Off Detector Electronics Upgrade

S. Cadeddu - INFN Cagliari 2

Outline

• Present schemes and features

• New schemes of nSYNC

• Technology

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S. Cadeddu - INFN Cagliari 3

Present ODE implementation

L0 front-end electronics stage• 192 LVDS input signals • 24 SYNC chips (on 3 types of piggy board)

TFC system interface and clock management• 1 optical receiver + 1 TTCrx chip• 1 QPLL chip• Tree network based on MC100LVEP family

L0 trigger interface• 12 GOL chips + 1 parallel optical transmitter• Valid data transmission @40MHz

L1 DAQ interface• 1 GOL chip + 1 VCSel diode• Valid data transmission @1 MHz

FPGA board controller• Flash RAM based Actel FPGA (ProAsicPlus)• 3 buses (32 bit) for SYNC and GOL interfaces

ECS interface• 1 ELMB board

– CANbus link on the backplane– 2 I2C internal buses

6U Compact PCI card• 10 layers motherboard with controlled impedance• Mixed 5/3.3/2.5 V devices

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SYNC

DAQ inter.

TRG inter.

TFC inter.

GOL

ECS inter.

Controller

S. Cadeddu - INFN Cagliari 4

Present SYNC implementation

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TDC & Synchronizer: • 4 bit TDC (1.5 ns resolution @ 40 MHz) –

DLL based. Custom Macro-cell.L0 Trigger Interface: • Sends 8 synchronized hits along with the

2 LSB of the BX Id @ 40 MHz.• Prog. buffer depthL0 buffer & Derandomizer: • Based on the 128x27 SRAM blocks (CERN

development – K. Kouklinas)• Circular buffer of 256x54 SRAM.• Initial R/W address programmable.• FIFO of 128x54 SRAM• The depth is programmable to 16, 32, 64

or 128.EDAC: • Single Error detection and correction,

Double Error detection. 7 bits code.Histogram Builder: • 16 bins of 224 entries each. I2C Interface• Used to R/W internal configuration.• Configuration Registers are triple voted

and auto-corrected for best SEU immunity.

• All other registers are triple voted

Trigger link testL1 link test

S. Cadeddu - INFN Cagliari 5

SYNC 1.0: The present …

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L0 Buffers L0 Buffers

L0 BuffersL0 Buffers

Derand Derand

TDC’s

VD

D

VDD

VDD

VDD

VDD

VD

D

VD

D

VD

D

GN

D

GN

D

GN

D

GND

GND

GND

GND

8 LVDS Input

Output to L1 electronics

GO

L ou

tput

GND

I2C I2C

I 2CC

TR

LS

SYNC 1.0

97 pins

4x4 mm2

QFP 14x14 100 pins

IBM 0.25 mm RadHard

S. Cadeddu - INFN Cagliari 6

ODE upgrade specs

• Design new boards (nODE), almost “plug & play” with current ODEs– No need to touch cables from chamber to crates– Same transition boards (no crate re-cabling)– Single type of board for all stations/regions

• Use new GBT and versatile link components to implement trigger, DAQ, TFC and ECS interfaces– Optimized number of links to the L0 Muon trigger

• Maintain the trigger unit information on the same link• Possible implementation in the TELL40

– Read TDC data @ 40 MHz rate– No more need to maintain present TFC and ECS systems

• Use a new custom ASIC (nSYNC) to integrate all the required functionalities– Clock synchronization and Bx alignment – Time measurements and histogram capability– Zero suppression algorithm and buffering– Test facilities and diagnostic– Trigger, DAQ, TFC and ECS interfaces via GBTx

• Guarantee enough flexibility to increase granularity and reduce channel occupancy– Possible IB boards replacement in the high occupancy zone – Possible chambers replacement in low granularity zone

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nODE Architecture

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nODE

DATA Path

Sync

nSYNC

Bu

nch

cro

ss s

ynch

r.

TDC

Hit format

Hist.

GBT interf.

Zero Supp.

GBT interf.

ECS/TFC

LVD

S R

ecei

vers

Tr

ansl

ato

rs

GBTx Hit data

serializer

VTTx Optical

transmitter

GBT-SCAControlMonitor

VTRx Optical

transceiver

GBTxData

Ser/Des

VTTx Optical

transmitter

GBTx Hit data

serializer

Sync

nSYNC

Bu

nch

cro

ss s

ynch

r.

TDC

Hit format

Hist.

GBT interf.

Zero Supp.

GBT interf.

Sync

nSYNC

Bu

nch

cro

ss s

ynch

r.

TDC

Hit format

Hist.

GBT interf.

Zero Supp.

GBT interf.

Sync

nSYNC

Bu

nch

cro

ss s

ynch

r.

TDC

Hit format

Hist.

GBT interf.

Zero Supp.

GBT interf.

LVD

S R

ecei

vers

Tr

ansl

ato

rsLV

DS

Rec

eive

rs

Tran

slat

ors

LVD

S R

ecei

vers

Tr

ansl

ato

rsLV

DS

Rec

eive

rs

Tran

slat

ors

LVD

S R

ecei

vers

Tr

ansl

ato

rs

Sync

nSYNC

Bu

nch

cro

ss s

ynch

r.

TDC

Hit format

Hist.

GBT interf.

Zero Supp.

GBT interf.

192 Input channels

Power section

Voltage regulators

DC/DC converter

Power up sequencer

Clock management

Clock driver

Phase adjust

Sync

nSYNC

Bu

nch

cro

ss s

ynch

r.

TDC

Hit format

Hist.

GBT interf.

Zero Supp.

GBT interf.

GBTx TDC data serializer

GBTx HIT data serializer

To TELL40 Links

simplex

To Trigger links

simplex

To/from TFC1 linkduplex

S. Cadeddu - INFN Cagliari 8

nSYNC Architecture

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TDC + Histogram builder: • 4 bit TDC (1.5 ns resolution @ 40 MHz)• 16 bins of 224 entries each. The counts stop

when any of the bins saturates. Dead time free in hit capture.

Muon Trigger TELL40 Interface: • Sends synchronized hits every machine cycle

(40 MHz).• Prog. buffer depth to guarantee the

synchronization between different nSYNC sending data through the same GBT

TDC ZS: • Zero Suppression of TDC’s data not related to

hit events.

TDC TELL40 Interface: • Sends synchronized ZS TDC data every

machine cycle (40 MHz).• Prog. buffer depth to guarantee the

synchronization between different nSYNC sending data through the same GBT

I2C Interface: • Configure through the ECS.• Triple-voted configuration

S. Cadeddu - INFN Cagliari 9

SYNC 1.0 vs nSYNC

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8 ch vs 32 ch

Histo for each TDC

No more needs forRAM’s + EDAC

TDC data ZS

97 pins vs 220 pins

S. Cadeddu - INFN Cagliari 10

Why an asic

• Modularity: we are thinking at three possible modularity (32, 48, 96 channels), to best fit the requirements for:– Power consumptions (less then 20mA per channel)– Best ZS for TDC data

• An eye on LS3 stage: If we go to design a new detector with higher granularity for at least M2R1 and M2R2 (and maybe for the same regions of M3 too), we have also to design a new front-end electronics and a new front-end board where we can integrate the nSYNC direct on the detector.

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S. Cadeddu - INFN Cagliari 11

Technologies

IMEC DARE (Design Against Radiation Effects) technology:

• Radiation-hardened-by-design libraries in standard commercial technology– DARE180 well supported (UMC .18)– DARE90 small core & IO library available(UMC 90nm)

• Manufacturing, Packaging, Testing, Characterization (lot) Qualification & Radiation test up to FM is supported by imec’s ASIC Services– Through subcontractors (Microtest, Maser, MAPRAD)

• Flexible solution– DARE allows for mixed signal design

• Can add specific analog blocks; designed by customer, design house or imec• Encrypted models of library cells can be used in analog design ervironment.

– Cells can be added to the library– IO pads can be customized ...

• Imec has expertise on the full DSM design flow • They tested DARE digital blocks up to 1 MRad without failures or

leakage current increases. • SEU performance is in the order of a LET cross-section of  48/60

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S. Cadeddu - INFN Cagliari 12

Technologies

DARE UMC 180 Family

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IO a

t 3.3

and

2.5

V

Logic MMRF CIS

combinatorial 50 50 50normal' FF's 20 20 20HIT FF's 20 20 20HIT FF with M1 progr. Reset no no 4Clock Gating cells 3 3 3TIEx 2 2 2Digital IO 40 40 40Analog IO 5 5 6LVDS (extended Com. Mode Range) 3 3 3PLL 1 1 1

SRAM Compiler (6Tor cell) a a noDPRAM Compiler (6Tor cell) a a no

IO

IO

Core 1.8V

pads:- 70x70- 110x110- custom

All FF’s have scan equivalents

+ Fillers & Corners

+ Customer Requests+ Additional Analog IP developed by an external design house (DAC, ADC, ...)

S. Cadeddu - INFN Cagliari 13

nSYNC: work in progress

I2C interface:• Designed and tested in another chip for

a INFN gruppo 5 experiments.

PLL and Delay lines:• These are the main crucial parts for the

TDC implementation as well as the GBT interfaces that needs a different frequencies from the master clock.They are under study and develpment in another INFN gruppo 5 experiment (alldigitall)

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S. Cadeddu - INFN Cagliari 14

All Digital PLL

• An ADPLL include a DCO instead of a VCO

• In most architecture the DCO=DAC+VCO

• In other case the DCO is based on effects of analog components

• The aim of ALLDIGITALL experiment is to realize a true DCO, portable on differenttechnologies (FPGA, ASIC), integrable in a flow fully digital

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S. Cadeddu - INFN Cagliari 15

DCO in 130nm technology

Frequency Range (1.3 – 25.5) ns(770 – 39) MHz

LSB 95 psDNL (+/- 13) ps

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S. Cadeddu - INFN Cagliari 16

DCO in 130nm technology

Frequency Range (0.75 – 39) ns(1250 – 26) MHz

LSB 150 psDNL (+/- 10) ps

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