J. Ye SMU Joint ATLAS-CMS Opto-electronics working group, April 10-11, 2008 CERN 1 Test Results on LOC1 and Design considerations for LOC2 LOC1 test results:

Slides:

Advertisements

Similar presentations

Electrical Data Transmission on Flex Cables at 320 Mbps Peter Manning, Vitaliy Fadeyev, Jason Nielsen Santa Cruz Institute for Particle Physics University.

Advertisements

OIF SFI-5 40G Transponder Big Bear Networks OFC 2003.

J.Ye / SMU May 18, 2015 GOL + SoS R & D Work at SMU 1.The Test of the GOL chip. 2.First test on the SoS driver chip and the submission of a dedicated test.

Richard Kass IEEE NSS 11/14/ Richard Kass Radiation-Hard ASICs for Optical Data Transmission in the ATLAS Pixel Detector K.E. Arms, K.K. Gan, M.

CHAPTER 1 Digital Concepts

1 A 16:1 serializer for data transmission at 5 Gbps Datao Gong 1, Suen Hou 2, Zhihua Liang 1, Chonghan Liu 1, Tiankuan Liu 1, Da-Shun Su 2, Ping-Kun Teng.

David Nelson STAVE Test Electronics July 1, ATLAS STAVE Test Electronics Preliminary V3 Presented by David Nelson.

20-24 September 2010, TWEPP, Aachen, Germany D. 1 Datao Gong On behalf of the ATLAS Liquid Argon Calorimeter Group Department of Physics,

Figure 1–1 Graph of an analog quantity (temperature versus time). Thomas L. Floyd Digital Fundamentals, 9e Copyright ©2006 by Pearson Education, Inc. Upper.

Status of opto R&D at SMU Jingbo Ye Dept. of Physics SMU For the opto WG workshop at CERN, March 8 th, 2011.

SRS-DTC Links WG5 RD51 Miniweek Alfonso Tarazona Martínez, CERN PH-AID-DT.

Digital Fundamentals Floyd Chapter 1 Tenth Edition

Sub- Nyquist Sampling System Hardware Implementation System Architecture Group – Shai & Yaron Data Transfer, System Integration and Debug Environment Part.

A Serializer ASIC for High Speed Data Transmission in Cryogenic and HiRel Environment Tiankuan Liu On behalf of the ATLAS Liquid Argon Calorimeter Group.

Technion – Israel Institute of Technology Department of Electrical Engineering Winter 2009 Instructor Amit Berman Students Evgeny Hahamovich Yaakov Aharon.

1 A Serializer ASIC at 5 Gbps for Detector Front-end Electronics Readout 1.Overview. 2.Test results of LOCs1, the 5 Gbps 16:1 serializer. 3.Test results.

Hardware Design of High Speed Switch Fabric IC. Overall Architecture.

2.5Gbps jitter generator Part 1 final presentation.

ECE 477 DESIGN REVIEW TEAM 2  FALL 2011 Members: Bo Yuan, Yimin Xiao, Yang Yang, Jintao Zhang.

October 31st, 2005CSICS Presentation1 A 1-Tap 40-Gbps Decision Feedback Equalizer in a  m SiGe BiCMOS Technology Adesh Garg, Anthony Chan Carusone.

© 2009 Pearson Education, Upper Saddle River, NJ All Rights ReservedFloyd, Digital Fundamentals, 10 th ed Digital Fundamentals with PLD Programming.

SRS DIGITAL C-CARD. TEST AND APPLICATIONS Mihai Cuciuc.

Leo Greiner IPHC meeting HFT PIXEL DAQ Prototype Testing.

Testing OIF Optical and Electrical Implementation Agreements Gary Goncher Tektronix, Inc.

1 Demo Link and the LOC Status Report 1.Demo Link status 2.LOC2 status 3.Irradiation tests on optical fiber 4.Summary Vitaliy for the SMU team.

Design studies of a low power serial data link for a possible upgrade of the CMS pixel detector Beat Meier, Paul Scherrer Institut PSI TWEPP 2008.

High-Speed Serial Optical Link Test Bench Using FPGA with Embedded Transceivers Serial optical data transmission provides a solution to High Energy Physics.

BTeV Pixel Detector Optical link receiver chip Data In and Out project.

A CTIVITY II: ALICE ITS R EADOUT E LECTRONICS S ERIAL L INK C HARACTERIZATION Hira Ilyas Madiha Tajwar Jibran Ahmed Raise Ikram (carrier board) Dr. Attiq.

Leo Greiner PIXEL Hardware meeting HFT PIXEL detector LVDS Data Path Testing.

1 LAr high speed optical link studies: the status report on the LOC ASIC 1.The LOC ASIC, an introduction 2.The SOS technology 3.LOC1 test results 4.LOC2.

Presented by: Sergey Volkovich Vladimir Dibnis Spring 2011 Supervisor: Mony Orbach.

Alexei SemenovGeneric Digitizer Generic Digitizer 10MHZ 16 bit 6U VME Board.

Optical Readout and Control Interface for the BTeV Pixel Vertex Detector Optical interface for the PCI board –1.06 Gbps optical link receiver –Protocol.

J.Ye / SMU Sept.4, 2007 Joint ATLAS CMS Opto-electronics working group, subgroup C 1 Report from sub-group C, Optical Link Evaluation Criteria and Test.

Technion – Israel Institute of Technology Department of Electrical Engineering Winter 2009 Instructor Amit Berman Students Evgeny Hahmovich Yaakov Aharon.

High Speed Digital System Lab Final Presentation 1 semester project  Instructor: Mony Orbach  Students: Pavel Shpilberg Ohad Fundoianu.

1 Status Report on the LOC ASIC 1.The LOC ASIC proposal 2.The SOS technology 3.LOC1 test results 4.LOC2 design status 5.Summary Datao Gong, Andy Liu, Annie.

PS/2 Mouse/Keyboard Port

SMU Report: R&D work for ID upgrade May 3, UCSC R&D work on gigabit optical link for ATLAS ID readout upgrade at SMU Objectives: 1.Evaluate.

09/02/20121 Delay Chip Prototype & Delay Chip Test Board Joan Mauricio – Xavier Ondoño La Salle (URL) 12/04/2013.

A high speed serializer ASIC for ATLAS Liquid Argon calorimeter upgrade Tiankuan Liu On behalf of the ATLAS Liquid Argon Calorimeter Group Department of.

1 The Link-On-Chip (LOC) Project at SMU 1.Overview. 2.Status 3.Current work on LOCs6. 4.Plan and summary Jingbo Ye Department of Physics SMU Dallas, Texas.

1 Preparation to test the Versatile Link in a point to point configuration 1.Versatile Link WP 1.1: test the Versatile Link in a point to point (p2p) configuration.

High Speed Digital Systems Lab Spring/Winter 2010 Project definition Instructor: Rolf Hilgendorf Students: Elad Mor, Ilya Zavolsky Integration of an A/D.

BER-tester for GEB board. Main components&restrictions TLK2501 serializer/deserializer/pseudo random generator Genesys FPGA development board Multiplexer.

SEU WG, TWEPP SEU mitigation in GBT On behalf of GBT team Circuit design: TMR Full-custom/High Speed Configuration Registers Protocol Some results.

© 2001 By Default! A Free sample background from Slide 1 Optical Ethernet Design Receiver Group G1 David Gewertz Ryan Baldwin.

High speed signal transmission Jan Buytaert. Topics Electrical standards: CML,LVDS, SLVS Equalization. Testbench of a readout slice. Vacuum feed-throughs.

Opto Working Group Meeting Summary Tuesday 8 March 2011 Tobias Flick and Francois Vasey.

March 14, 2016 Report on SMU R&D work1 Link-On-Chip (LOC) 1st Prototype  Status:  Prototype chip with the clock unit (PLL), serializer, laser driver,

5 Gbps J. SMU 1 A Serializer for LAr Front-end electronics upgrade 1.Requirements and design philosophy. 2.Key features of the serializer.

Rutherford Appleton Laboratory September 1999Fifth Workshop on Electronics for LHC Presented by S. Quinton.

LOCld – The fastest VCSEL driver in optical link for ATLAS Futian Liang USTC-IHEP, May. 3 rd, 2013.

GBT protocol implementation on Xilinx FPGAs Csaba SOOS PH-ESE-BE-OT.

1 Status report on the LAr optical link 1.Introduction and a short review. 2.The ASIC development. 3.Optical interface. 4.Conclusions and thoughts Jingbo.

G.F. Tassielli - SuperB Workshop XI LNF1/11 02/12/2009 Status report on CLUster COUnting activities G. F. Tassielli on behalf of CLUCOU group SuperB Workshop.

October 12th 2005 ICALEPCS 2005D.Charlet The SPECS field bus  Global description  Module description Master Slave Mezzanine  Implementation  Link development.

Jitter and BER measurements on the CuOF prototype G. Dellacasa, G. Mazza – INFN Torino CMS Muom Barrel Workshop CERN, February 25th, 2011.

Status and Plans for Xilinx Development

Low Power, High-Throughput AD Converters

Hugo Furtado CERN - Microelectronics Group 11th Workshop on Electronics for LHC and future Experiments Delay25, an ASIC for timing adjustment in LHC Delay25.

EKT124 Digital Electronics 1 Introduction to Digital Electronics

Defining serial links for SuperB

Data transmission characterization with underwater copper link

Low Jitter PLL clock frequency multiplier

On Behalf of the GBT Project Collaboration

Interfacing Data Converters with FPGAs

Digital Fundamentals Floyd Chapter 1 Tenth Edition

Progress on the 40 MHz SEU Test System based on DE2 Board

Presentation transcript:

J. Ye SMU Joint ATLAS-CMS Opto-electronics working group, April 10-11, 2008 CERN 1 Test Results on LOC1 and Design considerations for LOC2 LOC1 test results: LOC1 test results: Electric output: rise/fall times, amplitude. Electric output: rise/fall times, amplitude. Eye diagram. Eye diagram. Understand the jitter. Understand the jitter. Bit error rate. Bit error rate. LOC2 design. LOC2 design.

J.Ye, SMU 2 Joint ATLAS-CMS Opto-electronics working group, April 10-11, 2008 CERN LOC1 block diagram Five function blocks: the input 8B/10B encoder, the 20:1 serializer, the output driver, the PLL and clock unit, and the control and configuration. Five function blocks: the input 8B/10B encoder, the 20:1 serializer, the output driver, the PLL and clock unit, and the control and configuration. Solid line box: implemented; dashed line box: not implemented. Solid line box: implemented; dashed line box: not implemented. Loc1 is the 1 st prototype only good for tests in lab. Loc1 is the 1 st prototype only good for tests in lab. PLL + clock unit 5:1 DFF based serializer 2:1 mux 5:1 DFF based serializer 2:1 mux 8B/10B encoder 16 bit data 2:1 mux Output driver Ref. clk Current driver to VCSEL CML driver to VCSEL CML signal Control + configuration

J.Ye, SMU 3 Joint ATLAS-CMS Opto-electronics working group, April 10-11, 2008 CERN LOC1 basic electrical characteristics Input power supply: Input power supply: 2.5V (Analog/Digital), 3.3V VCSEL 2.5V (Analog/Digital), 3.3V VCSEL Power consumption (with current configuration) ~200mW. Power consumption (with current configuration) ~200mW. Input data signals Input data signals LVCMOS 2.5V LVCMOS 2.5V Reference clock 62.5MHz 20bit 8B/10B encoded input data

J.Ye, SMU 4 Joint ATLAS-CMS Opto-electronics working group, April 10-11, 2008 CERN LOC1 test system diagram ElectricalDifferential Data Clock LVDS Driver Board LVDS Receiver Board Clock distribution I/O to PC FPGA: PRBS generator 8B/10B encoder Error detection LVDS Interface Board LOC1 Carrier Board TLK Carrier Board FPGA Board TLK Interface Board Test point Tektronix 20GHz real-time oscilloscope (DSA72004) and Anritsu BERT were used for the tests. The VCSEL driver is not functioning. All tests were carried out through the CML driver on electrical signals only. Signal amplitude, rise/fall times measurement and jitter analysis were performed at the test point (see figure). BER was measured with the Anritsu BERT. Data Clock

J.Ye, SMU 5 Joint ATLAS-CMS Opto-electronics working group, April 10-11, 2008 CERN Rise/Fall time and Amplitude The logic in the digital part, and the PLL + clock unit are functioning as designed. The output serial bits are correct, checked on the scope. The differential signal amplitude is about 240mV, measured by a differential probe. This is much lower than the 400 mV design spec. The reason of this problem is known and will be fixed in LOC2. Rise/Fall times are data pattern dependent, measured to be around 150ps. This is boarder line for 2.5 Gbps signal. The reason is not known. The whole driver design will be abandoned. We will use a new driver design in LOC2. Comma (k28.5) code on differential electrical channel

J.Ye, SMU 6 Joint ATLAS-CMS Opto-electronics working group, April 10-11, 2008 CERN Eye diagram Eye diagram of the Input Pseudo random data. UI = 400ps, for 2.5 Gbps. An eye diagram is measured. There is huge jitter generated inside the chip. Careful measurements were carried out to identify the components as well as possible sources of this jitter. We think that we understand this problem very thoroughly. The huge DJ comes from the 4-arm 2-stage mux serializer design. This architecture is not necessary. New serializer design will be implemented in LOC2 to address this problem. The RJ comes mostly from the PLL. Efforts are spent to improve the PLL design for LOC2.

J.Ye, SMU 7 Joint ATLAS-CMS Opto-electronics working group, April 10-11, 2008 CERN Jitter measurement method DSA72004 employs software package TDSJIT3 for jitter analysis. DSA72004 employs software package TDSJIT3 for jitter analysis. Sample records at 40ps and up to 50M data points in one data file — a snapshot of 2ms waveform length, for long term jitter analysis. Sample records at 40ps and up to 50M data points in one data file — a snapshot of 2ms waveform length, for long term jitter analysis. Algorithm performed in the frequency domain. Algorithm performed in the frequency domain. RJ and DJ components are extracted. RJ and DJ components are extracted.

J.Ye, SMU 8 Joint ATLAS-CMS Opto-electronics working group, April 10-11, 2008 CERN Jitter measurement with TDSJIT3 Jitter spectrum Results: RJ_rms = 10ps, DJ_pk-pk = 230ps. Out of 230 DJ, the periodic jitter coming from the serializer structure is175ps. This can be eliminated in LOC2. Total jitter -12 BER) = 310ps. Reminder: UI = 400ps.

J.Ye, SMU 9 Joint ATLAS-CMS Opto-electronics working group, April 10-11, 2008 CERN Periodic jitter A large periodic jitter is observed. This strong data dependent, n×492KHz jitter structure (2.5GHz/127/40 = 492KHz) is a clear indication that the jitter comes from an unmatched 4-arm 2-stage serializer. New serializer structure will be implemented in LOC2 to address this problem.

J.Ye, SMU 10 Joint ATLAS-CMS Opto-electronics working group, April 10-11, 2008 CERN Bit error rate measurement BERT signal generator 62.5MHz FPGA board LOC1 BERT Error Detect 62.5MHz20bit Data Serialized Data 2.5GHz BER The BER measurement system We use Anritsu MP1763/1764 BER Tester for this test The input amplitude is 110mV because of the Differential to single-ended converter.

J.Ye, SMU 11 Joint ATLAS-CMS Opto-electronics working group, April 10-11, 2008 CERN The bathtub curve The bathtub curve at 2.5Gbps, the best BER reached is ~ By shifting the reference clock with respect the parallel data, we get the bathtub curve. From this curve we extract: DJ_pk-pk = 235ps, RJ_rms =18ps, and total jitter = 478ps -12 BER) The low signal amplitude might cause the large RJ measurement. The BERT error detect requires 250 mV amplitude input, but our input is 240mV/2 ~ 110mV.

J.Ye, SMU 12 Joint ATLAS-CMS Opto-electronics working group, April 10-11, 2008 CERN LOC2 block diagram The preliminary LOC2 block diagram We aim LOC2 for a usable chip for “users” to implement in their systems. A design document is being drafted and circulated for experts’ opinions. A design document review with people from ATLAS LAr and ID (users + designers) will be held in ~2-3 weeks time frame. A design review will be held end of We aim for a submission in early 2009, and make the chip available mid bit Input register LVDS to LVCMOS 2:1 MUX to 8 bit 8B/10B Comma PRBS PLL + clks MUX Cntrl config Odd bits shift register Even bits shift register Latch CML driver 2:1 MUX Data Clk_ref Cntrl/Config 16 LVDS 10 bit Serial output to Versatile Link

J.Ye, SMU 13 Joint ATLAS-CMS Opto-electronics working group, April 10-11, 2008 CERN LOC2 key features A Serializer at 3.125Gbps or higher speeds; A Serializer at 3.125Gbps or higher speeds; Differential electrical output (CML), to be coupled to the Versatile Link input; Differential electrical output (CML), to be coupled to the Versatile Link input; Compatible with commercial GBE receivers (8B/10B encoder); Compatible with commercial GBE receivers (8B/10B encoder); 16 bit LVDS differential data input; 16 bit LVDS differential data input; Differential 156 MHz reference clock; Differential 156 MHz reference clock; Data sampling at rising or falling edge of the reference clock Data sampling at rising or falling edge of the reference clock Internal PRBS; Internal PRBS; Single 2.5 voltage power supply. Single 2.5 voltage power supply.

J.Ye, SMU 14 Joint ATLAS-CMS Opto-electronics working group, April 10-11, 2008 CERN Conclusion LOC1 is under tests at SMU. The testing results provide a lot of information for LOC2 design. LOC1 is under tests at SMU. The testing results provide a lot of information for LOC2 design. Irradiation tests on LOC1 will be carried out June/July Irradiation tests on LOC1 will be carried out June/July The design on LOC2 started. A design document is being generated and a design review will be held April 2008 in the community. The design on LOC2 started. A design document is being generated and a design review will be held April 2008 in the community. We aim for a submission early 2009 and having chips mid We aim for a submission early 2009 and having chips mid-2009.