upd

mysignal/__init__.py

@@ -1 +1 @@
-__version__ = '0.1.18'
+__version__ = '0.1.19'

mysignal/phasefreq.py

@@ -70,7 +70,7 @@ def filter_signal_by_modes(time, signal, num_modes=1, bandwidth_factor=0.1, requ
         bandwidth = bandwidth_factor * freq
         lowcut = max(0.01, freq - bandwidth)  # Éviter les fréquences négatives
         highcut = freq + bandwidth
-    
+
         # Éviter les fréquences supérieures à la fréquence de Nyquist
         nyq = 0.5 * fs
         highcut = min(highcut, nyq * 0.99)  # Laisser une marge
@@ -78,18 +78,18 @@ def filter_signal_by_modes(time, signal, num_modes=1, bandwidth_factor=0.1, requ
         # Normaliser les fréquences
         lowcut_norm = lowcut / nyq
         highcut_norm = highcut / nyq
-        
+
         print(f"Filtrage à {freq:.2f} Hz, bande : [{lowcut_norm:.5f}, {highcut_norm:.5f}] (normalisé)")
-        
+
         # Vérifier si le signal est suffisamment long
         period = 1 / lowcut if lowcut > 0 else 0
         #required_cycles = 40  # Vous avez mentionné 40 cycles
         min_length = required_cycles * period * fs
-        
+
         if len(signal_clean) < min_length:
             print(f"Avertissement: Signal court pour {freq:.2f} Hz. "
                   f"Requis: {min_length:.0f} échantillons, Disponible: {len(signal_clean)}")
-            
+
             # Méthode alternative: utiliser un filtre SOS (Second-Order Sections)
             # plus stable pour les signaux courts
             sos = butter(4, [lowcut_norm, highcut_norm], btype='band', output='sos')
@@ -98,7 +98,7 @@ def filter_signal_by_modes(time, signal, num_modes=1, bandwidth_factor=0.1, requ
             # Méthode standard
             b, a = butter(4, [lowcut_norm, highcut_norm], btype='band')
             filtered_signal = filtfilt(b, a, signal_clean)
-        
+
         filtered_signals.append(filtered_signal)
 
     # Le temps reste le même après filtrage
@@ -107,17 +107,17 @@ def filter_signal_by_modes(time, signal, num_modes=1, bandwidth_factor=0.1, requ
     return np.array(filtered_signals), dominant_freqs, time_filtered
 
 
-def plot_filtered_modes(t, e, e_filtered, e_frequencies, e_time, n_modes):
+def plot_filtered_modes(t, e, e_filtered, e_frequencies, e_time, n_modes, output=None):
 
     fig, ax = plt.subplots(nrows=n_modes+1, ncols=2, figsize=(12, 4 * n_modes), gridspec_kw={'width_ratios': [3, 1]})
-     
+
     ax[0, 0].plot(t, e)
     ax[0, 0].set_title('Signal original')
     ax[0, 0].set_xlabel('Temps (s)')
     ax[0, 0].set_ylabel('Amplitude')
-    
-    
-    
+
+
+
     for i in range(n_modes):
         ax[i+1, 0].plot(e_time, e_filtered[i])
         ax[i+1, 0].set_title(f'Mode #{i+1} filtré ({e_frequencies[i]:.2f} Hz)')
@@ -126,10 +126,12 @@ def plot_filtered_modes(t, e, e_filtered, e_frequencies, e_time, n_modes):
 
         ax[i+1, 1].plot(e_time, e, color='red')
         ax[i+1, 1].plot(e_time, e_filtered[i])
-        
+
         ax[i+1, 1].set_xlim(left=0.5 * e_time.mean(), right=0.5*e_time.mean() + 10/e_frequencies[i])
     plt.tight_layout()
     plt.show()
+    if output:
+        plt.savefig(output)
 
 
 
@@ -238,7 +240,7 @@ def analyze_signal_Hilbert(time, e_signal, s_signal, freq_rtol=0.01):
     period_e = 1 / freq_e
     period_s = 1 / freq_s
 
- 
+
 
     res = {'period_e': period_e,
            'period_s': period_s,
@@ -247,7 +249,7 @@ def analyze_signal_Hilbert(time, e_signal, s_signal, freq_rtol=0.01):
            'phase': mean_phase_diff,
            'phrase_deg': phase_diff_deg,
            'delay': time_shift}
-    
+
     return res
 
 def analyze_signal_sinfit(time, e_signal, s_signal, freq_rtol=0.01):
@@ -344,7 +346,7 @@ def analyze_signal_sinfit(time, e_signal, s_signal, freq_rtol=0.01):
     period_e = 1 / freq_e
     period_s = 1 / freq_s
 
- 
+
     res = {'period_e': period_e,
            'period_s': period_s,
            'freq_e': freq_e,
@@ -352,7 +354,7 @@ def analyze_signal_sinfit(time, e_signal, s_signal, freq_rtol=0.01):
            'phase': phase_diff,
            'phrase_deg': phase_diff_deg,
            'delay': time_shift}
-    
+
     return res
 
 
@@ -460,7 +462,7 @@ def analyze_signal_cross_correlation(time, e_signal, s_signal, freq_rtol=0.01):
            'phase': phase_diff,
            'phrase_deg': phase_diff_deg,
            'delay': time_shift}
-    
+
     return res
 
 
@@ -571,18 +573,18 @@ def analyze_signal_wavelet(time, e_signal, s_signal, freq_rtol=0.01):
            'phase': mean_phase_diff,
            'phrase_deg': phase_diff_deg,
            'delay': time_shift}
-    
+
     return res
 
 
 def plot_phases(e_time, e_filtered, e_frequencies, s_filtered, n_modes, callback=analyze_signal_wavelet):
     fig, ax = plt.subplots(nrows=n_modes, ncols=2, figsize=(12, 6), gridspec_kw={'width_ratios': [3, 1]})
-    
-    
+
+
     for mod in range(n_modes):
-    
+
         res = callback(e_time, e_filtered[mod], s_filtered[mod], freq_rtol=0.3)
-    
+
         ax[mod, 0].set_title(f'Freq: {res['freq_e']:.3f}, Phase: {res['phase']:.3f}, Delay: {res['delay']:.3f}' )
         ax[mod, 0].plot(e_time, e_filtered[mod], label='e')
         ax[mod, 0].plot(e_time, s_filtered[mod], label='s')
@@ -592,9 +594,11 @@ def plot_phases(e_time, e_filtered, e_frequencies, s_filtered, n_modes, callback
         ax[mod, 1].plot(e_time, e_filtered[mod], label='e')
         ax[mod, 1].plot(e_time, s_filtered[mod], label='s')
         ax[mod, 1].set_xlim(left=0.5 * e_time.mean(), right=0.5*e_time.mean() + 10/e_frequencies[mod])
-        
+
         for a in ax[:, 0]:
             a.legend()
-    
+
     plt.tight_layout();
-    plt.show();
+    plt.show();
+    if output:
+        plt.savefig(output)