Title: JWST's Near-Infrared Detectors: Ultra-Low Background Operation and Testing
1JWST's Near-Infrared DetectorsUltra-Low
Background Operation and Testing
- Bernard J. RauscherSpace Telescope Science
Institute
2Outline
- What is a Near-Infrared Array Detector?
- JWST Science Drivers
- Detector Requirements
- Detector testing at STScI/JHU
- Optimal Use
- Summary
3JWSTs IR Arrays are Hybrid Sensors
- PN junctions are bump bonded to a silicon
readout multiplexer (MUX). - Silicon technology is more advanced than other
semiconductor electronics technology. - The bump bonds are made of indium.
4JWST Needs Very Good Near Infrared Detectors!
- Completing the JWST Design Reference Mission on
time requires background limited near-infrared
(NIR) broadband imaging - Zodiacal light is the dominant background
component in the NIR - The total NIR detector noise requirement is
therefore 10 e- rms in a t1000 seconds
exposure. - NIRSpec will probably be detector noise limited.
The total noise goal is 3 e- rms per 1000
seconds exposure
5JWST Near Infrared (NIR) Detector Requirements
6Detector Testing at STScI/JHUIndependent
Detector Testing Laboratory
7- Past and present personnel
Eddie Bergeron Data Analyst
Tom Reeves Lab Technician
Robert Barkhouser Optical Engineer
Bernie Rauscher Project Scientist
Utkarsh Sharma Graduate Student
Mike Telewicz Intern
Gretchen Greene Mechanical Engineer
Steve McCandliss JHU Lead
Ernie Morse Data Analyst
Monica Rivera Intern
Scott Fels Intern
Don Figer Director
Sito Balleza Systems Engineer
Mike Regan System Scientist
Russ Pelton Technician
8NIR Detector Characteristics
- Dark current
- Read noise
- Linearity
- Latent charge (persistence)
- Relative and Absolute Quantum efficiency (QE)
- Intra-pixel sensitivity
- Thermal stability
- Radiation immunity
9Dark Current
- Lowest measured dark current is 0.006
e-/s/pixel.
10IDTL Measurements Read Noise
- Read noise is 10 e- for Fowler-8. (system read
noise is 2.5 e-)
11IDTL Measurements Conversion Gain
Per correlateddouble sample
12Hawaii 1R with 5 um Cutoff
13IDTL MeasurementsRelative and Absolute Quantum
Efficiency
We are currently working on better calibration to
enable measurements of absolute QE vs. wavelength.
14Relative QE Maps
- Relative QE maps show significant structure
15Hawaii Shirt
IDTL Test System
Hawaii Detector
16Then Now
November 2000
November 2002
17IDTL First Light Images
Rockwell HAWAII-1RG
Jun. 02 (MUX)
Jul. 02 (SCA)
18IDTL Test System
Leach II Controller Electronics
Dewar
Entrance Window
Vacuum Hose
He Lines
19Detector Readout System
T30-50 K
Unix Instrument Control Computer
Warm Harness
COTS Leach II IR Array Controller
T293 K
Cryogenic Harness
Detector Customization Circuit
JWST SCA
20An Adaptable Readout System
- The only hardware change required to run a
different detector is swap-in a DCC. - We have DCCs for the following detectors.
- Raytheon
- SB-290
- SB-304
- Rockwell
- HAWAII-1R
- HAWAII-1RG
- HAWAII-2RG
- Each DCC is a multi-layer PCB. Extensive use of
surface mount technology. Includes flexible
neck to simplify interfacing.
21Close-up ofDetector Customization Circuits (DCCs)
22Optimal Use
- JWST Detector Readout Strategies
- Anomalies seen in other instruments
- Other effects
- Use of Reference Pixels
23Detector Readout
- JWST science requires MULTIACCUM and SUBARRAY
readout. - Other readout modes can be implemented using
parameters. - For example, Fowler-8 can be implemented as
MULTIACCUM-2x8. - Cosmic rays may be rejected either on the ground
or on-orbit.
24NICMOS Anomalies ( how JWST will avoid them)
- Dark current
- JWST detectors already designed to minimize glow
- Careful detector characterization selection
- Do not exceed max temp. requirement!
- Bias drifts
- Good electronic design
- Avoid power supply coupling
- Avoid ground coupling
- Reference pixels will help
- Synchronous readout can help
- QE variations
- Careful detector characterization selection
- Amplifier glow
- JWST detectors should be much better than NICMOS
25NICMOS Anomalies 2
- Persistence
- There will be persistence on JWST
- Strongly dependent on detector fabrication
process - Careful detector characterization selection
needed to choose best detectors - In IDTL, we are exploring mitigation measures
26NICMOS Anomalies 3
- DC bias level drift
- Good electronic design is first line of defense
- Reference pixels should eliminated Pedestal
drifts. - Depending on reference pixel layout, reference
pixels may help reject bands. - Ghosts
- In NICMOS, may result from ground plane coupling
within the MUX. - Also seen in SIRTF InSb radiation testing.
- Good cable harness and electronic design help
27NICMOS Detector Effects
- Linearity
- In NICMOS, 10 intrinsic non-linearity can be
calibrated out to within 0.2. - Well depth
- Well-depth is a function of reverse bias in
photo-voltaic detectors. - Well-depth can also depend on temperature.
- In the IDTL, we will study well depth as a
function of reverse bias and temperature.
28NICMOS Detector Effects 2
- QE
- Can depend on wavelength and temperature.
- Dark current bump
- This is a curious effect seen in NICMOS.
29Reference Pixels
- All candidate JWST detectors have reference
pixels - Reference pixels are insensitive to light
- In all other ways, designed to mimic a regular
light-sensitive pixel - NIR detector testing at University of Rochester,
University of Hawaii, and in the IDTL at STScI -gt
reference pixels work! - Reference pixel subtraction is a standard part of
IDTL data reduction pipeline
30Use of Reference Pixels
- JWSTs NIR reference pixels will be grouped in
columns and possibly rows - Most fundamentally
- reference pixels should be read out in exactly
the same manner as any normal pixel - Data from many reference pixels should be
averaged to avoid adding noise to data - We have begun to explore how reference pixels
should be used. Approaches considered include the
following. - Maximal averaging (average all reference pixels
together and subtract the mean) - Spatial averaging
- Temporal averaging
- Spatial averaging is now a standard part of IDTL
calibration pipeline
31A Picture of IDTL System Noise
- Shorting resistor mounted at SCA location
- 1/f tail causes horizontal banding.
- Total noise is 7 e- rms per correlated double
sample.
32Averaging small numbersof reference pixels adds
noise
- Averaged the last 4 columns in each row and
performed row-by-row subtraction
33Spatial Averaging
This is a standardpart of the IDTL
datacalibration pipeline
- In spatial averaging, data from many (64 rows)
of reference pixels are used to calibrate each
row in the image - A Savitzky-Golay smoothing filter is used to fit
a smooth and continuous reference column - This reference column is subtracted from each
column in the image - Using this technique, we can remove some 1/f
noise power within individual frames - In practice, this technique works very well
34Spatial Averaging Before After
Before
After
35Temporal Averaging
- Dwell on the reference pixel and sample many
times before clocking next pixel - Potentially removes most 1/f
- Not tried this in IDTL yet. U. Hawaii has
reported some problems with reference pixels
heating up
36Temporal Averaging Before After
Before
After
37Summary of Reference Pixel Calibration Methods
- Spatial averaging works well using a Rockwell
HAWAII-1RG detector - Based on conversations with U. Rochester, we
foresee no problems with SB-304 - Temporal Averaging is promising. More work needed
using real detectors.
38Summary
- The Independent Detector Testing Laboratory
(IDTL) at STScI/JHU is up and running - Test results including dark current, read noise,
conversion gain, relative quantum efficiency, and
persistence are in good agreement with other JWST
test labs - Reference pixels work and are an invaluable part
of the data calibration pipeline - We have explored three techniques for using
reference pixels - Maximal averaging,
- Spatial averaging,
- Temporal averaging
- Spatial averaging works well and is robust
- Early reports from U. Hawaii using temporal
averaging are not encouraging due to reference
pixel self-heating. More work is planned in the
IDTL