1. First results from the DRS4 waveform digitizing chip
Stefan Ritt
Paul Scherrer Institute, Switzerland

2. 3 ps Timing with the DRS series ASICs
Stefan Ritt
Paul Scherrer Institute, Switzerland

3. Requirements High Sampling Speed SNR > 12 bit ps Timing Jitter
High Temperature Stability
Deep Sampling
Depth
Many Channels
Oct. 15th, 2008
Picosecond Workshop, Lyon

4. Picosecond Workshop, Lyon
A bit of history…
MEG Experiment searching
for me g down to 10-13
2001
DRS1
2004
DRS2
2006
DRS3
DRS4
3000 Channels with
GHz sampling
2008
Oct. 15th, 2008
Picosecond Workshop, Lyon

5. How to fulfill all these needs?
Design Principles
How to fulfill all these needs?

6. Picosecond Workshop, Lyon
The Domino Principle
0.2-2 ns
Inverter “Domino” ring chain IN
Waveform
stored
Out
FADC
33 MHz
Clock
Shift Register
“Time stretcher” GHz  MHz
Keep Domino wave running in a circular fashion and stop by trigger  Domino Ring Sampler (DRS)
Oct. 15th, 2008
Picosecond Workshop, Lyon

7. Picosecond Workshop, Lyon
Origin of Jitter
VDD/GND noise causes timing jitter!
VDD R R
GND
VDD
VDD’ t’
Golden Rules:
Make R small  Power Planes
Design for steep edges
VDD/2 t
Oct. 15th, 2008
Picosecond Workshop, Lyon

8. Picosecond Workshop, Lyon
Example: Bus drivers R C
Sheet resistance M5: W/sq., 4000mm x 0.4 mm  360 W
Area capacitance M5-M4: fF/mm fF/mm  0.35 pF
Oct. 15th, 2008
Picosecond Workshop, Lyon

9. Picosecond Workshop, Lyon
Bus driver simulation
Oct. 15th, 2008
Picosecond Workshop, Lyon

10. Picosecond Workshop, Lyon
Simulation Result 1
100 mV
Oct. 15th, 2008
Picosecond Workshop, Lyon

11. Picosecond Workshop, Lyon
Modified Bus Driver
Oct. 15th, 2008
Picosecond Workshop, Lyon

12. Picosecond Workshop, Lyon
Simulaiton Result 2
100 mV
Oct. 15th, 2008
Picosecond Workshop, Lyon

13. More elaborate evaluation
Timing-Jitter induced by power supply noise
A. Strak, H. Tenhunen,
Oct. 15th, 2008
Picosecond Workshop, Lyon

14. Rules for high precision timing
Keep local power supply stable
Low resistive power rails (planes)
Separate power supply for inverter chain + PLL from rest
Add on-chip decoupling capacitors
Try to keep number of simultaneously switching gates minimal
Design for fast transitions
Identify high load lines, driver them with enough power
Follow 1x 3x 10x 30x rule
Use differential signalling for critical lines
Inverter chain
Reference clock input
Do not use minimal transistors for critical paths  X
DRS4 
Oct. 15th, 2008
Picosecond Workshop, Lyon

15. “Residual charge” problem
After sampling a pulse, some residual charge remains in the capacitors on the next turn and can mimic wrong pulses
Solution: Clear before write
write
clear
“Ghost pulse”
2 GHz
Oct. 15th, 2008
Picosecond Workshop, Lyon

16. ROI readout mode
delayed trigger stop
normal trigger stop after latency
Trigger
stop
Delay
33 MHz
e.g MHz  3 us dead time (3.8 ns / 8 channels)
readout shift register
Patent pending!
Oct. 15th, 2008
Picosecond Workshop, Lyon

17. Simultaneous Write/Read
FPGA
Channel 0
readout 1
Channel 0
Channel 0
Channel 1
Channel 1 1
Channel 1
8-fold analog multi-event buffer
Channel 2 1
Channel 2
Channel 3
Channel 4
Channel 5
Channel 6
Channel 7
Expected crosstalk ~few mV
Oct. 15th, 2008
Picosecond Workshop, Lyon

18. Picosecond Workshop, Lyon
Interleaved sampling
6 GSPS * 8 = 48 GSPS
G. Varner et al., Nucl.Instrum.Meth. A583, 447 (2007)
delays (167ps/8 = 21ps)
Possible with DRS4 if delay is implemented on PCB
Oct. 15th, 2008
Picosecond Workshop, Lyon

19. New generation of FADCs
8 simultaneous flash ADCs on one chip
Require differential input
DRS4 has been redesigned with differential output
Oct. 15th, 2008
Picosecond Workshop, Lyon

20. Trigger an DAQ on same board
Using a multiplexer in DRS4, input signals can simultaneously digitized at 65 MHz and sampled in the DRS
FPGA can make local trigger (or global one) and stop DRS upon a trigger
DRS readout (5 GHz samples) though same 8-channel FADCs
DRS4
global trigger bus
trigger
FPGA
MUX
DRS
FADC 12 bit
65 MHz
analog front end
LVDS
SRAM
“Free” local trigger capability without additional hardware
Oct. 15th, 2008
Picosecond Workshop, Lyon

21. Picosecond Workshop, Lyon
Decisions
Usage of external ADC
Analog Devices has better engineers
Get information faster off-chip (1 sample in 30 ns, 12 bits would need 400 MHz clock)
Possibility for continuous sampling ( triggering)
Use passive input
Hard to design 1 GHz buffer in 0.25 mm technology, needed for 1V linear range
Lower power consumption
Problem: Bond wire Cparasitic limits bandwidth, high input current 0.8 mA
Use Gate-All-Around (GAA) transistors
Radiation hardness
Good W/L vs. chip area  bigger gates  reduced mismatch
On-chip PLL for sampling frequency stabilization
Flexible channel configuration
Oct. 15th, 2008
Picosecond Workshop, Lyon

22. Have we achieved the requirements?
DRS4
Have we achieved the requirements?

23. Picosecond Workshop, Lyon
DRS4
Fabricated in 0.25 mm 1P5M MMC process (UMC), 5 x 5 mm2, radiation hard
8+1 ch. each 1024 bins, 4 ch. 2048, …, 1 ch. 8192
Differential inputs/ outputs
Sampling speed 500 MHz … 6 GHz
On-chip PLL stabilization
Readout speed 30 MHz, multiplexed or in parallel
Oct. 15th, 2008
Picosecond Workshop, Lyon

24. Picosecond Workshop, Lyon
DRS4 packaging
DRS4
flip-chip
DRS4
DRS3
4.2 mm
9 mm
18 mm
Oct. 15th, 2008
Picosecond Workshop, Lyon

25. Picosecond Workshop, Lyon
On-chip PLL
Simulation
loop filter
DRS4
Phase detector up
Vspeed
down
Measurement
Reference
Clock fclk = fsamp / 2048
PLL jitter « 100 ps (Spartan-3 jitter 150 ps)
“Dead Band” free
Does not lock on higher harmonics
Oct. 15th, 2008
Picosecond Workshop, Lyon

26. Picosecond Workshop, Lyon
Linear Range (DRS3)
Excellent linearity from 0.1V … 33 MHz readout
0.5 mV max.
Oct. 15th, 2008
Picosecond Workshop, Lyon

27. Picosecond Workshop, Lyon
Bandwidth
Bandwidth is determined by bond wire and internal bus resistance/capacitance:
850 MHz (QFP), 950 MHz (QFN), ??? (flip-chip)
850 MHz (-3dB)
QFP package
Measurement
final bus width
Simulation
Oct. 15th, 2008
Picosecond Workshop, Lyon

28. Signal-to-noise ratio (DRS3!)
“Fixed pattern” offset error of 5 mV RMS can be reduced to 0.35 mV by offset correction in FPGA
SNR:
1 V linear range / 0.35 mV = 69 dB (11.5 bits)
Offset
Correction
Oct. 15th, 2008
Picosecond Workshop, Lyon

29. Picosecond Workshop, Lyon
Timing jitter
Inverter chain has transistor variations  Dti between samples differ  “Fixed pattern jitter”
“Differential temporal nonlinearity” TDi= Dti – Dtnominal
“Integral temporal nonlinearity” TIi = SDti – iDtnominal
“Random jitter” = variation of Dti between measurements
Dt1
Dt2
Dt3
Dt4
Dt5
TD1
TI5
Oct. 15th, 2008
Picosecond Workshop, Lyon

30. Fixed jitter calibration
Fixed jitter is constant over time, can be measured and corrected for
Several methods are commonly used
Most use sine wave with random phase and correct for TDi on a statistical basis
Oct. 15th, 2008
Picosecond Workshop, Lyon

31. Picosecond Workshop, Lyon
Sine Curve Fit Method i
yji : i-th sample of measurement j
aj fj aj oj : sine wave parameters
bi : phase error  fixed jitter
“Iterative global fit”:
Determine rough sine wave parameters for each measurement by fit
Determine bi using all measurements where sample “i” is near zero crossing
Make several iterations j
S. Lehner, B. Keil, PSI
Oct. 15th, 2008
Picosecond Workshop, Lyon

32. Fixed Pattern Jitter Results
TDi typically ~50 ps 5 GHz
TIi goes up to ~600 ps
Inter-channel variation on same chip is very small since all channels are driven by the same domino wave
Oct. 15th, 2008
Picosecond Workshop, Lyon

33. Picosecond Workshop, Lyon
Random Jitter Results
Sine curve frequency fitted for each measurement (PLL jitter compensation)
Encouraging result for DRS3: 2.7 ps RMS (best channel) 3.9 ps RMS (worst channel) phase error in fitting sine wave
Differential measurement t1 – t2 adds a 2, needs to be verified by measurement
Measurement of n points on a rising edge of a signal improves by n
Measurements for DRS4 currently going on, expected to be slightly better
Oct. 15th, 2008
Picosecond Workshop, Lyon

34. Inter-Chip Synchronization
Trigger t1
Reference Clock
Chip 2 t2
PLL Jitter?
Oct. 15th, 2008
Picosecond Workshop, Lyon

35. Rules for Synchronization
Synchronize chips with a global low jitter reference clock
Determine timing of a hit in respect to global clock (beginning of sampling window)
PLL timing jitter < desired accuracy  you’re done
PLL timing jitter > desired accuracy  use clock channel with sine
~100 ps jitter  few ps accuracy
8 inputs
Shift register
Domino + PLL
Reference Clock
Global Sine Wave
Oct. 15th, 2008
Picosecond Workshop, Lyon

36. Picosecond Workshop, Lyon
Chip Comparison
Oct. 15th, 2008
Picosecond Workshop, Lyon

37. Experiments using DRS chip
MEG 3000 channels DRS2
MAGIC-II 400 channels DRS2
BPM for
1000 channels DRS4 (planned)
MACE (India) 400 channels DRS4 (planned)
Oct. 15th, 2008
Picosecond Workshop, Lyon

38. Availability
DRS4 will become available in larger quantities in November 2008
Chip can be obtained from PSI on a “non-profit” basis
Delivery “as-is”
Reference design (schematics) from PSI
Costs ~ 10-15$/channel
Costs decrease if we find sell more…
VME boards from industry in 2009
32-channel 65 MHz/12bit digitizer
“boosted” by DRS4 chip to 5 GHz
ext.
Trigger
Input
DRS4
USB 2.0
Oct. 15th, 2008
Picosecond Workshop, Lyon

39. Picosecond Workshop, Lyon
Datasheet
Oct. 15th, 2008
Picosecond Workshop, Lyon

40. Conclusions http://midas.psi.ch/drs
Fast waveform digitizing is in my opinion the best choice to achieve ps timing
Phase noise of a single cell using a 500 MHz sine wave has been measured to be 3-4 ps in the DRS chip
More characterization is needed from community (Single pulse response, 48 GHz mode, …)
DRS4 has prospects to come quite a step closer to our goal
Oct. 15th, 2008
Picosecond Workshop, Lyon

42. Picosecond Workshop, Lyon
Simple inverter chain 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1
Oct. 15th, 2008
Picosecond Workshop, Lyon

43. Design of Inverter Chain
PMOS > NMOS
PMOS < NMOS
Oct. 15th, 2008
Picosecond Workshop, Lyon

44. Picosecond Workshop, Lyon
“Tail Biting”
speed
enable 1 2 3 4 1 2 3 4
Oct. 15th, 2008
Picosecond Workshop, Lyon

45. Picosecond Workshop, Lyon
Stopping
speed
enable 1 2 3 4
enable 1 2 3 4
time
Oct. 15th, 2008
Picosecond Workshop, Lyon

46. Picosecond Workshop, Lyon
Stop Schematics WE 1 2 WE 3 D Q D Q D Q
RES
RES
RES 1 2 3
Oct. 15th, 2008
Picosecond Workshop, Lyon

47. Picosecond Workshop, Lyon
Complete Domino Cells
Domino Cell 1
Domino Cell 2
Domino Cell 3
Vspeed
Enable
Write D Q D Q D Q
RES
RES
RES
Start
Sampling Cell 1
Sampling Cell 2
Sampling Cell 3
Oct. 15th, 2008
Picosecond Workshop, Lyon

48. On-line waveform display
PMTs
“virtual oscilloscope”
template
fit
click
pedestal
histo
Oct. 15th, 2008
Picosecond Workshop, Lyon

49. Constant Fraction Discr.
Delayed
signal
Inverted
signal
Sum
Clock
12 bit
Latch
Latch
Latch
Latch +
Latch
Latch S +
<0
&
MULT 0
Oct. 15th, 2008
Picosecond Workshop, Lyon