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HPS DAQ Overview

HPS DAQ Overview. Sergey Boyarinov JLAB June 17, 2014. Requirements. Up to 50kHz event rate Up to 100MB/s data rate Dead time < 1%. DAQ: System Overview. Calorimeter Readout: 442 channels of 12bit 250MHz Flash ADCs for Calorimeter (2 VXS crates, 4 ROCs)

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HPS DAQ Overview

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  1. HPS DAQ Overview Sergey Boyarinov JLAB June 17, 2014

  2. Requirements Up to 50kHz event rate Up to 100MB/s data rate Dead time < 1%

  3. DAQ: System Overview Calorimeter Readout: 442 channels of 12bit 250MHz Flash ADCs for Calorimeter (2 VXS crates, 4 ROCs) SVT readout system (1 ATCA crate, 8x2 ROCs, Ryan’s talk) 85ps resolution pipeline TDCs with discriminators (2 VME crates, 2 ROCs) Total 5 crates, 22 ROCs FADC-based trigger system (Ben’s talk) JLAB CODA DAQ software

  4. All modules are available FADC250 Flash ADC Crate Trigger Processor Sub-System Processor Signal Distribution Trigger Interface

  5. VXS crates with FADC and Trigger boards

  6. DAQ and Trigger System (no TDCs)

  7. DAQ and Trigger System (with TDCs)

  8. The CODA Trigger Distribution System With TI as TS VXS Crate The Trigger Supervisor (TS) accepts and distributes triggers by multi-link fiber to the TI boards. A proposed extension of the TI firmware will support up to 8 ROCs per TI module. TS Trigger ROC-VME ATCA Crate TI TI ROC ROC ROC-GTP ROC-VME ROC ROC-GTP ROC Master VXS Crate

  9. <!-- ===================== Buffer 21 contains 86 words (344 bytes) ===================== --> <event format="evio" count="21" content="bank" data_type="0x10" tag="1" padding="0" num="204" length="86" ndata="84"> <bank content="uint32" data_type="0x1" tag="49152" padding="0" num="0" length="5" ndata="3"> 0x13 0x1 0 </bank> <bank content="bank" data_type="0xe" tag="37" padding="0" num="19" length="67" ndata="65"> <composite data_type="0xf" tag="57601" padding="0" num="37" length="65" ndata="63"> <int8 data_type="0x6" tag="13"> c,i,l,N(c,Ns) </int8> <data> <row> 08bit: 0x03(3) 32bit: 0x00c00013(12582931) 64bit: 0x8ecbf3000194(157006606369172) 1( 08bit: 0x00(0) 100: 16bit: 0x0159(345) 0x0248(584) 0x03a1(929) 0x04ba(1210) 0x0560(1376) 0x0564(1380) 0x04fa(1274) 0x0440(1088) 0x038d(909) 0x02e8(744) 0x0262(610) 0x0204(516) 0x01b7(439) 0x0182(386) 0x0163(355) 0x014a(330) 0x0139(313) 0x012d(301) 0x0124(292) 0x0116(278) 0x010c(268) 0x0102(258) 0x00fd(253) 0x00f5(245) 0x00f4(244) 0x00f4(244) 0x00f4(244) 0x00f2(242) 0x00ed(237) 0x00ea(234) 0x00e6(230) 0x00e4(228) 0x00e5(229) 0x00e3(227) 0x00e5(229) 0x00e5(229) 0x00e4(228) 0x00e3(227) 0x00e2(226) 0x00df(223) 0x00e0(224) 0x00de(222) 0x00e1(225) 0x00e3(227) 0x00e4(228) 0x00e6(230) 0x00e2(226) 0x00e4(228) 0x00e0(224) 0x00de(222) 0x00df(223) 0x00dd(221) 0x00dd(221) 0x00e1(225) 0x00e1(225) 0x00de(222) 0x00de(222) 0x00e1(225) 0x00e4(228) 0x00e6(230) 0x00ea(234) 0x00ee(238) 0x00ef(239) 0x00ef(239) 0x00f0(240) 0x00ee(238) 0x00eb(235) 0x00e5(229) 0x00e4(228) 0x00e2(226) 0x00e1(225) 0x00db(219) 0x00c9(201) 0x00c3(195) 0x00c3(195) 0x00c4(196) 0x00c6(198) 0x00c5(197) 0x00c1(193) 0x00c6(198) 0x00c4(196) 0x00c5(197) 0x00c6(198) 0x00c1(193) 0x00c1(193) 0x00c4(196) 0x00c6(198) 0x00c4(196) 0x00c3(195) 0x00c4(196) 0x00c3(195) 0x00c3(195) 0x00c5(197) 0x00c3(195) 0x00c4(196) 0x00c7(199) 0x00c2(194) 0x00c2(194) 0x00c5(197) 0x00c5(197) </row> </data> </composite> </bank> <bank content="bank" data_type="0xe" tag="38" padding="0" num="19" length="12" ndata="10"> <uint32 data_type="0x1" tag="38" padding="0" num="0" length="10" ndata="8"> 0x85401301 0xff112001 0x1010003 0x13 0x948ecbf7 0x1 0x8d400007 0xfd400013 </uint32> </bank> </event> <!-- end buffer 21 -->

  10. CODA was ported on ARM processor (zed board) with SLAC help and successfully tested with dummy readout list TI firmware almost ready, SVT-TI section must be adjusted accordingly Configuration procedures must be integrated Starting July 2014, JLAB part of DAQ will be ready for integration with SVT (was June) DAQ: SVT integration

  11. Current Status and Timeline 2 VXS crate setup is ready (both daq and trigger system), minor issues will be resolved in few days TDAQ commissioning (Ben and Sergey): now – August 31 Ready for SVT integration: July 1

  12. Conclusion • DAQ in 2012 test run was nearly final configuration, do not expect any problems in final HPS DAQ system • JLAB part of DAQ and Trigger hardware 100% available and installed, and will be commissioned and ready by the end of August • SVT integration can be started after July 1

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