Difference between revisions of "CDC transfer func attempt"
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Electronics gain is 76.7 mV / 206 fC = 0.37 mV/fC | Electronics gain is 76.7 mV / 206 fC = 0.37 mV/fC | ||
− | (Gain of preamp alone measured by FJB as 0.57 mV/fC) | + | (Gain of preamp alone measured earlier (before modifications) by FJB as 0.57 mV/fC) |
Revision as of 10:06, 16 April 2014
Circuit
Actual component values used were... 51.1 Ohms, 908 Ohms and 2pF.
The aim is to inject a charge impulse into the electronics chain and measure its response.
Early results
Final results
Borrowed Phillips 5771 (no attenuators needed)
Fitted function
Beware typos in filenames, this was run #31941!
Input charge: 2 pF x 103 mV = 206 fC
Input current: divide by 12ns peaking time of preamp: 206 fC / 12 ns = 17.2 uA
Peak value of output data is 635 adc_units ~ 635 * 495 mV / 4096 = 76.7 mV
Electronics gain is 76.7 mV / 206 fC = 0.37 mV/fC
(Gain of preamp alone measured earlier (before modifications) by FJB as 0.57 mV/fC)
Convert to current using 50 Ohm resistance: 76.7 mV / 50 Ohm = 1.53 mA
Current gain is 1.53 mA / 17.2 uA = 89.0
Integrated value of output data is 19.03 adc_units.us ~ 19.03 * 495 mV / 4096 = 2.30 mV.us
Convert to charge using 50 Ohm resistance: 2.3 mV.us / 50 Ohm = 0.046 mA.us = 0.046 nC = 46 pC
Charge gain is 46 pC / 206 fC = 223
To convert histograms of summed ADC data (with 8ns sample time) to charge, multiply by 8 ns * 46 pC / 19.03 us = 19.3 fC
Garfield needs the transfer function expressed as current gain, but I want to see the results in adc units, so I need to scale the transfer function x 89 (current gain) x 635/1530 (adc units/uA). The remaining gain factor needed to match garfield adc data to real life data is the gas gain.