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FADC Boards for JPARC-K Preliminary Proposal Mircea Bogdan November 16, 2006

This proposal outlines the block diagrams, readout capabilities, and FPGA requirements for a 12-bit, 500MHz FADC board and a 14-bit, 125MHz ADC board. The boards offer high throughput and can sustain data transfer via the VME backplane without the need for a serial link. FPGA device migration is possible to adjust pipeline size and accommodate different trigger rates.

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FADC Boards for JPARC-K Preliminary Proposal Mircea Bogdan November 16, 2006

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  1. FADC Boards for JPARC-KPreliminary ProposalMircea BogdanNovember 16, 2006

  2. 12-Bit, 500MHz FADC Board – Block Diagram • Each FADC channel: one ATMEL - AT84AS001 chip: 12 bits/500MHz; • One STRATIX II FPGA can service up to 4 ADC channels : • After SERDES, data moved with 125MHz; • Trigger rate: 10kHz, 64 samples/trigger (128ns); • Two VME readout buffers - max 128 triggers each (10 ms); • Input Pipeline: 25 -100us max depth (8,000 - 51,200 samples); • FPGA device migration possible to increase/decrease max pipeline size;

  3. 12-Bit, 500MHz FADC Board - Readout • 4 ADC channels per Board: 6U VME32/64 with CBLT; • Throughput with 10KHz trigger rate, 100% channel hit occupancy, 64 samples/trigger: • One channel: 10KHz x 12bits x 64samples = 0.96 MBPS; • 4-channel board: 3.84 MBPS/board; • Crate with 7 boards (25 channels): 24 MBPS - can be sustained via VME backplane; • Serial Link not needed.

  4. 14-Bit, 125MHz ADC Board – Block Diagram • Each ADC channel - one AD9445 chip: 14 bits/125MHz; • One STRATIX II FPGA can service 16 ADC channels: • Logic design similar to 500MHz FADC without SERDES; • Memory requirements similar to 500MHz FADC with the same time delay; • Trigger rate: 10kHz, 16 samples/trigger (128ns); • Two VME readout buffers - max 128 triggers (10 ms); • Input Pipeline: 25 -100us max depth (2,000 – 12,800 samples); • FPGA device migration possible to increase/decrease max pipeline size;

  5. 14-Bit, 125 MHz ADC Board - Readout • 16 ADC channels per Board: 6U VME32/64 with CBLT; • 16 ADC Boards per Crate; • Throughput with 10 KHz trigger rate, 10% channel hit occupancy, 16 samples/trigger: • One channel: 10KHz x 10% x 2Bytes x 16samples = 32 KBPS; • 16-channel board: 512 KBPS/board • Crate with 16 boards: 8 MBPS - can be sustained via VME backplane; • Serial Link not needed.

  6. Conclusions • High level of reuse between the two designs; many logic blocks are the same; • FPGA requirements are about the same for: 4-ch,500MHz and 16-ch,125MHz boards; • Performed preliminary FPGA design tests: • With Altera EP2S60F1020C5 ($600): > 25us depth pipeline; • With Altera EP2S90F1020C5 ($1,600): > 50us depth pipeline; • With Altera EP2S130F1020C5 ($2,800): >100us depth pipeline; • Memory requirements may be slightly larger on the 4-ch, 500MHz board, because of higher readout throughput per board; • FPGA device migration possible on the same PCB.

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