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Timing and fast analog memories in Saclay

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Presentation on theme: "Timing and fast analog memories in Saclay"— Presentation transcript:

1 Timing and fast analog memories in Saclay eric.delagnes@cea.fr

2 Saclay’s microelectronics group
6 designers. Main Fields Of interest : Low Noise, Low Power Front-ends for capacitive Detectors. Analog Memories (Very High Speed and High dynamic range). Large dynamic range front–end for nuclear physics. MAPS for High Energy Physics Use of conservative CMOS technologies ( µm). Applications for all the physics divisions of DAPNIA .

3 Timing experience in DAPNIA ???
No experts at all on very fast timing in DAPNIA. But a little background concerning the 100ps-1ns resolution range. Mainly small parts of complex chips. 2 kinds of design: ramp generator T.A.C. with external ADC. DLL based TDC. In most of the case : deadtime.

4 MATE/ATHED chip for Nuclear Physics.
Common chip for the readout of Si,SiLi,Csi detectors of the hodoscop of the MUST2 experiment (GANIL). 16 channels, 14 bit dynamic range. 0.8µm CMOS Leading edge discriminator Track&hold for energy measurement. Voltage ramp for Time (of flight measurement). Performances: 600ns range <240 ps FWHM resolution (6MeV proton) in proc of IEEE 2003 /NSS Portland Oct 2003.

5 Time interpolator of the MATACQ chip.
MATACQ = multiGHz, high dynamic range analog memory. Heart of the « pipeline » circuit used in a handheld oscilloscope. used in the MATACQ (V2719) board industrialized by CAEN. A standard problem on oscilloscopes: how to avoid the jitter of the trace when triggered asynchronously Solution: to measure the time between the trigger and the clock. Achieved by a ramp based time interpolator: 50 ns range. 15 ps steps. <15 ps rms “noise” jitter. total of < 50 ps rms jitter (incl. NL) on the whole system (mainly due to digital coupling in the trigger signal outside the chip).

6 Fine Time measurement in the ARS Chip (ANTARES)
IEEE Trans.Nucl.Sci.49: ,2002 Timestamp: Counters + 2 voltage ramps in FlipFlop <200ps rms resol. low dead time

7 Using Analog Sampling solution for Timing measurement
Techniques for timing Measurement using sampling. Can deal with heavy pile-up. using FIR filter: Multiple sampling in ATLAS ATLAS: W. Cleland,   NIM A 338 (1994) Resol < 500ps Fs=40 MHz, 12 bits. ANTARES: Resol < 200ps Fs=700MHz, 6 bits. Fit : DEMIN: ~50ps rms. Fs= 2 GHz 12 bits M. Houry NIMA A 557 (2006) 648–656 CEBAF P. Bertin DVCS/E experiment : Final Readiness Report. Digital CFD : resol ~100ps Fs=100MHz 12 bits L. Bardelli NIM A A 521 (2004) 480–492. => resolution can be times smaller than the sampling period.

8 Matrix sampling DLL: higher bandwitdh and better time precision
Fast analog memories Well known principle (since early 90s): fast sampling of the analog signal on a switched capacitor array. Slowest readout (eventually multiplexing)and digitization. Low power but need « external » trigger Dead Time. Sampling speed increased over GHz ( with old technologies) by two techniques: The sampling DLL (ARS) Matrix sampling DLL: higher bandwitdh and better time precision (MATACQ, SAM)

9 The single ramp ADC revisited
Principle: increase the speed of ramp ADC by measuring time with DLL-based TDC without power penalty. Performances for the timing measurement (extracted from those of the ADC): Dynamic range > 12 bits Time step 320ps jitter < 30 ps rms NLD < +/-45 ps in proc of IEEE 2006/NSS San Diego Oct 2006

10 Système on chip integrating
Fast Analog Memories in DAPNIA Prospective AFTER : 05-06 TPC T2K 72 ch/ 512 pts Fe= 1-50 Mhz,BP = 10 Mhz Dyn= 10 bits AMS0.35 µm. Also includes FE. New Architectures ARS0 : 97-98 ANTARES/HESS1 5 ch/ 128 pts Fe= 1Gs/S BP = 80 Mhz Dyn~8-9bits AMS 0.8 µm ARS1 : 98-04 ANTARES 4 Ch system on chip including ARS0 KM3Net CTA HAMAC : 93-97 Calo ATLAS 12 canaux/ 144 pts Fe= 40 Mhz BP = 10 Mhz Dyn= 13,6 bits DMILL 0.8 µm SAM 04-05 HESS2 2 ch / 256 pts Fe= 50 MHz-2GHz BP = 300 Mhz Dyn= 12 bits AMS 0.35 µm MATACQ : 99-01 Matrix Structure 1 ch, 2560 pts Fe= 50 MHz-2GHz BP = 300 Mhz Dyn= 12 bits AMS 0.8 µm (PATENT) MATACQ 2 Fs~ 5-10GHz , BW>600MHz >5000 pts ? DSM technology PIPELINE :01- 02 METRIX 1 ch Système on chip integrating 1 MATACQ Technologically feasible Collaborations with l’ IN2P3/ LAL

11 Performances of the recent designs (MATACQ & SAM)
MATACQ: 0.8µm (Breton, TNS VOL. 52, NO. 6, DEC 2005 ) SAM: 0.35µm (Delagnes, NIMA567:21-26,2006) Max sampling freq. 2.5 GHz. 150 mW/ch (SAM) Voltage dynamic range bits. Xtalk >0.3%. Bandwidth 300 MHz. Sampling jitter : 20 ps rms. On recent (future) chips, efforts made on the readout speed (66 MHz on SAM) and input Bandwidth. SAM: HESS2 PMT-like pulse 1GS/s: In black single acquistion. In grey 1000 superimposed acquisition. timing precision (<20ps rms) MATACQ

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