14-BIT Custom ADC Board Rev. B

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Presentation transcript:

14-BIT Custom ADC Board Rev. B The University of Chicago Mircea Bogdan E14 Collaboration Meeting, KEK, May 18-20, 2008

E14 Collaboration Meeting, KEK, May 18-20, 2008 Block Diagram Same Block Diagram + Readout Memory outside FPGA (32 Mbytes): Input Pipeline: ~4us depth (512 samples); Two buffers inside FPGA – 4096 words each; 40kHz trigger, 100% hit occupancy, 32 samples/trigger (256ns), 32bytes/sample; Readout Memory (2 x MT45W8MW16BGX) can store 0.75 second spill. Mircea Bogdan E14 Collaboration Meeting, KEK, May 18-20, 2008

E14 Collaboration Meeting, KEK, May 18-20, 2008 Shaper/ADC Channel Revision B Schematic Noise STDEV Rev. A: 2.80 LSB – Dec.’07 FNAL recordings – full chain; 2.65 LSB – EShop recordings – ADC Module alone. Module SNR ~ 70dB Noise STDEV Rev. B (ADC Module alone): 1.90 LSB – same signal shape/bandwidth; 1.70 LSB – more signal filtering just before A/D chip –> pulse ~5% wider. Module SNR ~73-74dB Note: SNR was calculated as: RMS Full-scale/STDEV Noise. Mircea Bogdan E14 Collaboration Meeting, KEK, May 18-20, 2008

E14 Collaboration Meeting, KEK, May 18-20, 2008 PCB Layout Crosstalk related Modifications: - Increase channel spacing by 1mm; - Use 2 connectors - 8 channels each; - Fully split power planes between channels from connectors to ADC chips; - Use smaller size, shielded inductors for the shapers; - Provide solder pads for individual channel shielding (if needed). Layout – Preliminary (memory not included). Mircea Bogdan E14 Collaboration Meeting, KEK, May 18-20, 2008

E14 Collaboration Meeting, KEK, May 18-20, 2008 Specifications Digital I/Os (non VME) Backplane: - 16-BIT parallel outputs on P2/J2 – for ET Sum; - 14 bussed lines on P1/J1 ?? Front Panel: - 8 LVDS inputs – sampling clock and trigger pulses ?? Power Requirements: +5V – 2A; +3.3V – 4.7A; -5V – 1.25A (applied on the user defined –V1,V2 pins); The +/-12V power pins are not used any more. Mircea Bogdan E14 Collaboration Meeting, KEK, May 18-20, 2008

E14 Collaboration Meeting, KEK, May 18-20, 2008 Schedule Mircea Bogdan E14 Collaboration Meeting, KEK, May 18-20, 2008

E14 Collaboration Meeting, KEK, May 18-20, 2008 Self Trigger Method Implement a block inside FPGA (No Hardware Change): Calculate board total energy over last 32 samples, generate “board energy value” every 8 ns. Do on-the-fly fitting of each channel, generate a “board fitting accuracy value” every 8 ns. The two values produce self trigger. (May trigger at larger that 8ns increments.) Create self triggered “board event”. Time stamp (8 ns increments) in the header word for each board event. Off line, each board event gets associated, and aligned with the others. Generate "system event", and discard junk. How much junk (board events not part of system events) is recorded? Simulation may answer that. This method could be tested during the 100-channel test, and compared with the triggered solution. May prove itself useful for other applications. Mircea Bogdan E14 Collaboration Meeting, KEK, May 18-20, 2008