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The Mid-Infrared Interferometric
Instrument for the
Very Large Telescope
Interferometer
SterrewachtLeiden
MIDI
Correlation of MIDI Phase Fluctuations with Fluctuations ofWater and Carbon Dioxide, Paranal June 2007
Doc. No. UL-TRE-MID-15829-0113Issue 1Date March 14, 2008
Prepared Richard J. Mathar March 14, 2008Signature
Approved Walter J. Jaffe March 14, 2008Signature
ReleasedSignature
ii Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
Change Record
Issue Date Section/Parag. affected Reason/Initiation/Documents/Remarks
0.1.185 04-Jul-2007 all created (rjm)1.0 13-Mar-2008 all first official release (rjm)
Contents
1 OVERVIEW 11.1 Scope . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.2 Data Sources . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.3 References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11.4 Acronyms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2
2 FITTED DISPERSED MIDI SCANS 52.1 Parameters: times, baselines, meteorological . . . . . . . . . . . . . . . . . . . . . . . . 52.2 Reduction of Dispersion with Linear Fits to Wavenumber . . . . . . . . . . . . . . . . 11
3 COMPARISON INTERFEROMETRY AND GAS ANALYZER 473.1 Refractive Index Model . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 473.2 Structure Functions and Fried Parameter . . . . . . . . . . . . . . . . . . . . . . . . . 513.3 Power Spectra of Phases . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 583.4 Phases Extrapolated to Zero Wavenumber . . . . . . . . . . . . . . . . . . . . . . . . . 63
4 SUMMARY 73
List of Figures
1 associated MIDI data files . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 62 wind velocity 300 mbar . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83 Wind Speed during MIDI nights . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 104 MIDI data file 0 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 145 MIDI data file 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 156 MIDI data file 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 167 MIDI data file 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 178 MIDI data file 4 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 189 MIDI data file 5 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1910 MIDI data file 6 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2011 MIDI data file 7 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2112 MIDI data file 8 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2213 MIDI data file 9 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2314 MIDI data file 10 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2415 MIDI data file 11 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 iii
16 MIDI data file 12 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2617 MIDI data file 13 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2718 MIDI data file 14 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2819 MIDI data file 15 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2920 MIDI data file 16 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3021 MIDI data file 17 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3122 MIDI data file 18 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3223 MIDI data file 19 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3324 MIDI data file 20 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3425 MIDI data file 21 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3526 MIDI data file 22 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3627 MIDI data file 23 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3728 MIDI data file 24 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3829 MIDI data file 25 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3930 MIDI data file 26 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4031 MIDI data file 27 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4132 MIDI data file 28 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4233 MIDI data file 29 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4334 Phase Structure Function, weak points flagged . . . . . . . . . . . . . . . . . . . . . . 4435 Phase Structure Function Dϕ0 with oscillations, weak points flagged . . . . . . . . . . 4536 Structure Function Dϕ′ , weak points flagged, slope 1.3 . . . . . . . . . . . . . . . . . . 4537 N-band water vapor dispersion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4838 N-band dry air dispersion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4939 N-band carbon dioxide dispersion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5040 fitted H2O structure functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5241 fitted CO2 structure functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5442 Digitization error of molar densities . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5543 Expected phases from VLTI mirror vibrations . . . . . . . . . . . . . . . . . . . . . . . 5944 Comparison Clifford model and MIDI 10 µm PDF 1st night . . . . . . . . . . . . . . . 6045 Comparison Clifford model and MIDI 10 µm PDF 2nd night . . . . . . . . . . . . . . 6146 Comparison Clifford model and MIDI 10 µm PDF 4th night . . . . . . . . . . . . . . 6247 Correlation phase and delay 1st night . . . . . . . . . . . . . . . . . . . . . . . . . . . 6548 Correlation phase and delay 2nd night . . . . . . . . . . . . . . . . . . . . . . . . . . . 6649 Correlation phase and delay 3rd night . . . . . . . . . . . . . . . . . . . . . . . . . . . 6750 Correlation phase and delay 4th night . . . . . . . . . . . . . . . . . . . . . . . . . . . 6851 Comparison Clifford model and MIDI zero-k PDF 1st night . . . . . . . . . . . . . . . 7052 Comparison Clifford model and MIDI zero-k PDF 2nd night . . . . . . . . . . . . . . . 7153 Comparison Clifford model and MIDI zero-k PDF 4th night . . . . . . . . . . . . . . 72
List of Tables
1 Parameters of MIDI data sets: baselines, dates, delays . . . . . . . . . . . . . . . . . . 72 MIDI data delayed start times, star altitudes and azimuths . . . . . . . . . . . . . . . 133 Parameters of data sets: wind angles, structure constants . . . . . . . . . . . . . . . . 57
iv Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 1
1 OVERVIEW
1.1 Scope
Fluctuations of water and carbon dioxide densities have been measured by W. J. Jaffe and R. S. LePoole on the roof top of the VLTI control building, in the VLTI tunnel, and the hull of the VST domewith a LI-COR gas analyzer at the end of June 2007 [16].
During four nights in the same period, the fringe tracker of the MIDI/VLTI interferometer collecteddata on the motion jitter at the mid-infrared wavelength of 10 µm. We combine a subset of 30of these exposures on visibility calibrators—each of a duration of approximately 2 minutes—wherean overlap with ambient LI-COR data exists. A quantitative comparison between phase powerspectra and structure functions is drawn here; the adjective “quantitative” indicates that not onlythe power exponents of these spectra are examined—which has been done before in OI [2] and willnot be reviewed—but also the strength of the turbulence, commonly associated with various seeingparameters.
1.2 Data Sources
This manuscript has drawn information from
• a one-time campaign with a loaned LI-COR water/carbon-dioxide gas analyzer, June 25–30,2007 [16].
• an ASCII interface to the temperatures, pressures, relative humidities, wind directions, windvelocities and seeing parameters stored in the Paranal ambient server data base [19].
• data on precipitable water vapor, wind speed and wind direction on the 300 mbar level (height)originating from the ECMWF.
• characterisation of interferometric geometry (including air mass), snapshots of the ambientmeteorology and seeing, and stored in FITS files of MIDI raw data of four nights overlappingwith the gas analyzer data during 30 exposures of approximately 2 minutes duration (each).
• data reduction products of the same MIDI detector data with the MIDI prism, equivalent to aspectral resolution of roughly 32 channels in the N band,
• Temperatures and relative humidities of four sensors in the VLTI tunnel and ducts copied froma directory on ESO’s anonymous ftp server.
1.3 References
[1] Clifford, S. F. 1971, J. Opt. Soc. Am., 61, 1285
[2] Colavita, M. M., Shao, M., & Staelin, D. H. 1987, Appl. Opt., 26, 4106
2 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
[3] d’Arcio, L. 1995, Differential anisoplanatic OPDs and OPD spectra for the VLTI at CerroParanal from PARSCA 1992 Balloon Data. VLT-TRE-ESO-15000-0835
[4] de Mooij, E. 2006, Atmospheric turbulence measured with MIDI, Tech. rep.
[5] Fried, D. L. 1965, J. Opt. Soc. Am., 55, 1427. E: [6]
[6] — 1966, J. Opt. Soc. Am., 56, 410E
[7] Hufnagel, R. E., & Stanley, N. R. 1964, J. Opt. Soc. Am., 54, 52
[8] Koehler, B. 2000, Results of OPD measurement on UT#3 in May ’00, Test Report. VLT-TRE-ESO-15000-2258
[9] Koresko, C., Colavita, M., Serabyn, E., Booth, A., & Garcia, J. 2006, in Advances in Stellar In-terferometry, edited by J. D. Monnier, M. Scholler, & W. Danchi (Int. Soc. Optical Engineering),vol. 6268, 626817
[10] Labit, P. 1998, Meteorological Prediction Software, User and Maintenance Manual. VLT-TRE-ESO-17443-1678
[11] Leveque, S. 2002, Temperature sensor network for the VLTI. VLT-TRE-ESO-15000-2532
[12] Marchetti, S., & Simili, R. 2006, Infr. Phys. Techn., 47, 263. Presumbably, the factor 10−4 oughtread 10+4 and the temperature 296 ◦C read 23 ◦C in Table 1.
[13] Mathar, R. J. 2006, Astrometric Survey for Extra-Solar Planets with PRIMA, Astrometricdispersion correction. UL-TRE-AOS-15753-0010
[14] — 2007, Baltic Astronomy, 16, 287
[15] — 2007, J. Opt. A: Pure and Appl. Optics, 9, 470
[16] Mathar, R. J., Jaffe, W. J., & Le Poole, R. S. 2007, High Frequency Fluctuations of Water andCarbon Dioxide, Paranal July 25–27, 2007. UL-TRE-ESO-15000-0836
[17] Roddier, F. 1981 (Amsterdam: North Holland), vol. XIX of Prog. Opt., 281–376
[18] Roddier, F., & Lena, P. 1984, J. Optics (Paris), 15, 171
[19] Sarazin, M. 2003, Astroclimatology of Paranal, Tech. rep., European Southern Observatory.URL http://www.eso.org/gen-fac/pubs/astclim/paranal
[20] Schwider, J. 1990 (Amsterdam: Elsevier), vol. 28 of Prog. Opt., 271–359
1.4 Acronyms
AO Adaptive Optics
DICB Data Interface Definition Board (of ESO) http://archive.eso.org/dicb
DL Delay Line
ECMWF European Center for Medium-Range Weather Forecasts http://www.ecmwf.int/
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 3
ESO European Southern Observatory http://www.eso.org
FITS Flexible Image Transport System http://fits.gsfc.nasa.gov
FT Fourier Transform
GPS Global Positioning System
GUI Graphical User Interface
IDL Interactive Data Language http://www.uni-giessen.de/hrz/software/idl/
IR Infrared
IRIS Infrared Image Sensor http://www.eso.org/projects/vlti/iris/
ISS Interferometric Supervisor-Software
MDL main delay linehttp://www.eso.org/outreach/press-rel/pr-2000/phot-26-00.html
MIDI Mid-Infrared Interferometric Instrument http://www.mpia.de/MIDI
NOVA Nederlandse Onderzoekschool voor Astronomiehttp://www.strw.leidenuniv.nl/nova/
OI Optical Interferometry http://olbin.jpl.nasa.gov/
OPD optical path difference
OS Observation Software
PDF Power Density Function http://en.wikipedia.org/wiki/Spectral_density
PWV precipitable water vapor
UT Unit Telescope (of the VLTI) http://www.eso.org/projects/vlt/unit-tel/
UTC Universal Time Coordinated
VLT Very Large Telescope http://www.eso.org/
VLTI Very Large Telescope Interferometer http://www.eso.org/vlti
VST VLT Survey Telescope http://vstportal.oacn.inaf.it/
4 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 5
2 FITTED DISPERSED MIDI SCANS
2.1 Parameters: times, baselines, meteorological
An overview of the time allocation of the 30 MIDI exposures in the four nights is in Figure 1. Someparameters extracted from the primary headers of the first in each group of FITS files of an exposureare in table 1.
• The first column is a small integer to avoid tagging with the full standard file name that isgiven in the second column.
• Baselines are listed in the third column.
• Two temperatures along the DL tunnel are in the 4th and 5th column, taken from the keywordsISS TEMP TUN1 and ISS TEMP TUN4 [11].
• P is the column with the projected baseline, ISS PBL12 START.
• D and D are the external path delay (in vacuum) and its time derivative, using LST, OCS ISSRA and OCS ISS DEC as inputs. The sum b2 = P 2 + D2 is the squared baseline length andconstant for a pair of stations, b = 46.4 m (46.6 m according to the distance between thestation coordinates in the OPD model of Mfile22) for UT23 and b = 62.4 m for UT34.
• The column τ0 is the mean of AMBI TAU0 START and AMBI TAU0 END.
• The column ∂T/∂h is the value of AMBI LRATE.
• The column AIRM is the air mass of ISS AIRM START.
The detector cycle time (average distance between start of two exposures) was 20.9 ms (49 Hz) inall cases. These are non-chopped observations which basically ensures that the stream of data fillsthe time axis almost continuously. The number of piezo steps per scan was 40 in all cases (keywordPIEZ POSNUM), which means block adjustments of the internal or main delay lines initiated by theMIDI fringe tracker could occur in intervals of 0.836 seconds. (This is roughly equivalent to the meanpassage time for a UT diameter at characteristic wind speeds of 10 m/s.) Multiplication with D ofTable 1—which is of the order of 1 mm/s—gives an estimate of how much the main delay line movedduring that time.
Some additional characterization of the seeing conditions is in Figure 2; its data will not be used inthe followup analysis.
6 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
-500
006/2500:00
06/2504:00
06/2508:00
06/2512:00
06/2516:00
06/2520:00
06/2600:00
delay [mu]
Mfile0
-500
0
50006/2600:00
06/2604:00
06/2608:00
06/2612:00
06/2616:00
06/2620:00
06/2700:00
delay [mu]
Mfile1
Mfile2Mfile3Mfile4
Mfile5
Mfile6Mfile7
Mfile8 -500
0 500
1000 1500 200006/27
00:0006/2704:00
06/2708:00
06/2712:00
06/2716:00
06/2720:00
06/2800:00
delay [mu]
LI-CO
R to tunnel
Mfile9Mfile10
Mfile11
Mfile12Mfile13
Mfile14Mfile15
-1500-1000 -500
0 500
1000 1500 200006/28
00:0006/2804:00
06/2808:00
06/2812:00
06/2816:00
06/2820:00
06/2900:00
delay [mu]
LI-CO
R to V
ST
Mfile16
Mfile17Mfile18
Mfile19
Mfile20
Mfile21
Mfile22
1000 1500 2000 2500 300006/29
00:0006/2904:00
06/2908:00
06/2912:00
06/2916:00
06/2920:00
06/3000:00
delay [mu]
Mfile23
Mfile24
Mfile25
Mfile26Mfile27
Mfile28
Mfile29
Figure 1: Timing overview of the four nights with MIDI data files.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 7
ARCFILE
TELESCOP
TUN1
TUN4
PBL12
TAU0
LRATE
AIRM
WINDSP
Mfilen
startstations
TW
estE
astP
DD
τ0
∂T
/∂h
( ◦C)
( ◦C)
(m)
(m)
(mm
/s)(m
s)( ◦C
/m)
(m/s)
0M
IDI.2007-06-25T
23:53:33U
3413.49
14.2762.3
4.0-1.2
1.00-0.0143
1.47811.90
1M
IDI.2007-06-25T
01:42:35U
3412.96
14.4161.9
6.2-0.7
1.18-0.0054
1.45112.78
2M
IDI.2007-06-26T
02:58:18U
3413.37
14.3162.2
6.2-0.7
0.95-0.0100
1.73010.73
3M
IDI.2007-06-26T
03:41:14U
3413.38
14.3658.5
-21.8-3.6
1.24-0.0139
1.06711.68
4M
IDI.2007-06-26T
03:49:39U
3413.32
14.3557.8
-23.6-3.5
1.21-0.0136
1.08011.38
5M
IDI.2007-06-26T
04:56:08U
3413.29
14.3443.8
44.6-1.3
0.94-0.0171
1.77911.53
6M
IDI.2007-06-26T
05:54:39U
3413.39
14.3758.3
22.6-2.9
0.81-0.0171
1.1228.98
7M
IDI.2007-06-26T
06:35:22U
3413.34
14.4250.9
36.2-2.1
0.84-0.0275
1.3828.68
8M
IDI.2007-06-26T
08:15:15U
3413.22
14.4949.5
38.1-3.4
0.83-0.0504
1.3238.48
9M
IDI.2007-06-27T
01:24:27U
2313.41
14.5045.2
-11.4-0.8
0.78-0.0121
1.26716.25
10M
IDI.2007-06-27T
01:50:36U
2312.36
14.4344.9
-12.7-0.9
0.78-0.0107
1.22814.73
11M
IDI.2007-06-27T
03:04:41U
2312.09
14.4439.9
-24.2-1.5
0.60-0.0282
1.18317.10
12M
IDI.2007-06-27T
04:26:37U
2312.30
14.4946.0
-7.70.2
0.83-0.0304
1.96715.88
13M
IDI.2007-06-27T
04:31:47U
2312.29
14.5146.0
-7.70.2
0.87-0.0268
1.92516.00
14M
IDI.2007-06-27T
07:06:52U
2312.30
14.5245.8
-8.9-0.7
0.94-0.0304
1.28915.15
15M
IDI.2007-06-27T
07:27:32U
2312.31
14.4445.7
-9.2-0.8
0.97-0.0357
1.22816.58
16M
IDI.2007-06-28T
04:50:12U
3412.88
14.3560.6
-15.1-1.4
3.12-0.0189
1.44913.45
17M
IDI.2007-06-28T
05:42:41U
3413.16
14.3756.8
-26.0-3.7
3.22-0.0111
1.1049.93
18M
IDI.2007-06-28T
06:27:47U
3413.08
14.4354.6
-30.4-2.0
3.44-0.0132
1.35610.53
19M
IDI.2007-06-28T
07:15:28U
3413.08
14.5039.2
48.7-1.4
4.73-0.0061
1.8698.90
20M
IDI.2007-06-28T
08:23:48U
3413.28
14.5646.9
-41.3-3.2
2.68-0.0304
1.3998.43
21M
IDI.2007-06-28T
09:42:30U
3413.19
14.6458.0
23.2-3.4
1.91-0.0671
1.9839.93
22M
IDI.2007-06-28T
23:51:18U
2313.34
14.6446.6
2.1-0.4
2.68-0.0236
1.3979.13
23M
IDI.2007-06-29T
01:29:51U
2313.37
14.6546.6
1.4-0.7
2.98-0.0218
1.2649.80
24M
IDI.2007-06-29T
02:46:08U
2313.39
14.6345.8
-8.7-1.5
2.94-0.0039
1.0548.23
25M
IDI.2007-06-29T
03:58:27U
2313.39
14.5546.4
4.5-1.7
3.11-0.0054
1.0167.72
26M
IDI.2007-06-29T
05:11:09U
2313.41
14.5643.6
-16.5-1.8
2.89-0.0089
1.0716.95
27M
IDI.2007-06-29T
05:56:11U
2313.40
14.6446.2
-6.1-2.1
2.71-0.0032
1.0117.80
28M
IDI.2007-06-29T
07:01:57U
2313.42
14.5242.8
-18.4-2.2
2.43-0.0021
1.1736.50
29M
IDI.2007-06-29T
08:26:56U
2313.47
14.4739.2
-25.3-2.0
3.28-0.0346
1.3367.00
Table 1: Parameters of the 30 MIDI data sets derived from primary FITS headers.
8 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
0 5 10 15 20 25 30 35 40 45 5025 Jun
00:0026 Jun00:00
27 Jun00:00
28 Jun00:00
29 Jun00:00
300 mbar wind [m/s]
0 1 2 3 4 5 6
PWV [mm]
0 1 2 3 4 5 6
τ0 [ms]
Mfile0Mfile1
Mfile2Mfile3Mfile4Mfile5
Mfile6Mfile7Mfile8
Mfile9Mfile10Mfile11
Mfile12Mfile13
Mfile14 Mfile15
Mfile16Mfile17Mfile18
Mfile19Mfile20
Mfile21
Mfile22Mfile23
Mfile24Mfile25
Mfile26Mfile27Mfile28
Mfile29
0.51.01.52.02.53.025 Jun
00:0026 Jun00:00
27 Jun00:00
28 Jun00:00
29 Jun00:00
seeing [as]
Figure 2: Upper two plots: The wind velocity during the five days of observation at the 300 mbarpressure level, and the precipitable water vapor, from the ECMWF [10, 19]. The PWV plot is a sectionof Figure 57 in [13]. Lower two plots: seeing and coherence time from the ambient data base serverat the same times. The 25th of June is included in the plot to demonstrate implicitly through thePWV that it was rainy.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 9
Fig. 3 is a close-up (redundant) view on the wind speeds of Figs. 2–7 of [16] during the times of the30 MIDI observations, a synopsis of the WINDSP column of Table 1 with the markers of Fig. 1. Theintent is to demonstrate that the wind speed is stable over the approximate 2 minutes of an exposureonly to within 0.5 m/s. The WINDSP entry in the FITS headers are (due to some known constraintsof data handling procedures in the instrument software) a snapshot taken at some time during thepart of the exposure covered by the first FITS file of the series; the nominal accuracy of 0.01 m/s isnot achieved.
10 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
6 8 10 12 14 16
26 Jun00:00
26 Jun01:00
26 Jun02:00
26 Jun03:00
26 Jun04:00
26 Jun05:00
26 Jun06:00
26 Jun07:00
26 Jun08:00
26 Jun09:00
26 Jun10:00
wind (m/s)
Mfile0
Mfile1
Mfile2
Mfile3Mfile4
Mfile5
Mfile6
Mfile7
Mfile8
10 12 14 16 18
27 Jun00:00
27 Jun01:00
27 Jun02:00
27 Jun03:00
27 Jun04:00
27 Jun05:00
27 Jun06:00
27 Jun07:00
27 Jun08:00
27 Jun09:00
27 Jun10:00
wind (m/s)
Mfile9
Mfile10
Mfile11
Mfile12Mfile13
Mfile14
Mfile15
6 8 10 12 14 16
28 Jun00:00
28 Jun01:00
28 Jun02:00
28 Jun03:00
28 Jun04:00
28 Jun05:00
28 Jun06:00
28 Jun07:00
28 Jun08:00
28 Jun09:00
28 Jun10:00
wind (m/s)
Mfile16
Mfile17
Mfile18
Mfile19
Mfile20
Mfile21
2 4 6 8 10 12
29 Jun00:00
29 Jun01:00
29 Jun02:00
29 Jun03:00
29 Jun04:00
29 Jun05:00
29 Jun06:00
29 Jun07:00
29 Jun08:00
29 Jun09:00
29 Jun10:00
wind (m/s)
Mfile22
Mfile23
Mfile24
Mfile25
Mfile26
Mfile27
Mfile28
Mfile29
Figure 3: Ground wind speeds from the ambient server database during the MIDI observations.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 11
2.2 Reduction of Dispersion with Linear Fits to Wavenumber
The interferometric phase ϕϕ = n(k)kDi − kDe (1)
measured at wave vectors k = 2πσ at internal (stepped) delays Di, external geometric path delay De
for nominal refractive index n(k) is fitted over the MIDI band width to a model of constant interbandgroup delay [9]
ϕ = ϕ0 + kϕ′. (2)
This is a self-sustained data reduction without “astrometric” support, which means the input isessentially the cosine of ϕ, so ϕ0 is only determined modulo 2π. The algorithm is essentially thetechnique of taking the FT of the interferograms and putting a window around one of the two sidebands that arise from splitting the cosine with the Euler formula [20, §3.4].
Some cleansing of the 2-parametric reduced data is done before display and further use of φ0 and φ′:
• At the start of some MIDI files, the initial time segment shows the behaviour during fringeacquisition, with much larger changes than for the rest of the approximately 2 1/2 minutescovered in total. Chopping off some initial frames of the MIDI exposures—typically a sequenceof fringe acquisition—leads to modified start times of the exposures of Table 2. For exposureswith index 12, Fig. 16, such a simple way of discarding data is not effective and has not beenattempted.
• Some spikes in ϕ′ are removed: frames where ∆ϕ′ differs from the average of the previous 15frames by more than 20 µm are discarded. This removes data which claim an OPD motion ofmore than 20 µm within 0.3 seconds.
• One second is chopped off the end to remove the tail wiggle.
In each of the figures 4–33
• The top 4 plots show data as a function of UTC. Each small vertical bar represents the spreadof values within an individual second, so we have 60 of these per major tic mark on the timeaxis.
• the two plots with ordinate ϕ0 and ϕ′ show the MIDI parameters reduced to ϕ0 (in units ofcycles, ie, 2π) and reduced to ϕ′ (in units of µm) after this removal of some optional initialnumber of frames.
• the plots carrying ordinate units of some powers of mol/m3 summarize the LI-COR measure-ments at its local position (outdoors or tunnel) during that same time. The CO2 densities areas monitored, the water densities transformed with the linear equation (1) of [16] for Lfile6and later. The power spectral density derived for the water vapor is the third plot from below.The enumeration Lfile1—Lfile10 is the same as in [16].
• The MIDI phase fluctuation at λ = 10 µm, the value
ϕ(10µ) ≡ ϕ0 + 2πϕ′/(10µm) (3)
that combines the two variables ϕ0 and ϕ′ of each MIDI frame, is transformed to the PDF of ϕand ϕ0 with ordinate units rad2/Hz. A local maximum in PDFϕ0 near 1.2 Hz with occasionalghosts at multiples seems to be some artifact of the data reduction algorithm, where 1.2 Hz isthe inverse of the period of the sawtooth pattern of the phase shifting internal delay line.
12 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
• In PDF plots, the frequency abscissa axis is accompanied by a second logarithmic axis, whichshows wave numbers
σ ≡ ν/v (4)
in units of inverse meters associated with the frequencies ν by the individual wind velocity vduring that observation (Fig. 3 and Table 1). They are inverse length scales of the densityfluctuations assuming constant speed during the exposure.
As mentioned earlier, the Nyquist frequency of the LI-COR data is 10 Hz, the Nyquist frequency ofthe MIDI data 25 Hz. In all spectra and structure functions, a linear drift term has been removedbefore the Fourier transform; the sub-plots with the data as a function of UTC time show the dataprior to this transformation. The spectra appear noisier than those of Fig. 29–45 in [16] because anadditional averaging on the time axes has been introduced in Fig. 29–45 of [16] for display (but notfor calculation of the derived quantities like autocorrelation and structure function) but not here.
The time axis of LI-COR is a PC clock manually adjusted to UTC, whereas the MIDI exposures areclocked with a GPS based system with sub-second accuracy. A relative shift of the two time axes ofthe order of 2 seconds is expected.1 The PDF of the molecular LI-COR water density is calculatedover the time interval shown in the upper part of the figures. A linear drift has been removed, andthe water density correction (1) of [16] is made for all measurements in the tunnel and in the VST.
1The UTC keyword of the MIDI primary headers does not show the start of the exposures but a time when ISS
received some specific message from the MIDI OS. This is typically 8 seconds ahead of the values of MJD-OBS andOBS-DATE which should be used for accurate reference of the start of exposures.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 13
start ALT AZMfilen (deg) (deg)
0 2007-06-25T23:53:45 42.509 15.8391 2007-06-25T01:42:47 43.512 9.9542 2007-06-26T02:58:30 35.245 13.8493 2007-06-26T03:41:26 69.571 108.7944 2007-06-26T03:49:51 67.571 106.4345 2007-06-26T04:56:20 34.124 321.3016 2007-06-26T05:54:52 62.991 328.0857 2007-06-26T06:35:33 46.294 323.8128 2007-06-26T08:15:27 49.061 269.3639 2007-06-27T01:24:39 52.051 333.53210 2007-06-27T01:50:48 54.498 338.09211 2007-06-27T03:04:53 57.676 25.90612 2007-06-27T04:27:16 30.470 321.10013 2007-06-27T04:32:04 31.209 321.10714 2007-06-27T07:07:04 50.852 327.67915 2007-06-27T07:27:44 54.485 329.78516 2007-06-28T04:50:24 43.570 40.32217 2007-06-28T05:42:53 64.872 122.50618 2007-06-28T06:27:59 47.452 66.85519 2007-06-28T07:15:42 32.262 313.86120 2007-06-28T08:23:59 45.577 130.04621 2007-06-28T09:42:42 30.196 226.21022 2007-06-28T23:51:29 45.663 306.28223 2007-06-29T01:30:03 52.278 307.14724 2007-06-29T02:46:19 71.600 346.12425 2007-06-29T03:58:38 79.934 276.84626 2007-06-29T05:11:20 69.035 31.84327 2007-06-29T05:56:22 81.636 66.87528 2007-06-29T07:02:08 58.453 81.03529 2007-06-29T08:27:07 48.414 75.355
Table 2: Time stamps of the first exposures in the MIDI data files of Table 1 after optional removalof a variable initial portion (of typically up to 550 frames) which show large variation of the delayparameter. ALT and AZ are the pointing coordinates in degrees in the local coordinate system followingDICB conventions, from the FITS headers.
14 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
-200
-150
-100
-50
23:54 23:55 23:56
MID
I ϕ’ (
µm) Mfile0
2.0
3.0
4.0
5.0
ϕ 0 (
cycl
)
UTC 2007 06 25
Mfile0
0.0260.0270.0280.0290.0300.0310.0320.0330.0340.035
LI-C
OR
wat
er (
mol
/m3 )
Lfile3
11.95
12.00
CO
2 (m
mol
/m3 ) Lfile3
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile3
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile0
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile0
Figure 4: Correlation of MIDI data file 0 with LI-COR densities.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 15
-150
-100
-50
0
50
01:43 01:44 01:45
MID
I ϕ’ (
µm) Mfile1
2.0
3.0
4.0
ϕ 0 (
cycl
)
UTC 2007 06 26
Mfile1
0.026
0.027
0.028
0.029
LI-C
OR
wat
er (
mol
/m3 )
Lfile3
11.90
11.95
12.00
CO
2 (m
mol
/m3 ) Lfile3
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile3
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile1
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile1
Figure 5: Correlation of MIDI data file 1 with LI-COR densities.
16 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
-50
0
50
100
150
02:59 03:00 03:01
MID
I ϕ’ (
µm) Mfile2
-2.0
-1.0
0.0
1.0
ϕ 0 (
cycl
)
UTC 2007 06 26
Mfile2
0.027
0.028
0.029
0.030
0.031
LI-C
OR
wat
er (
mol
/m3 )
Lfile3
11.90
11.95
12.00
CO
2 (m
mol
/m3 ) Lfile3
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile3
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile2
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile2
Figure 6: Correlation of MIDI data file 2 with LI-COR densities.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 17
-200
-150
-100
-50
03:42 03:43
MID
I ϕ’ (
µm) Mfile3
1.0
2.0
3.0
ϕ 0 (
cycl
)
UTC 2007 06 26
Mfile3
0.026
0.027
0.028
0.029
0.030
0.031
LI-C
OR
wat
er (
mol
/m3 )
Lfile3
11.90
11.95
12.00
CO
2 (m
mol
/m3 ) Lfile3
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile3
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile3
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile3
Figure 7: Correlation of MIDI data file 3 with LI-COR densities.
18 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
-250
-200
-150 -100
-50
0
03:50 03:51 03:52
MID
I ϕ’ (
µm) Mfile4
2.0
3.0
4.0
ϕ 0 (
cycl
)
UTC 2007 06 26
Mfile4
0.029
0.030
0.031
LI-C
OR
wat
er (
mol
/m3 )
Lfile3
11.90
11.95
12.00
12.05
CO
2 (m
mol
/m3 ) Lfile3
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile3
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile4
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile4
Figure 8: Correlation of MIDI data file 4 with LI-COR densities.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 19
100
150
200
250
04:57 04:58
MID
I ϕ’ (
µm) Mfile5
2.0
3.0
4.0
ϕ 0 (
cycl
)
UTC 2007 06 26
Mfile5
0.028
0.029
0.030
0.031
LI-C
OR
wat
er (
mol
/m3 )
Lfile3
11.90
11.95
12.00
CO
2 (m
mol
/m3 ) Lfile3
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile3
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile5
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile5
Figure 9: Correlation of MIDI data file 5 with LI-COR densities.
20 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
100
150
200
250
300
05:55 05:56 05:57
MID
I ϕ’ (
µm) Mfile6
-1.0
0.0
1.0
2.0
ϕ 0 (
cycl
)
UTC 2007 06 26
Mfile6
0.029
0.030
0.031
0.032
0.033
LI-C
OR
wat
er (
mol
/m3 )
Lfile3
11.90
11.95
12.00
12.05
CO
2 (m
mol
/m3 ) Lfile3
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile3
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile6
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile6
Figure 10: Correlation of MIDI data file 6 with LI-COR densities.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 21
50
100
150
200
250
06:36 06:37 06:38
MID
I ϕ’ (
µm) Mfile7
-2.0
-1.0
0.0
1.0
ϕ 0 (
cycl
)
UTC 2007 06 26
Mfile7
0.0290.0300.0310.0320.0330.0340.0350.0360.0370.038
LI-C
OR
wat
er (
mol
/m3 )
Lfile3
11.90
11.95
12.00
CO
2 (m
mol
/m3 ) Lfile3
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile3
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile7
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile7
Figure 11: Correlation of MIDI data file 7 with LI-COR densities.
22 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
-350
-300
-250 -200
-150
-100
08:16 08:17 08:18
MID
I ϕ’ (
µm) Mfile8
-3.0
-2.0
-1.0
0.0
ϕ 0 (
cycl
)
UTC 2007 06 26
Mfile8
0.0320.0330.0340.0350.0360.0370.0380.0390.0400.0410.042
LI-C
OR
wat
er (
mol
/m3 )
Lfile3
11.90
11.95
12.00
CO
2 (m
mol
/m3 ) Lfile3
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile3
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile8
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile8
Figure 12: Correlation of MIDI data file 8 with LI-COR densities.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 23
1150
1200
1250
1300
1350
01:25 01:26 01:27
MID
I ϕ’ (
µm) Mfile9
-3.0 -2.0 -1.0 0.0 1.0 2.0 3.0
ϕ 0 (
cycl
)
UTC 2007 06 27
Mfile9
0.101
0.102
0.103
0.104
0.105
0.106
LI-C
OR
wat
er (
mol
/m3 )
Lfile5
11.75
11.80
11.85
CO
2 (m
mol
/m3 ) Lfile5
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile5
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile9
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile9
Figure 13: Correlation of MIDI data file 9 with LI-COR densities.
24 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
1200
1250
1300
1350
1400
01:51 01:52 01:53
MID
I ϕ’ (
µm) Mfile10
-1.0 0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0
ϕ 0 (
cycl
)
UTC 2007 06 27
Mfile10
0.105
0.106
0.107
0.108
LI-C
OR
wat
er (
mol
/m3 )
Lfile5
11.75
11.80
11.85
CO
2 (m
mol
/m3 ) Lfile5
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile5
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile10
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile10
Figure 14: Correlation of MIDI data file 10 with LI-COR densities.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 25
1500
1550
1600
1650
1700
03:05 03:06 03:07
MID
I ϕ’ (
µm) Mfile11
-3.0
-2.0
-1.0 0.0
1.0
2.0
ϕ 0 (
cycl
)
UTC 2007 06 27
Mfile11
0.1030.1040.1050.1060.1070.1080.109
LI-C
OR
wat
er (
mol
/m3 )
Lfile5
11.80
11.85
CO
2 (m
mol
/m3 ) Lfile5
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile5
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile11
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile11
Figure 15: Correlation of MIDI data file 11 with LI-COR densities.
26 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
-250 -200 -150 -100 -50 0
50 100 150 200
04:28 04:29
MID
I ϕ’ (
µm) Mfile12
1.0 2.0 3.0 4.0 5.0 6.0 7.0 8.0 9.0
10.0
ϕ 0 (
cycl
)
UTC 2007 06 27
Mfile12
0.119
0.120
0.121
0.122
0.123
0.124
LI-C
OR
wat
er (
mol
/m3 )
Lfile5
11.75
11.80
11.85
CO
2 (m
mol
/m3 ) Lfile5
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile5
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile12
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile12
Figure 16: Correlation of MIDI data file 12 with LI-COR densities.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 27
-100
-50
0 50
100
150
04:33 04:34
MID
I ϕ’ (
µm) Mfile13
-2.0 -1.0 0.0 1.0 2.0 3.0 4.0
ϕ 0 (
cycl
)
UTC 2007 06 27
Mfile13
0.118
0.119
0.120
0.121
0.122
LI-C
OR
wat
er (
mol
/m3 )
Lfile5
11.75
11.80
11.85
CO
2 (m
mol
/m3 ) Lfile5
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile5
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile13
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile13
Figure 17: Correlation of MIDI data file 13 with LI-COR densities.
28 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
1200
1250
1300
1350
07:08 07:09
MID
I ϕ’ (
µm) Mfile14
0.0
1.0
2.0
3.0
ϕ 0 (
cycl
)
UTC 2007 06 27
Mfile14
0.107
0.108
0.109
0.110
0.111
0.112
LI-C
OR
wat
er (
mol
/m3 )
Lfile5
11.75
11.80
11.85
CO
2 (m
mol
/m3 ) Lfile5
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile5
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile14
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile14
Figure 18: Correlation of MIDI data file 14 with LI-COR densities.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 29
1300
1350
1400
07:28 07:29 07:30
MID
I ϕ’ (
µm) Mfile15
-1.0
0.0
1.0
2.0
3.0
ϕ 0 (
cycl
)
UTC 2007 06 27
Mfile15
0.108
0.109
0.110
0.111
LI-C
OR
wat
er (
mol
/m3 )
Lfile5
11.75
11.80
11.85
CO
2 (m
mol
/m3 ) Lfile5
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile5
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile15
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile15
Figure 19: Correlation of MIDI data file 15 with LI-COR densities.
30 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
-500
-450
-400
04:51 04:52
MID
I ϕ’ (
µm) Mfile16
-1.0
0.0
1.0
ϕ 0 (
cycl
)
UTC 2007 06 28
Mfile16
0.123
0.124
0.125
0.126
0.127
0.128
LI-C
OR
wat
er (
mol
/m3 )
Lfile6
10.20
10.25
10.30
10.35
CO
2 (m
mol
/m3 ) Lfile6
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile6
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile16
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile16
Figure 20: Correlation of MIDI data file 16 with LI-COR densities. The water densities in Figs. 20–33 are those reduced with Equation (1) of [16]. The wavenumber scale ν/v on the LI-COR densitiesdoes not make much sense in these figures because they have been measured in the tunnel and arescaled here with the weather pole wind velocity.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 31
-800
-750
-700
-650
05:43 05:44 05:45
MID
I ϕ’ (
µm) Mfile17
-4.0
-3.0
-2.0
ϕ 0 (
cycl
)
UTC 2007 06 28
Mfile17
0.127
0.128
0.129
0.130
0.131
LI-C
OR
wat
er (
mol
/m3 )
Lfile6
10.35
10.40
10.45
CO
2 (m
mol
/m3 ) Lfile6
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile6
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile17
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile17
Figure 21: Correlation of MIDI data file 17 with LI-COR densities. Note that the wavenumber scaleon the LI-COR densities does not make much sense here because they have been measured in thetunnel and are scaled here with the weather pole wind velocity.
32 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
-800
-750
-700
06:28 06:29 06:30
MID
I ϕ’ (
µm) Mfile18
-3.0
-2.0
-1.0
ϕ 0 (
cycl
)
UTC 2007 06 28
Mfile18
0.145
0.146
0.147
LI-C
OR
wat
er (
mol
/m3 )
Lfile6
10.05
10.10
10.15
CO
2 (m
mol
/m3 ) Lfile6
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile6
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile18
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile18
Figure 22: Correlation of MIDI data file 18 with LI-COR densities. Note that the wavenumber scaleon the LI-COR densities does not make much sense here because they have been measured in thetunnel and are scaled here with the weather pole wind velocity.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 33
-750
-700
-650
-600
-550
07:16 07:17 07:18
MID
I ϕ’ (
µm) Mfile19
-1.0
0.0
1.0
2.0
ϕ 0 (
cycl
)
UTC 2007 06 28
Mfile19
0.137
0.138
0.139
LI-C
OR
wat
er (
mol
/m3 )
Lfile6
10.25
10.30
10.35
10.40
CO
2 (m
mol
/m3 ) Lfile6
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile6
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile19
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile19
Figure 23: Correlation of MIDI data file 19 with LI-COR densities. Note that the wavenumber scaleon the LI-COR densities does not make much sense here because they have been measured in thetunnel and are scaled here with the weather pole wind velocity.
34 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
-1050
-1000
-950
-900
08:24 08:25 08:26
MID
I ϕ’ (
µm) Mfile20
-1.0
0.0
1.0
2.0
ϕ 0 (
cycl
)
UTC 2007 06 28
Mfile20
0.136
0.137
0.138
0.139
0.140
LI-C
OR
wat
er (
mol
/m3 )
Lfile6
10.20
10.25
10.30
CO
2 (m
mol
/m3 ) Lfile6
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile6
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile20
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile20
Figure 24: Correlation of MIDI data file 20 with LI-COR densities. Note that the wavenumber scaleon the LI-COR densities does not make much sense here because they have been measured in thetunnel and are scaled here with the weather pole wind velocity.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 35
-550 -500 -450 -400 -350 -300 -250 -200
09:43 09:44 09:45
MID
I ϕ’ (
µm) Mfile21
-1.0
0.0
1.0 2.0
3.0
4.0
ϕ 0 (
cycl
)
UTC 2007 06 28
Mfile21
0.115
0.116
0.117
0.118
LI-C
OR
wat
er (
mol
/m3 )
Lfile6
10.40
10.45
10.50
10.55
CO
2 (m
mol
/m3 ) Lfile6
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile6
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile21
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile21
Figure 25: Correlation of MIDI data file 21 with LI-COR densities. Note that the wavenumber scaleon the LI-COR densities does not make much sense here because they have been measured in thetunnel and are scaled here with the weather pole wind velocity. The origin of the sudden piston near09:43:40 and of the even more obvious hub in Fig. 27 is unknown.
36 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
1500
1550
1600
1650
1700
23:52 23:53 23:54
MID
I ϕ’ (
µm) Mfile22
-7.0 -6.0 -5.0 -4.0 -3.0 -2.0 -1.0
ϕ 0 (
cycl
)
UTC 2007 06 28
Mfile22
0.0900.0910.0920.0930.0940.0950.0960.097
LI-C
OR
wat
er (
mol
/m3 )
Lfile8
10.75
10.80
10.85
CO
2 (m
mol
/m3 ) Lfile8
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile8
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile22
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile22
Figure 26: Correlation of MIDI data file 22 with LI-COR densities.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 37
1400 1450 1500 1550 1600 1650 1700
01:31 01:32
MID
I ϕ’ (
µm) Mfile23
-3.0
-2.0
-1.0
0.0
ϕ 0 (
cycl
)
UTC 2007 06 29
Mfile23
0.084
0.085
0.086
0.087
0.088
0.089
LI-C
OR
wat
er (
mol
/m3 )
Lfile8
10.80
10.85
CO
2 (m
mol
/m3 ) Lfile8
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.001 0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile8
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile23
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile23
Figure 27: Correlation of MIDI data file 23 with LI-COR densities.
38 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
2300
2350
2400
02:47 02:48
MID
I ϕ’ (
µm) Mfile24
-1.0
0.0
1.0
ϕ 0 (
cycl
)
UTC 2007 06 29
Mfile24
0.086
0.087
0.088
LI-C
OR
wat
er (
mol
/m3 )
Lfile8
10.80
10.85
10.90
CO
2 (m
mol
/m3 ) Lfile8
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile8
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile24
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile24
Figure 28: Correlation of MIDI data file 24 with LI-COR densities.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 39
2100
2150
2200
2250
03:59 04:00 04:01
MID
I ϕ’ (
µm) Mfile25
0.0
1.0
2.0
3.0
ϕ 0 (
cycl
)
UTC 2007 06 29
Mfile25
0.094
0.095
0.096
0.097
LI-C
OR
wat
er (
mol
/m3 )
Lfile8
10.80
10.85
10.90
CO
2 (m
mol
/m3 ) Lfile8
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile8
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile25
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile25
Figure 29: Correlation of MIDI data file 25 with LI-COR densities.
40 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
1900
1950
2000
2050
05:12 05:13
MID
I ϕ’ (
µm) Mfile26
1.0
2.0
3.0
ϕ 0 (
cycl
)
UTC 2007 06 29
Mfile26
0.098
0.099
0.100
0.101
0.102
LI-C
OR
wat
er (
mol
/m3 )
Lfile8
10.80
10.85
10.90
CO
2 (m
mol
/m3 ) Lfile8
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile8
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile26
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile26
Figure 30: Correlation of MIDI data file 26 with LI-COR densities.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 41
2350
2400
2450
2500
2550
05:57 05:58
MID
I ϕ’ (
µm) Mfile27
0.0
1.0
2.0
3.0
ϕ 0 (
cycl
)
UTC 2007 06 29
Mfile27
0.100
0.101
0.102
0.103
LI-C
OR
wat
er (
mol
/m3 )
Lfile8
10.80
10.85
10.90
CO
2 (m
mol
/m3 ) Lfile8
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile8
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile27
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile27
Figure 31: Correlation of MIDI data file 27 with LI-COR densities.
42 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
2650
2700
2750
07:03 07:04
MID
I ϕ’ (
µm) Mfile28
-2.0
-1.0
0.0
ϕ 0 (
cycl
)
UTC 2007 06 29
Mfile28
0.0940.0950.0960.0970.0980.0990.1000.1010.1020.1030.1040.105
LI-C
OR
wat
er (
mol
/m3 )
Lfile8
10.80
10.85
10.90
CO
2 (m
mol
/m3 ) Lfile8
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile8
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile28
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile28
Figure 32: Correlation of MIDI data file 28 with LI-COR densities.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 43
2450
2500
2550
08:28
MID
I ϕ’ (
µm) Mfile29
-2.0
-1.0
0.0
1.0
ϕ 0 (
cycl
)
UTC 2007 06 29
Mfile29
0.100
0.101
0.102
0.103
LI-C
OR
wat
er (
mol
/m3 )
Lfile8
10.80
10.85
10.90
CO
2 (m
mol
/m3 ) Lfile8
1e-10
1e-8
1e-6
0.01 0.1 1 10
0.01 0.1 1
PD
F (
(mol
/m3 )2 /H
z)
ν/v (1/m)
Lfile8
1e-2
1e+0
1e+2
0.01 0.1 1 10
PD
Fϕ
(rad
2 /Hz) Mfile29
0.0010.010.1
110
100
0.01 0.1 1 10
PD
Fϕ 0
(ra
d2 /Hz)
ν (Hz)
Mfile29
Figure 33: Correlation of MIDI data file 29 with LI-COR densities.
44 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
Figures 34–36 show the structure function of ϕ0 or ϕ′ for Mfile25–Mfile28 after flagging of weakpoints.
Figure 34: Dϕ0 in units of rad2.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 45
Figure 35: Dϕ0 in units of rad2. The detector cycle time has been the same for all 30 runs, and isnot any different for run 5 shown here (see page 5). It is therefore not possible to evaluate from thedata in this report whether the oscillations are an artifact of instrumental hardware, or some part ofthe data evaluation, for example Gibb’s oscillations of some Fourier Transform.
Figure 36: Dϕ′ in units of µm2.
46 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 47
3 COMPARISON INTERFEROMETRY AND GAS ANALYZER
3.1 Refractive Index Model
An instrument like MIDI with some spectral dispersion may differentiate the chemical componentsin the optical paths if their refractive indices offer sufficient differences in the instrument’s spectralband. We employ a linearized phase model of the dispersion [4]
kχdry(λ) = adry + bdryk; kχwet(λ) = awet + bwetk. (5)
We use the variables χ for the susceptibility, and χ for its value (“intrinsic” polarizability) dividedby the molecular number density. Differentiation of (5) with respect to k shows that the parametersbdry and bwet represent the augmented group refractive indices ng−1 [14, (7)] divided by the numberdensities.2
Numerical examples of the theory are shown in Fig. 37, Fig. 38 and 39. The coefficients in the fitsquoted there are supposedly all proportional to the densities—that is, for our purposes here we mayignore the higher-order effects [15] because we do not need to achieve astrometric accuracy—and aredivided through the partial pressures to generate the intrinsic, density-independent numbers.3
In the N-band, the intrinsic linear fitting coefficients are
bdry ≈2.0485× 10−4
31.771mol ·m−3≈ 6.45× 10−6 m3
mol; bwet ≈
1.3224× 10−6
0.166mol ·m−3≈ 7.97× 10−6 m3
mol(6)
adry ≈−3.608× 10−4cm−1
31.771mol ·m−3≈ −1.14×10−5 m3
mol · cm; awet ≈
−4.21× 10−3cm−1
0.166mol ·m−3≈ −2.53×10−2 m3
mol · cm(7)
This means the two b coefficients (inclinations of the fit) are almost the same for the two components,whereas the a coefficients (constant terms, axis intersections) differ by a factor of 2× 103—on a per-molecule basis.
2This means (5) is the solution to the differential equation ng(k) ≡ n(k) + kdn/dk = b, assigning a constant grouprefractive index ng = 1 + b to the dispersion.
3Doing this quickly is supported by the water vapor saturation curve, Fig. 37 in [13] and the GUI in http://www.
strw.leidenuniv.nl/~mathar/progs/prWaterWeb.html.
48 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
0.0e+00
1.0e-07
2.0e-07
3.0e-07
4.0e-07
5.0e-07
6.0e-07
7.0e-07
8.0e-07
9.0e-07
1.0e-06
0 200 400 600 800 1000 1200 1400
n-1
wavenumber σ(cm-1)
393.7 Pa pure H2O, 285.15 K, 0.166 mole/m3
0.000
0.001
0.002
0.003
0.004
0.005
0.006
0.007
0.008
0.009
0 200 400 600 800 1000 1200 1400
(n-1
)k (
rad/
cm-1
)
wavenumber σ(cm-1)
393.7 Pa pure H2O, 285.15 K, 0.166 mole/m3
Figure 37: Upper plot: pure water vapor susceptibility χwet at an average ambient partial pressurein the N band. Lower plot: product of this susceptibility χwet and k = 2π/λ = 2πσ. A linear fit tothe lower plot is χk = −4.21× 10−3cm−1 + 1.3224× 10−6k, which means the group refractive indexis 1 + 1.3224 × 10−6 and “enhanced” by a factor of two relative to the 1 + 6.5 × 10−7 of the phaserefractive index of the upper plot.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 49
0.0e+00
5.0e-05
1.0e-04
1.5e-04
2.0e-04
2.5e-04
0 200 400 600 800 1000 1200 1400
n-1
wavenumber σ(cm-1)
75286.9 Pa dry air, 285.15 K, 31.771 mole/m3
0.0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
0 200 400 600 800 1000 1200 1400
(n-1
)k (
rad/
cm-1
)
wavenumber σ(cm-1)
75286.9 Pa dry air, 285.15 K, 31.771 mole/m3
Figure 38: Upper plot: dry air susceptibility χdry in the N band at a typical Paranal pressure.Lower plot: product of this susceptibility χdry and k = 2π/λ = 2πσ. A linear fit to the lower plot isχk = −3.608×10−4cm−1+2.0485×10−4k, which means the group refractive index is 1+2.0485×10−4
and close to the phase refractive index of the upper plot.
50 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
0.0e+00
2.0e-08
4.0e-08
6.0e-08
8.0e-08
1.0e-07
1.2e-07
1.4e-07
0 200 400 600 800 1000 1200 1400
n-1
wavenumber σ(cm-1)
27.4 Pa pure CO2, 289.15 K, 0.0113 mole/m3
0
0.0002
0.0004
0.0006
0.0008
0.001
0.0012
0 200 400 600 800 1000 1200 1400
(n-1
)k (
rad/
cm-1
)
wavenumber σ(cm-1)
27.4 Pa pure CO2, 289.15 K, 0.0113 mole/m3
Figure 39: Upper plot: pure CO2 susceptibility χc at a typical partial pressure in the N band. Lowerplot: product of this susceptibility χc and k = 2π/λ = 2πσ. Each molecule of Carbon Dioxide hasa polarizability which is approximately 1.53 times the polarizability of the average air molecule, inaccordance with 10.5 µm measurements [12, Tabl 2].
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 51
3.2 Structure Functions and Fried Parameter
Density fluctuations C2ρ are converted to line-of-sight-integrated refractive index structure functions
and corresponding phase structure functions Dϕ with
C2n = C2
ρ χ2; (8)
Dϕ = k2χ2C(0)(α)C2ρKP 1+α/ sin a (9)
at scale height K, projected baseline length P , Kolmogorov power α = 2/3, and star altitude a abovethe horizon. The sum of the fits (5) for the product kχ at k = 2π/(10 µm), and the definition of theFried parameter r0 [5, (6.3)] yield
Dϕ = (kχ)2C(0)(α)C2ρKP 1+α/ sin a = 6.884(P/r0)1+α. (10)
The constants are C(0)(α) = 2.914 [17] and kχ ≈ (−2.53 + 7.97× 10−62π/1× 10−5 − 1.14× 10−3 +6.45× 10−62π/1× 10−5) m2/mol ≈ 6.5 m2/mol as discussed in the other parts of the manuscript.
r0 =
(6.884 sin a
(kχ)2C(0)(α)C2ρK
)3/5
≈ 0.176
(sin a
C2ρK
)3/5mol6/5
m12/5. (11)
The fit of the water structure functions DH2O to a Kolmogorov 2/3 power law within the spatialdistances from 1 to 10 m is illustrated in Figure 40.4 On doubly-logarithmic axes, these are straight-line fits with fixed inclination. For Mfile16–Mfile21 this computation is skipped because the LICORmeasurements occurred in the VLTI tunnel during these observations.
4The only difference to Table 2 in [16] is that 4 hours of observation were summarized there, whereas the observationshere cover approximately 2 minutes each.
52 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
1e-08
1e-07
1e-06
1 10
DH
2O (
(mol
e/m
3 )2 )
∆x (m)
012345678
1e-08
1e-07
1e-06
1 10∆x (m)
9101112131415
1e-08
1e-07
1e-06
1 10
DH
2O (
(mol
e/m
3 )2 )
∆x (m)
2223242526272829
Figure 40: Kolmogorov fits to the LICOR water vapor structure functions. One panel is shown pernight, curves enumerated with the file numbers as in Table 3. The colored curves are the structurefunctions; the black straight lines are the fits ∝ (∆x)2/3, each with C2
H2O as the single free parameter.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 53
The procedure is repeated for the carbon dioxide data in Figure 41. The structure function is flatterthan the exponent 2/3 if DCO2 is small, particularly in the fourth night. The main reason for this isuncovered in Figure 42: the digitization of the LI-COR data is quantized in units of 10−5 mol/m3,which leads to a constant, distance-independent background noise level of 10−10 (mol/m3)2 in thestructure function. At the 1 Hz time intervals at which the fit is attempted here, this is most ofthe value of the structure function itself, and not providing information on the actual air densityfluctuations.
In detail, the connection between the density and refractive index structure functions is with (8) andscaling with C2
dry/C2CO2 = 1/(3.8× 10−4)2,
C2n =
(2.04× 10−4
31.771m3
mol
)2
C2dry ≈ 4.1× 10−11 m6
mol2C2
dry ≈ 2.9× 10−4 m6
mol2C2
CO2. (12)
For Paranal, C2n is in the range 5× 10−17/m2/3 –5× 10−16/m2/3 [3], which means the expected range
of C2CO2 is from 2 × 10−13/m2/3 to 2 × 10−12/m2/3, not 1 × 10−11/m2/3. If we reverse-engineer the
C2dry from the R0 MEAN data of the primary FITS headers at 500 nm with (11) for all 30 MIDI files,
C2dry =
6.884
r5/30
sin a
K
1k2χ2C(0)(α)
, (13)
a maximum of 4.75 × 10−6/m2/3 is found at MFILE22. Multiplied by (3.8 × 10−4)2 to extrapolateto the 380 ppm level of CO2, C2
CO2 is actually not supposed to be larger than 7 × 10−13/m2/3, inobvious discrepancy with the naıve fits to the noise level of the LI-COR CO2 data in Table 3.
54 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
1e-11
1e-10
1 10
DC
O2
((m
ole/
m3 )2 )
∆x (m)
012345678
1e-11
1e-10
1 10∆x (m)
9101112131415
1e-11
1e-10
1 10
DC
O2
((m
ole/
m3 )2 )
∆x (m)
2223242526272829
Figure 41: Kolmogorov fits to the LICOR CO2 vapor structure functions. One panel is shown pernight, curves enumerated with the file numbers as in Table 3. The colored curves are the structurefunctions; the black straight lines are the fits ∝ (∆x)2/3, each with C2
CO2 as the single free parameter.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 55
11.960
11.970
11.980
11.990
12.000
CO
2 (m
mol
/m3 ) Mfile0, Lfile3
0.026 0.027 0.028 0.029 0.030 0.031 0.032 0.033 0.034 0.035
H2O
(m
ol/m
3 )
Mfile0, Lfile3
11.920
11.930
11.940
11.950
11.960
11.970
11.980
CO
2 (m
mol
/m3 ) Mfile1, Lfile3
0.026
0.027
0.028
0.029
20 40 60 80 100 120 140 160
H2O
(m
ol/m
3 )
time since MJD-OBS (sec)
Mfile1, Lfile3
Figure 42: These replots of the LI-COR molar densities of Figures 4 and 5 demonstrate that adigitization (quantisation) noise of 1× 10−5 mol/m3 is inherent (and dominant at short time scales)to the CO2 measurements, and a noise of 5×10−5 mol/m3 is inherent (and relatively less important)to the water measurements.
56 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
The fitted C2ρ for water and carbon dioxide are gathered in Table 3 in the columns C2
H2O and C2CO2—
although the latter is not of any value as discussed above.
• R0 MEAN is the mean of the two COU A01 and COU A02 values of the primary FITS headers scaledfrom 500 nm to 10 µm proportional to λ6/5 [18, Table I]. Although the RO MEAN of the VLTI
FITS headers are essentially undocumented in DICB’s ESO-VLT-DIC.COU, we assume that thisis the value for pointing to the zenith.
• The column αv is the platform wind direction (primary header keyword WINDDIR) relative tothe baseline direction (ie, 111 and 40 degrees from North for the two UT baselines) reducedto the interval from 0 to 90 degrees. As expected from the dominant seasonal wind directionon Paranal, the U23 baseline of the second and fourth night is better aligned with the winddirection than the U34 baseline of the first and third night.
• The column v⊥ is the component of the wind vector (derived from WINDDIR and the WINDSPof Table 1 assumed horizontal) perpendicular to the pointing direction, i.e., parallel to theprojected baseline. (The latter is obtained from ALT and AZ of Table 2. If pointing were to thezenith, v⊥ would be |v cos Av|.)
• The column Av is the pointing direction relative to the wind direction—difference betweenWINDDIR and AZ if converted to a common coordinate system—reduced to the interval [0◦,180◦].0 refers to pointing into the wind, which is the worst case of shaking the main telescopestructures [8].
• The column ρwet is the mean water number density reading of the LI-COR instrument over theexposure time, corrected as documented [16], outdoors or in the tunnel.
• The column C2dry is the dry air fluctuation derived from the R0 MEAN keyword of the primary
FITS header via (13), the scale height guessed at K = 9600 m.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 57
R0 MEAN αv v⊥ C2H2O C2
CO2 Av ρwet C2dry
Mfilen (m) (deg) (m/s) (mol2/m20/3) (mol2/m20/3) (deg) (mol/m3) (m2/3)0 4.37 15 11.57 2.13× 10−7 1.15× 10−11 110 0.030 8.76× 10−7
1 4.24 31 11.34 4.42× 10−9 7.98× 10−12 132 0.027 9.37× 10−7
2 3.35 55 9.23 1.38× 10−8 1.50× 10−11 152 0.029 1.17× 10−6
3 6.32 57 10.25 1.85× 10−8 1.83× 10−11 59 0.030 6.56× 10−7
4 5.75 59 10.37 8.26× 10−9 1.63× 10−11 64 0.030 7.58× 10−7
5 3.35 61 10.10 1.25× 10−8 1.58× 10−11 149 0.029 1.13× 10−6
6 3.44 75 6.39 3.09× 10−8 2.61× 10−11 142 0.031 1.72× 10−6
7 3.08 83 7.69 2.76× 10−7 3.51× 10−11 130 0.034 1.68× 10−6
8 3.15 87 8.05 1.51× 10−7 2.77× 10−11 65 0.036 1.69× 10−6
9 2.93 2 15.28 3.42× 10−8 2.61× 10−11 116 0.104 1.99× 10−6
10 3.17 6 13.11 1.36× 10−8 1.73× 10−11 124 0.107 1.80× 10−6
11 2.59 9 10.76 3.13× 10−8 1.36× 10−11 157 0.106 2.62× 10−6
12 2.48 8 15.87 1.56× 10−8 1.30× 10−11 93 0.121 1.70× 10−6
13 2.75 6 15.98 1.48× 10−8 1.08× 10−11 95 0.120 1.46× 10−6
14 3.68 4 14.89 8.83× 10−9 1.06× 10−11 104 0.110 1.34× 10−6
15 3.68 8 16.35 7.02× 10−9 1.16× 10−11 102 0.110 1.40× 10−6
16 7.10 65 11.70 136 0.125 3.98× 10−7
17 7.76 77 9.20 65 0.129 4.51× 10−7
18 6.68 83 9.43 127 0.146 4.70× 10−7
19 5.70 85 8.78 108 0.138 4.45× 10−7
20 4.19 71 8.43 90 0.138 9.93× 10−7
21 2.46 62 8.59 3 0.117 1.70× 10−6
22 3.28 1 9.12 7.69× 10−8 1.18× 10−11 87 0.095 4.75× 10−6
23 4.62 2 9.80 1.37× 10−8 1.40× 10−11 89 0.086 9.32× 10−7
24 6.34 24 4.68 6.19× 10−9 1.15× 10−11 150 0.087 6.61× 10−7
25 4.95 23 7.60 7.96× 10−9 1.77× 10−11 80 0.095 1.03× 10−6
26 4.62 28 3.32 1.61× 10−8 1.83× 10−11 160 0.100 1.10× 10−6
27 5.68 18 5.56 4.72× 10−9 1.18× 10−11 135 0.101 8.27× 10−7
28 4.55 18 5.84 3.12× 10−7 1.70× 10−11 121 0.100 1.03× 10−6
29 4.22 2 5.47 2.79× 10−8 1.64× 10−11 147 0.102 1.03× 10−6
Table 3: Parameters of the 30 MIDI data sets—continued from Tables 1 and 2. The meaning ofcolumns is detailed on page 56.
58 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
3.3 Power Spectra of Phases
The conversion of C2ρ to predicted power spectra of the phase fluctuations is done with the Clifford
formula (last line of Table 1 in [1]),
PDFϕ(ν) = 0.06601k2 K
sin aC2
nv5/3⊥ [1− cos(2πPν/v⊥)]ν−8/3 (14)
where 0.06601 = Γ(8/3) sin(π/3)/(2π2) [17], where v⊥ is in Table 3, P the projected baseline of Table1, and the air mass in Table 1 or the reciprocal sine of the altitude of table 2.
Supposed the water vapor and dry air contributions to the statistics are independent and add inquadrature, the factor in (14) is replaced by
k2KC2n = k2KwetC
2n,wet + k2KdryC
2n,dry = k2χ2
wetKwetC2H2O + k2χ2
dryKdryC2dry (15)
with Kwet ≈ 1660 m, Kdry ≈ 9600 m (Fig. 25 in [13]), and kχ as in (5).
The synopsis of these predictions from the water vapor fluctuations (red) or all contributions (blue)compared to the individual MIDI fringe tracker data of Figures 4, 5, 6,. . . ,33 (green) follows in Figures44–46.
• The predictions (red) constructed/extrapolated from LI-COR water vapor fluctuations aretypically a factor 100 too small.
• The predictions (blue) constructed from re-interpretation of the R0 MEAN keywords of the FITS
headers (blue) via (13)—essentially not using any LI-COR data and therefore out-of-topic forthis report here—are approximately correct in the frequency range up to 5 Hz.
The expected discrepancy is at most a factor of 2, because the contribution of various surface vi-brations within the VLTI train to the PDF [8] of ϕ—as estimated in Fig. 43—is typically less thanthe expected contribution of the fluctuations of the ambient air humidity, supposed that the mirrorvibrations of the VLTI mirror train, including effects of the MDL and responses of mirrors driven byIRIS, are negligible.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 59
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
ν (Hz)
r00-05-11-17r00-05-11-19r00-05-11-20r00-05-11-22r00-05-11-24r00-05-11-34r00-05-12-05r00-05-15-07r00-05-17-14
Figure 43: Contribution of some VLT mirror vibrations up to M6 to the PDF of the 10 µm phase.Values from [8] measured with UT3 under various conditions of activities of motors and pumps havebeen halved to account for an undocumented, presumably 1-sided definition of the spectra, thendoubled to account for an (again undocumented) overlay of 2 telescope mirror trains, and scaledwith k2 = 4π2/λ2 ≈ 4× 1011 m2 to transform lengths to phases.
60 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile0wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile1wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile2wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile3wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile4wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile5wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile6wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile7wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile8wet
wet+dry
Figure 44: Comparison of the Clifford model (14) with the measured PDFs of the 10 µm phases ofthe first night. The numbers of (14) have been halved to account for the fact that the Clifford model(presumably) uses 1-sided PDFs.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 61
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile9wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile10wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile11wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile12wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile13wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile14wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile15wet
wet+dry
Figure 45: Continued from figure 44 into the second night of MIDI observations.
62 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile22wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile23wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile24wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile25wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile26wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile27wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile28wet
wet+dry
0.0001
0.001
0.01
0.1
1
10
1 10
PD
Fϕ
(rad
2 /Hz)
Hz
Mfile29wet
wet+dry
Figure 46: Continued from figure 45 covering the fourth night of MIDI observations. Mfile23 isessentially to be ignored because it is contaminated by the bi-stable sudden 100 µm jump of ϕ′ inFig. 27.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 63
3.4 Phases Extrapolated to Zero Wavenumber
If one decomposes the intrinsic air refractive index
n = 1 + ρdryχdry + ρwetχwet (16)
as in Section 3.1,kχdry = adry + bdryk; kχwet = awet + bwetk, (17)
equations (1)–(2) are the associations
ϕ0 = ρdryadryDt + ρwetawetDt (18)
andϕ′ = Dt + ρdrybdryDt + ρwetbwetDt −De (19)
between observed and theoretical parameters. The full meaning of terms like ρdryDt is∫1 ρdrydl −∫
2 ρdrydl, the difference between two path integrals for telescopes 1 and 2 over atmosphere and tunnelup to the detector. None of these two variables is actually correlated with the De of Table 1: ϕ0
contains arbitrary offsets in units of 2π, and ϕ′ is kept close to zero by group delay tracking.
ρwetawet and ρdryadry are typically −0.42 1/m and −0.036 1/m (Figs. 37, 38). The benefit of ex-trapolation of the phases to zero wavenumber, represented by ϕ0, is that statistical variations of DL
mirrors or AO optics up to some δDi ≈ 1 mm could at most change this wave-number independentcomponent of the phase on sub-milli-radian scales. One has essentially found a parameter that isvery insensitive to incoherent vibrations and motions of the two beam’s optical subsystems and DL
carriages, but still sensitive to the differential water-column over which the two beams integrate whiletraveling through the atmosphere.
The 2D phase structure function Dϕ is related to the 3D structure function Dn of the refractive indexas [5, 7]
Dϕ(ξ) = KC(0)(α)k2Dnξ, (20)
where ξ = vt is the projected lateral distance across the pupil, C(0)(α) a numerical factor dependingon the exponent α that describes the growth of the 3D structure function, K the distance over whichthe phase is integrated along the line of sight, and k = 2πσ the momentum number of the radiation.Splitting the refractive index into the zero-extrapolated awet,dry and slopes bwet,dry decomposes theprevious equation into
Dϕ(ξ) = Dϕ0(ξ) + k2Dϕ′(ξ)︸ ︷︷ ︸∝k2
+Dab︸︷︷︸∝k
. (21)
So we look only at the component of
k2Dn = k2(χ2dryDρ,dry + χ2
wetDρ,wet) = k2(χ2dryDρ,dry + χ2
wetDρ,wet) (22)
of (20) which is independent of k
Dϕ0(ξ) = KC(0)(α)(a2wetDH2O + a2
dryDdry)ξ. (23)
Here K ≈ 1660 m (Figure 59 in [13]), C(2/3) ≈ 2.9 and a2wet ≈ (2.53 × 10−2)2m6/(mol2cm2) ≈
6.4m4/mol2 (eq (7)), therefore KC(2/3)a2wet ≈ 3.1× 104 m5/mol2.
64 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
Figs. 47–50 show the correlation between the ϕ′ and ϕ0 values, one figure per night, one panel perexposure. The first 2000 frames of each exposure are shown with red plusses, the 2nd 2000 frameswith green crosses, the 3rd 2000 frames with blue boxes, and the final set of frames (none left overin this category for Mfile19 and Mfile29 which were shorter) magenta squares. This are painted ontop of each other; so the read portions tend to be hidden by the latter data if all of them stay close.
The model of air dominated phase fluctuations predicts a correlation between ϕ0 and ϕ′ with anegative slope, which means a change of the overall air density modifies the (positive) slope of thebottom of Figures 37 and 38 by the same factor as their (negative) intersection. This explains whythe point spread functions in Figs. 47–50 are tilted: For water-dominated fluctuations the slope ispredicted as
ϕ0
ϕ′=
awet
bwet=−4.21× 10−1m−1
1.3224× 10−6≈ −31.8/(100µm), (24)
and for dry-air dominated fluctuations it is
ϕ0
ϕ′=
adry
bdry=−3.608× 10−2m−1
2.0485× 10−4≈ −0.0176/(100µm), (25)
the latter too small to be distinguishable from the zero of mirror surface fluctuations.
This could be used to separate the components [4]: The actual slopes are smaller than −5/(100µm)during the very dry first night, Fig. 47, around −10/(100µm) during the second and fourth nightof average humidity, Figs. 48+50, and largest, around −12/(100µm) for the slightly wetter thirdnight, Fig. 49. These estimates confirm that the slope of ϕ0/ϕ′ is sensitive to the water content inthe air—the VLTI is indeed an (expensive) hygrometer, the negative aspect is that either the jittersin the reflecting mirror surfaces or the contribution of the dry air fluctuations do contribute to thefringe motion substantially, as the value of ϕ0/ϕ′ near −32/(100µm) of (24) is not reached.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 65
15
20
25
30
-200 -100
ϕ 0 (
rad)
Mfile0
10
15
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25
-100 0
ϕ 0 (
rad)
Mfile1
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-5
0
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0 100
ϕ 0 (
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Mfile2
0
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ϕ 0 (
rad)
Mfile3
10
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ϕ 0 (
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rad)
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-5
0
5
10
100 200
ϕ 0 (
rad)
Mfile6
-10
-5
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5
100 200
ϕ 0 (
rad)
ϕ’ (µm)
Mfile7
-15
-10
-5
0
-300 -200
ϕ 0 (
rad)
ϕ’ (µm)
Mfile8
Figure 47: Correlation between ϕ′ and ϕ0 for the fringe fits of the first night. ϕ0/ϕ′ is in the rangeof 0 to −5/(100µm).
66 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
-20-15-10-5 0 5
10 15 20
1200 1300
ϕ 0 (
rad)
Mfile9
0 5
10 15 20 25 30 35
1300 1400
ϕ 0 (
rad)
Mfile10
-20-15-10-5 0 5
10 15
1500 1600
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rad)
Mfile11
10 15 20 25 30 35 40 45
-200 -100
ϕ 0 (
rad)
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-10-5 0 5
10 15 20 25
0 100
ϕ 0 (
rad)
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-5 0 5
10 15 20 25 30
1200 1300
ϕ 0 (
rad)
ϕ’ (µm)
Mfile14
-10-5 0 5
10 15 20 25 30
1300 1400
ϕ 0 (
rad)
ϕ’ (µm)
Mfile15
Figure 48: Correlation ϕ′ and ϕ0 for the fringe fits of the second night. ϕ0/ϕ′ is of the order−10/(100µm). Formation of separated streaks is probably an indicator of 2π errors in the phaseunwrapping algorithm—the optimistic interpretation is that a clustering algorithm on this type ofdisplay may detect this condition in imaging modes. The colorization of the exposures in blocks of2000 frames (chunks of ≈ 42 s per color) is meant to bolster this interpretation.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 67
-5
0
5
10
-500 -400
ϕ 0 (
rad)
Mfile16
-25
-20
-15
-10
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rad)
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-20
-15
-10
-5
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ϕ 0 (
rad)
Mfile18
0
5
10
15
-700 -600
ϕ 0 (
rad)
Mfile19
-5
0
5
10
-1000 -900
ϕ 0 (
rad)
ϕ’ (µm)
Mfile20
5
10
15
20
-400 -300
ϕ 0 (
rad)
ϕ’ (µm)
Mfile21
Figure 49: ϕ′ and ϕ0 for the MIDI fringe fits of the third night. ϕ0/ϕ′ is of the order −12/(100µm).
68 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
-35
-30
-25
-20
1500 1600
ϕ 0 (
rad)
Mfile22
-15
-10
-5
0
1500 1600
ϕ 0 (
rad)
Mfile23
-10
-5
0
5
2300 2400
ϕ 0 (
rad)
Mfile24
0
5
10
15
2100 2200
ϕ 0 (
rad)
Mfile25
5
10
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20
1900 2000
ϕ 0 (
rad)
Mfile26
0
5
10
15
2400 2500
ϕ 0 (
rad)
Mfile27
-15
-10
-5
0
2600 2700
ϕ 0 (
rad)
ϕ’ (µm)
Mfile28
-10
-5
0
5
2400 2500
ϕ 0 (
rad)
ϕ’ (µm)
Mfile29
Figure 50: ϕ′ and ϕ0 for the MIDI fringe fits of the fourth night. ϕ0/ϕ′ is of the order −10/(100µm).
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 69
The influence of the dry air fluctuations are in comparison: a2dry/a2
wet ≈ 2× 10−7 (Eq. 7). The scaleheight ratio contributes with a factor Kdry/Kwet ≈ 9.5/1.6 ≈ 6. From Figure 47 in [16] we estimateDdry/DH2O ≈ 3× 103. So the relative magnitude of the dry air structure function is the product ofthese factors, 2× 10−7× 6× 3× 103 ≈ 3.6× 10−3, negligible for our purposes. As we show the powerdensity functions of ϕ0 in Figures 51–53, the predictions (in red) are essentially the same, whetherthe dry air components are included or not.
The fluctuations of the zero-extrapolated component of the MIDI fringe fits are roughly two ordersof magnitude higher than derived from the measured water structure functions: Figs. 51–53. Theyare of the 1/f -noise shape at frequencies below 1 Hz, flat in the region up to 5 Hz, with a crossoverto the predicted ν−8/3 Kolmogorov shape above 5 Hz.
The transition at 5 Hz is a result of a smoothing operation in the IDL software: a 5 Hz Nyquistfrequency is equivalent to a filter of 0.1 s width in the time domain, or equivalent to averaging over5 frames (see Section 2.1).
The model of constant group delay has re-written (1) and (16) as
ϕ(k) = k(Di −De) + ρdryDi(adry + bdryk) + ρwetDi(awet + bwetk). (26)
The difference between this Section 3.4 here and Section 3.3 is that we are now looking at the limitk → 0; instead of addressing inclinations of the straight lines in the lower plots of Figures 37 and38 we are now looking at the interception with the ordinate axes. The difference between the MIDI
fringe tracker fits and projected estimates from air turbulence profiles (LI-COR etc) is measured bysome missing factor between the PDF, typically 100 in Figures 51–53, or in units of amplitudes thesquare root of this, typically 10, but anyway a relative measure. The failure to converge the two datasets is a result of a very unfortunate error propagation in the lower plot of Figure 38: since the MIDI
phase estimates in the range of 700 to 1400 cm−1 are inherently noisy in all ≈ 30 dispersed channelsof the prism, a measure of the slope of the curve with acceptable relative error is still possible sincethe value on the curve drops by ≈ 30 % over the full range of the spectrum—which could not bedone if the curve would be much flatter. A measure of the interception with the ordinate axis, onthe other hand, with a relative error of same quality is almost impossible because the value of kχ(k)at the interception is only 3× 10−4 of its magnitude within the N-band.
In summary, the green curves of the ϕ0 parameter in Figures 51–53 are only a measure of infraredbackground and detector-readout noise; this shadows entirely the fluctuations we would expect inaddition from the turbulence in the atmosphere above the two telescopes, represented by the redcurves. A detailed look into these curves is of no value within the scope of this report.
70 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
1e-05
0.0001
0.001
0.01
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1
1 10
PD
Fϕ 0
(ra
d2 /Hz)
Hz
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1
1 10
PD
Fϕ 0
(ra
d2 /Hz)
Hz
Mfile1
1e-05
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1
1 10
PD
Fϕ 0
(ra
d2 /Hz)
Hz
Mfile2
1e-05
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Fϕ 0
(ra
d2 /Hz)
Hz
Mfile3
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(ra
d2 /Hz)
Hz
Mfile4
1e-05
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Fϕ 0
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d2 /Hz)
Hz
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1e-05
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Fϕ 0
(ra
d2 /Hz)
Hz
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1e-05
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Fϕ 0
(ra
d2 /Hz)
Hz
Mfile7
1e-05
0.0001
0.001
0.01
0.1
1
1 10
PD
Fϕ 0
(ra
d2 /Hz)
Hz
Mfile8
Figure 51: Comparison of the Clifford model (14) with the measured PDFs of the phases extrapolatedto k = 0 in the range 0.2–15 Hz. Red the values derived from gas density fluctuations (both with orwithout water vapor), green the MIDI phases extrapolated from the N band to infinite wavelength.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 71
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1
1 10
PD
Fϕ 0
(ra
d2 /Hz)
Hz
Mfile15
Figure 52: Continued from figure 51 covering the second night of MIDI observations.
72 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
1e-05
0.0001
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d2 /Hz)
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d2 /Hz)
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1e-05
0.0001
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1
1 10
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Fϕ 0
(ra
d2 /Hz)
Hz
Mfile29
Figure 53: Continued from figure 52 covering the fourth night of MIDI observations.
MIDI Interferom. and Water Vapor Fluct. Issue 1 UL-TRE-MID-15829-0113 73
4 SUMMARY
We summarize 30 exposures of prism-dispersed MIDI N-band interferometric fringe phase data—atotal exposure time of roughly an hour spred over four nights in June 2007—in terms of powerdensity spectra.
1. Prediction of the 10 µm phase fluctuation from the UT AO system’s Fried parameter (at awavelength of 500 nm) is robust in the frequency range up to 3 Hz. Deviations in the powerspectral density are typical less than a factor of two. The stability of this analysis is due to thefact that (i) the integration over the scale height of the Troposphere is already done implicitlyin the AO system which receives the path integrated phases anyway, and (ii) the other majorparameters (wind speed/direction and air mass) are either well known or well represented byground measurements.
In the plots of the power spectral density of this phase ϕ evaluated at λ = 10µm, there is nonoticable difference between either using or neglecting the water vapor content measured atthe ground in the composition of the C2
n.
2. The LICOR IR gas analyzer’s carbon dioxide data cannot be used to estimate the local airdensity fluctuations at medium and high frequencies because the digitization noise is roughlya factor 10 higher than the (estimated) actual equivalent value of C2
n. This is the reason whythe strength of the turbulence is computed from the AO data as described above.
3. Since the N-band refractive index dispersion is large compared to the dispersion at smallerwavelengths, there is a promise that dispersed phase measurement across the N-band may sep-arate the wet and dry air delays by 2-parametric fits of slope and interception. Unfortunately,the actual shape of the gas dispersion means that the sensitivity in the determination of theinterception (extrapolation of phases to zero wavenumber in the plot of phase versus wavenum-ber) cannot be reached by MIDI; the noise sources besides the fluctuations in the optical pathdifferences (that is, detector readout and background noise) dominate the noise in the fittedinterception, and the extracted spectral density of that parameter is non-Kolmogorov, spotnoise reshaped by software filters.
For this reason, qualitatively quite different from abandoning the carbon dioxide information,the high frequency water vapor density measurements with the LICOR analyzer have notcontributed to the current analysis.
4. Another general aspect of the 2-parametric fit of dispersed phase data with slope and intercep-tion is that the interception is insensitive to the OPD induced by mirror motions/vibrations.Here, the analysis of low-frequent co-motions of slope and interception monitored over typi-cally 30 seconds reveals that the sensitivity of the interception to the slope parameter is cor-related with the average ambient humidity. (The methodological difference to the point madeabove is just that a scan over 30 seconds extracts information that remains hidden by othernoises/fluctuations if restricted to 1 Hz information.)
As noticed under the first item, this information does matter if the phase fluctuations are tobe modeled; this does not preempt evaluation in other contexts, such as (i) determinationof the precipitable water vapor integrated over some 2 kilometers above the telescopes, (ii)detection of fringe jumps in unwrapping algorithms, potentially related to imaging modes, (iii)separation of phase jitters contributed from reflecting mirror surfaces or contributed from gasdensity flucuations, and others.
74 Mathar–Jaffe, NEVEC, Leiden Observatory Issue 1 UL-TRE-MID-15829-0113
oOo