subplot(212) grid() plot(xpOverCoupled, ypOverCoupled / pi, xpOverCoupled, fitfunc2(p2, xpOverCoupled) / pi, '--') # ylim([-13,1]) yticks([.3, .1, -.1, -.3], ('0.3$\pi$', '0.1$\pi$', '-0.1$\pi$', '-0.3$\pi$')) ylabel('Phase (rad)') xlabel('Wavelength (nm)') # legend( ('data', 'fit') ) # plot(xpOverCoupled,ypOverCoupled,xpOverCoupled,unwrap(fitfunc2(p0,xpOverCoupled))) NO Es capaz de fitear la fase # title('Fit') amp = '/home/joaquin/Documents/reports/20121025_dispersionAnillos_/data/linearV740D9_TMrings_TErings.dat' xa, ya = importaa(amp) fitfunc = lambda p, x: field2dBnormalized( ring(x * 1e-9, p[0], p[1], p[2], p[3])) # Target function errfunc = lambda p, x, y: fitfunc(p, x ) - y # Distance to the target function index1560 = where(xa[10] > 1560)[0][0] # index1560=-1 indexTrace = 12 indexTraceNoRing = 11 xaOverCoupled = xa[indexTrace][0:index1560] yaOverCoupled = (ya[indexTrace][0:index1560] - interp(xa[indexTrace][0:index1560], xa[indexTraceNoRing], ya[indexTraceNoRing]))
def main(): #overcoupled ring amplitude is trace number 10 phase = 'dispersionV740D9_TMringsTErings.dat' xphase, yphase = importap(phase) indexTrace = 12 indexTraceNoRing = 13 index1560 = where(xphase[indexTrace] > 1560)[0][0] xp = xphase[indexTrace][0:index1560] yp = yphase[indexTrace][0:index1560] dataShift = 21 yp = -yphase[indexTrace][0:index1560] + interp( xphase[indexTrace][dataShift:index1560 + dataShift], xphase[indexTraceNoRing], yphase[indexTraceNoRing]) amp = 'linearV740D9_TMrings_TErings.dat' xamp, yamp = importaa(amp) indexTraceNoRing = 11 indexTrace = 10 index1560 = where(xamp[10] > 1560)[0][0] xa = xamp[indexTrace][0:index1560] ya = 10**((yamp[indexTrace][0:index1560] - interp(xamp[indexTrace][0:index1560], xamp[indexTraceNoRing], yamp[indexTraceNoRing])) / 20) ya = ya / max(ya) x = xa y = ya * exp(1j * yp) fitfunc = lambda p, x: ring(x * 1e-9, p[0], p[1], p[2], p[ 3]) # Target function ring(x,phi=0,k=0.3,A=0.99,ng=4.36,R=20e-6) errfunc = lambda p, x, y: abs(real(fitfunc(p, x) - y)) + abs( imag(fitfunc(p, x) - y)) # Distance to the target function p0 = [3, 0.3, .9, 4.3526515] # Initial guess for the parameters p1, success = optimize.leastsq(errfunc, p0[:], args=(x, y)) ax1 = subplot(211) plot(x, abs(y), '-', x, abs(fitfunc(p1, x)), '--') ylabel('Transmission') ax1.yaxis.set_label_coords(-0.1, 0.5) title( '$ 200nm-gap $ Overcoupled ring ($k=0.350$, $\mathrm{A=0.963}$, $n_g=4.36$)' ) # yticks(arange(0,1.1,0.2),('0','','','','','1')) yticks([0, 1], ('0', '1')) xticks([1530, 1560], ['', '']) # xticks(arange(1530,1561,5),repeat('',shape(arange(1530,1561,5))[-1])) print 'p0 = [phi,k,A,ng] = ', p0 print 'p1 = [phi,k,A,ng] = ', p1 a = p1[2] print 'losses = ', -log(a) / pi / (20e-6 * 100) * 10 / log(10) print 20 * log10(p1[2]) / (2 * pi * 20e-6 * 100) # a=exp(-alfa*L/2)=exp(-alfa*2*pi*R/2)=exp(-alfa*pi*R) # log(a)=-alfa*pi*R # alfa = -log(a)/pi/R [m^-1] print -log(a) / pi / 20e-4 print 20 * log10((p1[2]) / (2 * pi * 20e-6 * 100)) ax2 = subplot(212) ax2.yaxis.grid(True) plot(x, -unwrap(angle(y)) / pi, x, -unwrap(angle(fitfunc(p1, x))) / pi, '--') ylabel('Phase (rad)') ola = ax2.yaxis.set_label_coords(-0.1, 0.5) xlabel('Wavelength (nm)') legend(('data', 'fit'), loc=8) yticks( [0, 2, 4, 6, 8, 10, 12], ('$0$', '$2\pi$', '$4\pi$', '$6\pi$', '$8\pi$', '$10\pi$', '$12\pi$')) # xticks(arange(1530,1561,5),['1530','','','','','','1560']) xticks([1530, 1560], ['1530', '1560']) savefig('r20g200TE_fitPhaseAmp.eps') show() return
def main(): #corrugated 6 (27\mum)','corrugated 1 (450\mum) x6, y6 = importap( '/home/joaquin/Dropbox/reports/20110724_DispersionSara/dataJoaquin/corrugada6_setbottom_scan_all.dat', [0]) x1, y1 = importap( '/home/joaquin/Dropbox/reports/20110724_DispersionSara/dataJoaquin/corrugada1_setbottom_C11_Pin=-1.dat', [0]) c = 3e8 x1t = x1[0][31:300] # from 1569 to 1596~nm y1t = y1[0][31:300] x6t = x6[0] y6t = y6[0] w1 = 2 * pi * c / (x1t * 1e-9) - 2 * pi * c / 1574e-9 yw1 = y1t w6 = 2 * pi * c / (x6t * 1e-9) - 2 * pi * c / 1564e-9 yw6 = y6t xmin = 1e-6 * array([ 1.563778713098983, 1.564429468006409, 1.565494339673106, 1.566559211339802, 1.568038199765770, 1.569517188191737, 1.571232814765860, 1.573007600877021, 1.575196503747453, 1.577267087543807, 1.579810947636471, 1.581999850506903, 1.584129593840296, 1.586495975321844, 1.588684878192276, 1.591051259673824, 1.592589407636830, 1.595014948655417, 1.596553096618423, 1.598327882729584, 1.599511073470358, 1.600990061896326, 1.602232412174138, 1.603297283840835, 1.604184676896416 ]) x = linspace(min(xmin), max(xmin), len(yw6)) w = 2 * pi * 3e8 / x - 2 * pi * 3e8 / 1574e-9 orderPol = 5 p1 = polyfit(w1, yw1, orderPol) p6 = polyfit(w6, yw6, orderPol) figure(2) plot(x1t, yw1, x6t, yw6, x1t, polyval(p1, w1), x6t, polyval(p6, w6), x1t, polyval(p1 - p6, w1)) figure(3) subplot(212) plot(x * 1e9, 7.8 - c / 423e-6 * polyval(polyder(p1 - p6), w), 'b-') ax = subplot(211) ax.set_title( '(a)', ha='left', ) aa = '/home/joaquin/Dropbox/reports/20121025_dispersionAnillos/data/linear_santec0dBm_V740_C11_MiddleSet_18deg_corrugadas_Antoine.dat' xmzi, ymzi = importaa(aa, [0, 1], 0) xmin = 1e-6 * array([ 1.563778713098983, 1.564429468006409, 1.565494339673106, 1.566559211339802, 1.568038199765770, 1.569517188191737, 1.571232814765860, 1.573007600877021, 1.575196503747453, 1.577267087543807, 1.579810947636471, 1.581999850506903, 1.584129593840296, 1.586495975321844, 1.588684878192276, 1.591051259673824, 1.592589407636830, 1.595014948655417, 1.596553096618423, 1.598327882729584, 1.599511073470358, 1.600990061896326, 1.602232412174138, 1.603297283840835, 1.604184676896416 ]) ymin = array([ -30.112883270882282, -30.319110314265075, -31.040904966104854, -32.037669009121686, -33.137546573829916, -34.031197095155349, -35.612271094423434, -37.090231572000121, -37.708912702148496, -41.420999483038770, -42.658361743335533, -42.830217612821194, -48.054636045185291, -44.273806916500746, -47.848409001802494, -46.164221480843018, -47.917151349596757, -49.223255957687783, -48.707688349230800, -50.976185826441522, -51.801093999972693, -51.251155217618582, -51.319897565412845, -53.554023868726439, -51.732351652178437 ]) xmax = 1e-6 * array([ 1.564133670321216, 1.564961903839758, 1.566026775506454, 1.567150806710189, 1.568748114210234, 1.570227102636202, 1.571942729210324, 1.574249951154833, 1.576083896803033, 1.578331959210504, 1.580757500229090, 1.583301360321754, 1.585312784581070, 1.587383368377425, 1.589868068933050, 1.591997812266443, 1.593890917451682, 1.595665703562843, 1.597440489674004, 1.598682839951816, 1.600161828377784, 1.601640816803751, 1.602764848007487, 1.603474762451951, 1.604598793655686 ]) ymax = array([ -29.700429184116697, -29.597315662425299, -29.562944488528167, -30.112883270882282, -29.459830966836773, -29.666058010219565, -30.284739140367943, -31.144018487796249, -31.762699617944627, -32.793834834858593, -33.378144791109840, -34.306166486332408, -34.924847616480790, -36.987118050308723, -37.468314484868571, -39.221244353622311, -40.939803048478922, -41.317885961347379, -43.620754612455229, -43.792610481940898, -47.092243176065587, -47.332841393345511, -47.092243176065587, -47.882780175699622, -50.701216435264470 ]) xlim(1563, 1605) ylim(-55, -29) xticks([1570, 1600], ('', '')) yticks([-30, -55], ( '-30', '-55', )) ylabel('Transmission (dB)') ax.yaxis.set_label_coords(-0.1, 0.5) plot(xmzi[0], ymzi[0], 'b-', xmin * 1e9, ymin, 'go', xmax * 1e9, ymax, 'go') legend() ax2 = subplot(212) title('(b)') ng2 = (xmin * xmax) / 2 / 450e-6 / abs(xmin - xmax) + 4.36 plot(xmin * 1e9, ng2, 'go') xlabel('Wavelength (nm)') ylabel('Group index') xticks([1570, 1600], ('1570', '1600')) yticks([7, 9, 11, 13], ('7', '9', '11', '13')) xlim(1563, 1605) ylim([6, 14]) legend(('Heterodyne', 'fringes'), loc=9) savefig('gropIndexComparison_2.png') savefig('gropIndexComparison_2.eps') show() return
def main(): #corrugated 6 (27\mum)','corrugated 1 (450\mum) xmin = 1e-6 * array([ 1.563778713098983, 1.564429468006409, 1.565494339673106, 1.566559211339802, 1.568038199765770, 1.569517188191737, 1.571232814765860, 1.573007600877021, 1.575196503747453, 1.577267087543807, 1.579810947636471, 1.581999850506903, 1.584129593840296, 1.586495975321844, 1.588684878192276, 1.591051259673824, 1.592589407636830, 1.595014948655417, 1.596553096618423, 1.598327882729584, 1.599511073470358, 1.600990061896326, 1.602232412174138, 1.603297283840835, 1.604184676896416 ]) x6, y6 = importap( '/home/joaquin/Dropbox/reports/20110724_DispersionSara/dataJoaquin/corrugada6_setbottom_scan_all.dat', [0]) x1, y1 = importap( '/home/joaquin/Dropbox/reports/20110724_DispersionSara/dataJoaquin/corrugada1_setbottom_C11_Pin=-1.dat', [0]) c = 3e8 x1t = x1[0][31:300] # from 1569 to 1596~nm y1t = y1[0][31:300] x6t = x6[0] y6t = y6[0] w1 = 2 * pi * c / (x1t * 1e-9) - 2 * pi * c / 1574e-9 yw1 = y1t w6 = 2 * pi * c / (x6t * 1e-9) - 2 * pi * c / 1564e-9 yw6 = y6t figure(1) plot(x1t, y1t, x6t, y6t) orderPol = 5 p1 = polyfit(w1, yw1, orderPol) p6 = polyfit(w6, yw6, orderPol) figure(2) plot(w1, yw1, w6, yw6, w1, polyval(p1, w1), w6, polyval(p6, w6), w1, polyval(p1 - p6, w1)) figure(3) subplot(211) p = polyfit(w6, (interp(w6, w1, yw1) - yw6) / 423e-6, orderPol) # plot(x1t,7.8-1/423e-6*polyval(polyder(p1-p6),w1)) plot(x1t, 7.8 - c / 423e-6 * polyval(polyder(p1 - p6), w1)) subplot(212) aa = '/home/joaquin/Dropbox/reports/20121025_dispersionAnillos/data/linear_santec0dBm_V740_C11_MiddleSet_18deg_corrugadas_Antoine.dat' xmzi, ymzi = importaa(aa, [0, 1], 0) # from scipy.io import loadmat # loadmat('/home/joaquin/Dropbox/samples/V740/linear/maxYminCorr1001.mat') xmin = 1e-6 * array([ 1.563778713098983, 1.564429468006409, 1.565494339673106, 1.566559211339802, 1.568038199765770, 1.569517188191737, 1.571232814765860, 1.573007600877021, 1.575196503747453, 1.577267087543807, 1.579810947636471, 1.581999850506903, 1.584129593840296, 1.586495975321844, 1.588684878192276, 1.591051259673824, 1.592589407636830, 1.595014948655417, 1.596553096618423, 1.598327882729584, 1.599511073470358, 1.600990061896326, 1.602232412174138, 1.603297283840835, 1.604184676896416 ]) ymin = array([ -30.112883270882282, -30.319110314265075, -31.040904966104854, -32.037669009121686, -33.137546573829916, -34.031197095155349, -35.612271094423434, -37.090231572000121, -37.708912702148496, -41.420999483038770, -42.658361743335533, -42.830217612821194, -48.054636045185291, -44.273806916500746, -47.848409001802494, -46.164221480843018, -47.917151349596757, -49.223255957687783, -48.707688349230800, -50.976185826441522, -51.801093999972693, -51.251155217618582, -51.319897565412845, -53.554023868726439, -51.732351652178437 ]) xmax = 1e-6 * array([ 1.564133670321216, 1.564961903839758, 1.566026775506454, 1.567150806710189, 1.568748114210234, 1.570227102636202, 1.571942729210324, 1.574249951154833, 1.576083896803033, 1.578331959210504, 1.580757500229090, 1.583301360321754, 1.585312784581070, 1.587383368377425, 1.589868068933050, 1.591997812266443, 1.593890917451682, 1.595665703562843, 1.597440489674004, 1.598682839951816, 1.600161828377784, 1.601640816803751, 1.602764848007487, 1.603474762451951, 1.604598793655686 ]) ymax = array([ -29.700429184116697, -29.597315662425299, -29.562944488528167, -30.112883270882282, -29.459830966836773, -29.666058010219565, -30.284739140367943, -31.144018487796249, -31.762699617944627, -32.793834834858593, -33.378144791109840, -34.306166486332408, -34.924847616480790, -36.987118050308723, -37.468314484868571, -39.221244353622311, -40.939803048478922, -41.317885961347379, -43.620754612455229, -43.792610481940898, -47.092243176065587, -47.332841393345511, -47.092243176065587, -47.882780175699622, -50.701216435264470 ]) plot(xmzi[0], ymzi[0], xmax * 1e9, ymax, 'g.', xmin * 1e9, ymin, 'g.') xlim(1563, 1605) ylim(-55, -29) xticks([1570, 1580, 1590, 1600], ('1570', '1580', '1590', '1600')) xlabel('Wavelenght (nm)') ylabel('Transmission (dB)') # ## approximate_taylor_polynomial(y,0,2,1) # # figure(3) # ng = 1580e-9**2/diff(xmin)/450e-6 + 4.36 ng2 = (xmin * xmax) / 2 / 450e-6 / abs(xmin - xmax) + 4.36 # plot(xmin[0:-1]*1e9,ng,'o') plot(xmin * 1e9, ng2, 'o') xlabel('Wavelenght (nm)') ylabel('Group index') xticks([1570, 1580, 1590, 1600], ('1570', '1580', '1590', '1600')) yticks([7, 9, 11, 13], ('7', '9', '11', '13')) # xlim([1563,1603]) ylim([6, 14]) legend(('Heterodyne', 'fringes'), ncol=2, mode="expand", loc=2) # legend(["Heterodyne"], loc=1, ["fringes"], loc=4) # l2 = legend([p2], ["fringes"], loc=4) # this removes l1 from the axes. # gca().add_artist(l1) # add l1 as a separate artist to the axes # ng2 = 1580e-9**2/diff(xmax*1e-9)/450e-6 + 4.36 # plot(xmax[0:-1],ng2,'+') # this is another inset axes over the main axes # a = axes([0.25, 0.5, .5, .3], axisbg='y') plot(xmzi[0], ymzi[0], xmin * 1e9, ymin, 'o', xmax * 1e9, ymax, 'go') # setp(a, xlim=(1563,1605),ylim=(-55,-29), xticks=[],yticks=[]) savefig('gropIndexComparison_2.png') savefig('gropIndexComparison_2.eps') show() # w1 = 2*pi/(x1t*1e-9) -2*pi/1585e-9 # yw1 = y1t # # w6 = 2*pi/(x6[0]*1e-9) -2*pi/1585e-9 # yw6 = y6[0] # # orderPol = 6 # # ## approximate_taylor_polynomial(y,0,2,1) # # p1 = polyfit(w1,yw1,orderPol) # p6 = polyfit(w6,yw6,orderPol) # # plot(w1,yw1,w6,yw6) return
def main(): #overcoupled ring amplitude is trace number 10 phase = 'dispersionV740D9_TMringsTErings.dat' xphase, yphase = importap(phase) indexTrace = 14 indexTraceNoRing = 13 index1560 = where(xphase[indexTrace] > 1560)[0][0] xp = xphase[indexTrace][0:index1560] yp = yphase[indexTrace][0:index1560] dataShift = 21 yp = -yphase[indexTrace][0:index1560] + interp( xphase[indexTrace][dataShift:index1560 + dataShift], xphase[indexTraceNoRing], yphase[indexTraceNoRing]) amp = 'linearV740D9_TMrings_TErings.dat' xamp, yamp = importaa(amp) indexTraceNoRing = 11 indexTrace = 12 index1560 = where(xamp[10] > 1560)[0][0] xa = xamp[indexTrace][0:index1560] ya = 10**((yamp[indexTrace][0:index1560] - interp(xamp[indexTrace][0:index1560], xamp[indexTraceNoRing], yamp[indexTraceNoRing])) / 20) ya = ya / max(ya) x = xa y = ya * exp(1j * yp) fitfunc = lambda p, x: ring(x * 1e-9, p[0], p[1], p[2], p[3] ) # Target function errfunc = lambda p, x, y: abs(real(fitfunc(p, x) - y)) + abs( imag(fitfunc(p, x) - y)) # Distance to the target function p0 = [8.8, 0.3, .9, 4.3526515] # Initial guess for the parameters p1, success = optimize.leastsq(errfunc, p0[:], args=(x, y)) ax1 = subplot(211) plot(x, abs(y), '-', x, abs(fitfunc(p1, x)), '--') ylabel('Transmission') ax1.yaxis.set_label_coords(-0.1, 0.5) legend(('data', 'fit'), loc=8) title( '$ 275nm-gap $ Undercoupled ring ($k=0.217$, $\mathrm{A=0.934}$, $n_g=4.35$)' ) yticks([0, 1], ('0', '1')) xticks([1530, 1560], ['', '']) print 'p0=' print p0 a = p1[2] print 'p1=' print p1 alpha = -log(a**2) / (2 * pi * 20e-6 * 100) # cm^-1 alphadBcm = -log(a**2) / (2 * pi * 20e-6 * 100) # cm^-1 ax2 = subplot(212) plot(x, angle(y) / pi, x, angle(fitfunc(p1, x)) / pi, '--') ylabel('Phase (rad)') ax2.yaxis.set_label_coords(-0.1, 0.5) xlabel('Wavelength (nm)') yticks([-0.5, .5], ('$-\pi/2$', '$\pi/2$')) xticks([1530, 1560], ['1530', '1560']) savefig('r20g275TE_fitPhaseAmp.eps') show() return