The TORCH time-of-flight (TOF) detector is being developed to provide particle identification up to a momentum of 10 GeV/c over a flight distance of 10 m. It has a DIRC-like construction with View the MathML source10mm thick synthetic amorphous fused-silica plates as a Cherenkov radiator. Photons propagate by total internal reflection to the plate periphery where they are focused onto an array of customised position-sensitive micro-channel plate (MCP) detectors. The goal is to achieve a 15 ps time-of-flight resolution per incident particle by combining arrival times from multiple photons. The MCPs have pixels of effective size 0.4 mm×6.6 mm2 in the vertical and horizontal directions, respectively, by incorporating a novel charge-sharing technique to improve the spatial resolution to better than the pitch of the readout anodes. Prototype photon detectors and readout electronics have been tested and calibrated in the laboratory. Preliminary results from testbeam measurements of a prototype TORCH detector are also presented

Brook, Nick H

Castillo-Garcia, L.

Conneely, T.

Cussans, David G

Foehl, K.

Forty, R.

Frei, C.

Gao, R.

Gys, T.

Harnew, N.

Milnes, J.

Piedigrossi, D.

Rademacker, Jonas

Ros Garcia, Ana

Van Dijk, Maarten W U

Ros, A

Brook, N H

Castillo-Garcia, L

Conneely, T

Cussans, D

Foehl, K

Forty, R

Frei, C

Gao, R

Gys, T

Harnew, N

Milnes, J

Piedigrossi, D

Rademacker, J

Van Dijk, M

CERN Document Server

Test-beam and laboratory characterisation of the TORCH prototype detector

The TORCH time-of-flight (TOF) detector is being developed to provide particle identification up to a momentum of 10 GeV/c over a flight distance of 10 m. It has a DIRC-like construction with  thick synthetic amorphous fused-silica plates as a Cherenkov radiator. Photons propagate by total internal reflection to the plate periphery where they are focused onto an array of customised position-sensitive micro-channel plate (MCP) detectors. The goal is to achieve a 15 ps time-of-flight resolution per incident particle by combining arrival times from multiple photons. The MCPs have pixels of effective size 0.4 mm×6.6 mm2 in the vertical and horizontal directions, respectively, by incorporating a novel charge-sharing technique to improve the spatial resolution to better than the pitch of the readout anodes. Prototype photon detectors and readout electronics have been tested and calibrated in the laboratory. Preliminary results from testbeam measurements of a prototype TORCH detector are also presented

Ros, Ana

Brook, Nick H.

Castillo-Garcia, Lucia

Conneely, Tom

Cussans, David

Foehl, Klaus

Forty, Roger

Frei, Christophe

Gao, Rui

Gys, Thierry

Harnew, Neville

Milnes, James

Piedigrossi, Didier

Van Dijk, Maarten

Oxford University Research Archive

AbstractThe TORCH time-of-flight (TOF) detector is being developed to provide particle identification up to a momentum of 10GeV/c over a flight distance of 10m. It has a DIRC-like construction with 10mm thick synthetic amorphous fused-silica plates as a Cherenkov radiator. Photons propagate by total internal reflection to the plate periphery where they are focused onto an array of customised position-sensitive micro-channel plate (MCP) detectors. The goal is to achieve a 15ps time-of-flight resolution per incident particle by combining arrival times from multiple photons. The MCPs have pixels of effective size 0.4mm×6.6mm2 in the vertical and horizontal directions, respectively, by incorporating a novel charge-sharing technique to improve the spatial resolution to better than the pitch of the readout anodes. Prototype photon detectors and readout electronics have been tested and calibrated in the laboratory. Preliminary results from testbeam measurements of a prototype TORCH detector are also presented

Ros, A.

Brook, N.H.

Cussans, D.

Rademacker, J.

Van Dijk, M.

Elsevier - Publisher Connector 

Nuclear Instruments and Methods in Physics Research A ∎ (∎∎∎∎) ∎∎∎–∎∎∎Contents lists available at ScienceDirectNuclear Instruments and Methods in
Physics Research Ahttp://d
0168-90
n Corr
E-m
Pleas
nimajournal homepage: www.elsevier.com/locate/nimaTest-beam and laboratory characterisation of the TORCH prototype
detector
A. Ros a,n, N.H. Brook b, L. Castillo-Garcia d, T. Conneely e, D. Cussans a, K. Foehl d, R. Forty d,
C. Frei d, R. Gao c, T. Gys d, N. Harnew c, J. Milnes e, D. Piedigrossi d, J. Rademacker a,
M. Van Dijk a
a University of Bristol, H.H. Wills Physics Laboratory, Bristol BS8 1TL, UK
b University College London, Department of Physics & Astronomy, Gower Street, London WC1E 6BT, UK
c University of Oxford, Denys Wilkinson Building, 1 Keble Road, Oxford OX1 3RH, UK
d CERN, EP Department, CH-1211 Geneva 23, Switzerland
e Photek Ltd, St. Leonards-on-Sea TN38 9NS, UKa r t i c l e i n f o
Article history:
Received 24 March 2016
Received in revised form
7 June 2016
Accepted 15 June 2016
Keywords:
Cherenkov radiation
Particle identiﬁcation
TORCH
MCP-PMTx.doi.org/10.1016/j.nima.2016.06.087
02/& 2016 Elsevier B.V. All rights reserved.
esponding author.
ail address: ana.rosgarcia@bristol.ac.uk (A. Ro
e cite this article as: A. Ros, et al.,
.2016.06.087ia b s t r a c t
The TORCH time-of-ﬂight (TOF) detector is being developed to provide particle identiﬁcation up to a
momentum of 10 GeV/c over a ﬂight distance of 10 m. It has a DIRC-like construction with 10 mm thick
synthetic amorphous fused-silica plates as a Cherenkov radiator. Photons propagate by total internal
reﬂection to the plate periphery where they are focused onto an array of customised position-sensitive
micro-channel plate (MCP) detectors. The goal is to achieve a 15 ps time-of-ﬂight resolution per incident
particle by combining arrival times from multiple photons. The MCPs have pixels of effective size
0.4 mm6.6 mm2 in the vertical and horizontal directions, respectively, by incorporating a novel
charge-sharing technique to improve the spatial resolution to better than the pitch of the readout an-
odes. Prototype photon detectors and readout electronics have been tested and calibrated in the la-
boratory. Preliminary results from testbeam measurements of a prototype TORCH detector are also
presented.
& 2016 Elsevier B.V. All rights reserved.1. Introduction
The goal of the TORCH (Timing Of internally Reﬂected CHer-
enkov photons) detector is to achieve a 15 ps time-of-ﬂight re-
solution per incident charged particle over a ﬂight distance of
10 m. TORCH is designed for large-area coverage, of approximately
30 m2, and has been proposed for the upgrade of the LHCb ex-
periment to complement the particle identiﬁcation capabilities of
the RICH detectors. The timing precision is accomplished by
combining arrival times from multiple photons, requiring a re-
solution of 70 ps for single photons [1]. A schematic of a single
module of the TORCH detector is shown in Fig. 1.
A prototype TORCH detector has been constructed which is a
scaled-down version of the full TORCH module, and consists of a
synthetic amorphous fused-silica bar, 12035010 mm3 (width
 length  thickness), coupled to a quartz block with a mirrored
cylindrical surface that focusses the Cherenkov photons onto po-
sition-sensitive microchannel plate photomultiplier (MCP-PMT)s).
Nuclear Instruments & Medetectors. A customised MCP, shown in Fig. 2, has been developed
in industrial partnership with Photek, UK. This so-called Phase-2
MCP has a circular 40 mm diameter housing and 26.526.5 mm2
active area.
The spatial resolution required by TORCH is =0.4 mm/ 12
0.12 mm in the “ﬁne” (vertical) direction. The MCP-PMT has
0.8 mm2 square pixels. A novel method of coupling the MCP-PMT
output pads to an interface-PCB through an Anisotropic Con-
ductive Film (ACF) is used, together with customised readout
electronics. The back-plane anode is formed by metallic pads
connected to the PCB that merges channels in groups of 8 in the
“coarse” (horizontal) direction, resulting in an array of 432 lo-
gical pixels for the Phase-2 MCP-PMT. The aim is to produce
square 22 in.2 long-lifetime MCP-PMT detectors with 864
logical pixels for the ﬁnal stage (Phase-3) of TORCH development.
Charge sharing between pixels maintains the required spatial re-
solution whilst halving the number of readout channels.
Fig. 3 is an example of a hit-map pattern that would be ex-
pected in the TORCH prototype, produced using a GEANT4 simu-
lation with 180 GeV/c protons traversing the centre of the TORCH
module [2]. Cherenkov light is internally reﬂected in the quartz
bar and is detected on the plane of MCP-PMTs via an additionalthods in Physics Research A (2016), http://dx.doi.org/10.1016/j.
Fig. 1. A module of the TORCH detector (662501 cm3). The TORCH modular
consists of 18 such modules with a overall area of about 65 m2.
A. Ros et al. / Nuclear Instruments and Methods in Physics Research A ∎ (∎∎∎∎) ∎∎∎–∎∎∎2reﬂection in the focussing block. A folding of the image pattern is
observed due to reﬂections from the side faces of the quartz bar;
there is also a ﬁnite width of the pattern resulting from chromatic
dispersion in the quartz. It is important to correctly distinguish
photons that have one or more side reﬂections from those that do
not, because these class of reﬂections correspond to different path
lengths, and hence times of propogation, of the photons inside the
quartz bar.2. Readout chain characterisation
The readout chain for the TORCH prototype detector is based
on the NINO front-end ampliﬁer/discriminator ASIC that was ori-
ginally developed for the TOF system of ALICE, along with the
HPTDC chip for digitisation [3,4]. Customised electronics boardsFig. 2. (Left) View through the entrance window of the Phase-2 Photek MCP-PMT, wh
Please cite this article as: A. Ros, et al., Nuclear Instruments & Me
nima.2016.06.087ihave been developed using a 32-channel version of the NINO chip
and HPTDC, as shown in Fig. 4.
The performance of the MCP and full electronics readout chain
has been studied with a Picosecond Diode Laser system (PiLas-
Advanced Laser Diode Systems) attenuated to produce single
photons, and optimised for measurements of efﬁciency, spatial
and time resolution. Laboratory measurements of the charge to
width calibration of the NINO32 were made using a pulse gen-
erator to inject charge and an oscilloscope to record the output
signals. The calibrations over several channels, with a pro-
grammed threshold of 60 mV for the Time Over Threshold (TOT)
NINO front-end ampliﬁer/discriminator, are shown in Fig. 5. The
curves exhibit two important features. Firstly the calibration of
charge-to-width is not linear, and secondly the behaviour changes
from channel-to-channel and from chip-to-chip. This demon-
strates that it is necessary to perform a charge-to-width calibra-
tion on every individual channel.
The Phase-2 MCP-PMT tube was tested in the laboratory to
understand its charge-sharing properties. The measurements were
performed with the laser scanning over four pixels of the tube in
0.414 mm steps (half the width of a pixel). The hit position was
then calculated using a Centre of Gravity (CoG) algorithm in which
the CoG was ﬁrst calculated from the position of the pixel cen-
troids weighted by the uncalibrated TOT widths of the signals
= ∑ ∑w x wP /i i i i iw , where the sum is overall pixels. Fig. 6 shows
the actual laser position on the MCP-PMT photocathode as a
function of the resulting measured position. The estimated posi-
tion was then re-calculated by using the CoG weighted with the
charges calculated from the charge-to-width calibration curves:
= ∑ ∑q x qP /i i i i iq . The resulting linear behaviour, also seen in
Fig. 6, illustrates that the charge sharing method is effective in
achieving improved spatial accuracy, however it also reinforces the
importance of accurate NINO calibrations.
Previous measurements of the NINO readout demonstrate
that a spatial resolution of σ = 0.031 mm is achievable [5]. These
measurements were performed with a different MCP-PMT,
readout electronics and calibration methodology to that pre-
sented here. Futher studies with different tubes and readoutich has an active area of 26.526.5 mm2; (Right) The backplane of the MCP-PMT.
thods in Physics Research A (2016), http://dx.doi.org/10.1016/j.
Fig. 3. A hit-map pattern expected from a fully instrumented TORCH prototype module. The area outlined in black shows the expected hit-map pattern measured by a single
Phase-2 MCP-PMT.
Fig. 4. A photograph of the customised electronic boards for TORCH. The NINO board is at the top left side, the HPTDC board on the bottom left side. The readout board on
the right is connected through an Ethernet cable to the control PC. The HPTDC and readout boards are connected through a back-board that has the capability to operate with
four NINO and HPTDC boards.
A. Ros et al. / Nuclear Instruments and Methods in Physics Research A ∎ (∎∎∎∎) ∎∎∎–∎∎∎ 3boards will be undertaken to study the optimal spatial resolution
performance.3. Testbeam preliminary results
Studies of the TORCH prototype detector, shown in Fig. 7, have
been performed at the CERN PS testbeam facility using a π p/ beam
of 1–12 GeV/c momentum; the nominal beam composition was
67% pions and 33% protons at 3 GeV/c. The purpose of the testsPlease cite this article as: A. Ros, et al., Nuclear Instruments & Me
nima.2016.06.087iwas to understand the spatial and timing resolutions of TORCH in
a realistic environment and to optimise the TORCH design. The PS
facility provides two Cherenkov threshold counters and one scin-
tillation detector. The TORCH MCP-PMT, readout electronics and
radiator with focussing quartz block were housed in a light-tight
box. A pair of scintillation ﬁnger modules, each containing one
plastic scintillator read out by a PMT, provided an event trigger. In
each of these two modules, a borosilicate bar acting as a source of
prompt Cherenkov light and read out by a single channel MCP,
provided a start/stop timing reference. The stations, shown inthods in Physics Research A (2016), http://dx.doi.org/10.1016/j.
Fig. 5. Charge-to-width calibration for eight NINO32 channels with a threshold setting of 60 mV.
Fig. 6. A laser scan of the Phase-2 MCP, showing the known laser position as a function of the measured MCP-MCP coordinate. The blue points show the position calculated
using the CoG method with the average pixel positions weighted by the measured widths of the signals Pw , and the orange points show the position calculated using the
average pixel positions weighted with calibrated charges Pq. The four coloured areas in the plot refer to the four pixels of the tubes over which the scan was performed. The
errors-bars are the 68% conﬁdence intervals of the ﬁtted distributions from each of the measurement points. (For interpretation of the references to colour in this ﬁgure
legend, the reader is referred to the web version of this article.)
A. Ros et al. / Nuclear Instruments and Methods in Physics Research A ∎ (∎∎∎∎) ∎∎∎–∎∎∎4Fig. 7, were separated by a distance of 10.60 m. The reference time
measurements were made by either commercial electronics or the
TORCH readout system.
Reference measurements of the time of ﬂight of 3 GeV/c beam
particles between the two borosilicate stations were made in order
to compare the timing resolution of the TORCH readout electronics
(with an HPTDC time binning of 100 ps) and with the commercial
module (with a time binning of 6.25 ps). Figs. 8 (Top and Bottom)
compare the reference TOF distributions for protons and pions
measured with the commercial module and with the TORCH
readout, respectively. The TOF difference is found to bePlease cite this article as: A. Ros, et al., Nuclear Instruments & Me
nima.2016.06.087iΔ ≈ ±t 1638 5 ps for the commercial setup and Δ ≈ ±t 1680 11 ps
for the TORCH readout. Any discrepancy can be attributed to sys-
tematic differences in the time binning of the two systems. These
results agree with the expected time of ﬂight difference between
pions and protons of Δ ≈t 1690 ps at 3 GeV/c over the nominal
ﬂight path.
Preliminary results from the TORCH prototype are compared
with simulation in Fig. 9. The simulations show the distribution of
photon arrival times in bins of 100 ps as a function of photon
position at the MCP-PMT plane. The timing of the photons and
their positions form bands, corresponding to those photonsthods in Physics Research A (2016), http://dx.doi.org/10.1016/j.
Fig. 7. (Top) The TORCH prototype module comprising a radiator plate of 12035010 mm3, a focussing block, a Phase-2 MCP-PMT, and customised electronic boards.
(Bottom) The scintillation ﬁnger modules and borosilicate bars with single-MCPs to provide a trigger and timing reference, respectively.
A. Ros et al. / Nuclear Instruments and Methods in Physics Research A ∎ (∎∎∎∎) ∎∎∎–∎∎∎ 5
Please cite this article as: A. Ros, et al., Nuclear Instruments & Methods in Physics Research A (2016), http://dx.doi.org/10.1016/j.
nima.2016.06.087i
Fig. 8. (Top) The reference TOF difference of 3 GeV/c pions and protons measured over a 10.60 m ﬂight path using commercial electronics with a 6.25 ps time binning;
(Bottom) the reference TOF difference using TORCH electronics with 100 ps time binning.
A. Ros et al. / Nuclear Instruments and Methods in Physics Research A ∎ (∎∎∎∎) ∎∎∎–∎∎∎6arriving directly to the MCP-PMT and those with one or two re-
ﬂections from the lateral sides of the quartz radiator plate. In
comparison, the testbeam measurements are also shown in Fig. 9.
The time projections as a function of hit pixels recorded by the
fully instrumented MCP-PMT demonstrate that patterns from di-
rect detection and from one or more side reﬂections can be re-
solved. Detailed analysis of these data is on-going.4. Conclusions and perspectives
Prototype micro-channel plate photon detectors and readout
electronics for the TORCH time-of-ﬂight detector have been testedPlease cite this article as: A. Ros, et al., Nuclear Instruments & Me
nima.2016.06.087iand calibrated in the laboratory. These detectors use charge divi-
sion to provide spatial measurements that have a resolution better
than the pixel width. Measurements in the laboratory with a laser
scanned over the MCP photocathode show a spatial response
which is linear, and giving an acceptable resolution. The mea-
surements show the importance of a full charge to width cali-
bration of the NINO32 electronics boards.
The ﬁrst CERN-PS testbeam measurements from a prototype
TORCH detector have also been presented. Preliminary results
show that direct, ﬁrst and double reﬂections from the quartz sides
are distinguished in raw data. Full calibrations must now be ap-
plied to the measured data in order to achieve optimal spatial and
timing resolutions.thods in Physics Research A (2016), http://dx.doi.org/10.1016/j.
Fig. 9. (Top plots) Simulated photon arrival-time patterns as a function of MCP column number for direct light (red), one reﬂection (blue, green) and two reﬂections (dark
blue, black). (Bottom and middle plots) The measured photon arrival time distributions in 100 ps bins as a function of hit position in a column (pixel number) from testbeam
data. (For interpretation of the references to colour in this ﬁgure legend, the reader is referred to the web version of this article.)
A. Ros et al. / Nuclear Instruments and Methods in Physics Research A ∎ (∎∎∎∎) ∎∎∎–∎∎∎ 7Acknowledgements
The support of the European Research Council is gratefully
acknowledged in the funding of this work (ERC-2011-AdG, 291175-
TORCH).References
[1] M.J. Charles, R. Forty, TORCH time of ﬂight identiﬁcation with cherenkov ra-
diation, Nucl. Instrum. Methods A 639 (1) (2011) 173–176, http://dx.doi.org/Please cite this article as: A. Ros, et al., Nuclear Instruments & Me
nima.2016.06.087i10.1016/j.nima.2010.09.021.
[2] M.V. Dijk, Design of the TORCH detector: a cherenkov based time-of-ﬂight
system for particle identiﬁcation, PhD thesis - University of Bristol.
[3] F. Anghinolﬁ, NINO: an ultra-fast and low-power front-end am-pliﬁer/dis-
criminator ASIC designed for the multigap resistive plate chamber, Nucl. In-
strum. Methods A 533 (1–2) (2004) 183–187, http://dx.doi.org/10.1016/j.
nima.2004.07.024.
[4] A. Akindinov, Design aspects and prototype test of a very precise TDC system
implemented for the multigap RPC of the ALICE-TOF, Nucl. Instrum. Methods A
533 (1–2) (2004) 178–182, http://dx.doi.org/10.1016/j.nima.2004.07.023.
[5] L. Castillo-Garcia, Development, characterization and beam tests of a small-
scale torch prototype module, DIRC2015, Workshop on Fast Cherenkov detec-
tors. To be published in Journal of Instrumentation.thods in Physics Research A (2016), http://dx.doi.org/10.1016/j.


Test-beam and laboratory characterisation of the TORCH prototype detector 

Brook, NH

Oxford University Research Archive (ORA)

Nuclear Instruments and Methods in Physics Research Section A Accelerators Spectrometers Detectors and Associated Equipment

The TORCH time-of-flight (TOF) detector is being developed to provide particle identification up to a momentum of 10 GeV/c over a flight distance of 10 m. It has a DIRC-like construction with 10 mm thick synthetic amorphous fused-silica plates as a Cherenkov radiator. Photons propagate by total internal reflection to the plate periphery where they are focused onto an array of customised position-sensitive micro-channel plate (MCP) detectors. The goal is to achieve a 15 ps time-of-flight resolution per incident particle by combining arrival times from multiple photons. The MCPs have pixels of effective size 0.4 mm×6.6 mm2 in the vertical and horizontal directions, respectively, by incorporating a novel charge-sharing technique to improve the spatial resolution to better than the pitch of the readout anodes. Prototype photon detectors and readout electronics have been tested and calibrated in the laboratory. Preliminary results from testbeam measurements of a prototype TORCH detector are also presented

Explore Bristol Research

                          Ros Garcia, A., Brook, N. H., Castillo-Garcia, L., Conneely, T., Cussans, D.G., Foehl, K., ... Van Dijk, M. W. U. (2016). Test-beam and laboratorycharacterisation of the TORCH prototype detector. Nuclear Instruments andMethods in Physics Research Section A: Accelerators, Spectrometers,Detectors and Associated Equipment. DOI: 10.1016/j.nima.2016.06.087Version created as part of publication process; publisher's layout; not normally made publicly availableLicense (if available):CC BY-NC-NDLink to published version (if available):10.1016/j.nima.2016.06.087Link to publication record in Explore Bristol ResearchPDF-documentThis is the final published version of the article (version of record). It first appeared online via Elsevier athttp://www.sciencedirect.com/science/article/pii/S0168900216306520. Please refer to any applicable terms ofuse of the publisher.University of Bristol - Explore Bristol ResearchGeneral rightsThis document is made available in accordance with publisher policies. Please cite only the publishedversion using the reference above. Full terms of use are available:http://www.bristol.ac.uk/pure/about/ebr-terms.htmlTest-beam and laboratory characterisation of the TORCH prototypedetectorA. Ros a,n, N.H. Brook b, L. Castillo-Garcia d, T. Conneely e, D. Cussans a, K. Foehl d, R. Forty d,C. Frei d, R. Gao c, T. Gys d, N. Harnew c, J. Milnes e, D. Piedigrossi d, J. Rademacker a,M. Van Dijk aa University of Bristol, H.H. Wills Physics Laboratory, Bristol BS8 1TL, UKb University College London, Department of Physics & Astronomy, Gower Street, London WC1E 6BT, UKc University of Oxford, Denys Wilkinson Building, 1 Keble Road, Oxford OX1 3RH, UKd CERN, EP Department, CH-1211 Geneva 23, Switzerlande Photek Ltd, St. Leonards-on-Sea TN38 9NS, UKa r t i c l e i n f oArticle history:Received 24 March 2016Received in revised form7 June 2016Accepted 15 June 2016Keywords:Cherenkov radiationParticle identiﬁcationTORCHMCP-PMTa b s t r a c tThe TORCH time-of-ﬂight (TOF) detector is being developed to provide particle identiﬁcation up to amomentum of 10 GeV/c over a ﬂight distance of 10 m. It has a DIRC-like construction with 10 mm thicksynthetic amorphous fused-silica plates as a Cherenkov radiator. Photons propagate by total internalreﬂection to the plate periphery where they are focused onto an array of customised position-sensitivemicro-channel plate (MCP) detectors. The goal is to achieve a 15 ps time-of-ﬂight resolution per incidentparticle by combining arrival times from multiple photons. The MCPs have pixels of effective size0.4 mm6.6 mm2 in the vertical and horizontal directions, respectively, by incorporating a novelcharge-sharing technique to improve the spatial resolution to better than the pitch of the readout an-odes. Prototype photon detectors and readout electronics have been tested and calibrated in the la-boratory. Preliminary results from testbeam measurements of a prototype TORCH detector are alsopresented.& 2016 Elsevier B.V. All rights reserved.1. IntroductionThe goal of the TORCH (Timing Of internally Reﬂected CHer-enkov photons) detector is to achieve a 15 ps time-of-ﬂight re-solution per incident charged particle over a ﬂight distance of10 m. TORCH is designed for large-area coverage, of approximately30 m2, and has been proposed for the upgrade of the LHCb ex-periment to complement the particle identiﬁcation capabilities ofthe RICH detectors. The timing precision is accomplished bycombining arrival times from multiple photons, requiring a re-solution of 70 ps for single photons [1]. A schematic of a singlemodule of the TORCH detector is shown in Fig. 1.A prototype TORCH detector has been constructed which is ascaled-down version of the full TORCH module, and consists of asynthetic amorphous fused-silica bar, 12035010 mm3 (width length  thickness), coupled to a quartz block with a mirroredcylindrical surface that focusses the Cherenkov photons onto po-sition-sensitive microchannel plate photomultiplier (MCP-PMT)detectors. A customised MCP, shown in Fig. 2, has been developedin industrial partnership with Photek, UK. This so-called Phase-2MCP has a circular 40 mm diameter housing and 26.526.5 mm2active area.The spatial resolution required by TORCH is =0.4 mm/ 120.12 mm in the “ﬁne” (vertical) direction. The MCP-PMT has0.8 mm2 square pixels. A novel method of coupling the MCP-PMToutput pads to an interface-PCB through an Anisotropic Con-ductive Film (ACF) is used, together with customised readoutelectronics. The back-plane anode is formed by metallic padsconnected to the PCB that merges channels in groups of 8 in the“coarse” (horizontal) direction, resulting in an array of 432 lo-gical pixels for the Phase-2 MCP-PMT. The aim is to producesquare 22 in.2 long-lifetime MCP-PMT detectors with 864logical pixels for the ﬁnal stage (Phase-3) of TORCH development.Charge sharing between pixels maintains the required spatial re-solution whilst halving the number of readout channels.Fig. 3 is an example of a hit-map pattern that would be ex-pected in the TORCH prototype, produced using a GEANT4 simu-lation with 180 GeV/c protons traversing the centre of the TORCHmodule [2]. Cherenkov light is internally reﬂected in the quartzbar and is detected on the plane of MCP-PMTs via an additionalContents lists available at ScienceDirectjournal homepage: www.elsevier.com/locate/nimaNuclear Instruments and Methods inPhysics Research Ahttp://dx.doi.org/10.1016/j.nima.2016.06.0870168-9002/& 2016 Elsevier B.V. All rights reserved.n Corresponding author.E-mail address: ana.rosgarcia@bristol.ac.uk (A. Ros).Please cite this article as: A. Ros, et al., Nuclear Instruments & Methods in Physics Research A (2016), http://dx.doi.org/10.1016/j.nima.2016.06.087iNuclear Instruments and Methods in Physics Research A ∎ (∎∎∎∎) ∎∎∎–∎∎∎reﬂection in the focussing block. A folding of the image pattern isobserved due to reﬂections from the side faces of the quartz bar;there is also a ﬁnite width of the pattern resulting from chromaticdispersion in the quartz. It is important to correctly distinguishphotons that have one or more side reﬂections from those that donot, because these class of reﬂections correspond to different pathlengths, and hence times of propogation, of the photons inside thequartz bar.2. Readout chain characterisationThe readout chain for the TORCH prototype detector is basedon the NINO front-end ampliﬁer/discriminator ASIC that was ori-ginally developed for the TOF system of ALICE, along with theHPTDC chip for digitisation [3,4]. Customised electronics boardshave been developed using a 32-channel version of the NINO chipand HPTDC, as shown in Fig. 4.The performance of the MCP and full electronics readout chainhas been studied with a Picosecond Diode Laser system (PiLas-Advanced Laser Diode Systems) attenuated to produce singlephotons, and optimised for measurements of efﬁciency, spatialand time resolution. Laboratory measurements of the charge towidth calibration of the NINO32 were made using a pulse gen-erator to inject charge and an oscilloscope to record the outputsignals. The calibrations over several channels, with a pro-grammed threshold of 60 mV for the Time Over Threshold (TOT)NINO front-end ampliﬁer/discriminator, are shown in Fig. 5. Thecurves exhibit two important features. Firstly the calibration ofcharge-to-width is not linear, and secondly the behaviour changesfrom channel-to-channel and from chip-to-chip. This demon-strates that it is necessary to perform a charge-to-width calibra-tion on every individual channel.The Phase-2 MCP-PMT tube was tested in the laboratory tounderstand its charge-sharing properties. The measurements wereperformed with the laser scanning over four pixels of the tube in0.414 mm steps (half the width of a pixel). The hit position wasthen calculated using a Centre of Gravity (CoG) algorithm in whichthe CoG was ﬁrst calculated from the position of the pixel cen-troids weighted by the uncalibrated TOT widths of the signals= ∑ ∑w x wP /i i i i iw , where the sum is overall pixels. Fig. 6 showsthe actual laser position on the MCP-PMT photocathode as afunction of the resulting measured position. The estimated posi-tion was then re-calculated by using the CoG weighted with thecharges calculated from the charge-to-width calibration curves:= ∑ ∑q x qP /i i i i iq . The resulting linear behaviour, also seen inFig. 6, illustrates that the charge sharing method is effective inachieving improved spatial accuracy, however it also reinforces theimportance of accurate NINO calibrations.Previous measurements of the NINO readout demonstratethat a spatial resolution of σ = 0.031 mm is achievable [5]. Thesemeasurements were performed with a different MCP-PMT,readout electronics and calibration methodology to that pre-sented here. Futher studies with different tubes and readoutFig. 1. A module of the TORCH detector (662501 cm3). The TORCH modularconsists of 18 such modules with a overall area of about 65 m2.Fig. 2. (Left) View through the entrance window of the Phase-2 Photek MCP-PMT, which has an active area of 26.526.5 mm2; (Right) The backplane of the MCP-PMT.A. Ros et al. / Nuclear Instruments and Methods in Physics Research A ∎ (∎∎∎∎) ∎∎∎–∎∎∎2Please cite this article as: A. Ros, et al., Nuclear Instruments & Methods in Physics Research A (2016), http://dx.doi.org/10.1016/j.nima.2016.06.087iboards will be undertaken to study the optimal spatial resolutionperformance.3. Testbeam preliminary resultsStudies of the TORCH prototype detector, shown in Fig. 7, havebeen performed at the CERN PS testbeam facility using a π p/ beamof 1–12 GeV/c momentum; the nominal beam composition was67% pions and 33% protons at 3 GeV/c. The purpose of the testswas to understand the spatial and timing resolutions of TORCH ina realistic environment and to optimise the TORCH design. The PSfacility provides two Cherenkov threshold counters and one scin-tillation detector. The TORCH MCP-PMT, readout electronics andradiator with focussing quartz block were housed in a light-tightbox. A pair of scintillation ﬁnger modules, each containing oneplastic scintillator read out by a PMT, provided an event trigger. Ineach of these two modules, a borosilicate bar acting as a source ofprompt Cherenkov light and read out by a single channel MCP,provided a start/stop timing reference. The stations, shown inFig. 3. A hit-map pattern expected from a fully instrumented TORCH prototype module. The area outlined in black shows the expected hit-map pattern measured by a singlePhase-2 MCP-PMT.Fig. 4. A photograph of the customised electronic boards for TORCH. The NINO board is at the top left side, the HPTDC board on the bottom left side. The readout board onthe right is connected through an Ethernet cable to the control PC. The HPTDC and readout boards are connected through a back-board that has the capability to operate withfour NINO and HPTDC boards.A. Ros et al. / Nuclear Instruments and Methods in Physics Research A ∎ (∎∎∎∎) ∎∎∎–∎∎∎ 3Please cite this article as: A. Ros, et al., Nuclear Instruments & Methods in Physics Research A (2016), http://dx.doi.org/10.1016/j.nima.2016.06.087iFig. 7, were separated by a distance of 10.60 m. The reference timemeasurements were made by either commercial electronics or theTORCH readout system.Reference measurements of the time of ﬂight of 3 GeV/c beamparticles between the two borosilicate stations were made in orderto compare the timing resolution of the TORCH readout electronics(with an HPTDC time binning of 100 ps) and with the commercialmodule (with a time binning of 6.25 ps). Figs. 8 (Top and Bottom)compare the reference TOF distributions for protons and pionsmeasured with the commercial module and with the TORCHreadout, respectively. The TOF difference is found to beΔ ≈ ±t 1638 5 ps for the commercial setup and Δ ≈ ±t 1680 11 psfor the TORCH readout. Any discrepancy can be attributed to sys-tematic differences in the time binning of the two systems. Theseresults agree with the expected time of ﬂight difference betweenpions and protons of Δ ≈t 1690 ps at 3 GeV/c over the nominalﬂight path.Preliminary results from the TORCH prototype are comparedwith simulation in Fig. 9. The simulations show the distribution ofphoton arrival times in bins of 100 ps as a function of photonposition at the MCP-PMT plane. The timing of the photons andtheir positions form bands, corresponding to those photonsFig. 5. Charge-to-width calibration for eight NINO32 channels with a threshold setting of 60 mV.Fig. 6. A laser scan of the Phase-2 MCP, showing the known laser position as a function of the measured MCP-MCP coordinate. The blue points show the position calculatedusing the CoG method with the average pixel positions weighted by the measured widths of the signals Pw , and the orange points show the position calculated using theaverage pixel positions weighted with calibrated charges Pq. The four coloured areas in the plot refer to the four pixels of the tubes over which the scan was performed. Theerrors-bars are the 68% conﬁdence intervals of the ﬁtted distributions from each of the measurement points. (For interpretation of the references to colour in this ﬁgurelegend, the reader is referred to the web version of this article.)A. Ros et al. / Nuclear Instruments and Methods in Physics Research A ∎ (∎∎∎∎) ∎∎∎–∎∎∎4Please cite this article as: A. Ros, et al., Nuclear Instruments & Methods in Physics Research A (2016), http://dx.doi.org/10.1016/j.nima.2016.06.087iFig. 7. (Top) The TORCH prototype module comprising a radiator plate of 12035010 mm3, a focussing block, a Phase-2 MCP-PMT, and customised electronic boards.(Bottom) The scintillation ﬁnger modules and borosilicate bars with single-MCPs to provide a trigger and timing reference, respectively.A. Ros et al. / Nuclear Instruments and Methods in Physics Research A ∎ (∎∎∎∎) ∎∎∎–∎∎∎ 5Please cite this article as: A. Ros, et al., Nuclear Instruments & Methods in Physics Research A (2016), http://dx.doi.org/10.1016/j.nima.2016.06.087iarriving directly to the MCP-PMT and those with one or two re-ﬂections from the lateral sides of the quartz radiator plate. Incomparison, the testbeam measurements are also shown in Fig. 9.The time projections as a function of hit pixels recorded by thefully instrumented MCP-PMT demonstrate that patterns from di-rect detection and from one or more side reﬂections can be re-solved. Detailed analysis of these data is on-going.4. Conclusions and perspectivesPrototype micro-channel plate photon detectors and readoutelectronics for the TORCH time-of-ﬂight detector have been testedand calibrated in the laboratory. These detectors use charge divi-sion to provide spatial measurements that have a resolution betterthan the pixel width. Measurements in the laboratory with a laserscanned over the MCP photocathode show a spatial responsewhich is linear, and giving an acceptable resolution. The mea-surements show the importance of a full charge to width cali-bration of the NINO32 electronics boards.The ﬁrst CERN-PS testbeam measurements from a prototypeTORCH detector have also been presented. Preliminary resultsshow that direct, ﬁrst and double reﬂections from the quartz sidesare distinguished in raw data. Full calibrations must now be ap-plied to the measured data in order to achieve optimal spatial andtiming resolutions.Fig. 8. (Top) The reference TOF difference of 3 GeV/c pions and protons measured over a 10.60 m ﬂight path using commercial electronics with a 6.25 ps time binning;(Bottom) the reference TOF difference using TORCH electronics with 100 ps time binning.A. Ros et al. / Nuclear Instruments and Methods in Physics Research A ∎ (∎∎∎∎) ∎∎∎–∎∎∎6Please cite this article as: A. Ros, et al., Nuclear Instruments & Methods in Physics Research A (2016), http://dx.doi.org/10.1016/j.nima.2016.06.087iAcknowledgementsThe support of the European Research Council is gratefullyacknowledged in the funding of this work (ERC-2011-AdG, 291175-TORCH).References[1] M.J. Charles, R. Forty, TORCH time of ﬂight identiﬁcation with cherenkov ra-diation, Nucl. Instrum. Methods A 639 (1) (2011) 173–176, http://dx.doi.org/10.1016/j.nima.2010.09.021.[2] M.V. Dijk, Design of the TORCH detector: a cherenkov based time-of-ﬂightsystem for particle identiﬁcation, PhD thesis - University of Bristol.[3] F. Anghinolﬁ, NINO: an ultra-fast and low-power front-end am-pliﬁer/dis-criminator ASIC designed for the multigap resistive plate chamber, Nucl. In-strum. Methods A 533 (1–2) (2004) 183–187, http://dx.doi.org/10.1016/j.nima.2004.07.024.[4] A. Akindinov, Design aspects and prototype test of a very precise TDC systemimplemented for the multigap RPC of the ALICE-TOF, Nucl. Instrum. Methods A533 (1–2) (2004) 178–182, http://dx.doi.org/10.1016/j.nima.2004.07.023.[5] L. Castillo-Garcia, Development, characterization and beam tests of a small-scale torch prototype module, DIRC2015, Workshop on Fast Cherenkov detec-tors. To be published in Journal of Instrumentation.Fig. 9. (Top plots) Simulated photon arrival-time patterns as a function of MCP column number for direct light (red), one reﬂection (blue, green) and two reﬂections (darkblue, black). (Bottom and middle plots) The measured photon arrival time distributions in 100 ps bins as a function of hit position in a column (pixel number) from testbeamdata. (For interpretation of the references to colour in this ﬁgure legend, the reader is referred to the web version of this article.)A. Ros et al. / Nuclear Instruments and Methods in Physics Research A ∎ (∎∎∎∎) ∎∎∎–∎∎∎ 7Please cite this article as: A. Ros, et al., Nuclear Instruments & Methods in Physics Research A (2016), http://dx.doi.org/10.1016/j.nima.2016.06.087i

A. Ros

N.H. Brook

L. Castillo-Garcia

T. Conneely

D. Cussans

K. Foehl

R. Forty

C. Frei

R. Gao

T. Gys

N. Harnew

J. Milnes

D. Piedigrossi

J. Rademacker

M. Van Dijk

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Test-beam and laboratory characterisation of the TORCH prototype detector

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