CLAS12 Micromegas Tracker: FE electronics eric.delagnes@cea.fr

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CLAS12 Micromegas TrackerFE electronicseric.d
elagnes_at_cea.fr
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Introduction

• Nearly no work made on the FEE since the May
  review.
• 50 of the slides already shown.
• Real work cannot start before March 2010.
• Preliminary study for compatibility with SVT.
• Outline
• Main Specification for the MicromégasTracker FE
  chip.
• VFE expected performances (starting from AFTER
  ones).
• Selected Architecture.
• MTFEC for SVT ?
• Plans.

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Features common to all FE solutions Technology
choices

• Technology choices
• Use an existing chip there are not a lot of
  available tracker chip adapted to both analog
  readout and large detector capacitances
• the APV0.25 designed for CMS could be an option
  (under evaluation)
• nearly a perfect chip
• we already use it.
• APV availability
• APV not designed for high detector capacitance.
• Large occupation time (RC-CR shaping).
• New chip
• Using a well known technology (AMS CMOS 0.35µm)
• very front-end part nearly already designed.
• Chip size if integrates a lot of digital
  electronics.
• Using a more recent technology
• long term availability.
• prepare the future for our lab.
• Less power consumption
• ? Less noisy.

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Features common to all FE Chip solutions

• Packaging, modularity
• For Mmegas Prefer a QFN/QFP package (no bare
  die).
• 32-64 channel/chip is the best modularity for
  integration on FE boards.
• 128 channel/chip gt big chip package difficult
  to handle during test.
• Power consumption
• As we are outside the magnet, the requirements
  can be relaxed/ 5 mW/ch for the FE Chip.
• Configuration (Slow-control) Link
• To program test modes, peaking time, ranges, etc.
• Test system
• Each Channel can be pulsed individually (or all
  together).
• For test purpose and not absolute calibration.
• Input Protections
• Designed to reduce the size (or even the need) of
  the external protections.

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Requirements for the CLAS12 MM electronics (1).

• For the moment only the barrel has been studied
• Use of standard (without resistive sheet)
  Micromegas assumed
• 20000 channels
• Electronics moved away from detector using 0.8m
  Kapton cables
• Particle rate lt 20MHz
• Hit Rategt 48 kHz/strip (considering cluster
  size4)
• External trigger with Max Trigger Rate 20 kHz,
  fixed latency 4.5µs
• Inefficiency due to electronics 2
• Ghost hits/trigger lt 8/view. Noise hits rate
  negligible
• Main functionalities (not necessary performed in
  this order)
• Collect, amplify and filter the detector signal
• Discriminate pulses
• Timestamp pulses
• Select pulses within a L1W ( 100ns) window
  around the L1 accept signal
• Measure signal charge (for centre of gravity
  calculation)
• Many requirements very similar to those of
  COMPASS tracker

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Requirements for the CLAS12 Micromegas
electronics (2).

• Channel Occupancy
• Tocc lt250ns to keep occupancy lt 1.2
• High order filtering (symmetrical shape).
• Shaping peaking time must be
• Large
• To avoid ballistic deficit .
• To Minimize noise.
• Small
• to limit occupancy
• to be Compatible with L1W100ns

From calculations and experience from
COMPASS 100ns peaking time should be ok gt
Tunable between 50-250ns.
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Requirements for the CLAS12 Micromegas
electronics (3).

• Dynamic Range
• 600 9-10 bit Max Signal over ENC required.
• - Max Charge 10 MIP
• - Threshold MIP/10 for efficiency
• - Threshold 6 Thresholds set to 6ENC (for
  noise rejection).
• Max range (and MIP) depends on the detector gain
• gt Variable gain front-end 4 ranges selectable
  by slow control
• i.e 160, 320, 640 fC for Micromegas.
• 40 fC range for Si detectors.
• Exemple
• For the160fC range
• gt MIP 100 Ke-
• gt Th 10 Ke
• gt ENC should be around 1500 e- rms (gives a
  S/N60)
• Feasible with our large detectors ( kapton
  cables) ?

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What we can learn from the AFTER chip

• AMS 0.35µm technology.
• Designed for the TPC of T2K.
• Slow Readout (incompatible with use in trackers)
• But very versatile
• shaping time, dynamic range are matching with
  our needs.
• Front-end part could be re-used nearly as it is
  associated with a custom back-end.
• Modifications (50ns shaping) in progress for
  another experiment.
• Noise deeply tested a complete parameterization
  has been extracted
• Ability to predict the noise in other conditions.
• 1Mrad radiation hardness demonstrated in another
  similar chip we designed using the same
  technology.

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AFTER ASIC design for T2K
IEEE Trans. Nucl Sci, June 2008

• No zero suppress.
• No auto triggering.
• No selective readout.

• AMS 0.35µm techno
• 500000 transistors

• Main features
• Input Current Polarity positive or negative
• 72 Analog Channels
• 4 Gains 120fC, 240fC, 360fC 600fC
• 16 Peaking Time values (100ns to 2µs)
• 511 analog memory cells / Channel
• Fwrite 1MHz-50MHz Fread 20MHz

• Optimized for 20-30pF detector capa
• 12-bit dynamic range
• Slow Control
• Power on reset
• Test modes
• Spy mode on channel 1
• CSA, CR or filter out

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Requirements for the CLAS12 Micromegas
electronics (3).

• Noise
• Must be minimized to be able to operate at low
  gain (if necessary to reduce spark rate).
• Huge Flex detector capacitance of 60-80 pF.
• 1600-2000 ENC (for very low gain operation) seems
  feasible even with short shaping time
• From COMPASS experience.
• From measurements on the AFTER chip.

ENC versus input capacitance for different
peaking times (120 fC range, ICSA400 µA).
Measured on the AFTER chip.
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VFE part of the Chip same as for AFTER
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3 possible options for the FE chip architecture
were proposed

• ONLY DEAD TIME-FREE solutions (with dual-port
  L1 buffers) are proposed
• ASD multihit TDC
• Similar to Micromegas COMPASS tracker readout.
• Time Stamping analog memory
• Trigerless Front-end.
• Selective Readout.
• Analog Memory L1-Buffer (APV-like)
• Similar to GEM COMPASS tracker readout.
• Solution selected
• Better noise rejection.
• Minimum work for us the only which could match
  with the schedule and the available manpower.

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Analog Memory L1 buffer solution (APV-like
solution)

• A Switched Capacitor Array is used as a circular
  analogue buffer
• The analog signals of all the channels is
  continuously sampled at Fs in a Switched
  Capacitor Array (analogue memories).
• When a L1-Trigger occurs it is sent to the chips
  with a FIXED LATENCY (TLAT)
• 3-4 samples on all channels are kept (frozen) for
  each triggered event.
• They are read and multiplexed towards an external
  ADC _at_ Fread.
• Cells are rewritten after readout or if no
  trigger occurs during after TLAT.
• Dead Time Free architecture
• No interruption of writing during readout of a
  triggered event.
• several triggered events can be stored in the
  SCA waiting for readout.
• No on-chip zero suppress all channels are read
  for a trigger.

Triggered cells
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SCA Key parameters

• Fsgt 2/Tp (2 samples in the trailing edge)
• gt Fs 20 MHz for Tpeak 100ns
• SCA DEPTH Latency buffer extra cells
• 8 µs latency gt 160 cells.
• 10 events derandomizing buffer gt 40 cells
• SCA depth 256
• 512 cells is feasible but increase cost

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Main advantages of this solution

• Charge is directly measured.
• Oscilloscope-like operation makes diagnostics
  easier.
• The timing can be accurately calculated from the
  samples
• better than 1/Fs precision In ATLAS LARG ECAL
  1ns rms timing performed with FS40 MHz (and
  tp50ns)
• Pile-up can be detected and even compensated.
• Common mode noise can be calculated and
  subtracted.
• Low frequency noise can be partially eliminated
  (by subtracting baseline samples).
• Operations are performed before zero-suppress
  (discrimination)

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Analog sampling solution (APV-like solution)

• Data flow for the whole MM tracker 1600 MByte/s
  _at_ the ADC output.
• Becomes 20 MByte/s after zero suppress.
• Can be reduced by 3 if an online filtering on
  timing is performed.
• For
• Simple Proven
• Very robust to bad grounding pickup (common
  mode node correction)
• Expertise of Saclay on SCAs
• Against
• Need for high frequency ADC FPGAs close to the
  very front-end.
• Not self triggered
• Need for a L1accept fast and synchronous.

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Use of the Micromégas chip with SVT ?

• Possible issues
• Input DC current limited to 5nA. Can be a problem
  with DC coupled Si detectors
• AC or DC coupled ?
• Increasing DC current capabilities under study.
• Power consumption
• 5mW/ch planned for MM readout gt cooling issue.
• Low power mode for Silicon detectors ?
• Can we move away the electronics (as for MM) ?
• Noise
• Preliminary study made using
• AFTER parameterization.
• Data from the ENC calculations for Barrel
  Modules of the SVT  Note assuming there is a
  mistake in the leakage current specification
  (20nA/ch inst. of 5uA/ch).
• A note (excell file) will be available soon.

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Few words about the noise

• Expressed as Equivalent Nose Charge gt input
  refered noise.
• Several sources, adding quadratically,can be
  categorized
• Parallel noise current noise at chip input.
  Scales as tp1/2
• Serie noise voltage noise at chip input. Scales
  as Cdet and tp-1/2
• 1/f noise 1/f noise of preamp Scales as Cdet.
  Constant with tp.
• 2nd stage noise constant.

• Analytical model takes into acount these noise
  sources.
• Parameters come from
• Measurements on AFTER
• Simulation
• Theory

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ENC Model
In red Chip Parameters (extracted from
measurements) In blue detector parameters
(calculated from theory) Tp  free parameter 
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AFTER measurement compared to model
Measurements (Ibias400µA)
Analytical model (Ibias400µA)
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ENC simul for SVT with AFTER-like FE

• Detector Parameters taken from equivalent Noise
  Charge calculations for Barrel Modules of the
  SVT (excepted Idet)
• Simulations on
• 3 ranges 3 ranges with 40pF added (to simulate
  a kapton cable)
• 3 shaping times (50 ns,100ns, 200ns).
• 2 bias currents for input transistor (5 6mW/ch).

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SVT ENC simulation noise contributions,
5.5mW/ch/ tp50ns
ENC is clearly dominated by serie noise gt
Improvement expected for higher tp
FEMTC model (tp50ns) gt
SVT Note (tp65ns) (reference)gt
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SVT ENC simulation varying tp, IPOL
With tpgt100ns Power6.5mW gt ENClt 2000 e-
(S/Ngt11) for range 12 including 40pF kaptons
cables We could imagine to move SVT
electronics away
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Short term plans.

• No manpower in microelectronics for this project
  before March 2010.
• VFE part with 50ns shaping is currently designed
  for GET.
• Study the use of this chip with Silicon
  detectors.
• Definition of Digital/DAQ electronics and of
  integration gt Irakli talk.
• Before summer 2010 Submission of a small size FE
  chip prototype
• 16 channels x 128 cells for lower prototype cost.
• Test during the fall.
• Check the possibility to use APV
• successful test with new large Micromégas of
  COMPASS last summer , but detailed analysis of
  beam data are required to check the efficiency).