Presentation is loading. Please wait.

Presentation is loading. Please wait.

Apr 17-22, 20061 Tunable filter wavelength scan and calibration of intensity ripple Y. Katsukawa (NAOJ) and SOT team.

Published byBrice McBride Modified over 8 years ago

Similar presentations

Presentation on theme: "Apr 17-22, 20061 Tunable filter wavelength scan and calibration of intensity ripple Y. Katsukawa (NAOJ) and SOT team."— Presentation transcript:

1 Apr 17-22, 20061 Tunable filter wavelength scan and calibration of intensity ripple Y. Katsukawa (NAOJ) and SOT team

2 Apr 17-22, 20062 TF wavelength scan Wavelength scan by the tunable filter was performed to verify spectroscopic performance and its uniformity over the field-of- view. Two data sets –Solar spectra to check spectrum line profiles and their uniformity –Lamp source (emitting continuum light) to check intensity variation through the scan Each full FOV image is divided into 8x4 sub-images, and spectrum is created in each sub-image.

3 Apr 17-22, 20063 Wavelength scan of the solar spectrum lines (1) Mg I 5172A Fe I 5250A Black: Measured spectra Red: Atlas +TF ideal profiles

4 Apr 17-22, 20064 Wavelength scan of the solar spectrum lines (2) Fe I 5576A Na I 5896A Black: Measured spectra Red: Atlas +TF ideal profiles

5 Apr 17-22, 20065 Wavelength scan of the solar spectrum lines (3) Fe I 6302A H I 6563A Black: Measured spectra Red: Atlas +TF ideal profiles

6 Apr 17-22, 20066 Solar spectra by NFI These data sets show the line profiles are roughly consistent with the atlas spectra, and roughly uniform over the FOV. Two features can be seen in the spectra 1. Periodic intensity variation, especially significant in 5250A. 2. The line profiles are slightly shallower than the atlas spectra. In order to distinguish the solar spectrum features and intensity variation caused by the instrument, wavelength scans were carried out using a lamp source emitting continuum light.

7 Apr 17-22, 20067 Wavelength scan of a lamp source (1) Mg I 5172A Fe I 5250A Black: Measured intensity Red: Fitting result

8 Apr 17-22, 20068 Wavelength scan of a lamp source (2) Fe I 5576A Na I 5896A Black: Measured intensity Red: Fitting result

9 Apr 17-22, 20069 Wavelength scan of a lamp source (3) Fe I 6302A H I 6563A Black: Measured intensity Red: Fitting result

10 Apr 17-22, 200610 Intensity ripple in TF wavelength scan Amplitudes of the ripple are around 10 – 20 %, and are position dependent over FOV. They are also dependent on wavelengths. Periodic variation is dominant in 5172A and 5250A. We found two periods are dominant in the ripples. For the longer wavelengths, the ripple profiles are more complex. Many periods may be superposed.

11 Apr 17-22, 200611 Model of the intensity ripple TF consists of 8 calcite blocks and 8 tuning elements (motors). Each calcite block has a halfwave plate in the middle of the block to make wide fields. The tuning elements move periodically through the scan, and their periods are different from each other. The intensity ripple can be reproduced by giving errors to retardation of the halfwave plates in the calcite blocks 3 and 6. halfwave-6; del=0.1, halfwave-3; del=0.05, 5250A

12 Apr 17-22, 200612 Calibration of the intensity ripple If the intensity ripple is caused by the halfwave plates in the calcite blocks, the intensity modulation can be represented as a function of the motor positions (provided by encoders) of the tuning elements. Calcite blockMotor pos Calcite-02*(Motor-0)+(Motor-1) Calcite-1(Motor-1) Calcite-22*(Motor-2)+(Motor-3) Calcite-3(Motor-3) Calcite-42*(Motor-4)+(Motor-5) Calcite-5(Motor-5) Calcite-62*(Motor-6)+(Motor-7) Calcite-7(Motor-7) : Intensity amplitude for ith calcite block (Position dependent) : Phase of the motor position for ith calcite block (Position dependent) : Motor positions corresponding to ith calcite block a i and b i are derived by fitting of the intensity profiles at each position in FOV.

13 Apr 17-22, 200613 5250A amplitude and phase distribution @ T  21  C Calcite-6 Calcite-3 Amplitude Phase

14 Apr 17-22, 200614 5250A amplitude and phase distribution @ T  25  C Calcite-6 Calcite-3 Amplitude Phase The amplitude and phase are almost the same as those at T  21  C.

15 Apr 17-22, 200615 Spectra after calibration of I-ripple: 5250A Fe I 5250A Black: After corrected Red: Atlas +TF ideal profiles Black: Measured Red: Atlas +TF ideal profiles

16 Apr 17-22, 200616 6302A amplitude and phase distribution Calcite-6 Calcite-3 Amplitude Phase Amplitude Phase Amplitude Phase Calcite-5

17 Apr 17-22, 200617 Spectra after calibration of I-ripple: 6302A Fe I 6302A Black: After corrected Red: Atlas +TF ideal profiles Black: Measured Red: Atlas +TF ideal profiles

18 Apr 17-22, 200618 Spectra after calibration of I-ripple: 5576A Fe I 5576A Black: After corrected Red: Atlas +TF ideal profiles Black: Measured Red: Atlas +TF ideal profiles

19 Apr 17-22, 200619 Spectra after calibration of I-ripple: 5172A Mg I 5172A Black: After corrected Red: Atlas +TF ideal profiles Black: Measured Red: Atlas +TF ideal profiles

20 Apr 17-22, 200620 Spectra after calibration of I-ripple: 5896A Na I 5896A Black: After corrected Red: Atlas +TF ideal profiles Black: Measured Red: Atlas +TF ideal profiles

21 Apr 17-22, 200621 Spectra after calibration of I-ripple: 6563A H I 6563A Black: After corrected Red: Atlas +TF ideal profiles Black: Measured Red: Atlas +TF ideal profiles

22 Apr 17-22, 200622 Summary On orbit, the ripple patterns move with respect to the solar spectrum lines because the satellite Doppler motion and temperature changes in TF. But we can calibrate them because they are the patterns fixed to the motor positions. The spectrum line profiles are significantly improved by the calibration of the intensity ripple using the motor positions of the tuning elements. Similar wavelength scan data will be obtained at times in flight in order to verify tuning accuracy and the calibration function (amplitude and phase distribution) of the intensity ripple.

23 Apr 17-22, 200623 Broadband Filter Imager (1) CN bandhead Center: 388.35nm FWHM: 0.7nm Ca II H Center: 396.85nm FWHM: 0.3nm

24 Apr 17-22, 200624 Broadband Filter Imager (2) G-band Center: 430.50nm FWHM: 0.8nm Blue continuum Center: 450.55nm FWHM: 0.4nm

25 Apr 17-22, 200625 Broadband Filter Imager (3) Green continuum Center: 555.05nm FWHM: 0.4nm Red continuum Center: 668.40nm FWHM: 0.4nm

Download ppt "Apr 17-22, 20061 Tunable filter wavelength scan and calibration of intensity ripple Y. Katsukawa (NAOJ) and SOT team."

Similar presentations

Richard Young Optronic Laboratories Kathleen Muray INPHORA

Richard Young Optronic Laboratories Kathleen Muray INPHORA
CAVIAR meeting May, 13, 2010 – UCL, London 1/11 Cambridge Centre for Atmospheric Science Broad Band Cavity Enhanced Absorption Spectroscopy of the Water.

CAVIAR meeting May, 13, 2010 – UCL, London 1/11 Cambridge Centre for Atmospheric Science Broad Band Cavity Enhanced Absorption Spectroscopy of the Water.
Spectrochemical Instrumentation Modules

Spectrochemical Instrumentation Modules
GOME-2 polarisation data and products L.G. Tilstra (1,2), I. Aben (1), P. Stammes (2) (1) SRON; (2) KNMI GSAG #42, EUMETSAT, 14-10-2008.

GOME-2 polarisation data and products L.G. Tilstra (1,2), I. Aben (1), P. Stammes (2) (1) SRON; (2) KNMI GSAG #42, EUMETSAT,
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.
2006/4/17-20 Extended 17 th SOT meeting Azimuth ambiguity resolution from dBz/dz M. Kubo (ISAS/JAXA), K. Shimada (University of Tokyo), K. Ichimoto, S.

2006/4/17-20 Extended 17 th SOT meeting Azimuth ambiguity resolution from dBz/dz M. Kubo (ISAS/JAXA), K. Shimada (University of Tokyo), K. Ichimoto, S.
1 Fingerprints in Sunlight Understanding Spectroscopy Stanford University Solar Center.

1 Fingerprints in Sunlight Understanding Spectroscopy Stanford University Solar Center.
1 Estimate on SOT light level in flight with throughput measurements in SOT sun tests T. Shimizu 1, T. Tarbell 2, T. Berger 2, Y. Suematsu 3, M. Kubo 1,

1 Estimate on SOT light level in flight with throughput measurements in SOT sun tests T. Shimizu 1, T. Tarbell 2, T. Berger 2, Y. Suematsu 3, M. Kubo 1,
1 Estimate on SOT light level in flight with throughput measurements in SOT sun tests T. Shimizu 1, T. Tarbell 2, Y. Suematsu 3, M. Kubo 1, K. Ichimoto.

1 Estimate on SOT light level in flight with throughput measurements in SOT sun tests T. Shimizu 1, T. Tarbell 2, Y. Suematsu 3, M. Kubo 1, K. Ichimoto.
VLBI: Visible Light Broadband Imager Instrument Conceptual Design Presentation Tom Berger Lockheed Martin Solar and Astrophysics Lab.

VLBI: Visible Light Broadband Imager Instrument Conceptual Design Presentation Tom Berger Lockheed Martin Solar and Astrophysics Lab.
1 Lites FPP-SP Performance SOT #17 Meeting, NAOJ, April. 2006 Solar-B FPP As-Built Performance of the FPP Spectro- Polarimeter October, 2004 FPP Team Bruce.

1 Lites FPP-SP Performance SOT #17 Meeting, NAOJ, April Solar-B FPP As-Built Performance of the FPP Spectro- Polarimeter October, 2004 FPP Team Bruce.
Measuring the Temperature of Hot Solar Flare Plasma with RHESSI Amir Caspi 1,2, Sam Krucker 2, Robert P. Lin 1,2 1 Department of Physics, University of.

Measuring the Temperature of Hot Solar Flare Plasma with RHESSI Amir Caspi 1,2, Sam Krucker 2, Robert P. Lin 1,2 1 Department of Physics, University of.
Performance Analysis Using Genesis 1.3 Sven Reiche LCLS Undulator Parameter Workshop Argonne National Laboratory 10/24/03.

Performance Analysis Using Genesis 1.3 Sven Reiche LCLS Undulator Parameter Workshop Argonne National Laboratory 10/24/03.
RHESSI/NESSIE, June 2003 H.S. Hudson The RHESSI 3-10 keV spectrum H. Hudson, B. Dennis, K. Phillips, R. Schwartz, D. Smith.

RHESSI/NESSIE, June 2003 H.S. Hudson The RHESSI 3-10 keV spectrum H. Hudson, B. Dennis, K. Phillips, R. Schwartz, D. Smith.
Diffraction Applications Physics 202 Professor Lee Carkner Lecture 28.

Diffraction Applications Physics 202 Professor Lee Carkner Lecture 28.
Modern Atomic Theory Ms. Hoang ACP Chemistry. Summary  Visible light is a small section of the EM spectrum  Light exhibits wave-like and particle-like.

Modern Atomic Theory Ms. Hoang ACP Chemistry. Summary  Visible light is a small section of the EM spectrum  Light exhibits wave-like and particle-like.
© 2012 HORIBA Scientific. All rights reserved. Applications of Raman microspectroscopy to fluid inclusions phase identification. S. Mamedov *, R. S. Darling.

© 2012 HORIBA Scientific. All rights reserved. Applications of Raman microspectroscopy to fluid inclusions phase identification. S. Mamedov *, R. S. Darling.
Reflectance Spectroscopy Lab. Different colors correspond to different wavelengths of visible light 665 nm 630 nm 600 nm 550 nm 470 nm 425 nm 400 nm.

Reflectance Spectroscopy Lab. Different colors correspond to different wavelengths of visible light 665 nm 630 nm 600 nm 550 nm 470 nm 425 nm 400 nm.
Physics 55 Monday, October 17, 2005 1.What light can tell us, continued 2.Application of thermal emission to greenhouse warming. 3.Doppler shift with application.

Physics 55 Monday, October 17, What light can tell us, continued 2.Application of thermal emission to greenhouse warming. 3.Doppler shift with application.
1 High-z galaxy masses from spectroastrometry Alessio Gnerucci Department of Physics and Astronomy University of Florence 13/12/2009- Obergurgl Collaborators:

1 High-z galaxy masses from spectroastrometry Alessio Gnerucci Department of Physics and Astronomy University of Florence 13/12/2009- Obergurgl Collaborators:

Similar presentations

Ads by Google