horizontalalignment='center',
rotation='horizontal')
-#savefig('harmonic-phase.pdf')
+savefig('harmonic-phase.pdf')
#
# 5 Hz basis row only
#
-fig = figure(figsize=(6.0, 2.0))
-subplots_adjust(top=0.97, bottom=0.25, left=0.10, right=0.98)
+fig = figure(figsize=(6.0, 1.5))
+subplots_adjust(top=0.95, bottom=0.28, left=0.10, right=0.98)
for name in glob('arb0-*5.0-005-*.npz'):
# ['f0', 'fs', 'vout', 'phase', 'Nperiods', 'fh', 'fsin', 'duration']
# verticalalignment='center',
# rotation='vertical')
-text(0.55, 0.02,
+text(0.55, 0.03,
'Input frequency',
size='large',
transform=fig.transFigure,
#
# 10 Hz basis row only
#
-fig = figure(figsize=(6.0, 2.0))
-subplots_adjust(top=0.97, bottom=0.25, left=0.10, right=0.98)
+fig = figure(figsize=(6.0, 1.5))
+subplots_adjust(top=0.95, bottom=0.28, left=0.10, right=0.98)
for name in glob('arb0-*5.0-010-*.npz'):
# ['f0', 'fs', 'vout', 'phase', 'Nperiods', 'fh', 'fsin', 'duration']
# verticalalignment='center',
# rotation='vertical')
-text(0.55, 0.02,
+text(0.55, 0.03,
'Input frequency',
size='large',
transform=fig.transFigure,
-x = 5.0 * arange(1, 8)
+#x = 5.0 * arange(1, 8)
-figure()
-subplot(211)
-plot(x, zphase_outs[0,:], 'o')
-plot([0, 70], [0, 0], '-k')
-ylim((-0.1, 0.8))
-xlim((4, 31))
+#figure()
+#subplot(211)
+#plot(x, zphase_outs[0,:], 'o')
+#plot([0, 70], [0, 0], '-k')
+#ylim((-0.1, 0.8))
+#xlim((4, 31))
-subplot(212)
-plot(x, zphase_outs[1,:], 'o')
-plot([0, 70], [0, 0], '-k')
-ylim((-0.1, 0.8))
-xlim((4, 31))
+#subplot(212)
+#plot(x, zphase_outs[1,:], 'o')
+#plot([0, 70], [0, 0], '-k')
+#ylim((-0.1, 0.8))
+#xlim((4, 31))
#savefig('tmp.pdf')
(5, 20),
(10, 10),
(10, 30)):
- break
fig = figure(figsize=(5.0, 3.0))
subplots_adjust(top=0.92, bottom=0.14, left=0.12, right=0.96)
xlabel(r'$\Delta \phi$, deg')
ylim((-0.8, 0.8))
- ylabel('$y_{I,%i}$ (V)' % (fsin/fh))
+ ylabel('$y_{Q,%i}$ (V)' % (fsin/fh))
if fsin/fh in (1, 3, 5):
legend(loc='lower right')