1. HLT architecture

2. FEC (Front End Card) - 128 CHANNELS (CLOSE TO THE READOUT PLANE)
TPC FEE
FEC (Front End Card) CHANNELS
(CLOSE TO THE READOUT PLANE)
DETECTOR
Power
consumption:
< 40 mW / channel
L1: 5ms
200 Hz
8 CHIPS x
16 CH / CHIP
8 CHIPS x
16 CH / CHIP
drift region
88ms
L2: < 100 ms
200 Hz
Digital
Circuit
gating grid
PASA
ADC
RAM
anode
wire
DDL
(4096 CH / DDL)
570132
PADS
pad
plane
CUSTOM IC
(CMOS 0.35mm)
CUSTOM IC (CMOS 0.25mm )
CSA
SEMI-GAUSS. SHAPER
1 MIP = 4.8 fC
S/N = 30 : 1
DYNAMIC = 30 MIP
BASELINE CORR.
TAIL CANCELL.
ZERO SUPPR.
10 BIT
< 10 MHz
MULTI-EVENT
MEMORY
GAIN = 12 mV / fC
FWHM = 190 ns

4. TPC electronics: ALICE TPCE READOUT CHIP (ALTRO)
ADC
Adaptive
Baseline
Correct. I
Tail
Cancel.
Adaptive
Baseline
Correct. II
Data
Format.
Multi-Event
Memory + -
10- bit
20 MSPS
11- bit CA2
arithmetic
18- bit CA2
arithmetic
11- bit
arithmetic
40-bit
format
40-bit
format
SAMPLING CLOCK 20 MHz
READOUT CLOCK 40 MHz
0.25 mm (ST) area:64mm2 power:29 mW / ch SEU protection
DIGITAL TAIL CANCELLATION PERFORMANCE
ADC counts
DIGITAL PROCESSOR & CONTROL LOGIC
8 ADCs
MEMORY
ADC counts
Time samples (170 ns)

5. Data compression: Entropy coder
Probability distribution of 8-bit TPC data
Results:
NA49:
compressed event size = 72%
ALICE:
= 65%
(Arne Wiebalck, diploma thesis, Heidelberg)
Variable Length Coding
short codes for long codes for frequent values infrequent values

6. TPC - RCU

7. RCU design – control flow
TTCrx
SIU
controller
FEE bus
controller
DDL
command
decoder
FEE SC
RCU
resource
&
priority manager
State machines
Huffman
encoder
Slow
control
Watch dog:
health agent
Debugger
PCI
core

8. RCU design - data flow Shared memory modules TTC controller
TTCrx registers
FEE bus controller
Event memory
SIU controller fifo
FEE bus controller
Event fragment
pointer list
SIU
Huffman encoder
FEE bus controller
Configuration memory
Slow control

9. Data compression: TPC - RCU
TPC front-end electronics system architecture and readout controller unit.
Pipelined Huffman Encoding Unit, implemented in a Xilinx Virtex 50 chip*
* T. Jahnke, S. Schoessel and K. Sulimma, EDA group, Department of Computer Science, University of Frankfurt

10. RCU prototypes Prototype I Prototype II Prototype III RCU production
Commercial OEM-PCI board
FEE-board test (ALTRO + FEE bus)
SIU integration
Qtr 3, 2001 – Qtr 2, 2002
Prototype II
Custom design
All functional blocks
PCB: Qtr 2, 2002
Implementation of basic functionality (FEE-board -> SIU): Qtr 2, 2002
Implementation of essential functionalty: Qtr 4, 2002
Prototype III
SRAM FPGA -> masked version or Antifuse FPGA (if needed)
RCU production
Qtr 2, 2003

11. RCU prototype I Commercial OEM-PCI board ALTERA FPGA APEX EP20K400
SRAM 4 x 32k x 16bits
PMC I/O connectors (178 pins)
Buffered I/O (72 pins)

12. RCU prototype I Implementation of basic test functionality
FEE boards
trigger
Implementation of basic test functionality
FEE-board test (ALTRO + FEE bus)
SIU integration
FEE-bus
daughter board
PMC
PCI bus
FPGA
APEX20k400
PCI core
I/O
internal
SRAM
SIU card
4 x 32k x 16
FLASH EEPROM
onboard SRAM

13. RCU prototype II Implementation of essential functionality
Custom design
All functional blocks SC
TTC
FEE-bus
PCI bus
SIU-CMC
interface
PCI core
FPGA
internal
SRAM
SIU
> 2 MB
FLASH EEPROM
Memory D32

14. RCU prototype II - schematics
JN2A
CIA miscellaneous
JN1
JN2
Flash
(1.8V Gen.)
Power
SRAM
Flash
Flash
JN3
JN4
JN5
SDRAM
SRAM
APEX
Connectors

15. RCU prototype II – RCU mezzanine
RCU Mezzanine Card
Components on top side
No maximum height restriction
Front-End Bus Conn 1
Front-End Bus Conn 2

16. RCU prototype II - schematics
SIU / DIU mezzanine card
(1/2 CMC)
RCU Mezzanine Card
Components on top side
No maximum height restriction
Front-End Bus Conn 1
Front-End Bus Conn 2
CIA miscellaneous
JN1
JN2
JN2A
Flash
(1.8V Gen.)
Power
SRAM
Flash
Flash
JN3
JN4
JN5
SDRAM
SRAM
APEX
Connectors

17. Programming model Development version – status December 2001 PC
LINUX
RH7.1 (2.4.2)
PCI-tools
RCU-API
device driver
PCI core
mailbox
memory
PLDA board
SIU
controller
FEE bus
controller
ALTRO
emulator
FEE bus
SIU
ALTRO
emulator
DDL

18. SIU-RORC integration RCU prototype I pRORC LINUX/NT PLDA/PCI-tools
RCU-API
devicer driver
SIU
FPGA
interface
SIU controller
PCI core
SIU
SRAM
PCI bus
DDL
pRORC
LINUX
DDL/PCI-tools
pRORC-API
device driver
DIU
PCI bridge
Glue logic
interface
DIU
PCI bus

19. send DDL-FEE command READY-TO-RECEIVE
SIU-RORC integration
Result
data control
PC1:
write memory block to
FPGA internal SRAM
PC1 memory block
PC2:
allocate bigphys area,
init link + pRORC
RCU internal SRAM
SIU controller:
wait for
READY-TO-RECEIVE
PC2:
send DDL-FEE command READY-TO-RECEIVE
SIU
SIU controller:
strobe data into SIU
DDL
DIU
pRORC:
copy data into
bigphys area
via DMA =
PC2
”bigphys”
memory area

20. RCU system for TPC test 2002 RCU prototype II/I pRORC Trigger
FEE-bus
FEE-boards
LINUX RH7.x
DATE
PLDA/PCI-tools
RCU-API
devicer driver
SIU
FPGA
interface
RCU prototype II/I
FEE-bus controller
SIU controller
Manager
PCI core
SIU
SRAM
FLASH
ext. SRAM
PCI bus
DDL
LINUX RH7.x
DATE
DDL/PCI-tools
pRORC-API
device driver
DIU
PCI bridge
Glue logic
interface
DIU
pRORC
PCI bus

21. Programming model TPC test version – summer 2002 DATE FEE configurator
LINUX
RH7.1 (2.4.2)
PCI-tools
RCU-API
device driver
PCI core
mailbox
memory
Prototype II
(Prototype I)
SIU
controller
RCU
resource
&
priority manager
FEE bus
controller
FEE bus
SIU
FEE boards
DDL

22. TPC PCI-RORC PCI bus FPGA Memory DIU - CMC PCI bridge Coprocessor
Glue logic
D32
interface
internal
2 MB
DIU card
SRAM
FLASH
EEPROM
2 MB
Memory D32

23. HLT architecture overview
Optical
Links to Front -
End
Not a specialized computer, but a generic large scale (>500 node) multi processor cluster
A few nodes have additional hardware (PCI RORC)
has to be operational in off-line mode also
Use of commodity processors
Use of commodity networks
Reliability and fault tolerance is mandatory
Use standard OS (Linux)
Use of on-line disks as mass storage
Receiver
Processos /
HLT Processor
RcvBd
RcvBd
RcvBd
RcvBd
RcvBd
RcvBd
RcvBd
RcvBd
RcvBd
RcvBd
RcvBd
RcvBd
NIC
PCI
PCI
NIC
NIC
NIC
PCI
PCI
NIC
NIC
NIC
PCI
PCI
NIC
NIC
NIC
PCI
PCI
NIC
NIC
Distributed
Farm Controller
HLT Network
NIC
PCI
PCI
NIC
NIC
PCI
NIC
NIC
Monitoring
Server
NIC
PCI
PCI
PCI
PCI
PCI
PCI
PCI
PCI
PCI
PCI
NIC
NIC
NIC
NIC
NIC
NIC
NIC
NIC
NIC
NIC
NIC
NIC
NIC
NIC
HLT
Processors

24. HLT - Cluster Slow Control
Features:
Battery Backed Completely independent of host
Power Controller Remote powering of host
Reset Controller Remote physical RESET
PCI Bus perform PCI bus scans, identify devices
Floppy/flash emulator create remotely defined boot image
Keyboard driver remote keyboard emulation
Mouse driver remote mouse emulation
VGA replace graphics card
price very low cost
Functionality:
complete remote control of PC like terminal server but already at BIOS level
intercept port 80 messages (even remotely diagnose dead computer)
interoperate with remote server, providing status/error information
watch dog functionality
identify host and receive boot image for host
RESET/Power maintenance

25. HLT Networking (TPC only)
All data rates in kB/sec (readout not included here)
92 000
spare
7 000
65 000
92 000
spare
180 links, 200 Hz
92 000
spare
65 000
7 000
92 000
160 Hz TRD with 4 sectors corresponds to 57 Hz  use 60 Hz full readout as baseline
Raw Event in 515 kB per receiver processor
Assume space points are about ½ of 8-bit raw data  average space point size per receiver processor 215 kB
Track segments are factor 10 smaller than appropriate space points ?
aggregate
cluster finder
nodes
Track segments
nodes
Track merger
72+36 nodes
Global L3
12 nodes
Assume 40 Hz coinzidence trigger plus 160 Hz TRD pretrig with 4 sectors per trigger

26. HLT Interfaces
HLT is autonomous system with high reliability standards (part of data path)
HLT has a number of operating modes
on-line trigger
off-line processor farm
possibly combination of both
very high input data rates (20 GB/sec)
high internal networking requirements
HLT front-end is first processing layer
Goal: same interface for data input, internal data exchange and data output
HLT internal, input and output interface
Publish/subscribe:
When local do not move data – Exchange pointers only
Separate processes, multiple subscribers for one publisher
Network API and architecture independent
Fault tolerant (can loose node)
Consider monitoring
Standard within HLT and for input and output
Demonstrated to work on both shared memory paradigm and sockets
Very light weight
Performance measurement was done on ordinary 700 MHz PC (December 2000)

27. HLT system structure Pattern Recognition (Sub)-event Reconstruction
TRD
trigger
PHOS
trigger
Dimuon trigger
Trigger detectors
Level-1
Pattern Recognition
TPC:
fast cluster finder + fast tracker
Hough transform + cluster evaluator
Kalman fitter
Dimuon arm tracking
Level-3
Extrapolate to ITS
...
Extrapolate to TOF
Extrapolate to TRD
(Sub)-event Reconstruction

28. Preprocessing per sector
RCU
raw data, 10bit dynamic range,
zero suppressed
Huffman encoding (and vector quantization)
detector front-end electronics
Huffman decoding,
unpacking, 10-to-8 bit conversion
fast cluster finder:
simple unfolding, flagging of overlapping clusters
RORC
fast track finder
initialization (e.g.
Hough transform)
cluster list
fast vertex finder
Hough histograms
Peakfinder
receiver node
global node
vertex position
raw data

29. FPGA coprocessor: cluster finder
Fast cluster finder
up to 32 padrows per RORC
up to 141 pads/row and up to 512 timebins/pad
internal RAM: 2x512x8bit
timing (in clock cycles, e.g. 5 nsec)1:
#(cluster-timebins per pad) / 2 + #clusters
outer padrow: 150 nsec/pad, 21 sec/row
centroid calculation: pipelined array multiplier
1. Timing estimates by K. Sulimma, EDA group, Department of Computer Science, University of Frankfurt

30. FPGA coprocessor: Hough transformation
Fast track finder: Hough transformations2
(row,pad,time)-to-(2/R,,) transformation
(n-pixel)-to-(circle-parameter) transformation
feature extraction: local peak finding in parameter space
2. E.g. see Pattern Recognition Algorithms on FPGAs and CPUs for the ATLAS LVL2 Trigger,
C. Hinkelbein et at., IEEE Trans. Nucl. Sci. 47 (2000) 362.

31. Processing per sector RORC receiver node raw data, 8bit dynamic range,
decoded and unpacked
vertex position,
cluster list
slicing of padrow-pad-time space into
sheets of pseudo-rapidity,
subdiving each sheet into overlapping patches
RORC
sub-volumes in r,,
fast track finder B:
1. Hough transformation
fast track finder A:
track follower
fast track finder B: 2. Hough maxima finder, 3. tracklett verification
track segments
receiver node
cluster deconvolution
and fitting
updated vertex position
updated cluster list,
track segment list