"
cdata2 = (20 * log10(c.MagAbs).transpose() -
bg_A1(c.frequency[c.indices])).transpose()
start_ind = 0
#c.magabs_colormesh(pl=plbg)
if 0:
ind = argmin(absolute(frq1 - c.freq_axis)) - 1
line(flux_axis,
10**(cdata2[ind, :] / 20.0),
pl=pl,
auto_xlim=False,
x_min=0.65,
x_max=1.5,
auto_ylim=False,
y_min=0.0,
y_max=0.12,
line(d0527.frequency/1e9, 20*log10(absolute(S13xS31))-4, color="red", pl=pl88,
auto_ylim=False, y_min=-40, y_max=0,
auto_xlim=False, x_min=4.2, x_max=4.7, xlabel="Frequency (GHz)",
ylabel="Transmission (dB)", linewidth=1.0,
)#.show()
pl88.axes.set_xticks(linspace(4.2, 4.7, 3))
pl88.axes.set_yticks(linspace(-40, 0, 5))
d0317.read_data()
cdata=10.0**((20.0*log10(mean(absolute(d0317.MagcomData[64:76, :, 0]), axis=0))-d0317.probe_pwr)/20.0)
pl88.axes.plot(d0317.frequency/1e9,
20*log10(cdata)+10-1.0-bg_A1(d0317.frequency), "x", 10,
color="green")
pl88.nplot=2
c.read_data()
c.filter_type="FFT"
print c.MagcomFilt.shape
cdata=(20*log10(absolute(c.MagcomFilt[:,:])).transpose()-bg_A4(c.frequency)).transpose()
flux_axis=c.flux_axis[c.flat_flux_indices]
freq_axis=c.freq_axis[c.indices]
#pl, pf=colormesh(flux_axis, freq_axis, (cdata[d1118.end_skip:-d1118.end_skip, :]/1.0),
# pl=pl, pf_too=True, auto_zlim=False,
# auto_xlim=False, x_min=0.35, x_max=0.5,
# auto_ylim=False, y_min=4.1, y_max=4.8, vmin=-65.0, vmax=-15.0)
x_max=4.7,
xlabel="Frequency (GHz)",
ylabel="Transmission (dB)",
linewidth=1.0,
) #.show()
pl88.axes.set_xticks(linspace(4.2, 4.7, 3))
pl88.axes.set_yticks(linspace(-40, 0, 5))
d0317.read_data()
cdata = 10.0**(
(20.0 * log10(mean(absolute(d0317.MagcomData[64:76, :, 0]), axis=0)) -
d0317.probe_pwr) / 20.0)
pl88.axes.plot(d0317.frequency / 1e9,
20 * log10(cdata) + 10 - 1.0 - bg_A1(d0317.frequency),
"x",
10,
color="green")
pl88.nplot = 2
c.read_data()
c.filter_type = "FFT"
print c.MagcomFilt.shape
cdata = (20 * log10(absolute(c.MagcomFilt[:, :])).transpose() -
bg_A4(c.frequency)).transpose()
flux_axis = c.flux_axis[c.flat_flux_indices]
freq_axis = c.freq_axis[c.indices]
#pl, pf=colormesh(flux_axis, freq_axis, (cdata[d1118.end_skip:-d1118.end_skip, :]/1.0),
# pl=pl, pf_too=True, auto_zlim=False,
# auto_xlim=False, x_min=0.35, x_max=0.5,
pl=plbg,
auto_ylim=False,
y_min=-80,
y_max=0,
auto_xlim=False,
x_min=3.85,
x_max=5.5,
xlabel="Frequency (GHz) ",
ylabel="Transmission (dB) ",
)
cdata = 10.0**(
(20.0 * log10(mean(absolute(d0317.MagcomData[64:76, :, :]), axis=0)) -
d0317.probe_pwr) / 20.0)
cdata2 = (20 * log10(cdata).transpose() + 10 - 1.0 -
bg_A1(d0317.frequency)).transpose()
#cdata=(20*log10(absolute(d0317.MagcomData[64:76, :, :])-bg_A1(c.frequency)).transpose()
# flux_axis=c.flux_axis[c.flat_flux_indices]
# freq_axis=c.freq_axis[c.indices]
plbg.nplot = 6
plbg, pfbg = colormesh(d0317.flux_axis / pi,
d0317.freq_axis,
10**(cdata2 / 20.0),
pl=plbg,
pf_too=True,
auto_zlim=False,
auto_xlim=False,
x_min=0.65 / 3.14,
x_max=1.5 / 3.14,
auto_ylim=False,
y_min=4.342,
line(d0527.frequency/1e9, 20*log10(absolute(S13*S31))-4, color="green", pl=plbg,
auto_ylim=False, y_min=-40, y_max=0,
auto_xlim=False, x_min=4.2, x_max=4.7, xlabel="Frequency (GHz)",
ylabel="Transmission (dB)",
)#.show()
#line(a.frequency, angle(magfilt))
#ifft_plot(a)#.show()
d0317.read_data()
cdata=10.0**((20.0*log10(mean(absolute(d0317.MagcomData[64:76, :, 0]), axis=0))-d0317.probe_pwr)/20.0)
scatter(d0317.frequency/1e9,
20*log10(cdata)+10-1.0-bg_A1(d0317.frequency),
pl=pl, color="purple", marker="x")
scatter(d0317.frequency/1e9,
20*log10(cdata)+10-1.0-bg_A1(d0317.frequency),
pl=plbg, color="purple", marker="x")
#a.save_plots([pl,])
#pl.show()
def ifft_plot(self, pl, plbg, **kwargs):
#process_kwargs(self, kwargs, pl="hannifft_{0}_{1}_{2}".format(self.filter_type, self.bgsub_type, self.name))
on_res=10*log10(absolute(self.filt.window_ifft(self.MagcomData[:,0])))
plbg=line(self.time_axis-0.05863, self.filt.fftshift(on_res), color="purple",
plot_name="onres_{}".format(self.on_res_ind), alpha=0.8, label="IFFT", pl=plbg, **kwargs)
#cbr=colorbar(pfbg.clt, ax=plbg.axes)
#cbr.set_label("$|S_{21}|$", size=8, labelpad=-10)
#cbr.set_ticks(linspace(0.0, 0.12, 2))
#plbg.axes.set_xticks(linspace(0.7, 1.5, 3))
#plbg.axes.set_yticks(linspace(4.35, 4.55, 5))
#plbg.axes.set_ylabel("Frequency (GHz)")
#plbg.axes.set_xlabel("$\Phi/\Phi_0$")
if 0:
frq1=c.freq_axis[595]
pl.nplot=3
flux_axis=c.flux_axis[c.flat_flux_indices]
freq_axis=c.freq_axis[c.indices]
c.filter_type="Fit"
cdata2=(20*log10(c.MagAbs).transpose()-bg_A1(c.frequency[c.indices])).transpose()
start_ind=0
#c.magabs_colormesh(pl=plbg)
if 0:
ind=argmin(absolute(frq1-c.freq_axis))-1
line(flux_axis, 10**(cdata2[ind, :]/20.0), pl=pl,
auto_xlim=False, x_min=0.65, x_max=1.5,
auto_ylim=False, y_min=0.0, y_max=0.12, color="red")
scatter(flux_axis, 10**(cdata[595, :]/20.0), pl=pl,
auto_xlim=False, x_min=0.65, x_max=1.5,
auto_ylim=False, y_min=0.0, y_max=0.12,
xlabel="$|S_{21}|$", ylabel="$\Phi/\Phi_0$")
pl.axes.set_xticks(linspace(0.7, 1.5, 3))
pl.axes.set_yticks(linspace(0.0, 0.1, 5))
X = idt.Np * pi * (a.frequency - idt.f0) / idt.f0
#line(a.frequency, 20*log10(0.5*(sin(X)/(X))**2), pl=pl)
ifft_plot(a) #.show()
from D0317_S4A1_frq_pulse_flux import a as c
from numpy import mean
c.read_data()
print c.comment
cdata = 10.0**(
(20.0 * log10(mean(absolute(c.MagcomData[64:76, :, 0]), axis=0)) -
c.probe_pwr) / 20.0)
pl = scatter(c.frequency,
20 * log10(cdata) + 10 - 1.0 - bg_A1(c.frequency),
pl=pl,
color="purple",
marker="x")
#pl=scatter(c.frequency, 20*log10(mean(absolute(c.MagcomData[64:76, :, 0]), axis=0))+0*8.5-bg(c.frequency),
# pl=pl, color="purple", marker="x")
#a.save_plots([pl,])
pl.show()
if __name__ == "__main__":
#b.filt_compare(a.on_res_ind)
print a.net_loss, a.rt_atten
#pl=a.magabs_colormesh()#magabs_colormesh3(s3a4_wg)
if 1:
print a.comment
scatter(absolute(a.MagcomFilt[50, 370, :]))
print a.frequency[50]
colormesh(absolute(a.MagcomFilt[a.end_skip:-a.end_skip, 362, :]))#.show()
pl.nplot=3
pl1=colormesh(a.flux_axis, a.pwr-40-60, absolute(a.MagcomFilt[50, :, :]).transpose(),
auto_xlim=False, x_min=0.33, x_max=0.40,
auto_ylim=False, y_min=-30-110, y_max=10-110,)
ax=pl.axes
ax.set_yticks(linspace(-30.0-110, 10.0-110, 3))
ax.set_xticks(linspace(0.34, 0.38, 3))
onres=20*log10(absolute(a.MagcomFilt[50, :, :]))+10-bg_A1(a.frequency[50])
colormesh(a.flux_axis, a.pwr-40-60, absolute(10**(onres/20.0)).transpose(),
pl=pl, auto_xlim=False, x_min=0.33, x_max=0.40,
auto_ylim=False, y_min=-30-100, y_max=10-100, ylabel="Power (dBm) ", xlabel=r"$\Phi/\Phi_0$")
#b.save_plots([pl1])
print a.pwr
print a.flux_axis.shape
#pl1.show()
pl.nplot=4
onres=20*log10(absolute(a.MagcomFilt[50, 362, :]))+10-bg_A1(a.frequency[50])
offres=20*log10(absolute(a.MagcomFilt[50, 0, :]))+10-bg_A1(a.frequency[50])
scatter(a.pwr-40-60, absolute(onres-offres))
pl_pwr_sat=scatter(a.pwr-40-60, (absolute(10**(onres/20.0)-10**(offres/20.0))), pl=pl,
auto_ylim=False, y_min=0.0, y_max=0.2, marker_size=10.0,
auto_xlim=False, x_min=-30-110, x_max=10-90, xlabel="Power (dBm)", ylabel=r"$|\Delta S_{21}|$",)#/0.18)
ax=pl.axes
