Preliminary Performance Measurements for Streak Camera with Large-Format Direct-Coupled CCD Readout* 15th Topical Conference on High-Temperature Plasma.

Slides:

Advertisements

Similar presentations

Digital Radiography.

Advertisements

Physical & Psychophysical Evaluation of a New Digital Specimen Radiography System for Use in Mammography Elizabeth Krupinski, PhD Hans Roehrig, PhD University.

Study of the MPPC Performance - contents - Introduction Fundamental properties microscopic laser scan –check variation within a sensor Summary and plans.

Astronomical Detectors

1 A Design of PET detector using Microchannel Plate PMT with Transmission Line Readout Heejong Kim 1, Chien-Min Kao 1, Chin-Tu Chen 1, Jean-Francois Genat.

Time resolved images of the x-ray emission from Ti foils and sandwiched Al/Ti/Al foils, in the region between 4.4 and 5.0 keV, show well resolved of K-

Photon Counting Sensors for Future Missions

Richard M. Bionta X-Ray Transport, Diagnostic, & Commissioning September 22, 2004 UCRL-PRES Two Problems... LCLS Diagnostics.

From CCD to EMCCD Scientific imaging for today’s microscopy.

CCD testing Enver Alagoz 12 April CCD testing goals CCD testing is to learn how to – do dark noise characterization – do gain measurements – determine.

Overview of Scientific Imaging using CCD Arrays Jaal Ghandhi Mechanical Engineering Univ. of Wisconsin-Madison.

Prototype string for a km3 Baikal neutrino telescope Roma International Conference on Astroparticle Physics V.Aynutdinov, INR RAS for the Baikal Collaboration.

Measurement of the absolute efficiency,

Copyright © Hamamatsu Photonics K.K. All Rights Reserved. Oct at NNN07 Workshop Hamamatsu Photonics Electron Tube Division Recent Progress in PMTs.

Detecting Electrons: CCD vs Film Practical CryoEM Course July 26, 2005 Christopher Booth.

Naoyuki Tamura (University of Durham) Expected Performance of FMOS ~ Estimation with Spectrum Simulator ~ Introduction of simulators  Examples of calculations.

Photon detection Visible or near-visible wavelengths

Latest developments in Hamamatsu Large Format PMTs

Chapter 13 Companion site for Light and Video Microscopy Author: Wayne.

Report on SiPM Tests SiPM as a alternative photo detector to replace PMT. Qauntify basic characteristics Measure Energy, Timing resolution Develop simulation.

SPECTROSCOPIC DIAGNOSTIC COMPLEX FOR STUDYING PULSED TOKAMAK PLASMA Yu. Golubovskii, Yu. Ionikh, A. Mestchanov, V. Milenin, I. Porokhova, N. Timofeev Saint-Petersburg.

HESSI Imaging Capability Pre Environmental Review Brian R. Dennis GSFC Tuesday, February 29, 2000.

Measurement Results Detector concept works! Flood fields show MCP fixed pattern noise that divides out Spatial resolution consistent with theory (Nyqvist.

CMOS Image Sensor Design. M. Wäny Nov EMVA Standard 1288 Standard for Measurement and Presentation of Specifications for Machine Vision Sensors and.

Experimental set-up Abstract Modeling of processes in the MCP PMT Timing and Cross-Talk Properties of BURLE Multi-Channel MCP PMTs S.Korpar a,b, R.Dolenec.

Optical Aeronomy Calibration Facility CEDAR WORKSHOP JUNE, 2007 Jeff Baumgardner, Center for Space Physics Boston University.

Crystal development Water jet cutting Glass glue bonding Diffusion bonding Large diameter boule growth Thermal stress analysis Reproducible growth of high.

The MPPC Study for the GLD Calorimeter Readout Introduction Measurement of basic characteristics –Gain, Noise Rate, Cross-talk Measurement of uniformity.

10/26/20151 Observational Astrophysics I Astronomical detectors Kitchin pp

Biophotonics lecture 11. January Today: -Correct sampling in microscopy -Deconvolution techniques.

05/05/2004Cyrille Thomas DIAMOND Storage Ring Optical and X-ray Diagnostics.

Brazilian Tunable Filter Imager (BTFI) Preliminary Design Review (PDR)‏ USP-IAG Universidade de São Paulo 18-19th June 2008 Julian David Rodriguez Javier.

Development of a high-speed single photon pixellated detector for visible wavelengths Introduction A photon incident on the photocathode produces a photoelectron.

Development of CCDs for the SXI We have developed 2 different types of CCDs for the SXI in parallel.. *Advantage =>They are successfully employed for current.

LSP modeling of the electron beam propagation in the nail/wire targets Mingsheng Wei, Andrey Solodov, John Pasley, Farhat Beg and Richard Stephens Center.

Development of a Gamma-Ray Beam Profile Monitor for the High-Intensity Gamma-Ray Source Thomas Regier, Department of Physics and Engineering Physics University.

March 2004 Charles A. DiMarzio, Northeastern University ECEG287 Optical Detection Course Notes Part 15: Introduction to Array Detectors Profs.

1 Optical observations of asteroids – and the same for space debris… Dr. D. Koschny European Space Agency Chair of Astronautics, TU Munich Stardust school.

CT QUALITY MANAGEMENT. SPATIAL RESOLUTION CONTRAST RESOLUTION NOISE IMAGE ARTIFACTS RADIATION DOSE.

R. Pani Department of Experimental Medicine and Pathology University of Rome La Sapienza-Italy. Flat Panel PMT: advances in position sensitive photodetection.

Timing Studies of Hamamatsu MPPCs and MEPhI SiPM Samples Bob Wagner, Gary Drake, Patrick DeLurgio Argonne National Laboratory Qingguo Xie Department of.

Lecture 3-Building a Detector (cont’d) George K. Parks Space Sciences Laboratory UC Berkeley, Berkeley, CA.

Modulation Transfer Function (MTF)

Prospects to Use Silicon Photomultipliers for the Astroparticle Physics Experiments EUSO and MAGIC A. Nepomuk Otte Max-Planck-Institut für Physik München.

Basic Detector Measurements: Photon Transfer Curve, Read Noise, Dark Current, Intrapixel Capacitance, Nonlinearity, Reference Pixels MR – May 19, 2014.

1 Correct Sampling. What is SAMPLING? Intensity [a.u.] X [µm] 1.

CMS HF PMT SYSTEM By Y. ONEL U. of Iowa, Iowa City, IA CMS HCAL at Fermilab Feb 6-8, 2003.

بسمه تعالی Fast Imaging of turbulent plasmas in the GyM device D.Iraji, D.Ricci, G.Granucci, S.Garavaglia, A.Cremona IFP-CNR-Milan 7 th Workshop on Fusion.

CCD Image Processing: Issues & Solutions. CCDs: noise sources dark current –signal from unexposed CCD read noise –uncertainty in counting electrons in.

Electron Spectrometer: Status July 14 Simon Jolly, Lawrence Deacon 1 st July 2014.

Fluroscopy and II’s. Fluroscopy Taking real time x-ray images Requires very sensitive detector to limit the radiation needed Image Intensifier (II) is.

Update on THGEM project for RICH application Elena Rocco University of Eastern Piedmont & INFN Torino On behalf of an Alessandria-CERN-Freiburg-Liberec-

Direct Digital Radiography or Direct Capture Radiography

Principles and Practices of Light Microscopy Lecture 7: Light sources and Cameras Kurt Thorn, NIC Image: Susanne Rafelski.

Cameras For Microscopy Ryan McGorty 26 March 2013.

Update on works with SiPMs at Pisa Matteo Morrocchi.

Characterization of Hamamatsu R12199 PMTs Oleg Kalekin KM3NeT Meeting CPPM, Marseille

Comparison of a CCD and the Vanilla CMOS APS for Soft X-ray Diffraction Graeme Stewart a, R. Bates a, A. Blue a, A. Clark c, S. Dhesi b, D. Maneuski a,

PHOTOTUBE SCANNING SETUP AT THE UNIVERSITY OF MARYLAND Doug Roberts U of Maryland, College Park.

KM2A PMT testing platform FENG Cunfeng, LI Chaoju, SUN Yansheng Shandong University THE 2 nd WORKSHOP OF AIR SHOWER DETECTION AT HIGH ALTITUDES IHEP, Beijing,

Page Detector and Electronics R&D for picosecond resolution, single photon detection and imaging J.S. MilnesPhotek Ltd T.M. ConneelyUniversity.

1 SuperB-PID, LNF 4/4/2011 MAPMTsSilvia DALLA TORRE COMPASS experience with HAMAMATSU MAPMTs S. Dalla Torre.

Electronics Lecture 5 By Dr. Mona Elneklawi.

Imaging Characteristics

Astronomy 920 Commissioning of the Prime Focus Imaging Spectrograph

The Pixel Hybrid Photon Detectors of the LHCb RICH

R&D status of a large HAPD

Recent Progress in Large Format PMTs

The MPPC Study for the GLD Calorimeter Readout

Volume 98, Issue 9, Pages (May 2010)

Presentation transcript:

Preliminary Performance Measurements for Streak Camera with Large-Format Direct-Coupled CCD Readout* 15th Topical Conference on High-Temperature Plasma Diagnostics San Diego, CA April , 2004 R. A. Lerche, J. W. McDonald, R. L. Griffith, D. S. Andrews, G. Vergel de Dios, A. W. Huey, P. M. Bell, O. L. Landen Lawrence Livermore National Laboratory P. A. Jaanimagi, R. Boni Laboratory for Laser Energetics, University of Rochester * This work was performed under the auspices of the U.S. Department of Energy by University of California Lawrence Livermore National Laboratory under contract No. W-7405-Eng-48. HTPD-2004-SC - 1 ral

HTPD-2004-SC - 2 ral Abstract Livermore’s ICF Program has a large inventory of optical streak cameras built in the 1970s and 1980s. The cameras are still very functional, but difficult to maintain because many of their parts are obsolete. The University of Rochester’s Laboratory for Laser Energetics is leading an effort to develop a fully automated, large- format streak camera that incorporates modern technology. Preliminary characterization of a prototype camera shows spatial resolution better than 20 lp/mm, temporal resolution of 12 ps, line- spread function of 40  m (fwhm), contrast transfer ratio (CTR) of 60% at 10 lp/mm, and system gain of 101 CCD electrons per photoelectron. A dynamic range of 175 for a 2 ns window is determined from system noise, linearity and sensitivity measurements.

HTPD-2004-SC - 3 ral Summary: We have characterized a new prototype streak camera (ROSS) 1.The streak camera ROSS (Rochester Optical Streak System) Design effort led by Laboratory for Laser Energetics LLNL collaborated on design Streak tube: Photonis P-510 Direct coupled CCD (2K x 2K E2V backside) LLNL input optics used for these tests 2.Camera performance Spatial magnification: 1.3 Spatial resolution: > 20 lp/mm (limiting visual) Temporal resolution: 12 2 ns window Sensitivity: 101 CCD e - / photoelectron System noise: 5 e - / pixel Dynamic range: ~225 (at best resolution) 3.Camera appears to meet NIF optical streak camera requirements

HTPD-2004-SC - 4 ral The compact streak camera has a direct-coupled large-format CCD readout Prototype camera configuration S-20 Streak tube Photonis P-510 CCD Input optics (for our tests*): LLNL input hardware Tek C-27 lens 1-mm slit Mag: Streak tube: Photonis P-510 S-20 photocathode CCD: Spectral Instruments SI-800 E2V backside 2K x 2K (13.5  m pixels) Prototype streak camera (ROSS) (12” x 7” x 28” without input optics) * The prototype input optics module for the ROSS is not yet available.

HTPD-2004-SC - 5 ral Prototype camera magnification is 1.35, field-of-view is 20.5 mm Sample image for magnification and FOV measurements Test conditions: Light: Collimated (532 nm) Mask: 10-  m slit every 1.5 mm CCD: 2K x 2K (13.5-  m pixels) Time (CCD pixels) Space (CCD pixels) Notes: CCD (27 mm square) records central (high-res) region of 60-mm dia streak tube image. Magnification and FOV are referred to photocathode of the streak tube.

HTPD-2004-SC - 6 ral System line-spread function (LSF) shows a 40  m resolution (fwhm) 1. Measure system magnification 2. Illuminate 10-  m mask 3. Take spatial lineout Mask: 11 um (at photocathode) Binning: 2x2 FWHM: 2.0 super pixels (40  m) 40  m fwhm Line-Spread Function Gaussian

HTPD-2004-SC - 7 ral We calculate the system contrast-transfer function (CTF) from the line-spread function Calculation convolves LSF with square wave at various frequencies * = Contrast Transfer Function - Ronchi ruling measurements

HTPD-2004-SC - 8 ral Ronchi ruling measurements at 8.6 lp/mm confirm 70% CTR estimated from LSF Spatial Lineout and CTR 8.6 lp/mm Measured: 68% LSF Prediction: 70% 8.6 lp/mm Ronchi Ruling Space Time

HTPD-2004-SC - 9 ral Contour plots show position dependence of spatial resolution in the streak camera image 1-mm slit 100-  m slit 2x2 binning Super-pix = 20  m FWHM (CCD super pixels) Position (CCD super pixel) Position (CCD super pixel) 8 0 4

HTPD-2004-SC - 10 ral Contour plot shows position dependence of time resolution in the streak camera image Contours showing position dependence of time resolution Test conditions: Collimated light (530 nm) Slit: 100  m CCD: 2K x 2K Sweep: Static (no sweep) Binning: 2x2 Time resolution: < 4 super pixels (fwhm) over 90% of image Position (CCD super pixel) FWHM (CCD super pixels) Position (CCD super pixel) Sweep (ns)  t (ps)

HTPD-2004-SC - 11 ral Camera gain is high enough to detect individual photoelectrons Determine total ADUs in signal Convert with CCD gain Determine number of pe - generated Energy at photocthode times QE Correct for streak camera time window Gain = 101 CCD e - / pe -  2x2 = 6 CCD e - * CCD gain = 1.09 e - /ADU FWHM: 11.3  = 4.81 pix Laser pulse Time (ns) Amp Noise for 2 sec exposure BinningNoise(e - ) 1x x x x47.92 Histogram of Background Number of pixels Counts (ADUs) FWHM: 11.3 ADUs  noise : 4.81 ADUs Image of swept slit (3 mm x 0.5 mm) Time Space

HTPD-2004-SC - 12 ral We use 20% temporal broadening to define the maximum usable current density J 0 = 2.2 amp/cm 2 2.C-L current depends on geometry and voltage 1.20% broadening occurs near 1% of Child- Langmuir space-charge limited current (J 0 ) for laser pulse  t = 45 ps FWHM vs Current 1% C-L Window pc -15 kV Extraction grid kV x Expect reduced performance for J > 1% of C-L current (J 0 )

HTPD-2004-SC - 13 ral We use SNR versus photoelectrons per resolution element as a figure-of-merit SNR = s 2 N / [s 2 N (  C /C) 2 + (s/s b ) 2 (  b /C) 2 ] 1/2 s 2 = # of detector pixels / image resolution element N = # of photoelectrons per detector pixel s b 2 = number of detector pixels per binned pixel  b = read plus dark current noise for one binned pixel C = # of CCD electrons / photoelectron  C = standard deviation in C For the ROSS streak camera we have: s 2 = 32 pixels (4 space, 8 time) s b 2 = 1, 4, 9, 16  b = 5.13, 5.97, 6.69, 7.92 C = 101 CCD e - / pe -  C = Unknown Time Space 1 pixel s b 2 (2x2) Image PSF (32 pixels) Maximize SNR by: Increasing s (more averaging) Increasing N (reduce sweep speed) Increasing C (more efficient pe - detection) Decreasing  read (improve CCD)

HTPD-2004-SC - 14 ral A SNR plot establishes the dynamic range (DR) at ~60 for an image resolution element SNR too low (avoid to ensure quality data) SNR versus Photoelectrons per Detector Pixel Sweep DR* 2ns175 6ns405 12ns855 * Binning: 2x2 Dynamic Range = f(s, sweep speed) >1% C-L 2ns 6ns 12ns C = 101

HTPD-2004-SC - 15 ral Summary: We have characterized a new prototype streak camera (ROSS) 1.The streak camera ROSS (Rochester Optical Streak System) Design effort led by Laboratory for Laser Energetics LLNL collaborated on design Streak tube: Photonis P-510 Direct coupled CCD (2K x 2K E2V backside) LLNL input optics used for these tests 2.Camera performance Spatial magnification: 1.3 Spatial resolution: > 20 lp/mm (limiting visual) Temporal resolution: 12 2 ns window Sensitivity: 101 CCD e - / photoelectron System noise: 5 e - / pixel Dynamic range: ~225 (at best resolution) 3.Camera appears to meet NIF optical streak camera requirements