PDFs: save all Axes as separate figures

simulations/12_noise_phase.py

@@ -93,8 +93,6 @@ if True:
 amplitudes = np.linspace(0,amp_max*5,500)
 signals = np.linspace(0.1,signal_max*5,101)
 if False:
-    fig2, ax2 = plt.subplots(2,2,figsize=(2*8,2*8))
-    ax2 = fig2.get_axes()
     V_theta = [variance(thetas,phase_distribution(thetas,sigma,s)) for s in signals ]
     E_theta=[expectation(thetas,phase_distribution(thetas,sigma,s)) for s in signals ]
     V_theta_g = [variance(thetas,phase_distribution_gauss(thetas,sigma,s)) for s in signals ]
@@ -104,23 +102,35 @@ if False:
     V_a_g = [variance(amplitudes,amplitude_distribution_gauss(amplitudes,sigma,s)) for s in signals ]
     E_a_g=[expectation(amplitudes,amplitude_distribution_gauss(amplitudes,sigma,s)) for s in signals ]
 
+    fig2, _ax2 = plt.subplots(2,2,figsize=(2*8,2*8))
+    ax2 = fig2.get_axes()
+    if True:
+        _figs = []
+        _axs = []
+        for i, ax in enumerate(_ax2):
+            _f, _a = plt.subplots(1,1, figsize=(1*8, 1*8))
+            _figs.append(_f)
+            _axs.append(_a)
+
+            ax2[i] = MethodProxy(ax2[0], _a)
+
     ax2[0].plot(signals,E_a,label='$p(a)$')
     ax2[0].plot(signals,E_a_g,ls='dashed',label='Gaussian approx.')
     ax2[0].set_xscale('log')
     ax2[0].set_yscale('log')
     ax2[0].set_ylabel('$\mu_a$')
-    
+
     ax2[1].plot(signals,V_a,label='$p(a)$')
     ax2[1].plot(signals,V_a_g,ls='dashed',label='Gaussian approx.')
     ax2[1].set_xscale('log')
     ax2[1].set_ylabel('$\sigma_a^2$')
-    
+
     ax2[2].plot(signals,E_theta,label=r'$p(\theta)$')
     ax2[2].plot(signals,E_theta_g,ls='dashed',label='Gaussian approx.')
     ax2[2].set_xscale('log')
     ax2[2].set_ylim(-1.1,1.1)
     ax2[2].set_ylabel(r'$\mu_\theta$')
-    
+
     ax2[3].plot(signals,V_theta,label=r'$p(\theta)$')
     ax2[3].plot(signals,V_theta_g,ls='dashed',label='Gaussian approx.')
     ax2[3].set_xscale('log')
@@ -130,9 +140,18 @@ if False:
         a.grid(which='both')
         a.set_xlabel(r'$s/\sigma$')
         a.legend()
-    
+
     fig2.tight_layout()
     fig2.savefig('expectation_variance.pdf')
+    for i, _f in enumerate(_figs):
+        fnames = [
+                'amplitude_mean',
+                'amplitude_sigma',
+                'phase_mean',
+                'phase_sigma',
+            ][i]
+        _f.savefig(fnames+'.pdf')
+        plt.close(_f)
 
 ## figure 3, beacon timing accuracy
 if True: