def test(self): # With initial condition y(1) = 2, solution is def exact(x): return np.power(x + x**2 * (0.5 * 2**(2. / 3.) - 1), -3) ystart = np.ones((1, )) ystart[:] = [2.0] rtol = 1.0e-13 atol = 1.0e-13 x0 = 1.0 x1 = 4.0 hmin = 0.0 h1 = 0.01 out = ode_solve.Output(1) a = ode_solve.ODEint(ystart, x0, x1, atol, rtol, h1,hmin, out,\ dopr853.StepperDopr853, integrand() ) a.integrate() y_calc = a.out.ysave[a.out.count - 1] y_exct = exact(a.out.xsave[a.out.count - 1]) self.assertAlmostEqual(y_calc, y_exct, delta=2 * atol * y_exct)
integrand = dfg_problem(pump_in, sgnl_in, idlr_in, crystal, disable_SPM=True, waist=beamwaist) # Set up integrator rtol = 1.0e-6 atol = 1.0e-6 x0 = 0.0 x1 = crystallength hmin = 0.0 h1 = 0.00001 out = ode_solve.Output(n_saves) a = ode_solve.ODEint(integrand.ystart, x0, x1, atol, rtol, h1,hmin, out,\ dopr853.StepperDopr853, integrand) a.integrate() print 'integrated!' pump_out = a.out.ysave[0:a.out.count, 0:npoints].T sgnl_out = a.out.ysave[0:a.out.count, npoints:2 * npoints].T idlr_out = a.out.ysave[0:a.out.count, 2 * npoints:3 * npoints].T z = a.out.xsave[0:a.out.count] pump_power_in = np.round( 1e3 * np.trapz(abs(IFFT_t(pump_out[:, 0]))**2, pump_in.T) * pump_in.frep, decimals=4)
sigma = 10.0 R = 28.0 b = 8.0 / 3.0 dydx[0] = sigma * (y[1] - y[0]) dydx[1] = R * y[0] - y[1] - y[0] * y[2] dydx[2] = -b * y[2] + y[0] * y[1] ystart = np.ones((3, ), dtype=np.complex128) ystart[:] = [10.0, 1.0, 1.0] dydxstart = np.ones((3, ), dtype=np.complex128) xstart = np.zeros((1, )) rtol = 1.0e-9 atol = 1.0e-9 x0 = 0.0 x1 = 250.0 hmin = 0.0 h1 = 0.01 out = ode_solve.Output(5000) a = ode_solve.ODEint(ystart, x0, x1, atol, rtol, h1,hmin, out,\ dopr853.StepperDopr853, integrand()) a.integrate() fig = plt.figure() ax = fig.add_subplot(111, projection='3d') ax.plot(a.out.ysave[:a.out.count, 0], a.out.ysave[:a.out.count, 1], a.out.ysave[:a.out.count, 2]) plt.show()
def test_fn(self): npoints = 2**6 # Physical lengths are in meters crystallength = 0.010 crystal = crystals.AgGaSe2() crystal = crystals.AgGaSe2(length=crystallength) n_saves = 10 # Wavelengths are in nanometers pump_wl_nm = 1560. + 10.0 * np.random.rand() sgnl_wl_nm = 2200. + 10.0 * np.random.rand() theta, idlr_wl_nm = crystal.phasematch(pump_wl_nm, sgnl_wl_nm, None, return_wavelength=True) crystal.set_theta(theta) pump_power = (1 + np.random.rand()) * 5000.0 sgnl_power = 0.10 * np.random.rand() twind = 25. beamwaist = 100e-3 pump_in = CWPulse(pump_power, pump_wl_nm, NPTS=npoints, time_window_ps=twind) sgnl_in = CWPulse(sgnl_power, sgnl_wl_nm, NPTS=npoints, time_window_ps=twind) integrand = dfg_problem(pump_in, sgnl_in, crystal, disable_SPM=True, pump_waist=beamwaist, apply_gouy_phase=True) # Set up integrator rtol = 1.0e-12 atol = 1.0e-12 x0 = 0.0 x1 = crystallength hmin = 0.0 h1 = 0.0000001 out = ode_solve.Output(n_saves) # From Boyd section 2.8, also my One Note omega = lambda l_nm: 2.0 * np.pi * speed_of_light / (l_nm * 1.0e-9) w_1 = omega(sgnl_wl_nm) w_2 = omega(idlr_wl_nm) k_1 = np.mean(2 * np.pi * crystal.n(sgnl_wl_nm, 'o') / (sgnl_wl_nm * 1.0e-9)) k_2 = np.mean(2 * np.pi * crystal.n(idlr_wl_nm, 'o') / (idlr_wl_nm * 1.0e-9)) n_1 = crystal.n(sgnl_wl_nm, 'o') n_2 = crystal.n(idlr_wl_nm, 'o') n_3 = crystal.n(pump_wl_nm, 'mix') A_3 = np.sqrt(pump_power) * integrand.pump_beam.rtP_to_a( crystal.n(pump_wl_nm, 'mix')) A_1 = np.sqrt(sgnl_power) * integrand.sgnl_beam.rtP_to_a( crystal.n(sgnl_wl_nm, 'o')) kappa = np.mean( np.sqrt(4 * crystal.deff**2 * w_1**2 * w_2**2 / (k_1 * k_2 * speed_of_light**4)) * A_3) a = ode_solve.ODEint(integrand.ystart, x0, x1, atol, rtol, h1,hmin, out,\ dopr853.StepperDopr853, integrand, dtype = np.complex128) a.integrate() pump_out = a.out.ysave[0:a.out.count, 0:npoints].T sgnl_out = a.out.ysave[0:a.out.count, npoints:2 * npoints].T idlr_out = a.out.ysave[0:a.out.count, 2 * npoints:3 * npoints].T z = a.out.xsave[0:a.out.count] pump_power_in = np.sum(np.abs(pump_out[:, 0]), axis=0)**2 sgnl_power_in = np.sum(np.abs(sgnl_out[:, ])**2, axis=0) idlr_power_in = np.sum(np.abs(idlr_out[:, 0]), axis=0)**2 pump_power_out = np.sum(np.abs(pump_out[:, -1]))**2 sgnl_power_out = np.sum(np.abs(sgnl_out[:, -1]))**2 idlr_power_out = np.sum(np.abs(idlr_out[:, -1]))**2 # Compare integrated and analytic values for signal power numeric_sgnl = np.sum(np.abs(sgnl_out[:, :])**2, axis=0) analytic_sgnl = sgnl_power_in * np.cosh(kappa * z)**2 self.assertLess( abs( np.sum(numeric_sgnl - analytic_sgnl) / np.sum(abs(analytic_sgnl))), 0.01) # Compare integrated and analytic values for idler power numeric_idlr = np.sum(np.abs(idlr_out[:, :])**2, axis=0) analytic_idlr = n_1 * w_2 / (n_2 * w_1) * sgnl_power_in * np.sinh( kappa * z)**2 self.assertLess( abs( np.sum(numeric_idlr - analytic_idlr) / np.sum(abs(analytic_idlr))), 0.02)