--- a/FXAnalyse.c	Thu Sep 18 18:02:20 2014 +0200
+++ b/FXAnalyse.c	Thu Sep 18 18:03:27 2014 +0200
@@ -241,24 +241,24 @@
 	N_MEASUREMENT_FREP_MINUS,
 };
 
-int Measuring_1 = N_MEASUREMENT_NONE;
-int Measuring_2 = N_MEASUREMENT_NONE;
-int Measuring_3 = N_MEASUREMENT_NONE;
+int n_measurement_1 = N_MEASUREMENT_NONE;
+int n_measurement_2 = N_MEASUREMENT_NONE;
+int n_measurement_3 = N_MEASUREMENT_NONE;
 
 int nobs = 0;
 int settling = 0;
 
 double f0_DDS1 = 110000000.0, f0_DDS2, f0_DDS3, f0_DDS4, df_DDS3;
 
-double SlopeTime1 = 40.0, DeltaT_1 = 40.0, delta_f_lock_1 = 500e3;
-double SlopeTime2 = 40.0, DeltaT_2 = 40.0, delta_f_lock_2 = 500e3;
-double SlopeTime3 = 40.0, DeltaT_3 = 40.0, delta_f_lock_3 = 500e3;
+double slope_time_1 = 40.0, integration_time_1 = 40.0, delta_f_lock_1 = 500e3;
+double slope_time_2 = 40.0, integration_time_2 = 40.0, delta_f_lock_2 = 500e3;
+double slope_time_3 = 40.0, integration_time_3 = 40.0, delta_f_lock_3 = 500e3;
 
 double t1, t2, t3;
 double f_rep_slope, f_beat_slope;
 double f_rep_plus, f_rep_minus;
 double f_beat_plus, f_beat_minus;
-double N_measured; 
+
 
 // Beatnote sign determination is done stepping the repetition rate by
 // stepping the comb phase-lock offset frequency f_lock generated by
@@ -752,6 +752,7 @@
 					logmsg("Error!");
 				value = value - read;
 				
+				// unpack event
 				utc = event.time.tv_sec + event.time.tv_usec * 1e-6;
 				Ch1 = event.data[0];
 				Ch2 = event.data[1];
@@ -792,7 +793,7 @@
 				
 				// N measurement
 
-				switch (Measuring_1) {
+				switch (n_measurement_1) {
 					
 					case N_MEASUREMENT_NONE:
 						// not measuring
@@ -815,7 +816,7 @@
 						f_rep_plus = f_rep_minus = 0.0;
 						
 						// next step
-						Measuring_1 += 1;
+						n_measurement_1 += 1;
 						break;
 						
 					case N_MEASUREMENT_SLOPE:
@@ -823,7 +824,7 @@
 						
 						stat_accumulate(&stat_math1, Math1);
 						
-						if ((utc - t1) > SlopeTime1) {
+						if ((utc - t1) > slope_time_1) {
 							f_rep_slope = stat_math1.slope;
 							
 							// frep positive step
@@ -834,7 +835,7 @@
 							settling = 3;
 							
 							// next step
-							Measuring_1 += 1;
+							n_measurement_1 += 1;
 						}
 						break;
 						
@@ -853,7 +854,7 @@
 						settling = 3;
 						
 						// next step
-						Measuring_1 += 1;
+						n_measurement_1 += 1;
 						break;								
 						
 					case N_MEASUREMENT_FREP_PLUS:
@@ -868,7 +869,7 @@
 						f_rep_plus += Math1 - f_rep_slope * (utc - t2);
 						nobs += 1;
 						
-						if ((utc - t2) > DeltaT_1) {
+						if ((utc - t2) > integration_time_1) {
 							f_rep_plus = f_rep_plus / nobs;
 							nobs = 0;
 							
@@ -880,7 +881,7 @@
 							settling = 3;
 							
 							// next step
-							Measuring_1 += 1;
+							n_measurement_1 += 1;
 						}
 						break;
 						
@@ -896,14 +897,14 @@
 						f_rep_minus += Math1 - f_rep_slope * (utc - t2);
 						nobs += 1;
 						
-						if ((utc - t3) > DeltaT_1) {
+						if ((utc - t3) > integration_time_1) {
 							f_rep_minus = f_rep_minus / nobs;
 							nobs = 0;
 							
 							// compute N1
 							double delta_f_rep = f_rep_minus - f_rep_plus;
-							N_measured = Sign1 * 2 * Ndiv * delta_f_lock_1 / delta_f_rep;
-							SetCtrlVal(CalcNPanel, CALCN_N, N_measured);
+							double measured = Sign1 * 2 * Ndiv * delta_f_lock_1 / delta_f_rep;
+							SetCtrlVal(CalcNPanel, CALCN_N, measured);
 							
 							// back to nominal frep
 							ad9912_ramp_frequency_w(&ad9912, 0, f0_DDS1, FREP_STEP_SIZE);
@@ -912,12 +913,12 @@
 							SetCtrlVal(MainPanel, PANEL_DDS2, ad9912.frequency[1]);
 							
 							// done
-							Measuring_1 = N_MEASUREMENT_NONE;
+							n_measurement_1 = N_MEASUREMENT_NONE;
 						}
 						break;
 				}
 
-				switch (Measuring_2) {
+				switch (n_measurement_2) {
 
 					case N_MEASUREMENT_NONE:
 						// not measuring
@@ -943,7 +944,7 @@
 						f_beat_plus = f_beat_minus = 0.0;
 						
 						// next step
-						Measuring_2 += 1;
+						n_measurement_2 += 1;
 						break;
 						
 					case N_MEASUREMENT_SLOPE:
@@ -952,7 +953,7 @@
 						stat_accumulate(&stat_math1, Math1);
 						stat_accumulate(&stat_ch2, Ch2);
 
-						if ((utc - t1) > SlopeTime2) {
+						if ((utc - t1) > slope_time_2) {
 							f_rep_slope = stat_math1.slope;
 							f_beat_slope = stat_ch2.slope;
 							
@@ -971,7 +972,7 @@
 							settling = 3;
 							
 							// next step
-							Measuring_2 += 1;
+							n_measurement_2 += 1;
 						}
 						break;
 
@@ -995,7 +996,7 @@
 						settling = 3;
 
 						// next step
-						Measuring_2 += 1;
+						n_measurement_2 += 1;
 						break;
 						
 					case N_MEASUREMENT_FREP_PLUS:
@@ -1011,7 +1012,7 @@
 						f_beat_plus += Ch2 - f_beat_slope * (utc - t2);
 						nobs += 1;
 						
-						if ((utc - t2) > DeltaT_2) {
+						if ((utc - t2) > integration_time_2) {
 							f_rep_plus = f_rep_plus / nobs;
 							f_beat_plus = f_beat_plus / nobs;
 							nobs = 0;
@@ -1031,7 +1032,7 @@
 							settling = 3;
 							
 							// next step
-							Measuring_2 += 1;
+							n_measurement_2 += 1;
 						}
 						break;
 						
@@ -1048,7 +1049,7 @@
 						f_beat_minus += Ch2 + f_beat_slope * (utc - t2);
 						nobs += 1;
 
-						if ((utc -t3) > DeltaT_2) {
+						if ((utc -t3) > integration_time_2) {
 							f_rep_minus = f_rep_minus / nobs;
 							f_beat_minus = f_beat_minus / nobs;
 							nobs = 0;
@@ -1061,8 +1062,8 @@
 							logmsg("delta frep: measured=%e expected=%e difference=%e rel=%e",
 								delta_f_rep_m, delta_f_rep, delta, delta / delta_f_rep);
 							
-							N_measured = -Sign2 * (df_DDS3 + f_beat_minus - f_beat_plus) / delta_f_rep;
-							SetCtrlVal(CalcNPanel, CALCN_N, N_measured);
+							double measured = -Sign2 * (df_DDS3 + f_beat_minus - f_beat_plus) / delta_f_rep;
+							SetCtrlVal(CalcNPanel, CALCN_N, measured);
 							
 							// back to nominal frequency
 							ad9912_ramp_frequency_w(&ad9912, 0, f0_DDS1, FREP_STEP_SIZE);
@@ -1073,12 +1074,12 @@
 							SetCtrlVal(MainPanel, PANEL_DDS3, ad9912.frequency[2]);
 							
 							// done
-							Measuring_2 = N_MEASUREMENT_NONE;
+							n_measurement_2 = N_MEASUREMENT_NONE;
 						}
 						break;
 				}
 				
-				switch (Measuring_3) {
+				switch (n_measurement_3) {
 					
 					case N_MEASUREMENT_NONE:
 						// not measuring N3
@@ -1104,7 +1105,7 @@
 						f_beat_plus = f_beat_minus = 0.0;
 						
 						// next step
-						Measuring_3 += 1;
+						n_measurement_3 += 1;
 						break;
 						
 					case N_MEASUREMENT_SLOPE:
@@ -1116,7 +1117,7 @@
 						stat_accumulate(&stat_math1, Math1);
 						stat_accumulate(&stat_ch3, Ch3);
 						
-						if (utc - t1 > SlopeTime3) {
+						if (utc - t1 > slope_time_3) {
 							// slope measurement
 							f_rep_slope = stat_math1.slope;
 							f_beat_slope = stat_ch3.slope;
@@ -1137,7 +1138,7 @@
 							settling = 3;
 							
 							// next step
-							Measuring_3 += 1;
+							n_measurement_3 += 1;
 						}
 						break;
 
@@ -1157,7 +1158,7 @@
 						settling = 3;
 						
 						// next step
-						Measuring_3 += 1;
+						n_measurement_3 += 1;
 						break;						
 						
 					case N_MEASUREMENT_FREP_PLUS:
@@ -1173,7 +1174,7 @@
 						f_beat_plus += Ch3 - f_beat_slope * (utc - t2);
 						nobs += 1;
 						
-						if (utc - t2 > DeltaT_3) {
+						if (utc - t2 > integration_time_3) {
 							f_rep_plus = f_rep_plus / nobs;
 							f_beat_plus = f_beat_plus / nobs;
 							nobs = 0;
@@ -1191,7 +1192,7 @@
 							settling = 3;
 							
 							// next step
-							Measuring_3 += 1;
+							n_measurement_3 += 1;
 						}
 						break;
 					
@@ -1208,7 +1209,7 @@
 						f_beat_minus += Ch3 - f_beat_slope * (utc - t2);
 						nobs += 1;
 						
-						if (utc - t3 > DeltaT_3) {
+						if (utc - t3 > integration_time_3) {
 							f_rep_minus = f_rep_minus / nobs;
 							f_beat_minus = f_beat_minus / nobs;
 							nobs = 0;
@@ -1228,10 +1229,10 @@
 							logmsg("delta fbeat: measured=%e expected=%e difference=%e",
 								delta_f_beat, delta_f_beat_expected, delta_f_beat - delta_f_beat_expected);
 							
-							N_measured = delta_f_beat / delta_f_rep;
-							SetCtrlVal(CalcNPanel, CALCN_N, N_measured);
+							double measured = delta_f_beat / delta_f_rep;
+							SetCtrlVal(CalcNPanel, CALCN_N, measured);
 							
-							logmsg("measured N3=%.3f", N_measured);
+							logmsg("measured N3=%.3f", measured);
 							
 							// back to nominal frep
 							ad9912_ramp_frequency_w(&ad9912, 0, f0_DDS1, FREP_STEP_SIZE);
@@ -1242,7 +1243,7 @@
 							SetCtrlVal(MainPanel, PANEL_DDS4, ad9912.frequency[3]);
 							
 							// done
-							Measuring_3 = N_MEASUREMENT_NONE;
+							n_measurement_3 = N_MEASUREMENT_NONE;
 						}
 						break;
 				}
@@ -1577,21 +1578,23 @@
 		void *callbackData, int eventData1, int eventData2)
 {
 	int measure;
-	
+	double measured;
+
 	switch (event) {
 		case EVENT_COMMIT:
 			GetPanelAttribute(panel, ATTR_CALLBACK_DATA, &measure);
+			GetCtrlVal(panel, CALCN_N, &measured);
 			switch (measure) {
 				case LO:
-					N1 = round(N_measured);
+					N1 = round(measured);
 					SetCtrlVal(MainPanel, PANEL_N1, N1);
 					break;
 				case HG:
-					N2 = round(N_measured);
+					N2 = round(measured);
 					SetCtrlVal(MainPanel, PANEL_N2, N2);
 					break;
 				case SR:
-					N3 = round(N_measured);
+					N3 = round(measured);
 					SetCtrlVal(MainPanel, PANEL_N3, N3);
 					break;
 			} 
@@ -1613,8 +1616,8 @@
 					if (! visible) {
 						SetPanelAttribute(CalcNPanel, ATTR_CALLBACK_DATA, LO);
 						SetPanelAttribute(CalcNPanel, ATTR_TITLE, "Measure N_Lo");
-						SetCtrlVal(CalcNPanel, CALCN_INTEGRATIONTIME, DeltaT_1);
-						SetCtrlVal(CalcNPanel, CALCN_SLOPETIME, SlopeTime1);
+						SetCtrlVal(CalcNPanel, CALCN_INTEGRATIONTIME, integration_time_1);
+						SetCtrlVal(CalcNPanel, CALCN_SLOPETIME, slope_time_1);
 						SetCtrlVal(CalcNPanel, CALCN_DELTAFREQ, delta_f_lock_1 / 1000.0);
 						SetCtrlVal(CalcNPanel, CALCN_N, 0.0);
 						DisplayPanel(CalcNPanel);
@@ -1625,8 +1628,8 @@
 					if (! visible) {
 						SetPanelAttribute(CalcNPanel, ATTR_CALLBACK_DATA, HG);
 						SetPanelAttribute(CalcNPanel, ATTR_TITLE, "Measure N_Hg");
-						SetCtrlVal(CalcNPanel, CALCN_INTEGRATIONTIME, DeltaT_2);
-						SetCtrlVal(CalcNPanel, CALCN_SLOPETIME, SlopeTime2);
+						SetCtrlVal(CalcNPanel, CALCN_INTEGRATIONTIME, integration_time_2);
+						SetCtrlVal(CalcNPanel, CALCN_SLOPETIME, slope_time_2);
 						SetCtrlVal(CalcNPanel, CALCN_DELTAFREQ, delta_f_lock_2 / 1000.0);
 						SetCtrlVal(CalcNPanel, CALCN_N, 0.0);
 						DisplayPanel(CalcNPanel);
@@ -1637,8 +1640,8 @@
 					if (! visible) {
 						SetPanelAttribute(CalcNPanel, ATTR_CALLBACK_DATA, SR);
 						SetPanelAttribute(CalcNPanel, ATTR_TITLE, "Measure N_Sr");
-						SetCtrlVal(CalcNPanel, CALCN_INTEGRATIONTIME, DeltaT_3);
-						SetCtrlVal(CalcNPanel, CALCN_SLOPETIME, SlopeTime3);
+						SetCtrlVal(CalcNPanel, CALCN_INTEGRATIONTIME, integration_time_3);
+						SetCtrlVal(CalcNPanel, CALCN_SLOPETIME, slope_time_3);
 						SetCtrlVal(CalcNPanel, CALCN_DELTAFREQ, delta_f_lock_3 / 1000.0);
 						SetCtrlVal(CalcNPanel, CALCN_N, 0.0);
 						DisplayPanel(CalcNPanel);
@@ -1660,28 +1663,28 @@
 			GetPanelAttribute(panel, ATTR_CALLBACK_DATA, &measuring);
 			switch (measuring) {
 				case LO:
-					GetCtrlVal(CalcNPanel, CALCN_INTEGRATIONTIME, &DeltaT_1);
-					GetCtrlVal(CalcNPanel, CALCN_SLOPETIME, &SlopeTime1);
+					GetCtrlVal(CalcNPanel, CALCN_INTEGRATIONTIME, &integration_time_1);
+					GetCtrlVal(CalcNPanel, CALCN_SLOPETIME, &slope_time_1);
 					GetCtrlVal(CalcNPanel, CALCN_DELTAFREQ, &delta_f_lock_1);
 					// convert from kHz to Hz
 					delta_f_lock_1 = delta_f_lock_1 * 1000.0;
-					Measuring_1 = TRUE;
+					n_measurement_1 = TRUE;
 					break;
 				case HG:
-					GetCtrlVal(CalcNPanel, CALCN_INTEGRATIONTIME, &DeltaT_2);
-					GetCtrlVal(CalcNPanel, CALCN_SLOPETIME, &SlopeTime2);
+					GetCtrlVal(CalcNPanel, CALCN_INTEGRATIONTIME, &integration_time_2);
+					GetCtrlVal(CalcNPanel, CALCN_SLOPETIME, &slope_time_2);
 					GetCtrlVal(CalcNPanel, CALCN_DELTAFREQ, &delta_f_lock_2);
 					// convert from kHz to Hz
 					delta_f_lock_2 = delta_f_lock_2 * 1000.0;
-					Measuring_2 = TRUE;
+					n_measurement_2 = TRUE;
 					break;
 				case SR:
-					GetCtrlVal(CalcNPanel, CALCN_INTEGRATIONTIME, &DeltaT_3);
-					GetCtrlVal(CalcNPanel, CALCN_SLOPETIME, &SlopeTime3);
+					GetCtrlVal(CalcNPanel, CALCN_INTEGRATIONTIME, &integration_time_3);
+					GetCtrlVal(CalcNPanel, CALCN_SLOPETIME, &slope_time_3);
 					GetCtrlVal(CalcNPanel, CALCN_DELTAFREQ, &delta_f_lock_3);
 					// convert from kHz to Hz
 					delta_f_lock_3 = delta_f_lock_3 * 1000.0;
-					Measuring_3 = TRUE;
+					n_measurement_3 = TRUE;
 					break;
 			}
 			break;
@@ -1700,18 +1703,18 @@
 			GetPanelAttribute(panel, ATTR_CALLBACK_DATA, &measuring);
 			switch (measuring) {
 				case LO:
-					Measuring_1 = FALSE;
+					n_measurement_1 = FALSE;
 					ad9912_ramp_frequency_w(&ad9912, 0, f0_DDS1, FREP_STEP_SIZE);
 					ad9912_set_frequency_w(&ad9912, 1, f0_DDS2);
 					break;
 				case HG:
-					Measuring_2 = FALSE;
+					n_measurement_2 = FALSE;
 					ad9912_ramp_frequency_w(&ad9912, 0, f0_DDS1, FREP_STEP_SIZE);
 					ad9912_set_frequency_w(&ad9912, 1, f0_DDS2);
 					ad9912_set_frequency_w(&ad9912, 2, f0_DDS3);
 					break;
 				case SR:
-					Measuring_3 = FALSE;
+					n_measurement_3 = FALSE;
 					ad9912_ramp_frequency_w(&ad9912, 0, f0_DDS1, FREP_STEP_SIZE);
 					ad9912_set_frequency_w(&ad9912, 1, f0_DDS2);
 					ad9912_set_frequency_w(&ad9912, 3, f0_DDS4);