data acquisition system for a proton imaging apparatus
DESCRIPTION
Data acquisition system for a proton imaging apparatus. - PowerPoint PPT PresentationTRANSCRIPT
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1
Data acquisition system for a proton imaging apparatus
V.Sipalaa,b, D.LoPrestia,b, N.Randazzob, M.Bruzzid,e, D.Menichellie,d, C.Civininid, M. Brianzid, M.Bucciolinic,d, C.Talamontic,d, M.Tesie, L.Marrazzoc,d, L.Capinerif,
S.Valentinid,f G.Cuttoneg, G.A.P.Cirroneg, G.Candianog, E.Mazzagliag
a) Dipartimento di Fisica, Università degli Studi di Catania
b) INFN, sezione di Catania
c) Dipartimento di Fisiopatologia Clinica, Università degli Studi di Firenze
d) INFN, sezione di Firenze
e) Dipartimento di Energetica, Università degli Studi di Firenze
f) Dipartimento di Elettronica e Telecomunicazioni, Università degli Studi di Firenze
g) Laboratori Nazionali del Sud-INFN, Catania.
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Outline Proton therapy and proton imaging Proton imaging apparatus Data acquisition system
Tracker Single module architecture Detector VLSI front-end
Calorimeter Crystal YAG:Ce Electronic readout Trigger system
First results with proton beam Conclusions
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Proton therapy
The proton therapy is a good clinical treatment for cancer as it permits to obtain a dose distribution extremely conform to the target volume.
The Bragg peak shape ensures that healthy tissues in front of and beyond the tumor are not damaged.
Through the weighted superposition of proton beams of different energies it is possible to deposit a homogenous dose in the target region using only a single proton beam direction. (Spread Out Bragg Peak -SOBP).
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photons and protons are a different interaction with the matter
proton Computed Tomography – pCTProton imaging
Main issues in the quality of treatment in proton therapy are: Patient positioning Dose planning
Actually X-rays radiography and X-CT are used but…
By the pCT it’s possible to obtain: Directly measurements of the stopping power distribution using
the same therapeutic beam In a single phase the patient positioning and the treatment
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pCT parameters
PARAMETER VALUE
Proton beam energy 250-270MeV
Proton beam rate 1MHz
Spatial resolution <1mm
Electronic density resolution <1%
Detector radiation hardness > 1000 Gy
Dose per scan < 5 cGy
Critical parameters: Proton beam rate Data acquisition system Spatial resolution Multiple Coulomb Scattering
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Reconstruct principle: Most Likely Path
A: Only entry position & direction known: straight line LB: Entry position & direction + exit position known: straight line L’C: Entry position & direction + exit position & direction known: curved
path L’’, “banana-shaped”, narrow confidence limits
L’ L’’L
B CA
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proton Computed Tomography concept
Reveal the trace of the single proton using a silicon telescope
Measure the residual energy of the proton using a calorimeter
Reconstruct the most likely path of the single proton
Reconstruct the imagine
Calorimeter
Silicon Telescope
Silicon Telescope
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Validation of semi-analytical algorithms with pre-existing dataData acquired at LLUMC Proton beam 201MeV
Silicon tracker UCSC CsI(Tl) calorimeter
Reconstructed on p5Acquired on p4Acquired on p5
C. Talamonti et al., "Proton Radiography for clinical applications," NIM A, in press.
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4 x-y TRACKER MODULES
1 CALORIMETER
Proton imaging apparatusFirst step in the realization of pCT device
Entry and Exit
position and direction
Residual Energy
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Single Tracker Module
Front-end board
Digital board
Detector location
Detector board with a detector and 8 chips containing the electronic front-end.
1 x-y plane consists of 2 single tracker modules1 x-y plane consists of 2 single tracker modules
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Tracker module architecture
14/3/2009
To achieve a read-out rate of 1MHz a fully parallel digital strip readout system has been developed
Eight 32-channel VLSI front-end chips acquire the detector signals and sends data in parallel to an FPGA (Xlinx Spartan-3AN) which performs zero suppression and moves data to a buffer memory (~5x105 events).
An Ethernet commercial module is used both for data transfer to the central acquisition PC and to control the tracker module DAQ parameters
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Detector Description
53 mm x 53 mm n-type substrate with p-type
implants 200 μm thickness 256 strips, each 57 μm thick 200 μm pitch Integrated resistance for bias
1.5MOhm
Bias ring
AC PADDC PAD
Substrate bias PAD Guard ring
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VLSI front-end description AMS 0.35u CMOS Technologie
1.6 mm x 6 mm
32 channels
Power dissipation = 14,5 mW @ chan
Vcc = +3.3 V
Charge Sensitive Amplifier
Differentiator
(high pass)
Integrator
(low pass)
Comparator Buffer
External threshold voltage
OUT
Single strip
Single channel
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Calorimeter
YAG:Ce propertiesYAG:Ce propertiesPHYSICAL PROPERTIES
Density [g/cm3] 4.57
Hygroscopic No
Chemical formula Y3Al5O12
LUMINESCENCE PROPERTIES
Wavelength of max. emission [nm] 550
Decay constant [ns] 70
Photon yield at 300k [103 Ph/MeV] 40-50
4 YAG:Ce scintillating crystals
Each crystal 30 x 30 mm2 x 100mm 4 Photodiode 18 mm x 18 mm 4 commercial front-end
(Charge Sensitive Amplifier & shaper )Charge spectrum @100MeV
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Tracker module test
First results of the beam test at
Laboratori Nazionali del Sud with 62MeV protons
New calibration
Test with beta source
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Tracker module: 62MeV proton beam at Laboratori Nazionali del Sud (LNS)
0 20 40 60 80 100
50
100
150
200
250
Time over Threshold (x10ns)
counts
Vth=1.80VVth=1.90VVth=2.00V
0 10 20 30 40 50 600
10
20
30
40
50
position (mm)
counts
Vth=1.90VVth=2.00V
Front-end board and digital board : beam profile Time Over Threshold for different threshold voltage
A threshold voltage value for all chips
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Efficiency of all channels vs input charge for fixed threshold voltage: ΔVth=0
Efficiency of all channels vs threshold voltage for fixed input signal: Q= 5MIP
Single tracker module:New calibration with a threshold voltage value for each chip
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T(Q) calibration curves: Duration pulse vs input equivalent charge
Single tracker module:New calibration with a threshold voltage value for each chip
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Single tracker module: Test with beta source 90Sr
Acquisition rate = 20kHz Total counts =100000 events
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Calorimeter: beam test -Loma Linda Medical Center Charge spectrum at different proton energies
0 200 400 600 800 10000,0
0,2
0,4
0,6
0,8
1,0
No
rma
lize
d c
ou
nts
Channel
Ein 35MeV Ein 100MeV Ein 200MeV
0 200 400 600 800 10000,0
0,2
0,4
0,6
0,8
1,0
No
rma
lize
d C
ou
nts
Channel
Ein 35MeV Ein 100MeV Ein 200MeV
0 200 400 600 800 10000,0
0,2
0,4
0,6
0,8
1,0
No
rmal
ized
Co
un
ts
Channel
Ein 35MeV Ein 100MeV Ein 200MeV
0 200 400 600 800 10000,0
0,2
0,4
0,6
0,8
1,0
No
rma
lize
d C
ou
nts
Channel
Ein 35MeV Ein 100MeV Ein 200MeV
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Calorimeter: beam test -Loma Linda Medical Center
Linearity ( 30-200MeV energy proton range )
0 50 100 150 2000
100
200
300
400
500
600
Pe
ak
po
sit
ion
Ein [MeV]
data linear fit
Y = -53,69 + 2,83 XLinearity 2,7%
0 50 100 150 2000
100
200
300
400
500
600
Pea
k P
osi
tio
n
Ein [MeV]
data linear fit
Y = -62,12 + 2,87 XLinearity 3,3%
0 50 100 150 2000
100
200
300
400
500
600
700
800
900
Pe
ak
po
sit
ion
Ein [MeV]
data linear fit
Y= -91,28 + 4,5 X Linearity 2,2%
0 50 100 150 200
0
100
200
300
400
500
600
700
Pea
k p
osi
tio
n
Ein [MeV]
data linear fit
Y = -84,63 + 3,69 XLinearity 2,9%
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Calorimeter: beam test -Loma Linda Medical CenterSingle crystal homogeneity study
60mm
60m
m
The tracker area has been divided into 30x30 squares (area = 2x2mm2). For each square the charge spectrum has been made.
This is the map of the charge spectrum peak value
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Calorimeter: New electronic readout Yesterday
CR110 + CR220-3us
Today
Low acquisition rate High acquisition rate
Bassini, Boiano and Pullia IEEE TNS, VOL. 49, NO. 5, OCTOBER 2002
Test with YAG:Ce in October ‘09
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ConclusionsA proton imaging device is being built by the Italian collaborationA proton imaging device is being built by the Italian collaboration Tracker
Single module: assembled and tested at LNS with 62MeV proton beam Calorimeter
YAG calorimeter: completely characterized at LLMC with 30-200MeV proton beam
Front-end electronics: prototype exists (commercial parts) Trigger generator assembled
Future plansFuture plans Calorimeter with new front-end (higher rate): to be tested with proton beam (by the
end of 2009) Two tracker modules (one x-y plan) and the calorimeter: to be tested with proton
beam (by the end of 2009) Complete device built (by the end of 2010)