Calorimeter Electronics

Calorimeter Electronics Jim Pilcher 11-Dec-2008

Introduction • Calorimeters essential for energy measurement in particle physics • Detection over a wide range of energies • Incident particles deposit their energy in a medium • Tank of liquid (water or scintillator), dense medium(iron/scintillator), air • Can be very large (esp. for neutrinos and cosmic rays) • In many calorimeters optical EM radiation is produced • Electronics converts this signal to digital information • For signal processing to calculate energy, time, quality of the measurement J. Pilcher

Introduction • SNO Calorimeter • Detect Cerenkov radiation from interactions of ~ 106 eV neutrinos • Also calorimeters in Double Chooz, Daya Bay, Minos, MiniBoone J. Pilcher

Tile barrel LAr hadronic end-cap (HEC) Tile extended barrel LAr EM end-cap (EMEC) LAr EM barrel LAr forward calorimeter (FCAL) Introduction • Collider detectors calorimeters (to E ~ 1013 eV) • Example for ATLAS Calorimeters • But also ALICE, CMS, LHCb, CDF, D0 • Will not discuss noble liquid calorimeters today J. Pilcher

Introduction • Auger observatory (to E ~ 1021 ev) • Detect fluorescence radiation from air showers induced by cosmic rays • Calorimeter absorption medium is the earth’s atmosphere • Detect muons from decay of hadrons produced in these air showers J. Pilcher

Photo-detectors • Role is to convert optical photons to electrical signal • Photons from Cerenkov radiation or scintillation • Amplify the number of electrons if possible • Many types • See proceedings from Beaune Conference 2005 in NIMA 567 (2006) • In this talk I touch on a few important types • Photomultipliers, Hybrid Photo Diode (HPD), Silicon PMT(SiPMT) • Choice depends on necessary area coverage, spatial segmentation, operation in magnetic field J. Pilcher

Photomultiplier Tubes (PMTs) • As used in ATLAS hadron calorimeter • Ideal current source • Operated at gain of 105 J. Pilcher

Photomultiplier Tubes (PMTs) • Very diverse device • Many sizes and shapes • Much experience from years of usage and development • Wide range of gains (~ 104 to ~107) • Set by operating voltage and number of amplifying stages • The ATLAS device is 10-year-old design • Now quantum efficiencies over 40% • Segmented anodes (eg. 8x8) J. Pilcher

The Physics of PMTs • Design principle • Amplification by electron acceleration in electric field and secondary emission from a metallic dynode Gain = V V is operating voltage  is ~ number of stages Fast devices signal rise time ~1ns transit time ~10ns J. Pilcher

Issues to consider for PMTs • Gain stability • Depends on geometry of dynodes • Emission coefficients of photocathode and dynodes • Requires careful control of temperature and HV • ATLAS PMT have G/G ~ 0.2% / C  1% / V • Magnetic field sensitivity • Low energy secondary electrons are easily deflected • Must use magnetic shielding in magnetic fields • Even for earth’s field • ATLAS PMTs shielded for axial B ~ 200 G (for 1% variation) • After-pulsing • Electron interaction with residual gas in tube • Secondary signal correlated in time with primary J. Pilcher

Hybrid Photodiodes • Used for CMS hadron calorimeter • Must operate in strong magnetic fields • CMS HCAL designed for ambient field of 4T • Need for segmented anode • Limited operational experience with large systems of HPDs J. Pilcher

Photons Electrical signals The Physics of HPDs • Incident photons produce electrons in photocathode • Electrons accelerated in electric field (few kV) • Energetic electrons are strike the silicon • Produce hole-electron pairs and hence current in reversed biased diode (gain) • CMS device operates at 12 kV for gain of 2500 • Can segment silicon structure for spatial information J. Pilcher

Issues to consider for HPDs • Must operate at high voltage without sparking • Cross talk can occur between readout pixels • Sensitivity to variations in magnetic field direction • modifies electron trajectories J. Pilcher

Silicon Photomultipliers • Development to useful devices in recent years • Just emerging from R&D stage • Pixels of ~ 30 m  ~ 30 m formed on a common silicon substrate • Typical sensitive area 1 mm  1 mm • ~ 1000 photosensitive pixels J. Pilcher

Physics of Silicon Photomultipliers • Photons produce hole-electron pairs in Si • Quantum efficiency > 70% • Applied voltage of ~ 50 V produces high local electric fields because of tiny size of structure • Results in gains of 106 • A saturated Geiger mode response (digital) for each pixel struck by photon • Signal from all pixels is on a common output terminal Can count number of photons detected from size of signal J. Pilcher

Issues for Silicon Photomultipliers • Sensitive area is small • Could use one per fiber • Photon detection efficiency ~ 50% because of geometric filling efficiency of pixels • Dark count rate is high ~ 300 kHz • Still limited experience in large systems • CALICE calorimeter for linear collider R&D uses them J. Pilcher

Pulse Shaping • Signal from photodetector is often conditioned prior to digitization • In some applications the photodector signal is digitized at very high rate (Gsps) to record the “wave form” as in an oscilloscope • I will not discuss this option here • Make pulse shape insensitive to timing variations in light collection • Fine details of waveform from photodetector may not be necessary for measurement of interest • Standardized shape facilitates time measurement • Can take multiple samples of the signal to allow estimate of time • Energy and time measurement can be made with the same hardware • Sub nanosecond time measurements are possible • Digital signal processing • Match bandwidth of PMT signal to bandwidth of ADC • Higher speed ADC increases power and cost • 10-year-old ATLAS design was close to practical limit at the time • Higher speed now practical if needed (eg sLHC readout) J. Pilcher

Pulse Shaping • ATLAS example • Very similar solution in Auger front-end electronics and E14 experiment at J-PARK • Shaper integrates input pulse and produces standardized shape determined by electronics components • Output pulse area proportional to charge of input pulse • If output shape is invariant then its amplitude is proportional to input charge • Can make a very linear system J. Pilcher

ATLAS TileCal Pulse Shaping • Photomultiplier is a near-ideal current source • Current is very insensitive to impedance load on anode • This allows a shaper built with fully passive elements (LC filter) • Very low noise since no active components and very low resistance • TileCal shaper is a 7-pole Bessel filter • Can produce near-Gaussian output shape for digital sampling J. Pilcher

ATLAS TileCal Pulse Shaping • The circuit • Followed by buffer amplifiers to set gain and limit maximum signal • Use two gain ranges for increased dynamic range J. Pilcher

Pulse Shaping • Issues slightly different in the noble liquid calorimeter Denis will describe • Tradeoff between long shaping time for low electronic noise and short shaping for low noise from multiple interactions within time window J. Pilcher

Digitization • Can follow shaper with sampling ADC • For multiple samples of the shaped waveform • Extract, energy, time, quality factor for pulse shape • Intense commercial development of ADCs for high volume applications • Medical instrumentation, cellular phone systems • Maxim, Analog Devices, Linear Technology, Texas Instruments • Dramatic improvements in performance with time • Smaller feature size • Less power • Higher speed • Lower cost • Sampling rate may be determined by application • At LHC sample at 40 MHz bunch crossing rate • Required dynamic range may necessitate multiple gain scales J. Pilcher

Digitization • Now lots of choice for ADC • e.g. Maxim offers 28 12-bit ADCs capable of sampling at 40 Msps or greater • Similar for other manufacturers • Let’s examine relevant characteristics • Example, MAX1126 (4 ADCs in one package) J. Pilcher

Digitization • Tiny device • Difficult to probe with scope • Optimized PCB design is essential to realize its performance • Generally pipelined, multistage ADCs • Sample every clock cycle • Deliver digital output 7 cycles later • 7 internal ADCs working in parallel J. Pilcher

Digitization Pipeline J. Pilcher

ADC Limitations • These are NOT ideal devices • Might expect resolution of step size / sqrt(12) if all steps uniform • Step sizes NOT uniform • Differential non-linearity • This is a very well behaved design J. Pilcher

ADC Limitations • Also, deviations of response from straight line fit • Integral non-linearity This is a very well behaved design Should not rely on averaging ADC measurements to an accuracy better than 1 count J. Pilcher

Data Flow • ADCs produces 2 x 12 bits (if dual range system) every 40 MHz • 960 Mbps • Essential to filter this to extract signal of interest • May require fast digital link to transport data to digital signal processor • A major challenge • Systems may have 1000’s of channels J. Pilcher

Conclusions • Modern readout electronics capable of high dynamic range measurements • Dual range system can give 16-bit dynamic range • Can measure timing with same hardware as energy • Can profit from commercial pressures to improve ADCs and optical data links J. Pilcher

Calorimeter Electronics

Calorimeter Electronics

Presentation Transcript

The Run II DØ Calorimeter Electronics Upgrade and its Performance

Calorimeter Upgrade

Calorimeter Status

Microwave Calorimeter

Hadron Calorimeter

Front-End-Electronics for ILC Calorimeter Development

Calorimeter detector

Bomb Calorimeter

Calorimeter reconstruction

Calorimeter Status

Calorimeter: Overview

Front-End Electronics of ATLAS Tile Calorimeter and its Commissioning

ATLAS tile calorimeter electronics upgrade

Hadron Calorimeter

a “ Calorimeter ”

D Ø Calorimeter Electronics Upgrade for Tevatron Run II

Calorimeter Mu2e Development electronics Front-end Review

Calorimeter Backgrounds

Calorimeter Status

Calorimeter

Calorimeter

Electromangetic calorimeter