25th June, 2003CMS Ecal MGPA first results1 MGPA first results testing begun 29 th May on bare die (packaging still underway) two chips looked at so far.

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Presentation transcript:

25th June, 2003CMS Ecal MGPA first results1 MGPA first results testing begun 29 th May on bare die (packaging still underway) two chips looked at so far – both working (all results here from one only) OUTLINE test setup description analogue performance gain linearity matching noise I2C offset adjust calibration feature power consumption

25th June, 2003CMS Ecal MGPA first results2 RAL test board packaged chips not yet available but RAL board can take bare die dual purpose design 1) standalone–used here 2) interface to standard DAQ system bias components fixed – no adjustment possible (without changing 0402 components)

25th June, 2003CMS Ecal MGPA first results3 Test setup for pulse shape measurements diff. probe or single- ended buffered signal note: very fast risetime charge injection -> pulse shape distortion on rising edge due to slew rate limitation at O/P of first stage current source magnitude OK for 10 nsec exponential edge Scope averaging -> 16 bit resolution. Multiple waveforms captured with different DC offsets to remove scope INL effects. I/P O/P first stage amplifier

25th June, 2003CMS Ecal MGPA first results4 Pulse shapes – low gain channel signals up to 60 pC (feedback components for barrel application: 1.2k//33pF) steps not equally spaced (log attenuator) 2 active probes on +ve and –ve outputs (before any buffering) linear range +/ V around Vcm (1.25 V nom.) note: Vcm defined by external pot’l divider (5% resistors) so not exactly 1.25 V

25th June, 2003CMS Ecal MGPA first results5 Pulse shapes – mid gain channel same signal steps as before (up to 60 pC) this range only linear up to ~ 10 pC shows saturation effects for out of range signals

25th June, 2003CMS Ecal MGPA first results6 Pulse shapes – high gain channel this range only linear up to ~ 5 pC

25th June, 2003CMS Ecal MGPA first results7 Pulse shapes – all 3 gain ranges for comparison

25th June, 2003CMS Ecal MGPA first results8 Differential pulse shape – low gain channel differential probe on chip outputs (before buffering) 60 pC fullscale signal as before differential swing +/ V around Vcm corresponds to ~1.8 Volt linear range pedestal subtracted no “obvious” pulse shape distortion due to higher gain channels saturating

25th June, 2003CMS Ecal MGPA first results9 Differential pulse shape – mid and high gain channels (60 pC fullscale signal) mid gain channel high gain channel

25th June, 2003CMS Ecal MGPA first results10 Differential pulse shapes – all 3 gain channels compared – gain ratios 1 : 5.6 : 11.3 (cf 1 : 6 : 12) no obvious interchannel distortion effects

25th June, 2003CMS Ecal MGPA first results11 Linearity and pulse shape matching – high gain channel fullscale signal 5.4 pC pulse shape matching in spec., linearity outside by factor ~2

25th June, 2003CMS Ecal MGPA first results12 Linearity and pulse shape matching – mid gain channel smallest signals show slower risetime – needs further investigation fullscale signal 10.8 pC

25th June, 2003CMS Ecal MGPA first results13 Linearity and pulse shape matching – low gain channel similar (but worse) effect as for mid-gain channel fullscale signal 61 pC

25th June, 2003CMS Ecal MGPA first results14 Pulse shape matching between gain channels Pulse shape matching definition: Pulse Shape Matching Factor PSMF=V(pk-25ns)/V(pk) Pulse shape matching = [(PSMF-Ave.PSMF)/Ave.PSMF] X 100 Ave.PSMF = average for all signal sizes and gain ranges systematic discrepancies between channels can be due to mismatch in diff. O/P termination components or (more likely here) difference in stray capacitance from PCB layout spec.

25th June, 2003CMS Ecal MGPA first results15 1 st stage of buffering differential O/P termination components (1% tolerance) mismatch of stray O/P capacitance likely due to signal routing on test card

25th June, 2003CMS Ecal MGPA first results16 effect of input capacitance on pulse shape pulse peak shifts by ~ 3 nsec.

25th June, 2003CMS Ecal MGPA first results17 Noise measurements use wide bandwidth true rms meter (single ended I/P) => need diff. to singled ended buffer circuitry => extra noise contribution to subtract and extra noise filtering Cstray Cstraysimulation (~20pF) +180pF (200pF) high gain 7,000 7,850 6,200 mid gain 8,250 9,100 8,200 low gain ~28,000 ~28,000 35,400 weak dependence on input capacitance as expected note: large uncertainty for low gain channel - buffer circuitry dominates here

25th June, 2003CMS Ecal MGPA first results18 I2C offset setting 0 I2C offset setting 105 linear range I2C pedestal offset adjustment high gain channel shown here (other channels similar) offset setting 0 -> 105 in steps of 5 (decimal) ~ optimum baseline setting here corresponds to I2C setting ~70

25th June, 2003CMS Ecal MGPA first results19 Calibration circuit functionality (1) 10pF 1nF 8 – bit DAC value 0 – 2.5 V MGPA I/P 10k Rtc external components on-chip external derived from external pulse high midlow distortion on rising edge for low gain channel – somehow related to external 1 nF cap.

25th June, 2003CMS Ecal MGPA first results20 Calibration circuit functionality (2) 10pF 1nF 8 – bit DAC value 0 – 2.5 V MGPA I/P 10k Rtc on-chip external with 1 nFwithout 1 nF calibration pulse shapes with/without external 1 nF show improvement if removed effect needs further investigation

25th June, 2003CMS Ecal MGPA first results21 main concern so far: high frequency instability (~ 250 MHz) can be introduced on first stage O/P when probing not clear whether problem on chip (no hint during simulation) or could be test board related decoupling components around first stage not as close in as would like VDDP, VS in particular test board for packaged chips should help with diagnosis decoupling closer in (may be cure?) bias currents easy to vary (should give clues)

25th June, 2003CMS Ecal MGPA first results22 Power consumption Current measured in 2.5 V rail supplying test board -> ~ 245 mA -> chip current + Vcm divider (4mA) + power LED (3mA)  chip current = 238 mA measuring bias currents and multiplying by mirroring ratios -> 235 mA may change if further testing indicates changing bias conditions -> performance improvements worth having

25th June, 2003CMS Ecal MGPA first results23 Summary all results so far for one unpackaged chip, barrel feedback components to first stage gains close to specification (1 : 5.6 : 11.3) pulse shapes good linearity ~ +/- 0.2% (~ 2 x spec.) pulse shape matching within spec. apart from lowest end of mid and low gain ranges no obvious distortion introduced on lower gain channels by higher gain channels saturating => good chip layout noise close to simulation values (< 10,000 electrons for mid and high gain ranges) I2C features (channel offsets, calibration) fully functioning plan to move to packaged chips as soon as available

25th June, 2003CMS Ecal MGPA first results24 external components define CR and CSA gain external components define RC V/I gain resistors offset & CAL pulse generation I2C interface offset adjust MGPA – architecture overview diff. O/P

25th June, 2003CMS Ecal MGPA first results25