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Preliminary measurements for the 8 channel prototype of SPD discriminator ASIC I. II. III. IV. V. VI. The 8 channel prototype. Status of the test. Noise. Gain. Test plan. Schedule for PRR and production. LHCb Calo Electronics Meeting – December 2003 – Clermont-Ferrand I. The 8 channel prototype (I). • • • • • • Random signal shape (20-30 phe/MIP): shaping methods discarded integration. Only about 80% of signal in 25 ns (no dead time for integration allowed) + response to consecutive events Dual channel: synchronous system + Pile-up correction PMT gain limited by aging (DC current) 100fC/MIP in hotest cells. 5-10 MIP range to perform tail correction. Robust to temperature variations (band gap reference). Small cavity Power consumption < 1W. Prototype at 3.3V (0.6 W) I. The 8 channel prototype (II). • Area: 30 mm2. • Package: naked die (10), JLCC68 (10) and EDQUAD TQFP 64 (30). • Target package is EDQUAD TQFP 64 for size and power dissipation. • Ceramic JLCC68 is also requested because better knowledge of its performance (used for previous prototypes) . II. Status of the test. • 10 JLCC + 10 naked dies were receive at beginning of November . • 46 EDQUAD TQFP were received last week. • Automated test system is under development. • Hardware (test boards and VHDL code for FPGA used for DAQ) is finished. • Software (Labview and C) for data taking and on-line analysis is almost finished. • Digital interface has been completely tested with random sequences write/read and is fully functional. • Power consumption is as expected: 180 mA (0.6 W). • Consumption of different supply pins is in agreement with simulation. • Some further “manual” measurements have been done. III. Noise (I): 50 PMT load (input resistor). Differentiated Histogram Chip 1 Ch 3-1 Differentiated Histogram Chip 1 - Ch 3-2 Histogram Chip 1 Ch 3-1 Histogram Chip 1 Ch 3-2 4,00 3,00 2,00 -d<VoD>/dt [V] 1,00 0,00 -1,00 -2,00 -3,00 -4,00 -90 -85 -80 -75 -70 -65 -60 -55 Threshold [mV] • • • Sigma of differential histogram between 1 and 2 mV r.m.s. Measurement error is not negligible compared with transition width. Possible contributions of pick-up noise should be studied. -50 III. Noise (II): 390 PMT load (input resistor). Differentiated Histogram Chip 1 Ch 5-1 Differentiated Histogram Chip 1 Ch 5-2 Histogram Chip 1 Ch 5-1 Histogram Chip 1 Ch 5-2 4,00 3,00 2,00 -d<VoD>/dt [V] 1,00 0,00 -1,00 -2,00 -3,00 -4,00 -100 -90 -80 -70 -60 Threshold [mV] • • • • Sigma of differential histogram between 1 and 2 mV r.m.s. Noise increase is not seen. Measurement error is not negligible compared with transition width. Possible contributions of pick-up noise should be studied. -50 -40 IV. Gain (I): pulse injection. • A step pulse is differentiated through a series capacitor: the charge over RLPMT must be Q=Cac x Vstep (Vstep is the pulse amplitude). Cac Vstep 1pF RLPMT 50-400 Ohm • • • The pulse must be much longer than 25ns The time constant of the circuit <<25ns to inject all the charge in 1 period. The 95 % of the signal is on 25 ns (gain has been corrected). IV. Gain (II): results. Gain for Ch 5-1 1500,000 Vth/Q C1 Threshold to 0->1 [mV] 1000,000 500,000 0,000 -1,50E+03 -1,00E+03 -5,00E+02 0,00E+00 5,00E+02 1,00E+03 1,50E+03 -500,000 -1000,000 -1500,000 Input charge [fC] • • • • Gain for 390 PMT load : 1mV/fC. Linear range 1 pC of input charge or 1 V of threshold. Input referred noise (ENC) between 1 and 2 fC. MIP signal between 100 fC and 50 fC (after first compensation of PMT non-uniformities). V. Test plan. 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. Offset per subchannel (function of pile-up compensation subtractor). Noise per subchannel (function of pile-up compensation subtractor and PMT load). Cross-talk between subchannel threshold (same Vref). Low frequency noise (random trigger vs. sync. trigger). Linearity (function of pile-up compensation subtractor). Matching and calibration of of pile-up compensation. Cross-talk between channels. Pedestal stability with time. Aging. Tª dependence. ESD test on inputs and control pins. Possible effects of pick-up noise cause by massive switching of digital outputs (PCB dependent). VI. Schedule. • If no serious troubles are found systematic measurements might be finished by end of January 2004. • When should we ask to pass the PRR? • If no defects are find and PRR is passed on February chip will be ready for production in March? • According to CMP it is possible “start production when you want”, different from a MPW run. • Sharing production masks with PS VFE chip might save some money... It has been asked to CMP/AMS. Are the schedules for both chips compatible?
