SSD Technical/Training Series - Photometry III
Brad Whitmore
10-10:30am, Monday
December 7, 1998
Auditorium
SSD Technical/Training Series - Photometry I- III Outline
November 5 - Photometry I - Brad Whitmore
- MOTIVATION (Big Science
from small measurements)
- H-R diagram
- Age of the universe from Cepheid variables
- PRACTICAL MEASUREMENTS
- Using APPHOT (walk through the WFPC2 Tutorial)
- Homework (due Nov. 11)
- BASICS
November 12 - Photometry II - Brad
Whitmore
- MORE BASICS
- THE NITTY GRITTY
December 7 - Photometry III - Brad Whitmore
December 10 - Photometry IV -
- STIS PHOTOMETRY - Harry Ferguson
- NICMOS PHOTOMETRY - Mark Dickinson
PHOTOMETRY III
HOMEWORK # 2 RESULTS -
| Result from homework #1 |
Aperture correction |
geometric correction |
contamination correction |
transform to Cousins |
| 17.985 |
17.349 |
17.325 |
17.325 |
17.300 |
| 17.985 |
17.349 |
17.351 |
17.353 |
|
| 17.985 |
17.339 |
17.341 |
17.341 |
17.331 |
| 17.985 |
17.349 |
17.351 |
17.351 |
17.359 |
| 17.985 |
17.339 |
17.341 |
17.341 |
17.306 |
HOMEWORK ASSIGNMENT # 3
| DUE: |
Wednesday, Dec. 9 (e-mail to Brad, he will compile results and show at Dec 10 class,
anonymously) |
| MEASURE: |
Correct the measurement made for assignment (i.e., start at u2g40o09t.c0h[1][499,447]
for:
|
NOTE: Please start with 17.306, to make comparisons more meaningful. Also, please
record after each step.
After Dec. 10 I will put the working script, and how I did the homework assignments,
on the training web site.
14. CHARGE TRANSFER EFFICIENCY (CTE)
- The efficiency of transferring the charge from pixel to pixel during the readout
of an image is not 1.0000000, but more like 0.99995 ("four nines five").
Hence a star at the top of the chip looses more of its charge during the readout,
and appears to be FAINTER by 800 X (1-0.99995) = 4 %.
- There is a similar, but smaller effect along the X axis, presumably due to the
shift register.
- The amount of CTE also depends on:
- target brightness,
- background, and
- aperture size.
- The CTE loss is relatively small for bright stars, but can be 20 - 30 % for very
faint stars on very faint backgrounds.
- See ISR 97-08 for details, and for a set of equations to correct for CTE to about
the 5 % level or better.
- CTE seems to be increasing with time, primarily for faint objects. See TIR 98-01
for details.
15. "LONG-VS-SHORT" ANOMALY
- Short exposures appear to give fainter magnitudes than long exposures. However,
this turns out to be a simple non-linearity which depends soley on TOTAL COUNTS in
a stellar image, and is actually independent of exposure time. Hence "Long-vs-Short"
is a misnomer.
- The effect can be as large as 40 % for very faint stars.
- A simple formula can be used to correct for the effect at roughly the 0.05 magnitude
level.
- See ISR 98-02.
16. COMMON GOTCHAS
- gain = 7 or 15
- ST-MAG (see section 8.7 in WFPC2 Instrument Handbook)
- red leaks (see section 3.8 in WFPC2 Instrument Handbook)
17. OTHER THINGS I NEVER MENTIONED
- Dependence on how well centered on the pixel. Holtzman-1 found < 0.01 effect.
- The PSF varies over the field of view of the chip. For 1 pixel radius this can
be roughly a 0.05 magnitude difference near the corners.
- The quantized nature of the pixel values add noise to the signal and can also
result in subtle systematic errors (e.g., if you use medians). See p. 279 of the
1995 Calibration Workshop.
- etc. etc. etc.
Tables and Figures
! Will be available shortly.
Updated: 12/07/98