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  proton-capture on 118Te, Page 22 of 29  Not logged in ELOG logo
ID Date Author Categorydown Subject Year
  71   Fri Mar 20 04:29:45 2020 JanDAQDAQ settings for the first night 
Attachment 1: e127.trlo
// -*- C++ -*-

/// ************************
// SETUP FILE FOR
// E127 experiment at ESR 2020
/// ************************
/////////////////////////////////
// ADC GATES
si_stretch = 2000 ns;
si_delay = 0 ns;
target_stretch = 15000 ns;
target_delay = 5000 ns; //5000 ns;
master_delay = 800 ns;
//////////////////////////////////
/// DOWNSCALING by 2^n
// n=5 >>  32
// n=6 >>  64
// n=7 >> 128
// n=8 >> 256
// n=9 >> 512
// TARGET ON
si_red   = 0;
xray_red = 0;
baf_red  = 5;//5; 
// TARGET OFF
si_red_OFF   = 0;
xray_red_OFF = 0;
baf_red_OFF  = 0;//5;
//////////////////////////////////
// INPUTS
si_y	=	ECL_IN(1);
si_x	=	ECL_IN(2);

xray1	=	ECL_IN(3);
xray2	=	ECL_IN(4);
xray3	=	ECL_IN(5);

baf	=	ECL_IN(6);
// =       ECL_IN(7);
// =       ECL_IN(8);
// =       ECL_IN(9);
// =       ECL_IN(10);
// =       ECL_IN(11);

trafo   =       ECL_IN(12);
I_cool  =       ECL_IN(13);
U_cool  =       ECL_IN(14);
jet_S1  =       ECL_IN(15);

// =       ECL_IN(16);

jet_on	=	LEMO_IN(1);
jet_off =  	LEMO_IN(2);

//////////////////////////////
// OUTPUTS
si_gate =     GATE_DELAY(1);
target_gate =   GATE_DELAY(3);
qdc_gate  =   GATE_DELAY(4);
master_trig = GATE_DELAY(2);

pico_a = si_gate;
pico_b = target_gate;
//////////////////////////////
// CONSTANTS
long_gate = 2000 ns;
short_gate = 650 ns;

SECTION(all)
{
	FRONT_LED(1) = TRIMI_TDT;

	SERIAL_TSTAMP_IN = SERIAL_TSTAMP_OUT;
	SERIAL_TSTAMP_LATCH = ACCEPT_PULSE;
	slew_counter_add = 0x1000000;

        fast_busy_len = 1000 ns; 
	DEADTIME_IN(1) = TRIMI_TDT;

	/////////////////////////////////////////////////////////////
	//PULSER
        
	// mega_clock
	period(4) = 1 us;   // needed by UDP reader 

	// TRIGGER 11 >> interval for scaler readouts 
	period(1) = 1000 ms;
	
	/////////////////////////////////////////////////////////////
	// TRIGGERS

	// coinc window length
	accept_window_len = 1950 ns;

	// THESE ARE THE VULOM INPUTS (det. triggers)
	// STRETCH THE TRIGGER SIGNAL LONGER THAN THE accept_window_len

	lmu_restart_mode(1) = LEAD_IF_INACT | GATE_ENABLE;
	lmu_stretch(1) = long_gate; // front-back coinc gate

	trig_stretch(1)  = long_gate;
	trig_stretch(2)  = long_gate;
	trig_stretch(3)  = long_gate;

	trig_stretch(9)  = long_gate;
	trig_stretch(10) = long_gate;
	trig_stretch(11) = long_gate;
	
	// SET UP DELAYS TO MATCH THE TRIGGER SIGNALS
	//trig_delay(1) = 800 ns;
	//trig_delay(2) = 800 ns;
	//trig_delay(3) = 1120 ns;

	//trig_delay(9) = 800 ns;
	//trig_delay(10) = 800 ns;
	//trig_delay(11) = 800 ns;
	
	// STANDARD IS MODE_LEADING_EDGE (trigger on the falling edge)
	// MODE_WHEN_PRESENT: check, if a signal is on (e.g. SPILL ON)

	//trig_delay_mode(1) = MODE_THIS | MODE_LEADING_EDGE; 
	
	// DOWNSCALING FACTORS
	// THIS IS FOR GENERATED TPATS (so downscale tpat number with red==2^n)

	trig_red(1) = si_red;
	trig_red(2) = xray_red;
	trig_red(3) = baf_red;

    
	trig_red(9) = si_red_OFF;	
	trig_red(10) = xray_red_OFF;	
	trig_red(11) = baf_red_OFF;	
	
	// ONLY NEEDED FOR MULTI-EVENT MODE / NO NEED NOW
	//multi_trigger = 1;

	////////////////////////////////////////////////////
	// LMU SETUP
	
	// THIS IS THE LOGIC MATRIX.
	// TRIG_LMU_OUT(n) with 'n' being the tpat.

        // TRIG_LMU_AUX 1
        // silicon x/y OR 
	LMU_IN(1) = si_x;
	LMU_IN(2) = si_y;
	LMU_OUT(1) = LMU_IN(1) or LMU_IN(2);
	TRIG_LMU_AUX(1) = LMU_OUT(1);
		
	// TRIG_LMU_AUX 2
        // xray OR
	all_or_mask(2) = xray1 | xray2 | xray3;
	LMU_IN(3) = ALL_OR(2);
	LMU_OUT(2) = LMU_IN(3);
	TRIG_LMU_AUX(2) = ALL_OR(2);

	// TRIG_LMU 3 
	// BaF OR
	LMU_IN(4) = baf;
	LMU_OUT(4) = LMU_IN(4);
	// BaF single
       	TRIG_LMU_AUX(3) = LMU_OUT(4);

	//
	TRIG_PENDING[11] = PULSER(1);

	// TARGET_ON flag is TRIG_LMU_AUX(4)

	// TARGET_ON_TRIGGERS
	TRIG_LMU_OUT(1) = TRIG_LMU_AUX(1) and TRIG_LMU_AUX(4); //Si_ON  
	TRIG_LMU_OUT(2) = TRIG_LMU_AUX(2) and TRIG_LMU_AUX(4); //Xray_ON
	TRIG_LMU_OUT(3) = TRIG_LMU_AUX(3) and TRIG_LMU_AUX(4); //BaF_ON
	TRIG_LMU_OUT(4) = TRIG_LMU_AUX(1) and TRIG_LMU_AUX(3) and TRIG_LMU_AUX(4); //BaF+Si_ON
	//TRIG_LMU_OUT(4) = ;
	//TRIG_LMU_OUT(5) = ;
	//TRIG_LMU_OUT(6) = ;
	//TRIG_LMU_OUT(7) = ;
	//TRIG_LMU_OUT(8) = ;

	// TARGET_OFF_TRIGGERS
	TRIG_LMU_OUT(9)  = TRIG_LMU_AUX(1) and not TRIG_LMU_AUX(4); //Si_OFF
	TRIG_LMU_OUT(10) = TRIG_LMU_AUX(2) and not TRIG_LMU_AUX(4); //Xray_OFF
	TRIG_LMU_OUT(11) = TRIG_LMU_AUX(3) and not TRIG_LMU_AUX(4); //BaF_OFF
	//TRIG_LMU_OUT(12) = ;
	//TRIG_LMU_OUT(13) = ;
	//TRIG_LMU_OUT(14) = ;
	//TRIG_LMU_OUT(15) = ;
	TRIG_LMU_OUT(16) =
	  si_x and si_y and
	  xray1 and xray2 and xray3 and baf and
	  trafo and I_cool and U_cool and jet_S1;
	
	////////////////////////////////////////////////////////////
	// TPAT SETUP
	
	// THIS IS FOR MATCHING: TPAT -> MBS_TRIGGER
	// tpat_trig(n) = m
	// with n = tpat, m = MBS_trigger

        // MBS trigger 1 = JET_ON
	tpat_trig(1) = 1;
	tpat_trig(2) = 1;
	tpat_trig(3) = 1;
	tpat_trig(4) = 1;
	tpat_trig(5) = 1;
	tpat_trig(6) = 1;
	tpat_trig(7) = 1;
	tpat_trig(8) = 1;

	// MBS_trigger 2 = JET_OFF
	tpat_trig(9)  = 2;
	tpat_trig(10) = 2;
	tpat_trig(11) = 2;
	tpat_trig(12) = 2;
	tpat_trig(13) = 2;
	tpat_trig(14) = 2;
	tpat_trig(15) = 2;
	tpat_trig(16) = 2;
        
	// THIS IS FOR ENABLING THE SINGLE TPATS
	// WITH A MASK, OR THE TPATS, OR RANGES WITH n : m.

	tpat_enable = 1:4, 9:11;	
	//tpat_enable = 9:11;	
	//tpat_enable = mask 0xffff;	

	///////////////////////////////////////////////////////
	// GATE & DELAY (MAX=4)

	
	// SET UP THE GATES AND DELAYS

	// Silicon ADC gate
	// si_gate
        GATE_DELAY(1) = MASTER_START;
        delay(1) = si_delay;
	stretch(1) = si_stretch;

	// Masterstart/trigger
	// master_trig
	GATE_DELAY(2) = MASTER_START;
        delay(2) = master_delay;
        stretch(2) = 200 ns;

	// Xray/BaF ADC gate
	// target_gate
	GATE_DELAY(3) = MASTER_START;
        delay(3) = target_delay;
        stretch(3) = target_stretch;

	//unused
	GATE_DELAY(4) = MASTER_START;
	delay(4) = 0 ns;
	stretch(4) = 200 ns;

	////////////////////////////////////////////////////////
	// SIGNAL I/O
	
	// MAP THE LEMO & ECL OUTS
	
        LEMO_OUT(1) = master_trig;
        LEMO_OUT(2) = master_trig;

	ECL_OUT(1) = si_gate; 
	ECL_OUT(2) = si_gate; 
	ECL_OUT(3) = target_gate;
        ECL_OUT(4) = target_gate;
	ECL_OUT(5) = qdc_gate; 
        ECL_OUT(6) = qdc_gate; 
        ECL_OUT(7) = master_trig; 
        ECL_OUT(8) = master_trig; 

	ECL_OUT(9) = pico_a;
	//ECL_OUT(10) = ;
	ECL_OUT(11) = pico_b;
	//ECL_OUT(12) = ;
	//ECL_OUT(13) = ;
	//ECL_OUT(14) = ;
	//ECL_OUT(15) = TRIG_LMU_OUT(1);
	//ECL_OUT(16) = LMU_OUT(1);


	
/* Generates internal BOS and EOS. */
/*
spill_period_duration = 20000000 us;
spill_on_duration =     12000000 us;

SECTION(bos_eos_generate)
{
	period(3) = spill_period_duration;

	GATE_DELAY(3) = PULSER(3);
	stretch(3) = spill_on_duration;
	delay(3) = 0 ns;

	TRIG_PENDING[12] = PULSER(3);
	GATE_DELAY(4) = GATE_DELAY(3);
	stretch(4) = 50 ns;
	delay(4) = 0 ns;
	restart_mode(4) = TRAILING_EDGE;
	TRIG_PENDING[13] = GATE_DELAY(4);

	TRIG_LMU_AUX(3) = GATE_DELAY(3);
}
*/
/* Listens to BOS and EOS from the accelerator. */

	////////////////////////////////////////////////////
	// JET ON/OFF TRIGGER SETUP
	
        EDGE_GATE_START(1) = jet_on;
        TRIG_PENDING[12] = jet_on;

        EDGE_GATE_STOP(1) = jet_off;
        TRIG_PENDING[13] = jet_off;

        TRIG_LMU_AUX(4) = EDGE_GATE(1);

}
Attachment 2: main.cfg
#log_level = verbose

CRATE("Master")
{
  event_max = 1
  	BARRIER
  	MESYTEC_MADC32(0x00A10000) {
		  nim_busy = gate0
   	          range = 8 V
		  resolution=8
		  hires=true
	}
	BARRIER
	MESYTEC_MADC32(0x00A20000) {
                  nim_busy = gate0
                  range = 4 V
                  resolution=8
                  hires=true
		  }
	#BARRIER
        #CAEN_V965 (0x00B10000) {
	#	  channel_enable = 0..11
        #}
	BARRIER
	CAEN_V775 (0x00C10000) {
		  common_start = false
		  time_range = 1200 ns
		  suppress_invalid = true
		  suppress_over_range = true
	}
	BARRIER
        CAEN_V775 (0x00C20000) {
                  common_start = false
                  time_range = 1200 ns
                  suppress_invalid = true
                  suppress_over_range = true
        }
	BARRIER
	#CAEN_V830 (0x00E10000) {
	#	  resolution = 32	
	#	  }
	#BARRIER
	#CAEN_V830 (0x00E20000) {
        #          resolution = 32
	#}
	#BARRIER
	GROUP("Timetamp")
	GSI_VULOM(0x05000000) {
		timestamp = true
	}
}
Attachment 3: r3bfuser.cfg
[r3bfuser]
# White Rabbit ID, =0 -> don't write MBS TO timestamp sub-event.
# Subevent 10/1: WR subsystem ID + timestamp
# wr_id = 0x100

# Save LOS/ROLU scalers/samplers every n:th spill, =0 -> don't read.
# Subevent 38/3800: ECL_IN scalers + pileup histogram
# Subevent 39/3900: trloii sampler data
do_beam_scalers = 1

# Save spill structure with 1/10s sized bins.
# do_spill_struct = 10

# Handle spill triggers 10..13 specially, >0 -> keep-alive grace period in s.
# period put to ~2 weeks, to enable long-term vulom scalers with targetOFF
do_spill_triggers = 1000000

# Save TPAT sub-event for every event
# Subevent 36/3600: trlo multi-event TPAT information
do_tpat = 1

# Save LMU scalers on spill triggers (10..13).
# Subevent 37/3700: lmu scalers (input, before / after DT & after reduction)
do_lmu_scalers = 1

# Send beam samplers and LMU scalers via UDP, !="" -> target host.
do_udp = "lxg1275.gsi.de"
Attachment 4: setting.1584673412
1584673412
Fri Mar 20 04:03:32 CET 2020
e127pi:mrcc:mscf1:getGainCommon 1
e127pi:mrcc:mscf1:getShapingTimeCommon 1
e127pi:mrcc:mscf1:getThresholdCommon 2
e127pi:mrcc:mscf1:getPzCommon  100
e127pi:mrcc:mscf2:getGainCommon 1
e127pi:mrcc:mscf2:getShapingTimeCommon 1
e127pi:mrcc:mscf2:getThresholdCommon 2
e127pi:mrcc:mscf2:getPzCommon  100
e127pi:mrcc:mscf3:getGainCommon 6
e127pi:mrcc:mscf3:getShapingTimeCommon 3
e127pi:mrcc:mscf3:getThresholdCommon 1
e127pi:mrcc:mscf3:getPzCommon  38
e127pi:mrcc:mscf1:getGain1     4
e127pi:mrcc:mscf1:getGain2     4
e127pi:mrcc:mscf1:getGain3     4
e127pi:mrcc:mscf1:getGain4     4
e127pi:mrcc:mscf1:getShapingTime1 1
e127pi:mrcc:mscf1:getShapingTime2 1
e127pi:mrcc:mscf1:getShapingTime3 1
e127pi:mrcc:mscf1:getShapingTime4 1
e127pi:mrcc:mscf2:getGain1     9
e127pi:mrcc:mscf2:getGain2     4
e127pi:mrcc:mscf2:getGain3     8
e127pi:mrcc:mscf2:getGain4     8
e127pi:mrcc:mscf2:getShapingTime1 2
e127pi:mrcc:mscf2:getShapingTime2 2
e127pi:mrcc:mscf2:getShapingTime3 2
e127pi:mrcc:mscf2:getShapingTime4 2
e127pi:mrcc:mscf3:getGain1     15
e127pi:mrcc:mscf3:getGain2     0
e127pi:mrcc:mscf3:getGain3     15
e127pi:mrcc:mscf3:getGain4     10
e127pi:mrcc:mscf3:getShapingTime1 0
e127pi:mrcc:mscf3:getShapingTime2 0
e127pi:mrcc:mscf3:getShapingTime3 1
e127pi:mrcc:mscf3:getShapingTime4 1
e127pi:mrcc:mscf1:getThreshold1 4
e127pi:mrcc:mscf1:getThreshold2 4
e127pi:mrcc:mscf1:getThreshold3 4
e127pi:mrcc:mscf1:getThreshold4 1
e127pi:mrcc:mscf1:getThreshold5 4
e127pi:mrcc:mscf1:getThreshold6 4
e127pi:mrcc:mscf1:getThreshold7 4
e127pi:mrcc:mscf1:getThreshold8 4
e127pi:mrcc:mscf1:getThreshold9 4
e127pi:mrcc:mscf1:getThreshold10 5
e127pi:mrcc:mscf1:getThreshold11 5
e127pi:mrcc:mscf1:getThreshold12 5
e127pi:mrcc:mscf1:getThreshold13 3
e127pi:mrcc:mscf1:getThreshold14 4
e127pi:mrcc:mscf1:getThreshold15 5
e127pi:mrcc:mscf1:getThreshold16 5
e127pi:mrcc:mscf1:getPz1       128
e127pi:mrcc:mscf1:getPz2       128
e127pi:mrcc:mscf1:getPz3       128
e127pi:mrcc:mscf1:getPz4       128
e127pi:mrcc:mscf1:getPz5       128
e127pi:mrcc:mscf1:getPz6       128
e127pi:mrcc:mscf1:getPz7       128
e127pi:mrcc:mscf1:getPz8       128
e127pi:mrcc:mscf1:getPz9       128
e127pi:mrcc:mscf1:getPz10      128
e127pi:mrcc:mscf1:getPz11      128
e127pi:mrcc:mscf1:getPz12      128
e127pi:mrcc:mscf1:getPz13      128
e127pi:mrcc:mscf1:getPz14      128
e127pi:mrcc:mscf1:getPz15      128
e127pi:mrcc:mscf1:getPz16      128
e127pi:mrcc:mscf2:getThreshold1 255
e127pi:mrcc:mscf2:getThreshold2 255
e127pi:mrcc:mscf2:getThreshold3 0
e127pi:mrcc:mscf2:getThreshold4 255
e127pi:mrcc:mscf2:getThreshold5 255
e127pi:mrcc:mscf2:getThreshold6 255
e127pi:mrcc:mscf2:getThreshold7 255
e127pi:mrcc:mscf2:getThreshold8 255
e127pi:mrcc:mscf2:getThreshold9 255
e127pi:mrcc:mscf2:getThreshold10 255
e127pi:mrcc:mscf2:getThreshold11 0
e127pi:mrcc:mscf2:getThreshold12 255
e127pi:mrcc:mscf2:getThreshold13 255
e127pi:mrcc:mscf2:getThreshold14 255
e127pi:mrcc:mscf2:getThreshold15 0
e127pi:mrcc:mscf2:getThreshold16 255
e127pi:mrcc:mscf2:getPz1       128
e127pi:mrcc:mscf2:getPz2       128
e127pi:mrcc:mscf2:getPz3       87
e127pi:mrcc:mscf2:getPz4       255
e127pi:mrcc:mscf2:getPz5       255
e127pi:mrcc:mscf2:getPz6       255
e127pi:mrcc:mscf2:getPz7       255
e127pi:mrcc:mscf2:getPz8       255
e127pi:mrcc:mscf2:getPz9       255
e127pi:mrcc:mscf2:getPz10      255
e127pi:mrcc:mscf2:getPz11      85
e127pi:mrcc:mscf2:getPz12      255
e127pi:mrcc:mscf2:getPz13      255
e127pi:mrcc:mscf2:getPz14      255
e127pi:mrcc:mscf2:getPz15      85
e127pi:mrcc:mscf2:getPz16      255
e127pi:mrcc:mscf3:getThreshold1 5
e127pi:mrcc:mscf3:getThreshold2 255
e127pi:mrcc:mscf3:getThreshold3 255
e127pi:mrcc:mscf3:getThreshold4 255
e127pi:mrcc:mscf3:getThreshold5 255
e127pi:mrcc:mscf3:getThreshold6 255
e127pi:mrcc:mscf3:getThreshold7 255
e127pi:mrcc:mscf3:getThreshold8 255
e127pi:mrcc:mscf3:getThreshold9 255
e127pi:mrcc:mscf3:getThreshold10 255
e127pi:mrcc:mscf3:getThreshold11 255
e127pi:mrcc:mscf3:getThreshold12 255
e127pi:mrcc:mscf3:getThreshold13 255
e127pi:mrcc:mscf3:getThreshold14 255
e127pi:mrcc:mscf3:getThreshold15 255
e127pi:mrcc:mscf3:getThreshold16 255
e127pi:mrcc:mscf3:getPz1       128
e127pi:mrcc:mscf3:getPz2       128
e127pi:mrcc:mscf3:getPz3       128
e127pi:mrcc:mscf3:getPz4       128
e127pi:mrcc:mscf3:getPz5       128
e127pi:mrcc:mscf3:getPz6       128
e127pi:mrcc:mscf3:getPz7       128
e127pi:mrcc:mscf3:getPz8       128
e127pi:mrcc:mscf3:getPz9       128
e127pi:mrcc:mscf3:getPz10      128
e127pi:mrcc:mscf3:getPz11      128
e127pi:mrcc:mscf3:getPz12      128
e127pi:mrcc:mscf3:getPz13      128
e127pi:mrcc:mscf3:getPz14      128
e127pi:mrcc:mscf3:getPz15      128
e127pi:mrcc:mscf3:getPz16      128
e127pi:mrcc:mscf1:getSingleChMode 0
e127pi:mrcc:mscf2:getSingleChMode 0
e127pi:mrcc:mscf3:getSingleChMode 0
e127pi:mrcc:mscf1:getRcMode    1
e127pi:mrcc:mscf2:getRcMode    1
e127pi:mrcc:mscf3:getRcMode    1
e127pi:mrcc:mscf1:getAutoPZ    0
e127pi:mrcc:mscf2:getAutoPZ    0
e127pi:mrcc:mscf3:getAutoPZ    1
e127pi:mrcc:mscf1:getMultiplicityHi 8
e127pi:mrcc:mscf2:getMultiplicityHi 8
e127pi:mrcc:mscf3:getMultiplicityHi 8
e127pi:mrcc:mscf1:getMultiplicityLo 4
e127pi:mrcc:mscf2:getMultiplicityLo 4
e127pi:mrcc:mscf3:getMultiplicityLo 1
e127pi:mrcc:mscf1:getSumTrgThresh 10
e127pi:mrcc:mscf2:getSumTrgThresh 10
e127pi:mrcc:mscf3:getSumTrgThresh 100
e127pi:mrcc:mscf1:getBlrOn     1
e127pi:mrcc:mscf2:getBlrOn     1
e127pi:mrcc:mscf3:getBlrOn     0
e127pi:mrcc:mscf1:getCoincTime 128
e127pi:mrcc:mscf2:getCoincTime 128
e127pi:mrcc:mscf3:getCoincTime 100
e127pi:mrcc:mscf1:getThreshOffset 100
e127pi:mrcc:mscf2:getThreshOffset 100
e127pi:mrcc:mscf3:getThreshOffset 1
e127pi:mrcc:mscf1:getShaperOffset 100
e127pi:mrcc:mscf2:getShaperOffset 100
e127pi:mrcc:mscf3:getShaperOffset 100
e127pi:mrcc:mscf1:getBlrThresh 25
e127pi:mrcc:mscf2:getBlrThresh 25
e127pi:mrcc:mscf3:getBlrThresh 10
e127pi:mrcc:mscf1:getECLDelay  0
e127pi:mrcc:mscf2:getECLDelay  0
e127pi:mrcc:mscf3:getECLDelay  0
  85   Fri Mar 20 16:54:53 2020 JanDAQBaF OFF downscaled red=32 
I introduced a downscaling by a factor of 2^5=32 for the BaF2 during target OFF.
The reason is, that we get a lot reasonable x-ray counts (K-alpha, K-REC) outside target ON phase.
So i want to minimize our deadtime during target OFF, to be able to use the data efficiently if needed.
BaF2 is not really needed in target OFF.
  86   Fri Mar 20 16:58:02 2020 JanDAQXray2 & Xray3 cabling 
We found that Xray2 and Xray3 the cabling is not consistent:

90 degree detector 
> E_Xray2 for energy
> t_Xray3 for times

145 degree detector
> E_Xray3 for energy
> t_Xray2 for timing

35 degree detector
> E_Xray1
> t_Xray1

We can run like this, but should be aware of it!
  149   Sat Mar 21 22:57:28 2020 Laszlo, JanDAQchanging cables of the Xray 90 and 145 
Energy signals of 90 and 145 degree detector have been checked and exchanged
They were connected to the wrong ADC channel.

Now 
E_Xray2 and t_Xray2 should belong to 90 degree
E_Xray3 and t_Xray3 belong to 145 degree
  250   Mon Mar 23 14:23:01 2020 Pierre-MichelDAQBackup recoil files 
Recoil detector files backup to lxg1260:/data.local2/hillenbrand/Laszlo
  297   Fri Apr 30 10:55:34 2021 Jan GloriusDAQXray multi-triggers - blocking gate2021
From the CFD of Xray1 (90deg) we get multiple trigger signals every ~5sec for unknown reasons. 
No hint from the preamp signals.

The solution now is to have an extended blocking gate active in the trlo-config of node 2.
There is now a trigger_stretch of 2500ns for all Xray triggers:

trig_stretch(1)  = 2500ns;
trig_stretch(2)  = 2500ns;
trig_stretch(3)  = 2500ns;

This prevents the multiple triggers to reach the lmu (before_dt scalers)
However, this will also lead to a very small loss of good signal triggers that overlay within 2.5 us.

This has to be taken into account for deadtime determination.
  316   Thu May 6 11:03:46 2021 Jan GloriusDAQCabling Documentation2021
Attachment 1: e127b_cabling_docu_06_05_2021_.pdf
e127b_cabling_docu_06_05_2021_.pdf e127b_cabling_docu_06_05_2021_.pdf
Attachment 2: e127b_2021_cabling_documentation.xlsx
  345   Sun May 16 12:55:48 2021 Jan GloriusDAQevent server lxg1299:60032021
new event server is set up at lxg1299 on port 6003
It runs as:
/data.local1/gstore/mrevserv64 lxg1275
  346   Sun May 16 13:31:49 2021 LaszloDAQCabling Documentation2021
Si HV and current was switched in the last documentation.
Attachment 1: e127b_2021_cabling_documentation.xlsx
  414   Mon May 24 06:30:42 2021 RaganDAQNTCAP2021
NTCAP started for recording Schottky data

SC_2021-05-24_06-29-31
\IQ_2021-05-24_06-29-31

Reference level: -30 dBm
Carrier frequency: 245 M
IQ Rate: 20 MS/s

RF attenuation (dB): 40
IF attenuation (dB): 19.9288

masterpath:
o:\E143\iq


ESR settings:
We recorded 3-4 full cycles with 5 stacks.
Then we recorded in SC5 manipulation for 10 min and afterwards in SC3 manipulation for 10 min.
  574   Thu Jun 24 09:43:01 2021 Jan GloriusDAQUnpacker2021
The unpacker used for the production runs of E127b is located at 
/u/litv-exp/unpacker/unpackexps/e127_TO_2021_with_ECL

It is also aliased for litv-exp user as: E127_unpack

This is for the data structure as documented here:
https://elog.gsi.de/esr/E127/346

As of now, this is compiled for ROOT v6-18-04 located here:
/cvmfs/csee.gsi.de/root/618-04/bin/root
  579   Wed Oct 13 15:15:53 2021 JanDAQroot-file header for analysis2021
Attached is the header file needed for root analysis.
Attachment 1: e127b.h
   // Declaration of leaf types
   UInt_t          TRIGGER;
   UInt_t          EVENTNO;
   UInt_t          Si_HV;
   UInt_t          Si_current;
   UInt_t          PARTICLE_trigger;
   UInt_t          PARTICLE_vulom_timestamp_lo;
   UInt_t          PARTICLE_vulom_timestamp_hi;
   UInt_t          PARTICLE_tpat;
   UInt_t          PARTICLE_WR_timestamp1;
   UInt_t          PARTICLE_WR_timestamp2;
   UInt_t          PARTICLE_WR_timestamp3;
   UInt_t          PARTICLE_WR_timestamp4;
   UInt_t          PARTICLE_mega_clock;
   UInt_t          PARTICLE_trafo;
   UInt_t          PARTICLE_I_cool;
   UInt_t          PARTICLE_U_cool;
   UInt_t          PARTICLE_jet_S1;
   UInt_t          PARTICLE_jet_S2;
   UInt_t          RATE_Si_ON_before_lmu;
   UInt_t          RATE_Si_ON_before_dt;
   UInt_t          RATE_Si_ON_after_dt;
   UInt_t          RATE_Si_ON_after_red;
   UInt_t          RATE_Si_OFF_before_lmu;
   UInt_t          RATE_Si_OFF_before_dt;
   UInt_t          RATE_Si_OFF_after_dt;
   UInt_t          RATE_Si_OFF_after_red;
   UInt_t          RATE_Xray_ON_before_lmu;
   UInt_t          RATE_Xray_ON_before_dt;
   UInt_t          RATE_Xray_ON_after_dt;
   UInt_t          RATE_Xray_ON_after_red;
   UInt_t          RATE_Xray_OFF_before_lmu;
   UInt_t          RATE_Xray_OFF_before_dt;
   UInt_t          RATE_Xray_OFF_after_dt;
   UInt_t          RATE_Xray_OFF_after_red;
   UInt_t          RATE_RAW_Si_X;
   UInt_t          RATE_RAW_Si_Y;
   UInt_t          RATE_RAW_Xray1;
   UInt_t          RATE_RAW_Xray2;
   UInt_t          RATE_RAW_Xray3;
   UInt_t          RATE_RAW_BaF_OR;
   UInt_t          RATE_RAW_SiBaF;
   UInt_t          RATE_SiBaF_ON_before_lmu;
   UInt_t          RATE_SiBaF_ON_before_dt;
   UInt_t          RATE_SiBaF_ON_after_dt;
   UInt_t          RATE_SiBaF_ON_after_red;
   UInt_t          RATE_BaF_OFF_before_lmu;
   UInt_t          RATE_BaF_OFF_before_dt;
   UInt_t          RATE_BaF_OFF_after_dt;
   UInt_t          RATE_BaF_OFF_after_red;
	UInt_t          E_SiY[17];
	UInt_t          E_SiX[17];
	UInt_t          t_SiY[17];
	UInt_t          t_SiX[17];
   //~ UInt_t          E_SiX1;
   //~ UInt_t          E_SiX2;
   //~ UInt_t          E_SiX3;
   //~ UInt_t          E_SiX4;
   //~ UInt_t          E_SiX5;
   //~ UInt_t          E_SiX6;
   //~ UInt_t          E_SiX7;
   //~ UInt_t          E_SiX8;
   //~ UInt_t          E_SiX9;
   //~ UInt_t          E_SiX10;
   //~ UInt_t          E_SiX11;
   //~ UInt_t          E_SiX12;
   //~ UInt_t          E_SiX13;
   //~ UInt_t          E_SiX14;
   //~ UInt_t          E_SiX15;
   //~ UInt_t          E_SiX16;
   //~ UInt_t          E_SiY1;
   //~ UInt_t          E_SiY2;
   //~ UInt_t          E_SiY3;
   //~ UInt_t          E_SiY4;
   //~ UInt_t          E_SiY5;
   //~ UInt_t          E_SiY6;
   //~ UInt_t          E_SiY7;
   //~ UInt_t          E_SiY8;
   //~ UInt_t          E_SiY9;
   //~ UInt_t          E_SiY10;
   //~ UInt_t          E_SiY11;
   //~ UInt_t          E_SiY12;
   //~ UInt_t          E_SiY13;
   //~ UInt_t          E_SiY14;
   //~ UInt_t          E_SiY15;
   //~ UInt_t          E_SiY16;
   UInt_t          E_BaF1;
   UInt_t          E_BaF2;
   UInt_t          E_BaF3;
   UInt_t          E_BaF4;
   UInt_t          E_BaF5;
   UInt_t          E_BaF6;
   UInt_t          E_xray1;
   UInt_t          E_xray2;
   UInt_t          E_xray3;
   //~ UInt_t          t_SiX1;
   //~ UInt_t          t_SiX2;
   //~ UInt_t          t_SiX3;
   //~ UInt_t          t_SiX4;
   //~ UInt_t          t_SiX5;
   //~ UInt_t          t_SiX6;
   //~ UInt_t          t_SiX7;
   //~ UInt_t          t_SiX8;
   //~ UInt_t          t_SiX9;
   //~ UInt_t          t_SiX10;
   //~ UInt_t          t_SiX11;
   //~ UInt_t          t_SiX12;
   //~ UInt_t          t_SiX13;
   //~ UInt_t          t_SiX14;
   //~ UInt_t          t_SiX15;
   //~ UInt_t          t_SiX16;
   //~ UInt_t          t_SiY1;
   //~ UInt_t          t_SiY2;
   //~ UInt_t          t_SiY3;
   //~ UInt_t          t_SiY4;
   //~ UInt_t          t_SiY5;
   //~ UInt_t          t_SiY6;
   //~ UInt_t          t_SiY7;
   //~ UInt_t          t_SiY8;
   //~ UInt_t          t_SiY9;
   //~ UInt_t          t_SiY10;
   //~ UInt_t          t_SiY11;
   //~ UInt_t          t_SiY12;
   //~ UInt_t          t_SiY13;
   //~ UInt_t          t_SiY14;
   //~ UInt_t          t_SiY15;
   //~ UInt_t          t_SiY16;
   UInt_t          t_BaF_NOdelay1;
   UInt_t          t_BaF_NOdelay2;
   UInt_t          t_BaF_NOdelay3;
   UInt_t          t_BaF_NOdelay4;
   UInt_t          t_BaF_NOdelay5;
   UInt_t          t_BaF_NOdelay6;
   UInt_t          t_BaF_delayA1;
   UInt_t          t_BaF_delayA2;
   UInt_t          t_BaF_delayA3;
   UInt_t          t_BaF_delayA4;
   UInt_t          t_BaF_delayA5;
   UInt_t          t_BaF_delayA6;
   UInt_t          t_BaF_delayB1;
   UInt_t          t_BaF_delayB2;
   UInt_t          t_BaF_delayB3;
   UInt_t          t_BaF_delayB4;
   UInt_t          t_BaF_delayB5;
   UInt_t          t_BaF_delayB6;
   UInt_t          t_xray1;
   UInt_t          t_xray2;
   UInt_t          t_xray3;
   UInt_t          PHOTON_trigger;
   UInt_t          PHOTON_vulom_timestamp_lo;
   UInt_t          PHOTON_vulom_timestamp_hi;
   UInt_t          PHOTON_tpat;
   UInt_t          PHOTON_WR_timestamp1;
   UInt_t          PHOTON_WR_timestamp2;
   UInt_t          PHOTON_WR_timestamp3;
   UInt_t          PHOTON_WR_timestamp4;
   UInt_t          PHOTON_mega_clock;
   UInt_t          PHOTON_trafo;
   UInt_t          PHOTON_I_cool;
   UInt_t          PHOTON_U_cool;
   UInt_t          PHOTON_jet_S1;
   UInt_t          PHOTON_jet_S2;

   // List of branches
   TBranch        *b_TRIGGER;   //!
   TBranch        *b_EVENTNO;   //!
   TBranch        *b_Si_HV;   //!
   TBranch        *b_Si_current;   //!
   TBranch        *b_PARTICLE_trigger;   //!
   TBranch        *b_PARTICLE_vulom_timestamp_lo;   //!
   TBranch        *b_PARTICLE_vulom_timestamp_hi;   //!
   TBranch        *b_PARTICLE_tpat;   //!
   TBranch        *b_PARTICLE_WR_timestamp1;   //!
   TBranch        *b_PARTICLE_WR_timestamp2;   //!
   TBranch        *b_PARTICLE_WR_timestamp3;   //!
   TBranch        *b_PARTICLE_WR_timestamp4;   //!
   TBranch        *b_PARTICLE_mega_clock;   //!
   TBranch        *b_PARTICLE_trafo;   //!
   TBranch        *b_PARTICLE_I_cool;   //!
   TBranch        *b_PARTICLE_U_cool;   //!
   TBranch        *b_PARTICLE_jet_S1;   //!
   TBranch        *b_PARTICLE_jet_S2;   //!
   TBranch        *b_RATE_Si_ON_before_lmu;   //!
   TBranch        *b_RATE_Si_ON_before_dt;   //!
   TBranch        *b_RATE_Si_ON_after_dt;   //!
   TBranch        *b_RATE_Si_ON_after_red;   //!
   TBranch        *b_RATE_Si_OFF_before_lmu;   //!
   TBranch        *b_RATE_Si_OFF_before_dt;   //!
   TBranch        *b_RATE_Si_OFF_after_dt;   //!
   TBranch        *b_RATE_Si_OFF_after_red;   //!
   TBranch        *b_RATE_Xray_ON_before_lmu;   //!
   TBranch        *b_RATE_Xray_ON_before_dt;   //!
   TBranch        *b_RATE_Xray_ON_after_dt;   //!
   TBranch        *b_RATE_Xray_ON_after_red;   //!
   TBranch        *b_RATE_Xray_OFF_before_lmu;   //!
   TBranch        *b_RATE_Xray_OFF_before_dt;   //!
   TBranch        *b_RATE_Xray_OFF_after_dt;   //!
   TBranch        *b_RATE_Xray_OFF_after_red;   //!
   TBranch        *b_RATE_RAW_Si_X;   //!
   TBranch        *b_RATE_RAW_Si_Y;   //!
   TBranch        *b_RATE_RAW_Xray1;   //!
   TBranch        *b_RATE_RAW_Xray2;   //!
   TBranch        *b_RATE_RAW_Xray3;   //!
   TBranch        *b_RATE_RAW_BaF_OR;   //!
   TBranch        *b_RATE_RAW_SiBaF;   //!
   TBranch        *b_RATE_SiBaF_ON_before_lmu;   //!
   TBranch        *b_RATE_SiBaF_ON_before_dt;   //!
   TBranch        *b_RATE_SiBaF_ON_after_dt;   //!
   TBranch        *b_RATE_SiBaF_ON_after_red;   //!
   TBranch        *b_RATE_BaF_OFF_before_lmu;   //!
   TBranch        *b_RATE_BaF_OFF_before_dt;   //!
   TBranch        *b_RATE_BaF_OFF_after_dt;   //!
   TBranch        *b_RATE_BaF_OFF_after_red;   //!
	TBranch          *b_E_SiY[17];
	TBranch          *b_E_SiX[17];
	TBranch          *b_t_SiY[17];
	TBranch          *b_t_SiX[17];
   //~ TBranch        *b_E_SiX1;   //!
   //~ TBranch        *b_E_SiX2;   //!
   //~ TBranch        *b_E_SiX3;   //!
   //~ TBranch        *b_E_SiX4;   //!
   //~ TBranch        *b_E_SiX5;   //!
   //~ TBranch        *b_E_SiX6;   //!
   //~ TBranch        *b_E_SiX7;   //!
   //~ TBranch        *b_E_SiX8;   //!
   //~ TBranch        *b_E_SiX9;   //!
   //~ TBranch        *b_E_SiX10;   //!
   //~ TBranch        *b_E_SiX11;   //!
   //~ TBranch        *b_E_SiX12;   //!
   //~ TBranch        *b_E_SiX13;   //!
   //~ TBranch        *b_E_SiX14;   //!
   //~ TBranch        *b_E_SiX15;   //!
   //~ TBranch        *b_E_SiX16;   //!
   //~ TBranch        *b_E_SiY1;   //!
   //~ TBranch        *b_E_SiY2;   //!
   //~ TBranch        *b_E_SiY3;   //!
   //~ TBranch        *b_E_SiY4;   //!
   //~ TBranch        *b_E_SiY5;   //!
   //~ TBranch        *b_E_SiY6;   //!
   //~ TBranch        *b_E_SiY7;   //!
   //~ TBranch        *b_E_SiY8;   //!
   //~ TBranch        *b_E_SiY9;   //!
   //~ TBranch        *b_E_SiY10;   //!
   //~ TBranch        *b_E_SiY11;   //!
   //~ TBranch        *b_E_SiY12;   //!
   //~ TBranch        *b_E_SiY13;   //!
   //~ TBranch        *b_E_SiY14;   //!
   //~ TBranch        *b_E_SiY15;   //!
   //~ TBranch        *b_E_SiY16;   //!
   TBranch        *b_E_BaF1;   //!
   TBranch        *b_E_BaF2;   //!
   TBranch        *b_E_BaF3;   //!
   TBranch        *b_E_BaF4;   //!
   TBranch        *b_E_BaF5;   //!
   TBranch        *b_E_BaF6;   //!
   TBranch        *b_E_xray1;   //!
   TBranch        *b_E_xray2;   //!
   TBranch        *b_E_xray3;   //!
   //~ TBranch        *b_t_SiX1;   //!
   //~ TBranch        *b_t_SiX2;   //!
   //~ TBranch        *b_t_SiX3;   //!
   //~ TBranch        *b_t_SiX4;   //!
   //~ TBranch        *b_t_SiX5;   //!
   //~ TBranch        *b_t_SiX6;   //!
   //~ TBranch        *b_t_SiX7;   //!
   //~ TBranch        *b_t_SiX8;   //!
   //~ TBranch        *b_t_SiX9;   //!
   //~ TBranch        *b_t_SiX10;   //!
   //~ TBranch        *b_t_SiX11;   //!
   //~ TBranch        *b_t_SiX12;   //!
   //~ TBranch        *b_t_SiX13;   //!
   //~ TBranch        *b_t_SiX14;   //!
   //~ TBranch        *b_t_SiX15;   //!
   //~ TBranch        *b_t_SiX16;   //!
   //~ TBranch        *b_t_SiY1;   //!
   //~ TBranch        *b_t_SiY2;   //!
   //~ TBranch        *b_t_SiY3;   //!
   //~ TBranch        *b_t_SiY4;   //!
   //~ TBranch        *b_t_SiY5;   //!
   //~ TBranch        *b_t_SiY6;   //!
   //~ TBranch        *b_t_SiY7;   //!
   //~ TBranch        *b_t_SiY8;   //!
   //~ TBranch        *b_t_SiY9;   //!
   //~ TBranch        *b_t_SiY10;   //!
   //~ TBranch        *b_t_SiY11;   //!
   //~ TBranch        *b_t_SiY12;   //!
   //~ TBranch        *b_t_SiY13;   //!
   //~ TBranch        *b_t_SiY14;   //!
   //~ TBranch        *b_t_SiY15;   //!
   //~ TBranch        *b_t_SiY16;   //!
   TBranch        *b_t_BaF_NOdelay1;   //!
   TBranch        *b_t_BaF_NOdelay2;   //!
   TBranch        *b_t_BaF_NOdelay3;   //!
   TBranch        *b_t_BaF_NOdelay4;   //!
   TBranch        *b_t_BaF_NOdelay5;   //!
   TBranch        *b_t_BaF_NOdelay6;   //!
   TBranch        *b_t_BaF_delayA1;   //!
   TBranch        *b_t_BaF_delayA2;   //!
   TBranch        *b_t_BaF_delayA3;   //!
   TBranch        *b_t_BaF_delayA4;   //!
   TBranch        *b_t_BaF_delayA5;   //!
   TBranch        *b_t_BaF_delayA6;   //!
   TBranch        *b_t_BaF_delayB1;   //!
   TBranch        *b_t_BaF_delayB2;   //!
   TBranch        *b_t_BaF_delayB3;   //!
   TBranch        *b_t_BaF_delayB4;   //!
   TBranch        *b_t_BaF_delayB5;   //!
   TBranch        *b_t_BaF_delayB6;   //!
   TBranch        *b_t_xray1;   //!
   TBranch        *b_t_xray2;   //!
   TBranch        *b_t_xray3;   //!
   TBranch        *b_PHOTON_trigger;   //!
   TBranch        *b_PHOTON_vulom_timestamp_lo;   //!
   TBranch        *b_PHOTON_vulom_timestamp_hi;   //!
   TBranch        *b_PHOTON_tpat;   //!
   TBranch        *b_PHOTON_WR_timestamp1;   //!
   TBranch        *b_PHOTON_WR_timestamp2;   //!
   TBranch        *b_PHOTON_WR_timestamp3;   //!
   TBranch        *b_PHOTON_WR_timestamp4;   //!
   TBranch        *b_PHOTON_mega_clock;   //!
   TBranch        *b_PHOTON_trafo;   //!
   TBranch        *b_PHOTON_I_cool;   //!
   TBranch        *b_PHOTON_U_cool;   //!
   TBranch        *b_PHOTON_jet_S1;   //!
   TBranch        *b_PHOTON_jet_S2;   //!

	// Set branch addresses
   fChain->SetBranchAddress("TRIGGER", &TRIGGER, &b_TRIGGER);
   fChain->SetBranchAddress("EVENTNO", &EVENTNO, &b_EVENTNO);
   fChain->SetBranchAddress("Si_HV", &Si_HV, &b_Si_HV);
   fChain->SetBranchAddress("Si_current", &Si_current, &b_Si_current);
   fChain->SetBranchAddress("PARTICLE_trigger", &PARTICLE_trigger, &b_PARTICLE_trigger);
   fChain->SetBranchAddress("PARTICLE_vulom_timestamp_lo", &PARTICLE_vulom_timestamp_lo, &b_PARTICLE_vulom_timestamp_lo);
   fChain->SetBranchAddress("PARTICLE_vulom_timestamp_hi", &PARTICLE_vulom_timestamp_hi, &b_PARTICLE_vulom_timestamp_hi);
   fChain->SetBranchAddress("PARTICLE_tpat", &PARTICLE_tpat, &b_PARTICLE_tpat);
   fChain->SetBranchAddress("PARTICLE_WR_timestamp1", &PARTICLE_WR_timestamp1, &b_PARTICLE_WR_timestamp1);
   fChain->SetBranchAddress("PARTICLE_WR_timestamp2", &PARTICLE_WR_timestamp2, &b_PARTICLE_WR_timestamp2);
   fChain->SetBranchAddress("PARTICLE_WR_timestamp3", &PARTICLE_WR_timestamp3, &b_PARTICLE_WR_timestamp3);
   fChain->SetBranchAddress("PARTICLE_WR_timestamp4", &PARTICLE_WR_timestamp4, &b_PARTICLE_WR_timestamp4);
   fChain->SetBranchAddress("PARTICLE_mega_clock", &PARTICLE_mega_clock, &b_PARTICLE_mega_clock);
   fChain->SetBranchAddress("PARTICLE_trafo", &PARTICLE_trafo, &b_PARTICLE_trafo);
   fChain->SetBranchAddress("PARTICLE_I_cool", &PARTICLE_I_cool, &b_PARTICLE_I_cool);
   fChain->SetBranchAddress("PARTICLE_U_cool", &PARTICLE_U_cool, &b_PARTICLE_U_cool);
   fChain->SetBranchAddress("PARTICLE_jet_S1", &PARTICLE_jet_S1, &b_PARTICLE_jet_S1);
   fChain->SetBranchAddress("PARTICLE_jet_S2", &PARTICLE_jet_S2, &b_PARTICLE_jet_S2);
   fChain->SetBranchAddress("RATE_Si_ON_before_lmu", &RATE_Si_ON_before_lmu, &b_RATE_Si_ON_before_lmu);
   fChain->SetBranchAddress("RATE_Si_ON_before_dt", &RATE_Si_ON_before_dt, &b_RATE_Si_ON_before_dt);
   fChain->SetBranchAddress("RATE_Si_ON_after_dt", &RATE_Si_ON_after_dt, &b_RATE_Si_ON_after_dt);
   fChain->SetBranchAddress("RATE_Si_ON_after_red", &RATE_Si_ON_after_red, &b_RATE_Si_ON_after_red);
   fChain->SetBranchAddress("RATE_Si_OFF_before_lmu", &RATE_Si_OFF_before_lmu, &b_RATE_Si_OFF_before_lmu);
   fChain->SetBranchAddress("RATE_Si_OFF_before_dt", &RATE_Si_OFF_before_dt, &b_RATE_Si_OFF_before_dt);
   fChain->SetBranchAddress("RATE_Si_OFF_after_dt", &RATE_Si_OFF_after_dt, &b_RATE_Si_OFF_after_dt);
   fChain->SetBranchAddress("RATE_Si_OFF_after_red", &RATE_Si_OFF_after_red, &b_RATE_Si_OFF_after_red);
   fChain->SetBranchAddress("RATE_Xray_ON_before_lmu", &RATE_Xray_ON_before_lmu, &b_RATE_Xray_ON_before_lmu);
   fChain->SetBranchAddress("RATE_Xray_ON_before_dt", &RATE_Xray_ON_before_dt, &b_RATE_Xray_ON_before_dt);
   fChain->SetBranchAddress("RATE_Xray_ON_after_dt", &RATE_Xray_ON_after_dt, &b_RATE_Xray_ON_after_dt);
   fChain->SetBranchAddress("RATE_Xray_ON_after_red", &RATE_Xray_ON_after_red, &b_RATE_Xray_ON_after_red);
   fChain->SetBranchAddress("RATE_Xray_OFF_before_lmu", &RATE_Xray_OFF_before_lmu, &b_RATE_Xray_OFF_before_lmu);
   fChain->SetBranchAddress("RATE_Xray_OFF_before_dt", &RATE_Xray_OFF_before_dt, &b_RATE_Xray_OFF_before_dt);
   fChain->SetBranchAddress("RATE_Xray_OFF_after_dt", &RATE_Xray_OFF_after_dt, &b_RATE_Xray_OFF_after_dt);
   fChain->SetBranchAddress("RATE_Xray_OFF_after_red", &RATE_Xray_OFF_after_red, &b_RATE_Xray_OFF_after_red);
   fChain->SetBranchAddress("RATE_RAW_Si_X", &RATE_RAW_Si_X, &b_RATE_RAW_Si_X);
   fChain->SetBranchAddress("RATE_RAW_Si_Y", &RATE_RAW_Si_Y, &b_RATE_RAW_Si_Y);
   fChain->SetBranchAddress("RATE_RAW_Xray1", &RATE_RAW_Xray1, &b_RATE_RAW_Xray1);
   fChain->SetBranchAddress("RATE_RAW_Xray2", &RATE_RAW_Xray2, &b_RATE_RAW_Xray2);
   fChain->SetBranchAddress("RATE_RAW_Xray3", &RATE_RAW_Xray3, &b_RATE_RAW_Xray3);
   fChain->SetBranchAddress("RATE_RAW_BaF_OR", &RATE_RAW_BaF_OR, &b_RATE_RAW_BaF_OR);
   fChain->SetBranchAddress("RATE_RAW_SiBaF", &RATE_RAW_SiBaF, &b_RATE_RAW_SiBaF);
   fChain->SetBranchAddress("RATE_SiBaF_ON_before_lmu", &RATE_SiBaF_ON_before_lmu, &b_RATE_SiBaF_ON_before_lmu);
   fChain->SetBranchAddress("RATE_SiBaF_ON_before_dt", &RATE_SiBaF_ON_before_dt, &b_RATE_SiBaF_ON_before_dt);
   fChain->SetBranchAddress("RATE_SiBaF_ON_after_dt", &RATE_SiBaF_ON_after_dt, &b_RATE_SiBaF_ON_after_dt);
   fChain->SetBranchAddress("RATE_SiBaF_ON_after_red", &RATE_SiBaF_ON_after_red, &b_RATE_SiBaF_ON_after_red);
   fChain->SetBranchAddress("RATE_BaF_OFF_before_lmu", &RATE_BaF_OFF_before_lmu, &b_RATE_BaF_OFF_before_lmu);
   fChain->SetBranchAddress("RATE_BaF_OFF_before_dt", &RATE_BaF_OFF_before_dt, &b_RATE_BaF_OFF_before_dt);
   fChain->SetBranchAddress("RATE_BaF_OFF_after_dt", &RATE_BaF_OFF_after_dt, &b_RATE_BaF_OFF_after_dt);
   fChain->SetBranchAddress("RATE_BaF_OFF_after_red", &RATE_BaF_OFF_after_red, &b_RATE_BaF_OFF_after_red);
	for(int a=1;a<17;a++)
	{
		fChain->SetBranchAddress(Form("E_SiX%d",a),&E_SiX[a], &b_E_SiX[a]);
		fChain->SetBranchAddress(Form("E_SiY%d",a),&E_SiY[a], &b_E_SiY[a]);
		fChain->SetBranchAddress(Form("t_SiX%d",a),&t_SiX[a], &b_t_SiX[a]);
		fChain->SetBranchAddress(Form("t_SiY%d",a),&t_SiY[a], &b_t_SiY[a]);
	}
   //~ fChain->SetBranchAddress("E_SiX1", &E_SiX1, &b_E_SiX1);
   //~ fChain->SetBranchAddress("E_SiX2", &E_SiX2, &b_E_SiX2);
   //~ fChain->SetBranchAddress("E_SiX3", &E_SiX3, &b_E_SiX3);
   //~ fChain->SetBranchAddress("E_SiX4", &E_SiX4, &b_E_SiX4);
   //~ fChain->SetBranchAddress("E_SiX5", &E_SiX5, &b_E_SiX5);
   //~ fChain->SetBranchAddress("E_SiX6", &E_SiX6, &b_E_SiX6);
   //~ fChain->SetBranchAddress("E_SiX7", &E_SiX7, &b_E_SiX7);
   //~ fChain->SetBranchAddress("E_SiX8", &E_SiX8, &b_E_SiX8);
   //~ fChain->SetBranchAddress("E_SiX9", &E_SiX9, &b_E_SiX9);
   //~ fChain->SetBranchAddress("E_SiX10", &E_SiX10, &b_E_SiX10);
   //~ fChain->SetBranchAddress("E_SiX11", &E_SiX11, &b_E_SiX11);
   //~ fChain->SetBranchAddress("E_SiX12", &E_SiX12, &b_E_SiX12);
   //~ fChain->SetBranchAddress("E_SiX13", &E_SiX13, &b_E_SiX13);
   //~ fChain->SetBranchAddress("E_SiX14", &E_SiX14, &b_E_SiX14);
   //~ fChain->SetBranchAddress("E_SiX15", &E_SiX15, &b_E_SiX15);
   //~ fChain->SetBranchAddress("E_SiX16", &E_SiX16, &b_E_SiX16);
   //~ fChain->SetBranchAddress("E_SiY1", &E_SiY1, &b_E_SiY1);
   //~ fChain->SetBranchAddress("E_SiY2", &E_SiY2, &b_E_SiY2);
   //~ fChain->SetBranchAddress("E_SiY3", &E_SiY3, &b_E_SiY3);
   //~ fChain->SetBranchAddress("E_SiY4", &E_SiY4, &b_E_SiY4);
   //~ fChain->SetBranchAddress("E_SiY5", &E_SiY5, &b_E_SiY5);
   //~ fChain->SetBranchAddress("E_SiY6", &E_SiY6, &b_E_SiY6);
   //~ fChain->SetBranchAddress("E_SiY7", &E_SiY7, &b_E_SiY7);
   //~ fChain->SetBranchAddress("E_SiY8", &E_SiY8, &b_E_SiY8);
   //~ fChain->SetBranchAddress("E_SiY9", &E_SiY9, &b_E_SiY9);
   //~ fChain->SetBranchAddress("E_SiY10", &E_SiY10, &b_E_SiY10);
   //~ fChain->SetBranchAddress("E_SiY11", &E_SiY11, &b_E_SiY11);
   //~ fChain->SetBranchAddress("E_SiY12", &E_SiY12, &b_E_SiY12);
   //~ fChain->SetBranchAddress("E_SiY13", &E_SiY13, &b_E_SiY13);
   //~ fChain->SetBranchAddress("E_SiY14", &E_SiY14, &b_E_SiY14);
   //~ fChain->SetBranchAddress("E_SiY15", &E_SiY15, &b_E_SiY15);
   //~ fChain->SetBranchAddress("E_SiY16", &E_SiY16, &b_E_SiY16);
   fChain->SetBranchAddress("E_BaF1", &E_BaF1, &b_E_BaF1);
   fChain->SetBranchAddress("E_BaF2", &E_BaF2, &b_E_BaF2);
   fChain->SetBranchAddress("E_BaF3", &E_BaF3, &b_E_BaF3);
   fChain->SetBranchAddress("E_BaF4", &E_BaF4, &b_E_BaF4);
   fChain->SetBranchAddress("E_BaF5", &E_BaF5, &b_E_BaF5);
   fChain->SetBranchAddress("E_BaF6", &E_BaF6, &b_E_BaF6);
   fChain->SetBranchAddress("E_xray1", &E_xray1, &b_E_xray1);
   fChain->SetBranchAddress("E_xray2", &E_xray2, &b_E_xray2);
   fChain->SetBranchAddress("E_xray3", &E_xray3, &b_E_xray3);
   //~ fChain->SetBranchAddress("t_SiX1", &t_SiX1, &b_t_SiX1);
   //~ fChain->SetBranchAddress("t_SiX2", &t_SiX2, &b_t_SiX2);
   //~ fChain->SetBranchAddress("t_SiX3", &t_SiX3, &b_t_SiX3);
   //~ fChain->SetBranchAddress("t_SiX4", &t_SiX4, &b_t_SiX4);
   //~ fChain->SetBranchAddress("t_SiX5", &t_SiX5, &b_t_SiX5);
   //~ fChain->SetBranchAddress("t_SiX6", &t_SiX6, &b_t_SiX6);
   //~ fChain->SetBranchAddress("t_SiX7", &t_SiX7, &b_t_SiX7);
   //~ fChain->SetBranchAddress("t_SiX8", &t_SiX8, &b_t_SiX8);
   //~ fChain->SetBranchAddress("t_SiX9", &t_SiX9, &b_t_SiX9);
   //~ fChain->SetBranchAddress("t_SiX10", &t_SiX10, &b_t_SiX10);
   //~ fChain->SetBranchAddress("t_SiX11", &t_SiX11, &b_t_SiX11);
   //~ fChain->SetBranchAddress("t_SiX12", &t_SiX12, &b_t_SiX12);
   //~ fChain->SetBranchAddress("t_SiX13", &t_SiX13, &b_t_SiX13);
   //~ fChain->SetBranchAddress("t_SiX14", &t_SiX14, &b_t_SiX14);
   //~ fChain->SetBranchAddress("t_SiX15", &t_SiX15, &b_t_SiX15);
   //~ fChain->SetBranchAddress("t_SiX16", &t_SiX16, &b_t_SiX16);
   //~ fChain->SetBranchAddress("t_SiY1", &t_SiY1, &b_t_SiY1);
   //~ fChain->SetBranchAddress("t_SiY2", &t_SiY2, &b_t_SiY2);
   //~ fChain->SetBranchAddress("t_SiY3", &t_SiY3, &b_t_SiY3);
   //~ fChain->SetBranchAddress("t_SiY4", &t_SiY4, &b_t_SiY4);
   //~ fChain->SetBranchAddress("t_SiY5", &t_SiY5, &b_t_SiY5);
   //~ fChain->SetBranchAddress("t_SiY6", &t_SiY6, &b_t_SiY6);
   //~ fChain->SetBranchAddress("t_SiY7", &t_SiY7, &b_t_SiY7);
   //~ fChain->SetBranchAddress("t_SiY8", &t_SiY8, &b_t_SiY8);
   //~ fChain->SetBranchAddress("t_SiY9", &t_SiY9, &b_t_SiY9);
   //~ fChain->SetBranchAddress("t_SiY10", &t_SiY10, &b_t_SiY10);
   //~ fChain->SetBranchAddress("t_SiY11", &t_SiY11, &b_t_SiY11);
   //~ fChain->SetBranchAddress("t_SiY12", &t_SiY12, &b_t_SiY12);
   //~ fChain->SetBranchAddress("t_SiY13", &t_SiY13, &b_t_SiY13);
   //~ fChain->SetBranchAddress("t_SiY14", &t_SiY14, &b_t_SiY14);
   //~ fChain->SetBranchAddress("t_SiY15", &t_SiY15, &b_t_SiY15);
   //~ fChain->SetBranchAddress("t_SiY16", &t_SiY16, &b_t_SiY16);
   fChain->SetBranchAddress("t_BaF_NOdelay1", &t_BaF_NOdelay1, &b_t_BaF_NOdelay1);
   fChain->SetBranchAddress("t_BaF_NOdelay2", &t_BaF_NOdelay2, &b_t_BaF_NOdelay2);
   fChain->SetBranchAddress("t_BaF_NOdelay3", &t_BaF_NOdelay3, &b_t_BaF_NOdelay3);
   fChain->SetBranchAddress("t_BaF_NOdelay4", &t_BaF_NOdelay4, &b_t_BaF_NOdelay4);
   fChain->SetBranchAddress("t_BaF_NOdelay5", &t_BaF_NOdelay5, &b_t_BaF_NOdelay5);
   fChain->SetBranchAddress("t_BaF_NOdelay6", &t_BaF_NOdelay6, &b_t_BaF_NOdelay6);
   fChain->SetBranchAddress("t_BaF_delayA1", &t_BaF_delayA1, &b_t_BaF_delayA1);
   fChain->SetBranchAddress("t_BaF_delayA2", &t_BaF_delayA2, &b_t_BaF_delayA2);
   fChain->SetBranchAddress("t_BaF_delayA3", &t_BaF_delayA3, &b_t_BaF_delayA3);
   fChain->SetBranchAddress("t_BaF_delayA4", &t_BaF_delayA4, &b_t_BaF_delayA4);
   fChain->SetBranchAddress("t_BaF_delayA5", &t_BaF_delayA5, &b_t_BaF_delayA5);
   fChain->SetBranchAddress("t_BaF_delayA6", &t_BaF_delayA6, &b_t_BaF_delayA6);
   fChain->SetBranchAddress("t_BaF_delayB1", &t_BaF_delayB1, &b_t_BaF_delayB1);
   fChain->SetBranchAddress("t_BaF_delayB2", &t_BaF_delayB2, &b_t_BaF_delayB2);
   fChain->SetBranchAddress("t_BaF_delayB3", &t_BaF_delayB3, &b_t_BaF_delayB3);
   fChain->SetBranchAddress("t_BaF_delayB4", &t_BaF_delayB4, &b_t_BaF_delayB4);
   fChain->SetBranchAddress("t_BaF_delayB5", &t_BaF_delayB5, &b_t_BaF_delayB5);
   fChain->SetBranchAddress("t_BaF_delayB6", &t_BaF_delayB6, &b_t_BaF_delayB6);
   fChain->SetBranchAddress("t_xray1", &t_xray1, &b_t_xray1);
   fChain->SetBranchAddress("t_xray2", &t_xray2, &b_t_xray2);
   fChain->SetBranchAddress("t_xray3", &t_xray3, &b_t_xray3);
   fChain->SetBranchAddress("PHOTON_trigger", &PHOTON_trigger, &b_PHOTON_trigger);
   fChain->SetBranchAddress("PHOTON_vulom_timestamp_lo", &PHOTON_vulom_timestamp_lo, &b_PHOTON_vulom_timestamp_lo);
   fChain->SetBranchAddress("PHOTON_vulom_timestamp_hi", &PHOTON_vulom_timestamp_hi, &b_PHOTON_vulom_timestamp_hi);
   fChain->SetBranchAddress("PHOTON_tpat", &PHOTON_tpat, &b_PHOTON_tpat);
   fChain->SetBranchAddress("PHOTON_WR_timestamp1", &PHOTON_WR_timestamp1, &b_PHOTON_WR_timestamp1);
   fChain->SetBranchAddress("PHOTON_WR_timestamp2", &PHOTON_WR_timestamp2, &b_PHOTON_WR_timestamp2);
   fChain->SetBranchAddress("PHOTON_WR_timestamp3", &PHOTON_WR_timestamp3, &b_PHOTON_WR_timestamp3);
   fChain->SetBranchAddress("PHOTON_WR_timestamp4", &PHOTON_WR_timestamp4, &b_PHOTON_WR_timestamp4);
   fChain->SetBranchAddress("PHOTON_mega_clock", &PHOTON_mega_clock, &b_PHOTON_mega_clock);
   fChain->SetBranchAddress("PHOTON_trafo", &PHOTON_trafo, &b_PHOTON_trafo);
   fChain->SetBranchAddress("PHOTON_I_cool", &PHOTON_I_cool, &b_PHOTON_I_cool);
   fChain->SetBranchAddress("PHOTON_U_cool", &PHOTON_U_cool, &b_PHOTON_U_cool);
   fChain->SetBranchAddress("PHOTON_jet_S1", &PHOTON_jet_S1, &b_PHOTON_jet_S1);
   fChain->SetBranchAddress("PHOTON_jet_S2", &PHOTON_jet_S2, &b_PHOTON_jet_S2);
  1   Thu Sep 13 11:42:33 2018 Jan GloriusCollaborationProposal 
Attached is the beam time proposal submitted and accepted by the G-PAC in 2017.
Attachment 1: E127_Reifarth_pg.pdf
E127_Reifarth_pg.pdf E127_Reifarth_pg.pdf E127_Reifarth_pg.pdf E127_Reifarth_pg.pdf E127_Reifarth_pg.pdf E127_Reifarth_pg.pdf E127_Reifarth_pg.pdf E127_Reifarth_pg.pdf
Attachment 2: E127_Approval.pdf
E127_Approval.pdf E127_Approval.pdf E127_Approval.pdf E127_Approval.pdf
  578   Wed Oct 13 15:09:04 2021 JanCollaborationK-REC cross sections A. Surzhykov2021
Attached are the theory K-REC cross sections as calculated by Andrey Surzhykov (August 2021).

They are done for 118Te52+ on H2 at 7.049 and 6.042 MeV/u as well as for 124Xe54+ on H2 at 7.049 MeV/u.


first column - photon angle (deg), second column - cross section (barn/sr). The results are given already in the laboratory frame.

Comment of Andrey on uncertainty:
Important question about theoretical model and, hence, accuracy of calculations. I used slightly improved "impulse approximation" that takes into account momentum and energy distribution of target electron (in initial state). By playing with the models for the Compton profile of target electron, I estimate the accuracy of calculations as 1 %. To be fair, it is rather conservative estimate. I suspect that for large emission angle (around 90 deg) accuracy is even better. But let us stay with 1 %. 
Attachment 1: DCS_Z_52_Tp_7.049MeV_NEW.dat
K-REC angle-differential cross section (barn/sr) in the laboratory frame
Charge of the projectile ion Z = 52
Charge of the target atom Zt = 1
Projectile energy Tp = 7.04900000000000000000000000000 MeV/u
Maximum number of partial waves used = 8
 
0. 0.9517827043684732
1. 1.0066452310231193
2. 1.1711617126669283
3. 1.4451189567110523
4. 1.828161983217117
5. 2.319794535777521
6. 2.919379795380727
7. 3.6261412958994796
8. 4.4391640394603895
9. 5.357395809574483
10. 6.379648679541435
11. 7.50460071327827
12. 8.730797855372112
13. 10.056656006812414
14. 11.480463282529886
15. 13.000382446547578
16. 14.61445352024514
17. 16.320596558942785
18. 18.116614591734237
19. 20.00019671923322
20. 21.968921363650026
21. 24.02025966538133
22. 26.15157902008221
23. 28.3601467499869
24. 30.643133903065568
25. 32.99761917343486
26. 35.42059293629655
27. 37.90896139054262
28. 40.4595508020561
29.000000000000004 43.069111840638186
30. 45.73432400341395
31. 48.45180011750791
32. 51.218090914733224
33. 54.0296896710139
34. 56.883036903242385
35. 59.77452511628241
36. 62.70050359284277
37. 65.65728321898483
38. 68.64114133807054
39.00000000000001 71.64832662602382
40. 74.6750639808498
41. 77.71755941944612
42. 80.7720049748392
43.00000000000001 83.83458358708674
44. 86.90147398121269
45. 89.96885552566536
46. 93.03291306493358
47.00000000000001 96.08984172009822
48. 99.13585165125326
49. 102.16717277588967
50. 105.18005943750022
51. 108.17079501883593
52. 111.13569649441845
53. 114.07111891708914
54. 116.97345983355952
55.00000000000001 119.83916362410676
56. 122.66472576174371
57. 125.44669698637684
58.00000000000001 128.1816873896506
59. 130.86637040635904
60. 133.49748670849502
61. 136.07184799817944
62. 138.58634069590647
63.00000000000001 141.03792952070884
64. 143.42366095903168
65.00000000000001 145.74066661927378
66. 147.98616646912959
67.00000000000001 150.15747195303302
68. 152.25198898717235
69.00000000000001 154.2672208297082
70. 156.20077082398603
71. 158.05034501269628
72. 159.81375462108485
73.00000000000001 161.4889184074721
74. 163.0738648794857
75.00000000000001 164.56673437455828
76. 165.9657810033841
77. 167.26937445516904
78.00000000000001 168.47600166364478
79. 169.58426833295331
80. 170.5929003226392
81. 171.5007448911178
82. 172.30677179711333
83.00000000000001 173.01007425868588
84. 173.6098697695902
85. 174.105500772829
86.00000000000001 174.49643519138178
87. 174.78226681620885
88. 174.9627155517448
89.00000000000001 175.03762751920837
90. 175.00697501817163
91. 174.87085634693935
92. 174.62949548240172
93.00000000000001 174.28324162013348
94.00000000000001 173.83256857561886
95. 173.2780740475935
96. 172.62047874459836
97. 171.8606253759504
98. 170.99947750844117
99.00000000000001 170.03811829018065
100. 168.97774904311123
101. 167.8196877258231
102. 166.56536726840946
103. 165.21633378120697
104. 163.77424463937433
105.00000000000001 162.24086644536905
106. 160.61807287148952
107. 158.90784238475976
108. 157.11225585653915
109. 155.23349405934877
110.00000000000001 153.27383505351617
111. 151.23565146634337
112. 149.1214076666166
113. 146.933656837378
114. 144.67503794999067
114.99999999999999 142.34827264263237
116.00000000000001 139.95616200645725
117. 137.5015832827731
118. 134.98748647467863
119. 132.4168908767123
120. 129.79288152615837
121.00000000000001 127.11860557975686
122. 124.39726861965754
123.00000000000001 121.63213089254982
124. 118.82650348599213
125. 115.98374444604976
126.00000000000001 113.10725484043212
127.00000000000003 110.20047477140473
128. 107.26687934282026
129. 104.30997458569307
130.00000000000003 101.33329334680292
131. 98.34039114488067
132. 95.33484199898601
133. 92.32023423374181
134.00000000000003 89.30016626613966
135. 86.27824237867115
136. 83.25806848358295
137. 80.24324788308304
138.00000000000003 77.23737703035452
139. 74.24404129625275
140. 71.26681074658053
141. 68.30923593484178
142. 65.37484371538308
143. 62.46713308182212
144. 59.589571035660434
145.00000000000003 56.74558848996043
146.00000000000003 53.938576212942536
147. 51.171880816333314
148. 48.448800793261626
149. 45.77258261045728
150.00000000000003 43.14641685945814
151. 40.57343447148395
152. 38.056703000566955
153. 35.599222979470866
154. 33.20392435284915
155. 30.87366299202191
156.00000000000003 28.611217295658832
157. 26.419284880566885
158. 24.30047936668375
159. 22.257327260271655
160. 20.2922649391984
161.00000000000003 18.407635744074394
162. 16.605687178895447
163. 14.888568224708305
164. 13.258326769689953
165. 11.716907158887912
166.00000000000003 10.266147866726094
166.99999999999997 8.907779295234612
168. 7.64342170080646
169. 6.474583252126237
170. 5.402658221753238
171. 4.428925313677599
172.00000000000003 3.554546128993118
173. 2.7805637716616936
174. 2.1079015961596985
175.00000000000003 1.537362098626752
176. 1.0696259529418157
176.99999999999997 0.7052511929759611
178.00000000000003 0.4446725420776998
179. 0.28820089065853977
180. 0.23602292255652846
Attachment 2: DCS_Z_54_Tp_7.049MeV_NEW.dat
K-REC angle-differential cross section (barn/sr) in the laboratory frame
Charge of the projectile ion Z = 54
Charge of the target atom Zt = 1
Projectile energy Tp = 7.04900000000000000000000000000 MeV/u
Maximum number of partial waves used = 8
 
0. 1.2188177109258354
1. 1.278471868213512
2. 1.4573561826377746
3. 1.755236297068105
4. 2.1717220000099693
5. 2.7062678003870118
6. 3.358173730633336
7. 4.126586376498984
8. 5.010500131527964
9. 6.008758673724422
10. 7.1200566614941385
11. 8.342941645525626
12. 9.675816192866327
13. 11.116940219048102
14. 12.664433523735411
15. 14.316278524996479
16. 16.07032318694543
17. 17.924284135163226
18. 19.87574995398717
19. 21.922184659453773
20. 24.060931341397055
21. 26.289215967938564
22. 28.60415134536191
23. 31.002741226136834
24. 33.48188455765655
25. 36.03837986406335
26. 38.66892975337887
27. 41.370145542007556
28. 44.1385519885634
29.000000000000004 46.970592128866635
30. 49.862632203875606
31. 52.81096667226053
32. 55.81182329928007
33. 58.86136831360672
34. 61.95571162373897
35. 65.09091208565872
36. 68.2629828134243
37. 71.46789652444522
38. 74.70159091125002
39.00000000000001 77.95997403164789
40. 81.238929709283
41. 84.53432293669857
42. 87.84200527315627
43.00000000000001 91.15782022959816
44. 94.4776086332971
45. 97.79721396490213
46. 101.11248766076663
47.00000000000001 104.41929437362921
48. 107.71351718491171
49. 110.99106276210144
50. 114.24786645488871
51. 117.47989732394566
52. 120.68316309644969
53. 123.85371504267135
54. 126.98765276817493
55.00000000000001 130.0811289163991
56. 133.1303537766143
57. 136.13159979247695
58.00000000000001 139.08120596662616
59. 141.9755821569921
60. 144.81121326070925
61. 147.58466328174143
62. 150.2925792785512
63.00000000000001 152.93169518835086
64. 155.4988355246892
65.00000000000001 157.9909189453289
66. 160.40496168757622
67.00000000000001 162.73808086841885
68. 164.98749764702174
69.00000000000001 167.15054024732217
70. 169.22464683864368
71. 171.20736827243576
72. 173.09637067341214
73.00000000000001 174.8894378835396
74. 176.58447375748733
75.00000000000001 178.17950430831337
76. 179.67267970231893
77. 181.06227610215524
78.00000000000001 182.34669735741542
79. 183.52447654208868
80. 184.5942773383957
81. 185.5548952666606
82. 186.4052587610087
83.00000000000001 187.14443009080932
84. 187.77160612791133
85. 188.28611895984264
86.00000000000001 188.687436349266
87. 188.97516204010392
88. 189.14903591086127
89.00000000000001 189.20893397578686
90. 189.15486823463294
91. 188.98698637187567
92. 188.70557130637232
93.00000000000001 188.3110405925406
94.00000000000001 187.80394567424474
95. 187.18497099268782
96. 186.45493294970518
97. 185.61477872796422
98. 184.66558496967582
99.00000000000001 183.6085563155263
100. 182.44502380564055
101. 181.17644314449237
102. 179.80439283177637
103. 178.33057216136146
104. 176.7567990905477
105.00000000000001 175.085007981952
106. 173.31724722044834
107. 171.4556767076973
108. 169.50256523689734
109. 167.46028775049814
110.00000000000001 165.33132248371973
111. 163.11824799682356
112. 160.82374009918797
113. 158.4505686683433
114. 156.0015943672253
114.99999999999999 153.47976526301093
116.00000000000001 150.88811335099805
117. 148.22975098710003
118. 145.5078672326172
119. 142.725724115057
120. 139.8866528088619
121.00000000000001 136.99404974000825
122. 134.05137261852877
123.00000000000001 131.06213640310358
124. 128.0299092019544
125. 124.95830811436285
126.00000000000001 121.85099501721349
127.00000000000003 118.7116723010482
128. 115.54407856018597
129. 112.35198424154208
130.00000000000003 109.13918725684333
131. 105.90950856300094
132. 102.66678771546286
133. 99.41487839941789
134.00000000000003 96.15764394377857
135. 92.8989528229059
136. 89.64267415108442
137. 86.3926731747853
138.00000000000003 83.15280676778272
139. 79.92691893420937
140. 76.71883632465385
141. 73.53236377040916
142. 70.37127984098917
143. 67.23933243001787
144. 64.14023437459531
145.00000000000003 61.077659113223454
146.00000000000003 58.05523638735112
147. 55.07654799156941
148. 52.14512357745419
149. 49.26443651600691
150.00000000000003 46.43789982359462
151. 43.66886215623952
152. 40.960603877038
153. 38.31633320142653
154. 35.739182424929524
155. 33.23220423794769
156.00000000000003 30.798368132051035
157. 28.44055690214702
158. 26.16156324879374
159. 23.964086484816164
160. 21.850729350271603
161.00000000000003 19.823994939687914
162. 17.88628374537359
163. 16.03989082046073
164. 14.287003065211067
165. 12.629696639965104
166.00000000000003 11.069934507966204
166.99999999999997 9.609564111139262
168. 8.250315181741737
169. 6.993797692640494
170. 5.841499948798817
171. 4.794786822387042
172.00000000000003 3.8548981337485957
173. 3.022947180277144
174. 2.299919415068962
175.00000000000003 1.6866712770370351
176. 1.1839291739707618
176.99999999999997 0.7922886198415147
178.00000000000003 0.5122135274536522
179. 0.34403565734385344
180. 0.28795422363490114
Attachment 3: DCS_Z_52_Tp_6.042MeV_NEW.dat
K-REC angle-differential cross section (barn/sr) in the laboratory frame
Charge of the projectile ion Z = 52
Charge of the target atom Zt = 1
Projectile energy Tp = 6.04200000000000000000000000000 MeV/u
Maximum number of partial waves used = 8
 
0. 1.1059830488249303
1. 1.1705845094490612
2. 1.3643054217865629
3. 1.6868954962204896
4. 2.1379379797930675
5. 2.716850250037873
6. 3.422884644800823
7. 4.255129526509179
8. 5.212510578921611
9. 6.293792333960063
10. 7.497579925812086
11. 8.82232106907979
12. 10.266308257353163
13. 11.827681178195974
14. 13.504429340155628
15. 15.294394907046415
16. 17.195275734402518
17. 19.20462860266338
18. 21.3198726413356
19. 23.538292938067528
20. 25.85704432629026
21. 28.27315534480606
22. 30.783532362453606
23. 33.38496386074608
24. 36.074124867163256
25. 38.8475815315786
26. 41.70179583812944
27. 44.633130444674165
28. 47.63785364184573
29.000000000000004 50.71214442358309
30. 53.8520976609279
31. 57.05372937078462
32. 60.31298207127901
33. 63.62573021530726
34. 66.98778569383447
35. 70.39490340049566
36. 73.84278684905499
37. 77.32709383530768
38. 80.84344213504548
39.00000000000001 84.38741522976329
40. 87.95456805185732
41. 91.54043274114993
42. 95.14052440467529
43.00000000000001 98.7503468717754
44. 102.36539843667731
45. 105.9811775808656
46. 109.59318866770427
47.00000000000001 113.19694760192732
48. 116.78798744678073
49. 120.3618639917743
50. 123.91416126418622
51. 127.44049697765236
52. 130.9365279113667
53. 134.39795521362424
54. 137.82052962363557
55.00000000000001 141.20005660575865
56. 144.53240139049885
57. 147.81349391684333
58.00000000000001 151.03933367071133
59. 154.20599441451554
60. 157.3096288030467
61. 160.346472881107
62. 163.31285045853312
63.00000000000001 166.20517735846312
64. 169.01996553490915
65.00000000000001 171.75382705591198
66. 174.40347794875575
67.00000000000001 176.96574190392633
68. 179.4375538346996
69.00000000000001 181.81596328944116
70. 184.09813771389628
71. 186.28136556093855
72. 188.36305924543606
73.00000000000001 190.34075794207644
74. 192.21213022417638
75.00000000000001 193.97497654167643
76. 195.6272315367003
77. 197.166966195225
78.00000000000001 198.5923898335825
79. 199.9018519186718
80. 201.09384372092964
81. 202.16699979926182
82. 203.1200993172981
83.00000000000001 203.95206719048417
84. 204.66197506367757
85. 205.24904211906352
86.00000000000001 205.71263571435173
87. 206.05227185136252
88. 206.2676154752499
89.00000000000001 206.3584806047541
90. 206.32483029401018
91. 206.16677642658257
92. 205.88457934252642
93.00000000000001 205.4786472994136
94.00000000000001 204.94953576839728
95. 204.29794656651484
96. 203.52472682657006
97. 202.63086780605636
98. 201.61750353672136
99.00000000000001 200.48590931649807
100. 199.23750004565898
101. 197.8738284091762
102. 196.39658290740232
103. 194.80758573731097
104. 193.10879052666732
105.00000000000001 191.3022799236243
106. 189.3902630443666
107. 187.3750727815542
108. 185.25916297644346
109. 183.0451054576862
110.00000000000001 180.7355869499388
111. 178.33340585553586
112. 175.8414689126046
113. 173.26278773312825
114. 170.6004752245808
114.99999999999999 167.8577418988831
116.00000000000001 165.03789207254906
117. 162.1443199620105
118. 159.18050567822488
119. 156.15001112478888
120. 153.05647580389206
121.00000000000001 149.903612534556
122. 146.6952030877137
123.00000000000001 143.43509374278906
124. 140.12719077053893
125. 136.77545584701824
126.00000000000001 133.38390140362577
127.00000000000003 129.95658591827743
128. 126.49760915284291
129. 123.01110734206114
130.00000000000003 119.50124833923267
131. 115.97222672405493
132. 112.42825887803583
133. 108.87357803298467
134.00000000000003 105.31242929813425
135. 101.74906467149661
136. 98.18773804110306
137. 94.6327001818155
138.00000000000003 91.0881937534257
139. 87.55844830578583
140. 84.04767529673249
141. 80.56006312857376
142. 77.09977220891855
143. 73.67093004161656
144. 70.27762635357502
145.00000000000003 66.92390826319266
146.00000000000003 63.61377549613141
147. 60.35117565411021
148. 57.1399995423664
149. 53.98407656138078
150.00000000000003 50.887170168406506
151. 47.85297341428077
152. 44.885104560922656
153. 41.987102784848155
154. 39.16242397193823
155. 36.41443660861304
156.00000000000003 33.74641777445342
157. 31.161549241208746
158. 28.662913683012476
159. 26.253491002502525
160. 23.93615477741538
161.00000000000003 21.71366883208299
162. 19.588683938120205
163. 17.563734648437823
164. 15.641236268561688
165. 13.823481969071878
166.00000000000003 12.112640042808831
166.99999999999997 10.510751310318
168. 9.01972667682475
169. 7.641344843839871
170. 6.377250178315511
171. 5.2289507420627155
172.00000000000003 4.197816483953261
173. 3.285077597214939
174. 2.491823043926343
175.00000000000003 1.8189992486040147
176. 1.2674089625583536
176.99999999999997 0.83771030048009
178.00000000000003 0.530415950493647
179. 0.3458925586976838
180. 0.28436028898352445
  41   Sun Mar 15 09:42:40 2020 JanCalibrationrun030 - Xray90 calib Am241 
measurement with old tennelec specAmps, do not use for efficiency!

Detector: 90
Source: Am-241
Distance: 167.5mm
Start time: 13:06:55 15.03.2020
Stop time:  13:24:57 15.03.2020

file name: run030_xxxx.lmd
avrg. rate: 650Hz
dead-time:  7%
  42   Sun Mar 15 13:08:38 2020 JanCalibrationrun031 - Xray90 calib Ba133 hi-rate 
measurement with old tennelec specAmps, do not use for efficiency!

Detector: 90
Source: Ba-133 strong source
Distance: 167.5mm
Start time: 13:28:42 15.03.2020
Stop time:13:38:16 15.03.2020

file name: run031_xxxx.lmd
avrg. rate: 2.7kHz
dead-time:  25%
  43   Sun Mar 15 13:40:11 2020 JanCalibrationrun032 - Xray90 calib Ba133 
measurement with old tennelec specAmps, do not use for efficiency!

Detector: 90
Source: Ba-133 weak source
Distance: 167.5mm
Start time: 13:39:30 15.03.2020
Stop time: 13:50:55 15.03.2020

file name: run032_xxxx.lmd
avrg. rate: 150Hz
dead-time:  1.5%
  44   Sun Mar 15 13:52:05 2020 JanCalibrationrun033 - Xray145 calib Am241 
measurement with old tennelec specAmps, do not use for efficiency!

Detector: 145
Source: Am-241
Distance: 305mm
Start time: 14:15;56 15.03.2020
Stop time:  14:40:21 15.03.2020

file name: run033_xxxx.lmd
avrg. rate: 300Hz
dead-time:  4%
  45   Sun Mar 15 14:41:34 2020 JanCalibrationrun034 - Xray145 calib B133 high rate -SOURCE MOVED! 
measurement with old tennelec specAmps, do not use for efficiency!

The source moved during the calibration, measurement stopped at half time.

Detector: 145
Source: B133 high rate
Distance: 305mm
Start time: 14:54:47 15.03.2020
Stop time:  15:06:53 15.03.2020

file name: run034_xxxx.lmd
avrg. rate: 1kHz
dead-time:  11%
  46   Sun Mar 15 15:08:44 2020 JanCalibrationrun035 - Xray145 calib B133 high rate 
measurement with old tennelec specAmps, do not use for efficiency!

Detector: 145
Source: B133 high rate
Distance: 305mm
Start time: 15:10:15 15.03.2020
Stop time:  15:31:16 15.03.2020

file name: run035_xxxx.lmd
avrg. rate: 1kHz
dead-time:  12%
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