Presentation is loading. Please wait.

Presentation is loading. Please wait.

Li, Ting Texas A&M University DePoy, Darren Texas A&M University Burke, David SLAC Kessler, Richard University of Chicago Marshall, Jennifer Texas A&M.

Published byEmil Skinner Modified over 8 years ago

Similar presentations

Presentation on theme: "Li, Ting Texas A&M University DePoy, Darren Texas A&M University Burke, David SLAC Kessler, Richard University of Chicago Marshall, Jennifer Texas A&M."— Presentation transcript:

1 Li, Ting Texas A&M University DePoy, Darren Texas A&M University Burke, David SLAC Kessler, Richard University of Chicago Marshall, Jennifer Texas A&M University Wise, Jason Texas A&M University Rheault, J-P Texas A&M University Boada, Steven Texas A&M University Carona, Don Texas A&M University Apr 16, 2011 Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

2 WHY we are building aTmCam? -- Motivation HOW we are going to build it? -- Method WHAT we have done so far? -- Results we will we do next? -- Future Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

3 Instrument Earth’s Atmosphere Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

4 Model the atmospheric transmission spectrum by libRadTran with different amount of precipitable water Hansen & Caimanque, 1975 (PASP) Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

5 Atmospheric Transmission is time, airmass and location dependent. Calibration stars have the different spectra as the program objects, e.g. SNs, Galaxies, etc. Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

6 Kessler DES docdb 5723

7 Kessler DES docdb 5723

8 WHY? Atmospheric transmission spectrum in real-time Reach a sub-1% precision photometry How? What? Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

9 Data Reduction for Spectroscopy = - - Instrument Sensitivity Atmospheric Transmission Raw data Spectrum Obtained from observing standard stars Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

10 Data Reduction for Spectroscopy = - - Observing standard stars = - - Instrument Sensitivity Atmospheric Transmission Raw data Spectrum Instrument Sensitivity Atmospheric Transmission Raw dataSpectrum Obtained from observing standard stars Obtained from Instrument Calibration System Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

11 WHY? Atmospheric transmission spectrum in real-time Reach a sub-1% precision photometry How?  Measure the standard star with a Calibrated Spectrograph? What? Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

12 WHY? Atmospheric transmission spectrum in real-time Reach a sub-1% precision photometry How? Χ Measure the standard star with a Calibrated Spectrograph? Photometry is always easier than spectroscopy! What? Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

13 Molecular/Rayleigh scattering Aerosol scattering Molecular absorption Cloud Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

14 Molecular/Rayleigh scattering Pressure Aerosol scattering Molecular absorption Cloud Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

15 Molecular/Rayleigh scattering Aerosol scattering Aerosol optical depth Molecular absorption Cloud Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

16 Molecular/Rayleigh scattering Aerosol scattering Molecular absorption Oxygen Cloud Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

17 Molecular/Rayleigh scattering Aerosol scattering Molecular absorption Oxygen Ozone Cloud Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

18 Molecular/Rayleigh scattering Aerosol scattering Molecular absorption Oxygen Ozone Water Cloud Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

19 pressureozonewater aerosol Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

20 Ratios from the simulation by libRadTran

21 WHY? Atmospheric transmission spectrum in real-time Reach a sub-1% precision photometry How? Measure the standard star with a Calibrated Spectrograph Multi Narrowband Imager Get the best fit model in the database Robotic, automatic multi-imaging system  aTmCam What? Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

22 WHY? Atmospheric transmission spectrum in real-time Reach a sub-1% precision photometry How? Measure the standard star with a Calibrated Multi Narrowband Imager Get the best fit model in the database Robotic, automatic multi-imaging system  aTmCam What?  Can we replace the spectrograph with imager? Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

23 Prototype aTmCam SBIG Camera Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012 Jaz Spectrograph Wedged Prisms + Narrowband Filters

24 Observing Vega at Texas A&M Observatory Red: Direct measurement from spectrograph Green: Best fit model picked by the ratios from Narrow-band Imager Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

25 Observing Vega at McDonald Observatory Green: Best fit model picked by the measurements from Spectrograph Black: Best fit model picked by the ratios from Narrow-band Imager Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

26 WHY? Atmospheric transmission spectrum in real-time Reach a sub-1% precision photometry How? Measure the standard star with a Calibrated Multi Narrowband Imager Get the best fit model in the database Robotic, automatic multi-imaging system  aTmCam What? We can replace the spectrograph with imager. Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

27 WHY? Atmospheric transmission spectrum in real-time Reach a sub-1% precision photometry How? Measure the standard star with a Calibrated Multi Narrowband Imager Get the best fit model in the database Robotic, automatic multi-imaging system  aTmCam What? We can replace the spectrograph with imager. Do we need to measure the atmospheric throughput at each field of the survey? If not, then how close? Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

28 Temporal or angular parameter of the variation Need to be answered in CTIO with REAL aTmCam 20-30 nights observation at CTIO this fall 3-4 telescopes and cameras Currently working on building a software system on: Target acquisition Simultaneously image taking ISMAIL: Imaging Software for Munnerlyn Astronomical Instrumentation Lab Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

29 Mount Control Panel Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

30 Camera Control Panel Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

31 WHY? Atmospheric transmission spectrum in real-time Reach a sub-1% precision photometry How? Measure the standard star with a Calibrated Multi Narrowband Imager Get the best fit model in the database Robotic, automatic multi-imaging system  aTmCam What? We can replace the spectrograph with imager. We will know whether or not we need to measure the atmospheric throughput at each field of the survey. Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

32 WHY? Atmospheric transmission spectrum in real-time Reach a sub-1% precision photometry How? Measure the standard star with a Calibrated Multi Narrowband Imager Get the best fit model in the database Robotic, automatic multi-imaging system  aTmCam What? We can replace the spectrograph with imager. We will know whether or not we need to measure the atmospheric throughput at each field of the survey. Calibration & Standardization of Large Surveys & Missions in Astronomy & Astrophysics Conference @ FermiLab, 16-19 April 2012

33

Download ppt "Li, Ting Texas A&M University DePoy, Darren Texas A&M University Burke, David SLAC Kessler, Richard University of Chicago Marshall, Jennifer Texas A&M."

Similar presentations

MAROON-X: An instrument for identifying another Earth

MAROON-X: An instrument for identifying another Earth
Atmospheric Optics - I. Recap Condensation above the Earth surface produces clouds. Clouds are divided into 4 main groups: ♦ High ♦ Middle ♦ Low ♦ Clouds.

Atmospheric Optics - I. Recap Condensation above the Earth surface produces clouds. Clouds are divided into 4 main groups: ♦ High ♦ Middle ♦ Low ♦ Clouds.
Extracting a SN spectrum from EMMI Thank you Sandro (and Hans, Jean-Louis, Gianni and the EMMI team)

Extracting a SN spectrum from EMMI Thank you Sandro (and Hans, Jean-Louis, Gianni and the EMMI team)
DESpec spectrographs Jennifer Marshall Darren DePoy Texas A&M University.

DESpec spectrographs Jennifer Marshall Darren DePoy Texas A&M University.
DESpec spectrographs Jennifer Marshall Darren DePoy Texas A&M University.

DESpec spectrographs Jennifer Marshall Darren DePoy Texas A&M University.
Atmospheric Effects and Other Observational Issues AS3100 Lab. Astronomi Dasar 1 Prodi Astronomi 2007/2008 B. Dermawan.

Atmospheric Effects and Other Observational Issues AS3100 Lab. Astronomi Dasar 1 Prodi Astronomi 2007/2008 B. Dermawan.
Fingerprints in Sunlight Understanding Spectroscopy

Fingerprints in Sunlight Understanding Spectroscopy
1 Fingerprints in Sunlight Understanding Spectroscopy Stanford University Solar Center.

1 Fingerprints in Sunlight Understanding Spectroscopy Stanford University Solar Center.
The National Science Foundation The Dark Energy Survey J. Frieman, M. Becker, J. Carlstrom, M. Gladders, W. Hu, R. Kessler, B. Koester, A. Kravtsov, for.

The National Science Foundation The Dark Energy Survey J. Frieman, M. Becker, J. Carlstrom, M. Gladders, W. Hu, R. Kessler, B. Koester, A. Kravtsov, for.
The SOAR Telescope MSU’s Laboratory for Astronomical Discovery.

The SOAR Telescope MSU’s Laboratory for Astronomical Discovery.
1 Non-linear Effects of Atmospheric Extinction on Observations in Astronomy Frédéric Zagury Institut Louis de Broglie Paris - France.

1 Non-linear Effects of Atmospheric Extinction on Observations in Astronomy Frédéric Zagury Institut Louis de Broglie Paris - France.
Sept. 18, 2008SLUO 2008 Annual Meeting Science Opportunities with LSST David L. Burke SLAC/KIPAC.

Sept. 18, 2008SLUO 2008 Annual Meeting Science Opportunities with LSST David L. Burke SLAC/KIPAC.
September 22, 2006 Natalia Kuznetsova Lawrence Berkeley National Laboratory The Super/Nova Acceleration Probe (SNAP) Natalia Kuznetsova Natalia Kuznetsova.

September 22, 2006 Natalia Kuznetsova Lawrence Berkeley National Laboratory The Super/Nova Acceleration Probe (SNAP) Natalia Kuznetsova Natalia Kuznetsova.
Observational Astrophysics II: May-June, 20041 Observational Astrophysics II (L2) Getting our NIRF What do want to do? 1.Image a selected.

Observational Astrophysics II: May-June, Observational Astrophysics II (L2) Getting our NIRF What do want to do? 1.Image a selected.
1 DESpec Outline Concept Technical Components –Optics –Fiber Positioner –Fibers & Spectrographs –CCD & RO Some discussion about choices that may be available.

1 DESpec Outline Concept Technical Components –Optics –Fiber Positioner –Fibers & Spectrographs –CCD & RO Some discussion about choices that may be available.
SIRTF NASA’s Space InfraRed Telescope Facility Alyssa A. Goodman Professor of Astronomy Harvard University.

SIRTF NASA’s Space InfraRed Telescope Facility Alyssa A. Goodman Professor of Astronomy Harvard University.
Astronomical Spectroscopy

Astronomical Spectroscopy
Spectroscopy Techniques and Projects at 1.2-m UK Schmidt Telescope

Spectroscopy Techniques and Projects at 1.2-m UK Schmidt Telescope
The KPNO 4m “Mayall” Telescope Arjun Dey (NOAO). National Optical Astronomy Observatory Mission: provide the best ground-based astronomical capabilities.

The KPNO 4m “Mayall” Telescope Arjun Dey (NOAO). National Optical Astronomy Observatory Mission: provide the best ground-based astronomical capabilities.
Spectroscopy in Stellar Astrophysics Alberto Rebassa Mansergas.

Spectroscopy in Stellar Astrophysics Alberto Rebassa Mansergas.

Similar presentations

Ads by Google