zhixiang zhao and qiyu peng...zhixiang zhao1 and qiyu peng2 1 university of shanghai for science and...

Zhixiang Zhao1 and Qiyu Peng2 1 University of Shanghai for Science and Technology

2 Lawrence Berkeley National Laboratory (qpeng@lbl.gov )

A novel read-out electronics design

Conventional front-end electronics

OpenPET 16-ch front-end board

Conventional front-end electronics

16-ch front-end board

24 cm

16 cm

8 x 8 MPPC array

24 mm

Expensive, high power consumption and large board size. Channel-reduction is required when using analog SiPM array. • Degradation in performances (SNR, and timing resolution) • Some applications need analog signals from individual SiPM pixels (detectors

constructed with a monolithic crystal, dMiCE detectors and etc.)

Method to read out analog SiPMs

Channel reduction – sacrifice performances

Method to read out analog SiPMs

128-ch ASIC (PETsys Inc. )

• Limited Energy resolution (ToT) • No compensation for temperature

sensitive SiPM

Method to read out analog SiPMs

Readout electronics for two 128-ch ASICs (PETsys Inc. )

dSiPM

dSiPM

dSiPM

Low-cost high-performance readout electronics for analog SiPM

Simple and easy to implement • Low cost ($ 0.49 per channel). • Low profile (about 3mm x 3mm per channel) • Low power consumption: (20mW per channel)

Great Performances: • Energy measurement: Good linearity, Robust to noise, Large dynamic range • Potential ability to compensate the temperature-related gain fluctuations

automatically (real-time measurement) • High sampling rate and precisions to support innovative detector designs (sampling

rate: 1GHz, precision: 1 bit; equivalent to 50MHz, 6.6246 bits). • High accuracy in time measurement (Potential with strong evidences). • Highly flexible in trigger, digital signal processing, calibration / correction, and readout. • Easy to implement in large scale. Automatically establish the stable operation states –

highly tolerant to variances in the circuit. No need to manually tune the circuit.

1. Method

General idea

• No analog ADC, TDC, trigger and etc. • Everything is performed in a FPGA • Minimize board size and power consumption • Maximize performance and flexibility

FPGA (ADCs, TDCs, trigger circuits,

multiplexers temperature compensation and etc.)

SiPM Array Amplifiers

2. Simulation results

Simulation results

• Typical signals

Sampling rate: 1GHz, precision: 1 bit; equivalent to 50MHz, 6.6246 bits

Input signal Output signal

Simulation results

• Performance in energy calculation

Transfer function DNL INL

Simulation results

• Performance in energy calculation

Transfer function DNL INL

3. Experimental results

Experimental system

FPGA: Cyclone II (DE2 board)

Na 22, LYSO, R9800, -1300V

Single channel ADC circuit

Test pulse

SiPM MicroFC30035

DC current

Hardware, software and firmware specifications

Single channel ADC circuit • Cost: $0.49 per channel • Power consumption: 3mA x 6.6 V =20mW • Size: 3mm x 6mm on one side of the board

FPGA • Resources: one register and one counter per channel

System specs. • Sampling rate: 1GHz, precision: 1 bit (equivalent to 50MHz, 6.6246 bits) • Precision of energy calculation: 4.1250*10^6 charges per LSB. • Dynamic range: 12 bits (0~4092). • On line (FPGA firmware) event triggering and energy calculation. • RS232 data interface.

Energy spectrum

Single channel ADC circuit OpenPET

ER: 11.4%, Ratio of peak: 2.56 ER: 11.4%, Ratio of peak: 2.32

• Similar energy spectrum • The same energy resolutions. • Better linearity.

1275 keV

511 keV

1275 keV

511 keV

Test pulse experiments

Transfer function DNL

INL Repeatability (or noise performances)

DC measurements In

crea

se 1

00nA

per

step

DC measurements

Transfer function

DC measurements

DNL INL

SiPM V-I curve measurements

• Break down voltage is 24.7 V, which the same as that measured by the vendor of the SiPM chip.

• The measured dark current at +2.5V were 310 nA, which is close to the typical value (319 nA) provided by the vendor.

SiPM gain and DCR measurements

Performance of 16 FPGA-based TDCs

• Average TR: 72.5ps ± 31.0 ps

Tigger timing Trigger charges Note

Experimental results

<51.6*10^6 charges

• triggers on p.e.#47 of PMT R9800 (gain: 1.1*10^6), • p.e.#41 of MPPC S12572-50P (gain: 1.25*10^6), • p.e.#17 of SensL MicroFC-30035-SMT (gain: 3*10^6).

Theoretic calculation (non-ideal components)

19.4*10^6 charges (delay = 3.6ns)

• triggers on p.e.#18 of PMT R9800 (gain: 1.1*10^6), • p.e.#15.6 of MPPC S12572-50P (gain: 1.25*10^6), • p.e.#6 of SensL MicroFC-30035-SMT (gain: 3*10^6).

Theoretic calculation (ideal components)

5*10^6 charges (delay = 0 ns)

• triggers on p.e.#5 of PMT R9800 (gain: 1.1*10^6), • p.e.#4 of MPPC S12572-50P (gain: 1.25*10^6), • p.e.#2 of SensL MicroFC-30035-SMT (gain: 3*10^6).

4. Summary

Features of our design Simple and easy to implement Low cost ($ 0.49 per channel). Low profile (about 3mm x 3mm per channel) Low power consumption: (20mW per channel)

Great Performances: Energy measurement: Good linearity, Robust to noise, Large dynamic range Ability to compensate the temperature-related gain fluctuations automatically (real-time

measurement) High sampling rate and precisions to support innovative detector designs (sampling rate:

1GHz, precision: 1 bit; equivalent to 50MHz, 6.6246 bits). Highly flexible in trigger, digital signal processing, calibration / correction, and readout. Easy to implement in large scale. Automatically establish the stable operation states –

highly tolerant to variances in the circuit. No need to manually tune the circuit. • High accuracy in time measurement (more testing on going).

Conclusion: A simple technology with great potentials

Ideal method for analog SiPM detectors – PET detectors using continuous crystals – Future TOF PET detectors

Questions?