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  HEPHY logbook of the Electronics Group, Page 3 of 4  Not logged in ELOG logo
  ID Date Author Project Measurement Type Object ID Subjectup
  37   Tue May 19 09:31:50 2015 Hao Yin   Noise Test ITA

Everything works except L3 p-side.

The config file is shown in the following:

### Original Configuration File Name: /home/katsuro/tuxdaq_devel/config/delay_scan.latency_scan.cfg ###
### Original Configuration File Name: /home/katsuro/tuxdaq_devel/config/delay_scan.updated.cfg ###
#
# This is the default config file for the APV_BELLE software
#
#
# Lines preceded by a # or ; sign are ignored.
#
# [rem] comments a whole section until the next section start marked by [xxx] .
#

[soc]
ena = 0
addr =
port = 9999

# [vme]
# VME addresses are given in the format
#  {module_name} = {vme_module_number},{vme_address_hex}
#  nec ... NECO module
#  adf ... particular FADC module
#
# Please note that the address ranges are not defined here,
# they are implicitly given by the hardware.
# Module numbers must fill from 0 (this is not checked).
# Please note that no range checking is performed.
# There is no access to VME modules that are not included in this list,

[vme]
nec = 0,0xaa000000

# p side
adf = 0,0x01000000
adf = 1,0x81000000
# n side

# [nec]
# NECO related information
#  mod = 0|1,{shift_register_delay},{adc_range},{win_delay},{win_length},{dead_time},{time_lat},{max_trg}
#          (default: 0,75,0,50?,900?,36,2,1)
#  res = {list of entries in reset sequence}                (default: 2,4)
#  cal = {list of entries in cal sequence}            (default: 2,3,250,251)
#  sw5 = {list of entries in single cal sequence}        (default: 2,3)
#  str = {list of entries in software trigger sequence}        (default: 75)
#  htr = {list of entries in hardware trigger sequence}        (default: 74)
#
# mod specifies to use either the sequencer (0) or the shift register (1) for hardware trigger and the
#  delay of the shift register (0..255); adc_range (0=1Vpp, 1=2Vpp) -- ignored; win_delay and win_length define
#  the starting point (relative to the APV trigger) and length of the ADC gate in transparent mode; dead_time is
#  the number of 254MHz clock cycles which are set to zero for time measurement after an incoming trigger;
#  time_lat is the latency for time measurement in terms of 40MHz clock cycles; max_trg is the number of incoming
#  triggers which required to activate the veto logic (usually 1; 0 completely disables the veto logic)
# res, cal, sw5, str and htr are containing the bits to set in the 256-element sequencer memory (nothing is set at -1)
# Please note that cal+str together produce a calibration request plus subsequent normal trigger, so the time
#  between them is the latency. sw5 is used to send a single cal request to achieve the correct polarity in
#  case the APV inverter is turned on (this feature only works for entire MAMBOs halves = groups of 3 REBOs)
#
# These settings are quite fragile! Do not modify until you know exactly what you are doing.

[nec]

# 30m cables, 40mhz, Tp=50ns, single-trigger
#mod = 0,75,0,70,250,36,2,1
#htr = 64,-1,-1,-1,-1,-1,-1,-1
#str = 100,-1,-1,-1,-1,-1,-1,-1

# TESTBEAM Nov 07, 30m cables, 40mhz, Tp=50ns, multi-trigger (6 samples)
# mod = {0:max triggers, 1:latency, 2:software trigger latency, do not care about the rest}
mod = 0,120,250,0,0,0,0,0

stp = 150,-1,-1,-1,-1,-1,-1,-1
stn = 150,-1,-1,-1,-1,-1,-1,-1

#common settings
rep =  2,-1,-1,-1,-1,-1,-1,-1
ren =  2,-1,-1,-1,-1,-1,-1,-1

cap =  2,52,-1,-1,-1,-1,-1,-1
can =  52,250,-1,-1,-1,-1,-1,-1

# location of file to fir filter can be rel. path
[fir]
# enable fir 1 true otherwise false
ena = 0
# path to fir coef file
pat = /mnt/data/LabLadder5/FIR_L5_class_b-_20150429153730.fir

# [daq]
# DAQ related specifications are given in the format
#  ads = {N},{search_max_subevents},0,x
#  ini = {initevents},{readout_mode},0,x
#  deh = {module_position},{apv_position},0,x
#  i2t = {N},0,0,x
#  pat = 0,0,0,{data_file_path}
#  clk = {N},{Delay25 frequency range},0,x
#  pdl = {Trigger input delay},0,0,x
#  crd = {crate_number},{clkdel},{trgdel},x
#
# ads N gives the number of samples that are read out from the FIFO1 in transparent mode, search_max_subevents is the
#  maximum number of subevents to search for within one ADC stream (default=1).
# ini: initevents is the number of software triggers in the beginning of a run for pedestal and noise
# evaluation. At the beginning of each run, 2*initevents are generated by software, after that the
# selected trigger source (hardware, software of calibration) is activated. The initial evaluation
# events are written to disk as normal events are.
# ini: readout_mode defines whether events beyond the initevents are read in raw transparent mode from FIFO1 (0) or
#  in processed mode (1) where only hit information is read from FIFO3
# deh is the APV chip for which single strip histograms are recorded
# i2t is the maximum number of I2C retries in case of failure
# pat specifies the save path for data files (must include a trailing backslash!)
# clk gives the system clock period in integer ns (25 max.) and the frequency range for the Delay25 chip:
#  0...40 MHz, 1...80 MHz, 2...32 MHz, 3...64 MHz
# pdl specifies the delay setting for the trigger input in 0.5ns steps (0..49)
# crd define the global clock and trigger delays between NECO and SVD3_buffer for crates 0 and 1
#  NOTE: clock and trigger is NOT propagated to any crate(s) NOT specified here


[daq]

# TESTBEAM Nov 07
#Standard
#ads = 600,3,0,x

# TESTBEAM Nov 07
#Multitrigger (6)
#~ ads = 940,6,0,x
ads = 250,1,0,x

# RAW (transparent mode) readout
ini = 300,0,0,x

# PROCESSED readout
#ini = 300,1,0,x

deh = 1,0,0,x
i2t = 5,0,0,x
pat = 0,0,0,/mnt/data/LabLadder5

#standard 40mhz clock (25ns)
clk = 25,0,0,x
pdl = 25,0,0,x

#crate distribution delays (set to mid-range to allow adjustments in both directions)
crd = 0,25,25,x

#we don't use crate 1, so we don't set any delay here -> no clock/trigger to crate 1
###crd = 1,25,25,x


# [hit]
# Hit recognition variables are specified here
#  hcs = {hitcut_/home/hao/Desktop/vme_tests/vme_test_caen/Releaseseed_strip},{hitcut_neighbor_strips}
#  nok = {x.x},0
#  
#
# hcs gives seed and neighbor hit cuts in units of strpAPVip sigma
# nok states the threshold over average noise at which strips are excluded from further analysis (to exclude noisy strips)

[hit]
# si sensor
hcs = 5.0,3.0

# do not exclude strips
nok = 2000.0,0


# [cal]
# Calibration related data
#  lvl = {level},0
#  lat = {latbeg},{latend}
#  sam = {average_samples},{number of samples in 6-tuple mode}
#  grp = {number_of_groups},0
#  lg6 = {latency},{group}
#  lv6 = {startlevel},{endlevel}
#
# lvl is the CLVL amplitude (0..255), 1 is 625e-, 36 is 1 MIP (22500e-) nominally, in reality 26 is 1 MIP
# lat is the Latency range to
#~ cover (latend-latbeg>=2, latend-latbeg<=15)
# sam is the number of samples to average per position for normal and 6-tuple modes
# grp is how many groups to scan (<=8), first group is strips 0,8,16,..., second group is 1,9,17,..., ...
# lg6 defines the latency in 6-tuple mode and which group to observe in that mode
# lv6 defines the scan range of amplitude in 6-tuple mode

[cal]
#real 1 MIP level (22400e)
lvl = 26,0

#real 5 MIPs level
#lvl = 130,0/home/hao/Desktop/vme_tests/vme_test_caen/Release

#LAT=95/98 Calibration (short display)
#lat = 89,100

#LAT=95/98 Calibration (short display for >=50mhz)
#lat = 81,98

#LAT=95/98 Calibration (long peak mode tail display)
lat = 75,100

#common settings
sam = 50,150
grp = 8,0

#6-tuple mode settings
lg6 = 97, 1
#lv6 =  1,95
lv6 =  50,52

 


# [i2c]
# This section defines one or more I2C sets for the APV25. In the [mod] section, those sets are referenced to by their number.
#  ia2 = {number},{mode},{lat},{ipre},{ipcasc},{ipsf},{isha},{issf},{ipsp},{imuxin},{vfp},{vfs},{vpsp},{muxgain}
#
# The I2C settings must be individually numbered (ascending from 0). The easiest case is to use the same
# settings for all chips of one type, but one could go so far to use separate settings for each chip.
# vadj/vpsp is set individually for each apv in the [mod] section, the value specified here is meaningless.

[i2c]

# apv25s1, peak, inverter ON, Tp=50ns, (p side)
ia2 = 0, 63, 23, 98, 52, 34, 34, 34, 55, 34, 30, 60, 0, 4

# apv25s1, peak, inverter OFF, Tp=50ns, (n side)
ia2 = 1, 31, 23, 98, 52, 34, 34, 34, 55, 34, 30, 60, 0, 4


# apv25s1, multi-peak, inverter ON, Tp=50ns, (p side)
#~ ia2 =          0,    61,   17,    98,      52,    34,    34,    34,    55,      34,   30,   60,     0,       4

# apv25s1, multi-peak, inverter OFF, Tp=50ns, (n side)
#~ ia2 =          1,    29,   17,    98,      52,    34,    34,    34,    55,      34,   30,   60,     0,       4

# apv25s1, peak, inverter ON, Tp=50ns, (p side), for cooled APV chips, -10C
#~ ia2 =          0,    61,   17,    85,      45,    30,    50,    30,    48,      30,   30,   50,     0,       4

# apv25s1, multi-peak, inverter OFF, Tp=50ns, (n side), for cooled APV chips, -10C
#~ ia2 =          1,    29,   17,    85,      45,    30,    34,    30,    48,      30,   30,   60,     0,       4


# [mod]
# Detector module (actually hybrid) specifications are given in the format
#  mod = {module_position},{crate_number},{fadc_number},{adc_number},{hybrid_number},m,{adc_delay},0,0,0,0,0,0,{Name}
#  apv = {module_position},{apv_position},{i2c_address},{i2c_settings},{vadj/vpsp},x,0,0,{fadc_offset},{fadc_number},{fadc_channel},{fadc_clkdelay [0..49]},{AD8128_gain},x
#
# mod gives the hybrid/module properties: The position counts from 0 to 7 in beam direction,
#  Name must not contain blanks ("_" is allowed).
# apv describes the chips located on a hybrid
#  and the ADC channel where they are read out, either a Vienna ADC (a) or a FED (f).
# The ADC offset is only available with the Vienna ADCs and shifts the baseline.
#~ # The individual chip vadj setting dominates over the [i2c] setting.

# p-side
[mod]
mod = 1,0,0,0,0,m,24,0,0,0,0,0,0,fw_p

apv = 1,0,34,0,30,x,0,0,0,0,0,0,0,x
apv = 1,1,36,0,30,x,0,0,0,0,1,0,0,x
apv = 1,2,38,0,30,x,0,0,0,0,2,0,0,x
apv = 1,3,40,0,30,x,0,0,0,0,3,0,0,x
apv = 1,4,42,0,30,x,0,0,0,0,4,0,0,x
#~ apv = 1,5,44,0,30,x,0,0,0,0,5,0,0,x


[mod]
mod = 2,0,0,1,1,m,38,0,0,0,0,0,0,ce_p

apv = 2,0,34,0,30,x,0,0,0,0,6,0,0,x
apv = 2,1,36,0,30,x,0,0,0,0,7,0,0,x
apv = 2,2,38,0,30,x,0,0,0,0,8,0,0,x
apv = 2,3,40,0,30,x,0,0,0,0,9,0,0,x
apv = 2,4,42,0,30,x,0,0,0,0,10,0,0,x
apv = 2,5,44,0,30,x,0,0,0,0,11,0,0,x

[mod]
mod = 3,0,0,2,2,m,40,0,0,0,0,0,0,-z_p

apv = 3,0,34,0,30,x,0,0,0,0,12,0,0,x
apv = 3,1,36,0,30,x,0,0,0,0,13,0,0,x
apv = 3,2,38,0,30,x,0,0,0,0,14,0,0,x
apv = 3,3,40,0,30,x,0,0,0,0,15,0,0,x
apv = 3,4,42,0,30,x,0,0,0,0,16,0,0,x
apv = 3,5,44,0,30,x,0,0,0,0,17,0,0,x

[mod]
mod = 4,0,0,3,3,m,24,0,0,0,0,0,0,bw_p

apv = 4,0,34,0,30,x,0,0,0,0,18,0,0,x
apv = 4,1,36,0,30,x,0,0,0,0,19,0,0,x
apv = 4,2,38,0,30,x,0,0,0,0,20,0,0,x
apv = 4,3,40,0,30,x,0,0,0,0,21,0,0,x
apv = 4,4,42,0,30,x,0,0,0,0,22,0,0,x
apv = 4,5,44,0,30,x,0,0,0,0,23,0,0,x

[mod]
#~ mod = 5,0,0,4,4,m,24,0,0,0,0,0,0,L3_p

#~ apv = 5,0,34,0,30,x,0,0,0,0,24,0,0,x
#~ apv = 5,1,36,0,30,x,0,0,0,0,25,0,0,x
#~ apv = 5,2,38,0,30,x,0,0,0,0,26,0,0,x
#~ apv = 5,3,40,0,30,x,0,0,0,0,27,0,0,x
#~ apv = 5,4,42,0,30,x,0,0,0,0,28,0,0,x
#~ apv = 5,5,44,0,30,x,0,0,0,0,29,0,0,x

[mod]
mod = 6,0,0,5,5,m,24,0,0,0,0,0,0,L4_p

apv = 6,0,34,0,30,x,0,0,0,0,30,0,0,x
apv = 6,1,36,0,30,x,0,0,0,0,31,0,0,x
apv = 6,2,38,0,30,x,0,0,0,0,32,0,0,x
apv = 6,3,40,0,30,x,0,0,0,0,33,0,0,x
apv = 6,4,42,0,30,x,0,0,0,0,34,0,0,x
apv = 6,5,44,0,30,x,0,0,0,0,35,0,0,x

[mod]
mod = 7,0,0,6,6,m,24,0,0,0,0,0,0,L5_p

apv = 7,0,34,0,30,x,0,0,0,0,36,0,0,x
apv = 7,1,36,0,30,x,0,0,0,0,37,0,0,x
apv = 7,2,38,0,30,x,0,0,0,0,38,0,0,x
apv = 7,3,40,0,30,x,0,0,0,0,39,0,0,x
apv = 7,4,42,0,30,x,0,0,0,0,40,0,0,x
apv = 7,5,44,0,30,x,0,0,0,0,41,0,0,x

[mod]
mod = 8,0,0,7,7,m,24,0,0,0,0,0,0,L6_p

apv = 8,0,34,0,30,x,0,0,0,0,42,0,0,x
apv = 8,1,36,0,30,x,0,0,0,0,43,0,0,x
apv = 8,2,38,0,30,x,0,0,0,0,44,0,0,x
apv = 8,3,40,0,30,x,0,0,0,0,45,0,0,x
apv = 8,4,42,0,30,x,0,0,0,0,46,0,0,x
apv = 8,5,44,0,30,x,0,0,0,0,47,0,0,x

#---------------------------------------------------- n-side
[mod]
mod = 9,0,1,0,0,m,28,0,0,0,0,0,0,fw_n

apv = 9,0,34,1,30,x,0,0,5,1,0,0,0,x
apv = 9,1,36,1,30,x,0,0,5,1,1,0,0,x
apv = 9,2,38,1,30,x,0,0,5,1,2,0,0,x
apv = 9,3,40,1,30,x,0,0,5,1,3,0,0,x

[mod]
mod = 10,0,1,1,1,m,33,0,0,0,0,0,0,ce_n

apv = 10,0,34,1,30,x,0,0,5,1,6,0,0,x
apv = 10,1,36,1,30,x,0,0,5,1,7,0,0,x
apv = 10,2,38,1,30,x,0,0,5,1,8,0,0,x
apv = 10,3,40,1,30,x,0,0,5,1,9,0,0,x

[mod]
mod = 11,0,1,2,2,m,35,0,0,0,0,0,0,-z_n

apv = 11,0,34,1,30,x,0,0,5,1,12,0,0,x
apv = 11,1,36,1,30,x,0,0,5,1,13,0,0,x
apv = 11,2,38,1,30,x,0,0,5,1,14,0,0,x
apv = 11,3,40,1,30,x,0,0,5,1,15,0,0,x

[mod]
mod = 12,0,1,3,3,m,27,0,0,0,0,0,0,bw_n

apv = 12,0,34,1,30,x,0,0,5,1,18,0,0,x
apv = 12,1,36,1,30,x,0,0,5,1,19,0,0,x
apv = 12,2,38,1,30,x,0,0,5,1,20,0,0,x
apv = 12,3,40,1,30,x,0,0,5,1,21,0,0,x

[mod]
mod = 13,0,1,4,4,m,24,0,0,0,0,0,0,L3_n

#~ apv = 13,0,34,0,30,x,0,0,0,1,24,0,0,x
apv = 13,1,36,0,30,x,0,0,0,1,25,0,0,x
apv = 13,2,38,0,30,x,0,0,0,1,26,0,0,x
apv = 13,3,40,0,30,x,0,0,0,1,27,0,0,x
apv = 13,4,42,0,30,x,0,0,0,1,28,0,0,x
#~ apv = 13,5,44,0,30,x,0,0,0,1,29,0,0,x

[mod]
mod = 14,0,1,5,5,m,24,0,0,0,0,0,0,L4_n

apv = 14,0,34,0,30,x,0,0,0,1,30,0,0,x
apv = 14,1,36,0,30,x,0,0,0,1,31,0,0,x
apv = 14,2,38,0,30,x,0,0,0,1,32,0,0,x
apv = 14,3,40,0,30,x,0,0,0,1,33,0,0,x
#~ apv = 14,4,42,0,30,x,0,0,0,1,34,0,0,x
#~ apv = 14,5,44,0,30,x,0,0,0,1,35,0,0,x

[mod]
mod = 15,0,1,6,6,m,24,0,0,0,0,0,0,L5_n

apv = 15,0,34,0,30,x,0,0,0,1,36,0,0,x
apv = 15,1,36,0,30,x,0,0,0,1,37,0,0,x
apv = 15,2,38,0,30,x,0,0,0,1,38,0,0,x
apv = 15,3,40,0,30,x,0,0,0,1,39,0,0,x
#~ apv = 15,4,42,0,30,x,0,0,0,1,40,0,0,x
#~ apv = 15,5,44,0,30,x,0,0,0,1,41,0,0,x

[mod]
mod = 16,0,1,7,7,m,24,0,0,0,0,0,0,L6_n

apv = 16,0,34,0,30,x,0,0,0,1,42,0,0,x
apv = 16,1,36,0,30,x,0,0,0,1,43,0,0,x
apv = 16,2,38,0,30,x,0,0,0,1,44,0,0,x
apv = 16,3,40,0,30,x,0,0,0,1,45,0,0,x
#~ apv = 16,4,42,0,30,x,0,0,0,1,46,0,0,x
#~ apv = 16,5,44,0,30,x,0,0,0,1,47,0,0,x

  1   Fri Apr 18 17:23:26 2008 Markus FriedlSPS Testbeam June08hybridhybrid 01Noise of hybrid 01, sensor fully bonded, no HV
HV bias not yet glued to backplane
Attachment 1: hybrid01_sen_nohv_pednoise_apv0.png
hybrid01_sen_nohv_pednoise_apv0.png
Attachment 2: hybrid01_sen_nohv_pednoise_apv1.png
hybrid01_sen_nohv_pednoise_apv1.png
  40   Tue May 19 11:01:29 2015 Hao YinBelle IIsystemPedestalPedestalRun

FIRRun001

Baseline measurement without injections, 50000 event,

room temperature.

noise results see attachments.

Attachment 1: 51.png
51.png
Attachment 2: 48.png
48.png
Attachment 3: 46.png
46.png
Attachment 4: 42.png
42.png
Attachment 5: 39.png
39.png
Attachment 6: 36.png
36.png
Attachment 7: 33.png
33.png
Attachment 8: 30.png
30.png
Attachment 9: 27.png
27.png
Attachment 10: 22.png
22.png
Attachment 11: 19.png
19.png
Attachment 12: 16.png
16.png
Attachment 13: 13.png
13.png
Attachment 14: 09.png
09.png
Attachment 15: 06.png
06.png
Attachment 16: 42.png
42.png
  2   Tue Apr 22 19:34:09 2008 Markus FriedlSPS Testbeam June08modulehybrid 01Properties of hybrid 01, sensor fully bonded, HV=100V
HV bias glued to backplane, HV=100V
Attachment 1: hybrid01_sen_hv100V_cal_apv0.png
hybrid01_sen_hv100V_cal_apv0.png
Attachment 2: hybrid01_sen_hv100V_cal_apv1.png
hybrid01_sen_hv100V_cal_apv1.png
Attachment 3: hybrid01_sen_hv100V_pednoise_apv0.png
hybrid01_sen_hv100V_pednoise_apv0.png
Attachment 4: hybrid01_sen_hv100V_pednoise_apv1.png
hybrid01_sen_hv100V_pednoise_apv1.png
Attachment 5: hybrid01_sen_hv100V_cmnoise_apv0.png
hybrid01_sen_hv100V_cmnoise_apv0.png
Attachment 6: hybrid01_sen_hv100V_cmnoise_apv1.png
hybrid01_sen_hv100V_cmnoise_apv1.png
  36   Thu Jun 5 10:34:45 2014 Benedikt WürknerBelle IIsourceSilc ModuleSilc Angle Measurement 10°

Measured the Silc 03/10 Module using the Sr90 Source to have a comparison for the Eta-Distribution at different angles. 

Data can be found on heros in: /home/medialib/LAB_Silc_Angle. 

Plots made with TuxOA for all different regions can be found in /home/users/bwuerkner/plots/. 

 

  33   Thu Jun 5 10:33:46 2014 Benedikt WürknerBelle IIsourceSilc ModuleSilc Angle Measurement 1°

Measured the Silc 03/10 Module using the Sr90 Source to have a comparison for the Eta-Distribution at different angles. 

Data can be found on heros in: /home/medialib/LAB_Silc_Angle. 

Plots made with TuxOA for all different regions can be found in /home/users/bwuerkner/plots/. 

 

  34   Thu Jun 5 10:34:06 2014 Benedikt WürknerBelle IIsourceSilc ModuleSilc Angle Measurement 4°

Measured the Silc 03/10 Module using the Sr90 Source to have a comparison for the Eta-Distribution at different angles. 

Data can be found on heros in: /home/medialib/LAB_Silc_Angle. 

Plots made with TuxOA for all different regions can be found in /home/users/bwuerkner/plots/. 

 

  35   Thu Jun 5 10:34:29 2014 Benedikt WürknerBelle IIsourceSilc ModuleSilc Angle Measurement 7°

Measured the Silc 03/10 Module using the Sr90 Source to have a comparison for the Eta-Distribution at different angles. 

Data can be found on heros in: /home/medialib/LAB_Silc_Angle. 

Plots made with TuxOA for all different regions can be found in /home/users/bwuerkner/plots/. 

 

Entry is currently edited by Hao Yin on 255.255.255.255    50   Fri May 29 11:47:56 2015 Hao YinBelle IIsystemPS FilterTesting PS LV filter and quantifying the required min noise lvl

Data of this entry is recorded in the folder: LV315kHz_Injections
Injecting noise to LV with a freq. of 314 kHz to emulate Caen PS with KenWood PS.

Run Name 315kHzKenWood_: (injecting cmc noise into p-side lv) (attachment 1)
000 ... baseline noise
001 ... 4mA
002 ... 1mA
003 ... 1mA wo Amplifier
004 ... 4mA wo Amplifier
005 ... 0.5mA wo Amplifier
006 ... 2mA wo Amplifier
007 ... 0.2mA wo Amplifier

Run Name 315kHzKenWood_Filter_BW_: (injecting cmc noise into p-side lv with filters (inductance with 470 mH x 6 ) conn. at bw) (attachment 1) (wo Amplifier)
000 ... baseline noise
001 ... 0.2mA
002 ... 0.4mA
003 ... 0.5mA
004 ... 1mA
005 ... 2mA
006 ... 4mA

Run Name 315kHzKenWood_Filer_BW_HVRET-GND:
000 ... baseline noise
001 ... 0.2mA
002 ... 0.4mA
 

  4   Wed Apr 23 13:37:18 2008 Markus FriedlSPS Testbeam June08sourcehybrid 01analysis results of source test
Ignore the "KEK November 2007" title - that's a legacy and is already changed :-)

As of now, there is no distinction in 16 separate zones. However, the gaps between the the zones are clearly visible in the Hit Profile, as the edge strips on both sides have a larger sensitive area and thus collect more hits than other strips; hence the spikes in the (otherwise pretty gaussian) beam profile. There is a single strip with no entries in the center - that's the one that suffered from the bias bond repair action.
SNR=21 (peak mode) is pretty healthy and fits to similar detectors operated with APV25.
All data was taken in multi-peak mode with subsequent hit fitting to obtain amplitude and timing (see separate posting for timing precision).

The verbose output of the analysis is pasted below.


Analysis of vie_run001

Peak Mode, 3 x 200 initevents (first 10 skipped) + 99400 events
Number hybrids:  1	number zones:  2	 number sensors:  1
Using calibration file vie_cal001
No pedestal correction file
Seed/Neighbor/Cluster/Noisy Strips Cuts [RMS noise]: 5.0/3.0/5.0
Min. hitlength:   3


Comments:
SILC module 01
HV=100V, 40MHz, Tp=50ns, 30ns
Sr90 1mCi ,  black cloth cover



Analysis date: 23.04.2008 13:25:09


Analysis settings:
 runname: vie_run001_cluster
 clock: 40.00 MHz
 datafilepath: data/
 outputpath: output/
 subevents:  6
 fitmode: 2 (cal. fit)
 options: h




Results:

ModuleName           ZoneType    Ch    OKCh     OK%   Entries    MClW    MPSignal   Noise   MPSNR   HpSE  Occup
p_side            JP single sensor    256    256   100.0     90385    2.53    21546.1    729.4   20.68   0.53   1.81
Attachment 1: vie_run001_cluster_sig_0.gif
vie_run001_cluster_sig_0.gif
Attachment 2: vie_run001_cluster_noi_0.gif
vie_run001_cluster_noi_0.gif
Attachment 3: vie_run001_cluster_hit_0.gif
vie_run001_cluster_hit_0.gif
Attachment 4: vie_run001_cluster_clw_0.gif
vie_run001_cluster_clw_0.gif
  14   Tue May 20 14:27:50 2008 Markus FriedlBELLE Upgradesourcemicronanalysis results of source test
*** NOTE: AFTER THIS MEASUREMENT WE REALIZED THAT BIASING WAS NOT DONE PROPERLY
          HENCE THE RESULTS BELOW ARE NOT RELIABLE 
          (in fact it is surprising that they are not worse) ***


Please find the results of the lab source test on the new Micron module here.
It is read out with 3 + 3 APV chips on either side.

Results table of the source measurement:
                      p-side     n-side
 Cluster signal [e]    18361      19434
 Strip noise [e]        1142       1193
 Avg cluster width      1.91       1.30
 Single strip SNR       16.1       16.3
 Cluster SNR            11.6       14.3
 Strip pitch [um]       50.0      153.5     

Apparently, the double metal capacitance is not so bad as expected, even though the Micron sensor does not use
the hourglass crossing scheme. Presumably the dielectric between metal 1 and 2 is rather thick (several um).
Strip noise is roughly the same on both p and n side, so the difference in Cluster SNR (*) only stems from the
unequal cluster width (which is a result of the different pitches).

Peak time precision vs SNR (last plot below) is worse compared to the values obtained with various HPK sensors
in the November 2007 beam test at KEK. However, this is a comparison of source and beam and thus might not be
significant. Let's see what we will get in the SPS beam test next week.

(*) Cluster SNR := sum(signal) / (strip_noise * sqrt(cluster_width) )
Attachment 1: vie_micron_run002_signal.gif
vie_micron_run002_signal.gif
Attachment 2: vie_micron_run002_noise.gif
vie_micron_run002_noise.gif
Attachment 3: vie_micron_run002_hit.gif
vie_micron_run002_hit.gif
Attachment 4: vie_micron_run002_clw.gif
vie_micron_run002_clw.gif
Attachment 5: vie_micron_p_run002_tres.gif
vie_micron_p_run002_tres.gif
Attachment 6: vie_micron_n_run002_tres.gif
vie_micron_n_run002_tres.gif
Attachment 7: vie_micron_p_run002_ressnr.gif
vie_micron_p_run002_ressnr.gif
Attachment 8: vie_micron_n_run002_ressnr.gif
vie_micron_n_run002_ressnr.gif
Attachment 9: trms_vs_snr_micron_src.gif
trms_vs_snr_micron_src.gif
  15   Wed Oct 7 14:23:35 2009 Dieter UhlBELLE Upgradehybrid#4hybrid-pitchadapter

opens at upper coat

pitchadapter4_upper_coat_opens.gif

 

shorts at upper coat

pitchadapter4_upper_coat.gif

 

opens at lower coat

pitchadapter4_lower_coat_opens.gif

 

shorts at lower coat

pitchadapter4_lower_coat.gif

  16   Wed Oct 7 14:24:06 2009 Dieter UhlBELLE Upgradehybrid#5hybrid-pitchadapter

shorts at upper coat

pitchadapter5_upper_coat.gif

 

opens at upper coat

pitchadapter5_upper_coat_opens.gif

 

shorts at lower coat

pitchadapter5_lower_coat.gif

 

opens at lower coat

pitchadapter5_lower_coat_opens.gif

  5   Wed Apr 30 16:52:17 2008 Markus FriedlBELLE Upgrademodulemicronmicron sensor glued to frame
soeben haben wir den micron-DSSD (double metal layer) in den 2-teiligen rahmen geklebt und auf beiden seiten
temporäre kapton-stückerln aufgeklebt, über die bias appliziert werden kann. nach trocknung und bonden der
bias-verbindungen (montag, 5.5.2008) wird dieser für sensor-tests zur verfügung stehen.
  6   Wed May 7 15:24:49 2008 Christian IrmlerSPS Testbeam June08modulemodule 10/02properties (noise, intcal), APVs bonded to the sensor
Module tested with 1 and 2 rows bonded to the sensor, respectively. HV = 100 V Ibias (100V) = 19.1 nA Ibias (200V) = 23.7 nA
Attachment 1: modul1002_1row_cal_apv0.png
modul1002_1row_cal_apv0.png
Attachment 2: modul1002_1row_cal_apv1.png
modul1002_1row_cal_apv1.png
Attachment 3: modul1002_1row_cmnoise_apv0.png
modul1002_1row_cmnoise_apv0.png
Attachment 4: modul1002_1row_cmnoise_apv1.png
modul1002_1row_cmnoise_apv1.png
Attachment 5: modul1002_1row_pednoise_apv0.png
modul1002_1row_pednoise_apv0.png
Attachment 6: modul1002_1row_pednoise_apv1.png
modul1002_1row_pednoise_apv1.png
Attachment 7: modul1002_final_cal_apv0.png
modul1002_final_cal_apv0.png
Attachment 8: modul1002_final_cal_apv1.png
modul1002_final_cal_apv1.png
Attachment 9: modul1002_final_cmnoise_apv0.png
modul1002_final_cmnoise_apv0.png
Attachment 10: modul1002_final_cmnoise_apv1.png
modul1002_final_cmnoise_apv1.png
Attachment 11: modul1002_final_pednoise_apv0.png
modul1002_final_pednoise_apv0.png
Attachment 12: modul1002_final_pednoise_apv1.png
modul1002_final_pednoise_apv1.png
  9   Wed May 7 15:26:24 2008 Christian IrmlerSPS Testbeam June08modulemodule 20/09properties (noise, intcal), APVs bonded to the sensor
Module tested with 1 and 2 rows bonded to the sensor, respectively. HV = 100 V Ibias (100 V) = 25.1 nA Ibias (200 V) = 31.4 nA
Attachment 1: modul2009_1row_cal_apv0.png
modul2009_1row_cal_apv0.png
Attachment 2: modul2009_1row_cal_apv1.png
modul2009_1row_cal_apv1.png
Attachment 3: modul2009_1row_cmnoise_apv0.png
modul2009_1row_cmnoise_apv0.png
Attachment 4: modul2009_1row_cmnoise_apv1.png
modul2009_1row_cmnoise_apv1.png
Attachment 5: modul2009_1row_pednoise_apv0.png
modul2009_1row_pednoise_apv0.png
Attachment 6: modul2009_1row_pednoise_apv1.png
modul2009_1row_pednoise_apv1.png
Attachment 7: modul2009_final_cal_apv0.png
modul2009_final_cal_apv0.png
Attachment 8: modul2009_final_cal_apv1.png
modul2009_final_cal_apv1.png
Attachment 9: modul2009_final_cmnoise_apv0.png
modul2009_final_cmnoise_apv0.png
Attachment 10: modul2009_final_cmnoise_apv1.png
modul2009_final_cmnoise_apv1.png
Attachment 11: modul2009_final_pednoise_apv0.png
modul2009_final_pednoise_apv0.png
Attachment 12: modul2009_final_pednoise_apv1.png
modul2009_final_pednoise_apv1.png
  8   Wed May 7 15:40:07 2008 Christian IrmlerSPS Testbeam June08modulemodule 07/07properties (noise, intcal), APVs bonded to the sensor
Module tested with 1 and 2 rows bonded to the sensor, respectively. HV = 100 V Ibias (100 V) = 20.2 nA Ibias (200 V) = 21.9 nA
Attachment 1: modul0707_1row_cal_apv0.png
modul0707_1row_cal_apv0.png
Attachment 2: modul0707_1row_cal_apv1.png
modul0707_1row_cal_apv1.png
Attachment 3: modul0707_1row_cmnoise_apv0.png
modul0707_1row_cmnoise_apv0.png
Attachment 4: modul0707_1row_cmnoise_apv1.png
modul0707_1row_cmnoise_apv1.png
Attachment 5: modul0707_1row_pednoise_apv0.png
modul0707_1row_pednoise_apv0.png
Attachment 6: modul0707_1row_pednoise_apv1.png
modul0707_1row_pednoise_apv1.png
Attachment 7: modul0707_final_cal_apv0.png
modul0707_final_cal_apv0.png
Attachment 8: modul0707_final_cal_apv1.png
modul0707_final_cal_apv1.png
Attachment 9: modul0707_final_cmnoise_apv0.png
modul0707_final_cmnoise_apv0.png
Attachment 10: modul0707_final_cmnoise_apv1.png
modul0707_final_cmnoise_apv1.png
Attachment 11: modul0707_final_pednoise_apv0.png
modul0707_final_pednoise_apv0.png
Attachment 12: modul0707_final_pednoise_apv1.png
modul0707_final_pednoise_apv1.png
  7   Wed May 7 16:12:58 2008 Christian IrmlerSPS Testbeam June08modulemodule 12/08properties (noise, intcal), APVs bonded to the sensor
Module tested with 1 and 2 rows bonded to the sensor, respectively. HV = 100 V Ibias (100 V) = 22.2 nA Ibias (200 V) = 26.5 nA
Attachment 1: modul1208_1row_cal_apv0.png
modul1208_1row_cal_apv0.png
Attachment 2: modul0707_1row_cal_apv1.png
modul0707_1row_cal_apv1.png
Attachment 3: modul0707_1row_cmnoise_apv0.png
modul0707_1row_cmnoise_apv0.png
Attachment 4: modul0707_1row_cmnoise_apv1.png
modul0707_1row_cmnoise_apv1.png
Attachment 5: modul0707_1row_pednoise_apv0.png
modul0707_1row_pednoise_apv0.png
Attachment 6: modul0707_1row_pednoise_apv1.png
modul0707_1row_pednoise_apv1.png
Attachment 7: modul0707_final_cal_apv0.png
modul0707_final_cal_apv0.png
Attachment 8: modul0707_final_cal_apv1.png
modul0707_final_cal_apv1.png
Attachment 9: modul0707_final_cmnoise_apv0.png
modul0707_final_cmnoise_apv0.png
Attachment 10: modul0707_final_cmnoise_apv1.png
modul0707_final_cmnoise_apv1.png
Attachment 11: modul0707_final_pednoise_apv0.png
modul0707_final_pednoise_apv0.png
Attachment 12: modul0707_final_pednoise_apv1.png
modul0707_final_pednoise_apv1.png
  10   Wed May 7 19:05:08 2008 Christian IrmlerSPS Testbeam June08modulemodule 04/04properties (noise, intcal), APVs bonded to the sensor
Module tested with 1 and 2 rows bonded to the sensor, respectively. HV = 100 V Ibias (100 V) = 27.8 nA Ibias (200 V) = 32.7 nA
Attachment 1: modul0404_1row_cal_apv0.png
modul0404_1row_cal_apv0.png
Attachment 2: modul0404_1row_cal_apv1.png
modul0404_1row_cal_apv1.png
Attachment 3: modul0404_1row_cmnoise_apv0.png
modul0404_1row_cmnoise_apv0.png
Attachment 4: modul0404_1row_cmnoise_apv1.png
modul0404_1row_cmnoise_apv1.png
Attachment 5: modul0404_1row_pednoise_apv0.png
modul0404_1row_pednoise_apv0.png
Attachment 6: modul0404_1row_pednoise_apv1.png
modul0404_1row_pednoise_apv1.png
Attachment 7: modul0404_final_cal_apv0.png
modul0404_final_cal_apv0.png
Attachment 8: modul0404_final_cal_apv1.png
modul0404_final_cal_apv1.png
Attachment 9: modul0404_final_cmnoise_apv0.png
modul0404_final_cmnoise_apv0.png
Attachment 10: modul0404_final_cmnoise_apv1.png
modul0404_final_cmnoise_apv1.png
Attachment 11: modul0404_final_pednoise_apv0.png
modul0404_final_pednoise_apv0.png
Attachment 12: modul0404_final_pednoise_apv1.png
modul0404_final_pednoise_apv1.png
  11   Fri May 9 09:56:15 2008 Christian IrmlerSPS Testbeam June08modulemodule 06/03properties (noise, intcal), APVs bonded to the sensor
Module tested with 1 and 2 rows bonded to the sensor, respectively. HV = 100 V Ibias (100 V) = 26.5 nA Ibias (200 V) = 37.8 nA
Attachment 1: modul0603_1row_cal_apv0.png
modul0603_1row_cal_apv0.png
Attachment 2: modul0603_1row_cal_apv1.png
modul0603_1row_cal_apv1.png
Attachment 3: modul0603_1row_cmnoise_apv0.png
modul0603_1row_cmnoise_apv0.png
Attachment 4: modul0603_1row_cmnoise_apv1.png
modul0603_1row_cmnoise_apv1.png
Attachment 5: modul0603_1row_pednoise_apv0.png
modul0603_1row_pednoise_apv0.png
Attachment 6: modul0603_1row_pednoise_apv1.png
modul0603_1row_pednoise_apv1.png
Attachment 7: modul0603_final_cal_apv0.png
modul0603_final_cal_apv0.png
Attachment 8: modul0603_final_cal_apv1.png
modul0603_final_cal_apv1.png
Attachment 9: modul0603_final_cmnoise_apv0.png
modul0603_final_cmnoise_apv0.png
Attachment 10: modul0603_final_cmnoise_apv1.png
modul0603_final_cmnoise_apv1.png
Attachment 11: modul0603_final_pednoise_apv0.png
modul0603_final_pednoise_apv0.png
Attachment 12: modul0603_final_pednoise_apv1.png
modul0603_final_pednoise_apv1.png
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