diff FXAnalyse.c @ 115:23f8b7b2b63a

Use DDS1 to change frep in the measurement of N3. Improve some variable names
author Daniele Nicolodi <daniele.nicolodi@obspm.fr>
date Fri, 05 Jul 2013 16:06:26 +0200
parents 77b442322984
children 4f56dbdad85d
line wrap: on
line diff
--- a/FXAnalyse.c	Tue Jul 02 13:07:18 2013 +0200
+++ b/FXAnalyse.c	Fri Jul 05 16:06:26 2013 +0200
@@ -59,8 +59,6 @@
 
 muParserHandle_t MathParser1, MathParser2, MathParser3, MathParser4, MathParser5;
 
-
-
 double Ndiv = 8.0;
 
 int settling = 0;
@@ -88,7 +86,7 @@
 int Measuring_2 = N_MEASUREMENT_NONE;											  
 int Measuring_3 = N_MEASUREMENT_NONE;
 
-double FrequDDS1=110000000.0, FrequDDS4=110000000.0;
+double FrequDDS1=110000000.0;
 double Slope_1=0.0, Slope_2=0.0, Slope_3=0.0, Beatslope_2=0.0;
 double SlopeTime1=40.0, SlopeTime2=40.0, SlopeTime3=40.0;
 double Ch4Slope = 0.0;
@@ -96,7 +94,7 @@
 double N_1=0.0, N_2=0.0, N_3=0.0;
 double DeltaT_1=20.0, DeltakHz_1=500.0, t1_1=0.0, t2_1=0.0, t3_1=0.0, Frepplus_1=0.0, Frepminus_1=0.0;
 double DeltaT_2=20.0, DeltakHz_2=500.0, t1_2=0.0, t2_2=0.0, t3_2=0.0, Frepplus_2=0.0, Frepminus_2=0.0;
-double DeltaT_3=20.0, DeltakHz_3=500.0, t1_3=0.0, t2_3=0.0, t3_3=0.0, Frepplus_3=0.0, Frepminus_3=0.0;
+double DeltaT_3=20.0, DeltakHz_3=500.0, t1_3=0.0, t2_3=0.0, t3_3=0.0;
 
 int n_1=0, n_2=0, n_3=0;
 
@@ -106,6 +104,7 @@
 double DeltaDDS3=0.0,Delta10K_Plus=0.0,Delta10K_Minus=0.0;
 double Nu1=0.0, Nu2= 200000-147000+282143746.557455e6;  
 
+double f_rep_plus, f_rep_minus;
 double f_beat_Sr_plus, f_beat_Sr_minus;
 
 double Step1=800000.0,Step2=800000.0;
@@ -744,7 +743,7 @@
 							SetCtrlVal(CalcNPanel, CALCN_SLOPE, Slope_1);
 							
 							// frep positive step
-							DDS4xAD9912_RampFrequency(&DDS4xAD9912,1, FrequDDS1, FrequDDS1 + DeltakHz_1 * 1000.0, FREP_STEP_SIZE);
+							DDS4xAD9912_RampFrequency(&DDS4xAD9912, 1, FrequDDS1, FrequDDS1 + DeltakHz_1 * 1000.0, FREP_STEP_SIZE);
 							SetCtrlVal(MainPanel, PANEL_DDS1, FrequDDS1 + DeltakHz_1 * 1000.0);
 							
 							// allow counter to settle
@@ -1031,15 +1030,15 @@
 					case N_MEASUREMENT_INIT:
 						// init
 						
-						SetCtrlVal(MainPanel, PANEL_DDS4, FrequDDS4);
-						DDS4xAD9912_SetFrequency(&DDS4xAD9912, 4, FrequDDS4);
+						SetCtrlVal(MainPanel, 1, FrequDDS1);
+						DDS4xAD9912_SetFrequency(&DDS4xAD9912, 1, FrequDDS1);
 						settling = 3;
 						
 						t1_3 = utc;
 						stat_zero(&stat_ch2);
 						stat_zero(&stat_ch3);
-						f_beat_Sr_plus = 0.0;
-						f_beat_Sr_minus = 0.0;
+						f_rep_plus = f_rep_minus = 0.0;
+						f_beat_Sr_plus = f_beat_Sr_minus = 0.0;
 						
 						// record current DDS3 frequency
 						GetCtrlVal(MainPanel, PANEL_DDS3, &FrequencyDDS3Init);
@@ -1068,8 +1067,8 @@
 							stat_zero(&stat_ch3);
 							
 							// frep positive step
-							SetCtrlVal(MainPanel, PANEL_DDS4, FrequDDS4 + DeltakHz_3 * 1000);
-							DDS4xAD9912_RampFrequency(&DDS4xAD9912, 4, FrequDDS4, FrequDDS4 + DeltakHz_3 * 1000, FREP_STEP_SIZE);
+							SetCtrlVal(MainPanel, PANEL_DDS1, FrequDDS1 + DeltakHz_3 * 1000);
+							DDS4xAD9912_RampFrequency(&DDS4xAD9912, 1, FrequDDS1, FrequDDS1 + DeltakHz_3 * 1000, FREP_STEP_SIZE);
 							// compensate with DDS3 to keep measured beatnote in counter box range
 							double fDDS3 = FrequencyDDS3Init + Signe1 * Signe3 * N3/N1 * Ndiv * DeltakHz_3 * 1000;
 							SetCtrlVal(MainPanel, PANEL_DDS3, fDDS3);
@@ -1113,20 +1112,20 @@
 						}
 						
 						n_3++;
-						Frepplus_3 += Math1 + 250000000 - Slope_3 * (utc - t3_2);
+						f_rep_plus += Math1 + 250000000 - Slope_3 * (utc - t3_2);
 						f_beat_Sr_plus += Ch3;
 						
 						if (utc - t2_3 > DeltaT_3) {
 							// positive step measurement
-							Frepplus_3 = Frepplus_3 / n_3;
+							f_rep_plus = f_rep_plus / n_3;
 							f_beat_Sr_plus = f_beat_Sr_plus / n_3;
 							
 							n_3 = 0;
 							t3_3 = utc;
 							
 							// frep negative step
-							SetCtrlVal(MainPanel, PANEL_DDS4, FrequDDS4 - DeltakHz_3 * 1000);
-							DDS4xAD9912_RampFrequency(&DDS4xAD9912, 4, FrequDDS4 + DeltakHz_3 * 1000, FrequDDS4 - DeltakHz_3 * 1000, FREP_STEP_SIZE);
+							SetCtrlVal(MainPanel, PANEL_DDS1, FrequDDS1 - DeltakHz_3 * 1000);
+							DDS4xAD9912_RampFrequency(&DDS4xAD9912, 1, FrequDDS1 + DeltakHz_3 * 1000, FrequDDS1 - DeltakHz_3 * 1000, FREP_STEP_SIZE);
 							// compensate with DDS3 to keep measured beatnote in counter box range
 							double fDDS3 = FrequencyDDS3Init - Signe1 * Signe3 * N3/N1 * Ndiv * DeltakHz_3 * 1000;
 							SetCtrlVal(MainPanel, PANEL_DDS3, fDDS3);
@@ -1150,18 +1149,18 @@
 						}
 						
 						n_3++;
-						Frepminus_3 += Ch2 - Slope_3 * (utc - t3_3);
+						f_rep_minus += Ch2 - Slope_3 * (utc - t3_3);
 						f_beat_Sr_minus += Ch3;
 						
 						if (utc - t3_3 > DeltaT_3) {
 							// negative step measurement
-							Frepminus_3 = Frepminus_3 / n_3;
+							f_rep_minus = f_rep_minus / n_3;
 							f_beat_Sr_minus = f_beat_Sr_plus / n_3;
 							
 							// check delta frep
-							double delta_f_rep = Frepplus_3 - Frepplus_3;
+							double delta_f_rep = f_rep_plus - f_rep_minus;
 							double expected = N1 / Ndiv * 2.0 * DeltakHz_3 * 1000.0;
-							logmsg("delta frep=%g expected=%g", delta_f_rep, expected);
+							logmsg("delta frep=%g Hz expected=%g Hz", delta_f_rep, expected);
 							
 							// compute N3
 							double delta_f_beat_Sr = f_beat_Sr_plus - f_beat_Sr_minus + 2.0 * N3/N1 * Ndiv * DeltakHz_3 * 1000;
@@ -1173,12 +1172,10 @@
 							t2_3=0.0;
 							t3_3=0.0;
 							n_3 = 0;
-							Frepminus_3 = 0.0;
-							Frepplus_3 = 0.0;
 							
 							// back to nominal frep
-							SetCtrlVal(MainPanel, PANEL_DDS4, FrequDDS4);
-							DDS4xAD9912_RampFrequency(&DDS4xAD9912, 4, FrequDDS4 - DeltakHz_3 * 1000, FrequDDS4, FREP_STEP_SIZE);
+							SetCtrlVal(MainPanel, PANEL_DDS1, FrequDDS1);
+							DDS4xAD9912_RampFrequency(&DDS4xAD9912, 1, FrequDDS1 - DeltakHz_3 * 1000, FrequDDS1, FREP_STEP_SIZE);
 							// back to initial DDS3 frequency
 							SetCtrlVal(MainPanel, PANEL_DDS3, FrequencyDDS3Init);
 							DDS4xAD9912_SetFrequency(&DDS4xAD9912, 3, FrequencyDDS3Init);