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Notes - Session 358 (2009-03-21)

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(S359)
 
2009-03-21
Bullet Restart from Park Position
Bullet Real-Time Focus Profile Graphs
Bullet PEC Training
Bullet Star Elongation Issue
Bullet Polar Alignment Checks
Bullet Tracking Rate Issue
 
2009-03-26
Bullet Tracking Rate Adjustment Trial
Bullet Flat Frames
Bullet Flat Framing Trials - M95
Bullet Filter Flats
Bullet CCD Edge Effects
 
>

Goto Images from 2009-03-21


Restart from Park Position  

Start up from Park. GPS fix achieved after 5 asterisks  (developing range is 3 to 7). 

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Real time Focus Profile graphs

Since the last session, I had updated my observatory profile to display graphs of focus profiles. Previously I had simply produced a table of data and calculated best focus result, and then plotted focus profiles during post-session analysis.  Screen shots of the new graphing capability are shown below. They provide a easy to see / visual check on Focus position and Seeing Quality.

Collimination Sequence on +7th mag star (altitude 50 deg)

Image
Image  
Measurement of peak FWHM before and after re-collimination

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PEC Training

PEC training was performed on the RA drive at the start of the session in order to try to reduce the effects of periodic error which were measured to be at least 20 arc secs during the first light session (S356).   

Previous experience with PEC training with LX200 Classic had suggested that the hand controller would  'countdown' to the start of the training interval and then indicate when the training was complete some 8 minutes later (representing one cycle of the worm drive), however it turned out that training with the LX200R (GPS) was somewhat different ...

Training was initialised via the LX200 Autostar II handset with auto-guiding performed using the main imager of the ST-10XME camera.  Instead of counting me down to the start of a cycle, the training period began almost immediately with the current 'Segment'.  After progressing through 200 segments I thought that controller would indicate that the training was over,  but instead it just kept counting more segments. After reaching 400 segments I decided to re-read the Manual section "Periodic Error Correction", p.39.  The paper copy of the manual that I have reads "...Autostar II display a count of the 200 positions of the worm drive, when the count reaches 200, one cycle is complete. A full cycle takes around 8 minutes. Press Mode to exit.  With 20 minutes of training complete and confused why the counter was now showing 500, I pressed the Mode button to exit from PEC Training.  To refine the training I followed it up with two "Update" periods of around 8-9 minutes duration.

[ It is noted that in a downloaded electronic copy of the LX200R manual the section on RA PEC training has been updated to read  "Autostar II display a count of the 200 positions of the worm drive, when the count reaches 600, one cycle is complete. A full cycle takes around 24 minutes. Press Mode to exit.]

With PEC training 'complete' a series of 10 sec exposures was taken of a target object (M66) over a 17 minute interval.  Analysis of these showed that whilst Periodic Error had reduced from previous level of 18-22 arc secs, the residual error was still significant - around 10 arc sec peak-to-peak. The error does not seem periodic (at least not on an obvious 8 minute cycle).

Performance with PEC On

Image
Previous Performance without PEC
Image

 

In order to check the correction values compiled during PEC training the PEC table was downloaded from the mount, using the Meade PEC tool. The table was saved as a .csv file with 200 rows and imported into Excel for Plotting.  The graph (below) has a general shape that mimics the general shape of the Periodic Error measured during 'First Light' session (S356).

Image


Reading various newgroup postings suggested that the LX200R (GPS) actually has a PEC table comprising 600 segments of 2.4 seconds each (equivalent to 3 x 8 minute cycles), rather than just 200 segments, but the Meade PEC tool hasn't been updated to handle 600 segments.

The PEC table was therefore re-examined using an evaluation copy of the PEMPro V2.6 by Sirius-Imaging.  The PEMPro software was installed along with an ASCOM driver for the LX200 GPS. Connection with LX200R scope was successfully established and the PE Curve downloaded.  This showed a 24 minutes of data (600 segments). with Peak to Peak PE of 33 arc secs. 

Image

 Whilst data looks complete and periodicity is evident, there are some significant differences between cycles.  It is suspected that PE curve is compromised by the premature ending to the 2-1/2 cycle training session and the short 'single cycle' Updates

Image

It is clear that PEC training will need to be redone.   It is hoped to perform this due an upcoming session, building upon the new knowledge and continuing evaluation of the PEMPro tool.

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Image Linking

The larger field of view with 12" LX200R +  ST-10XME and the greater sensitivity mean that new images are typically containing many more stars, than my previous 8" LX200 + ST-7E setup. This presents CCDSoft/TheSky with certain challenges, and means that Image Linking (Plate Solution determination) is not only liable to fail, but means that significant time is lost whilst the Bisque software and my own iterative Link Finding routine attempt in vain to find a link.

Adjusting certain settings in CCDSoft source extraction setting, raises the 'star detection' threshold, reducing the detected stars and then allows CCDSoft/TheSky to easily & quickly perform an Image Link. 

In the following example (star field around DY Per, which indeed also presented link problems with with imaging equipment),
detection threshold settings of under 3.0 (under 8.0 for GSC stars alone) will fail to link,  and consume 5.7 secs looking for a match via CCDSoft, or 129 secs looking for a match using detailed iterative search link method.

Setting the Detection Threshold to 10.0 ensures linking works for both USNO-B and GSC stars catalogs.  This setting is used during observatory imaging when the purpose is to rapidly perform image linking for Locating Target Objects, or for T-Point Mapping.

The setting of 10 is not sensitive enough however to regularly ensure that certain faint stars can be recognized during Photometric analysis.  To pick up DY Per at around mag +15, requires a Detection Threshold of between 3 and 5. (if higher than 5-5.5 DY Per is not found, if lower than 3 then image linking fails).

[Tests on another star RZ LMi at Mag +16.7, showed that certain 60s exposure frames needed threshold to be set as low as 3.0 in order for the star to be detected.
( 1 frame detected star at threshold of 10.0 / 1 frame detected at 5.0 / 1 frame detected at 3.0 ) ]

Image Link Trials
Star Field with DY Per
Inventory / Detection Threshold =1
GSC: No Link, USNO-B: No Link
Image Image
CCD Image (50% size reduction)
45s (single frame), 3x3 binning, V Filter
2009-03-21, (#358127), 12" LX200R  (at f/5.7) + ST-10XME
 
Inventory / Detection Threshold = 2
GSC: No Link, USNO-B: No Link
Inventory / Detection Threshold = 3
GSC: No Link, USNO-B: Link / 178 stars
Image Image
 
Inventory / Detection Threshold = 5
GSC: No Link, USNO-B: Link 177 stars
Inventory / Detection Threshold = 10
GSC: Link / 165 stars, USNO-B: Link / 165 stars
Image Image

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Star Elongation Issues

Problems were noticed with a batch of images of C/2009 T2 (Cardinal) where each frame shows a distinct and consistently orientated star elongation.

Analysis indicated that the elongation wasn't due to a N-S drift.

Two frames of C/2009 T2 (Cardinal) 
showing Star Elongation
Sky Position 307 deg Azimuth, 34.4 deg Altitude
Image
Image
CCD Images (cropped to central area)
30 sec exposure (single frame), 3x3 binning, C Filter 
2009-03-21 23:21/ 23:23 h UT  (#358136 & 39)
12" LX200R  (at f/5.7) + ST-10XME

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Polar Alignment Checks 

Drift Align Checks were made to determine the accuracy of the telescope's Polar Alignment. The N-S drift of a star in the Southern Sky (near to Meridian & Declination 0)  and the N-S drift of a star close to the western horizon (West Sky Point) were measured from images taken 12 minutes apart.

The N-S drift rates reveal that the Polar Axis of the telescope mount is 
a ) pointing 1.04 arc mins too far west (requiring that wedge is  rotated very slightly clockwise)
a ) pointing 5.39 arc mins too low (requiring that polar axis is slightly raised)

Images pairs - Binning 2x2, Plate Scale 1.612, Exposure 10 secs.

Log file associated with Polar Alignment Check

Slew to South Sky Point
  Slewing to Azimuth: 180.0deg, Altitude: 33.0deg

Measuring N-S Drift
Two pictures will now be taken separated by approximately 12 minutes
Do not move the scope during the operation.

  Taking 10s image (C)...      Ok        [00358002] 19:36:04UT Full 2x2 10s C
  Brightest Object...          X/Y =      982/220.8
  Linking image (GSC)...       Ok Stars 86, Scale 1.613, Angle 179.4°

  Taking 10s image (C)...      Ok        [00358003] 19:48:43UT Full 2x2 10s C
  Brightest Object...          X/Y =      957/222.8
  Linking image (GSC)...       Ok Stars 79, Scale 1.613, Angle 179.4°

  Time Interval :              12.65 mins
  Baseline Az :                180.7 degrees 
    Declination Drift :          0.27 arc secs/min NORTHWARDS
  Polar misalignment :
        1.04 arc mins (approx)

Operation...                   Completed

- South sky point (Northern Hemisphere)
    star drifts north --> scope's polar axis pointing too far west and needs turning clockwise 
    star drifts south --> scope's polar axis pointing too far east and needs turning anti-clockwise 

Slew to West Sky Point
  Slewing to Azimuth: 270.0deg, Altitude: 20.0deg

Measuring N-S Drift
Two pictures will now be taken separated by approximately 12 minutes
Do not move the scope during the operation.

  Taking 10s image (C)...      Ok        [00358004] 19:59:49UT Full 2x2 10s C
  Brightest Object...          X/Y =      321/332.6
  Linking image (GSC)...       Ok        Stars 30, Scale 1.614, Angle 179.5°

  Taking 10s image (C)...      Ok        [00358005] 20:11:53UT Full 2x2 10s C
  Brightest Object...          X/Y =      290/343.8
  Linking image (GSC)...       Ok        Stars 33, Scale 1.616, Angle 179.5°

  Time Interval :              12.07 mins
  Baseline Az :                271.5 degrees
  Declination Drift :          1.38 arc secs/min NORTHWARDS
  Polar misalignment :         5.39 arc mins (approx)

Operation...                   Completed

- West sky point (Northern Hemisphere)
    star drifts north --> scope's polar axis pointing too low and needs raising
    star drifts south --> scope's polar axis pointing too high  and needs lowering 

The image pairs also confirm previous indications that stars are drifting westwards in RA, showing that the scope is tracking slower than sidereal time - see below

Drift Align Images - South Sky Point
Frames taken 12.65 minutes apart
Dec drift 0.27 arc sec/min northwards
RA drift 3.2 arc sec/min westwards
Image
CCD Images (stacked & cropped to central area)
2 x 10s sec exposure (sum combine), 2x2 binning, C Filter
2009-03-21  (#358002-03)
12" LX200R  (at f/5.7) + ST-10XME
Drift Align Images - West Sky Point
Frames taken 12.07 minutes apart
Dec drift 1.38 arc sec/min northwards
RA drift 4.1 arc sec/min westwards
Image
CCD Images (stacked & cropped to central area)
2 x 10s sec exposure (sum combine), 2x2 binning, C Filter
2009-03-21  (#358004-05)
12" LX200R  (at f/5.7) + ST-10XME

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Tracking Rate Issue

Previous two sessions (S356 & 357) had indicated that the scope is drifting in RA during tracking by around 1.9 arc sec/minute (after removing effects of Periodic Error).

Image pairs used for Polar Alignment Check (see images above) were further examined for RA drift.  They show that stars are drifting westwards in RA by between 3.2 and 4.1 arc sec /minute. This is much more than can be explained by the relatively small polar mis-alignment.  The combined datasets suggest that the scope is tracking slower than sidereal time by around 0.3%

Analysis

South Sky Point    Stars drift westwards by 25 pixels in 12.65 minutes, 
equivalent to a rate of  3.2 arc secs/minute
West Sky Point  Stars drift westwards by 31 pixels in 12.07 minutes,
equivalent to a rate of  4.1 arc secs/minute.

Since sidereal motion is 15 arc min/min (or 900 arc sec/min), the tracking is therefore running slow by around 0.34%

[  3.2 arc sec/min = 0.344% slow,  4.1 arc sec/min = 0.47% slow,  1.9 arc sec/min = 0.21% slow ]

[ The slightly higher values in this session might be caused by an incomplete and therefore 'biased' PEC table. ]

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Tracking Rate Adjustment Trial (2009-03-26)

A few days later (2009-03-26) a trial run was made in which the LX200R tracking rate was adjusted to a custom setting of  "+3" using the AutoStar II controller. (Setup/Telescope/Tracking Rate Adjustment). This setting should equate with a rate "Sidereal Rate + 0.3%" and thus should negate the estimated 0.3% slowness in the scope's normal tracking..  

A series of 20 sec images were collected at 3x3 over a 50 minute period of a star field positioned approximately Due South / Declination 0 deg.  The conditions were to windy to collect useful observations or even half-decent images, but they were sufficient for the task in hand despite frequent wind shake.  Despite the poor quality it was an encouragingly fact that nearly although the images still managed to successfully achieve a plate solution (via TheSky).

The amount of star drift is shown in the left hand figure below.  Whilst the "+3" guiding rate adjustment did remove the previous westerly star drift,  it was replaced instead by a roughly equal amount of easterly star drift (with a rate of 2.5 arc mins / minute).  

The next session will examine performance with "+1" and "+2" guiding rates in order to find the best tracking rate. 
 [one newsgroup posting that I've seen suggests that tracking rate is partially temperature dependant ].

Image

After subtracting the average star drift (right-hand figure above) a residual error of 20 arc secs remains.  A cycle on the order of 24 minutes is noticeable that is most probably associated with an incompletely trained PEC table. (see Pec Training above). After a gap of several minutes data around the 50-51 minute point, shows less extreme easterly drift. This excursion is more extreme that can be explained by the 20 arc min error range associated with first 40 minutes of data.  

Notes : A subsequent Power Down/Power Up cycle showed that the Custom Tracking Rate entered (+3) is not retained, but instead Tracking Rate is reset to  'Sidereal'  (but with the rate that has previously been shown to be slow).    [Ideally Tracking Rate would be a setting that is retained during Power Down/Up cycles.]

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Flat Frames (2009-03-26)

A few days later (2009-03-26/27) opportunity was taken to acquire sets of Flat Frames, at 1x1, 2x2 and 3x3 binning using Dawn Sky with Semi-Dithering. These were the first high S/N flat frames taken through the scope, previous flats were taken using Moon-Lit Night Sky.

Flats were taken through through a Clear (C) filter, with master flats created using "Sigma Beta 10" after normalizing flat frames for the developing sky brightness.

Typical range of Flat Field features are evident.  
 - Vignetting (dark corners)
 - Small 'dust' motes due to particles on the CCD cover
 - Larger 'dust'motes due to particles on the Camera/Filter Wheel Window 
 - Larger still but fainter dust motes due to particles/dirt on Filters themselves.

Example Master Flat (3x3 binning) - Session 358b
Image
Master Flat Frame
18 x 0.5s exposure (verage combine), 3x3 binning, C Filter
2009-03-26, 12" LX200R  (at f/5.7) + ST-10XME
  
Flat Frame - detail
Image
Master Flat Frame - alternate Black/White range
Image details as above
  
Flat Analysis Map (CCD Inspector) 
 Image
Master Flat Frame
15 x 1s exposure (average median combine), 1x1 binning, C Filter
2009-03-26, 12" LX200R  (at f/5.7) + ST-10XME

In addition a slightly brighter patch of pixels is noted in several Filter Flats (just below center line on right hand side of above image).  The patch is not thought to be related to a star as frames were differed and then combined by Median Average.

Impact of using better Flat Frame
M95 with previous Moon-Lit Sky Master Flat M95 with new Dawn Sky Master Flat
Image Image
CCD Image (50% size reduction)
120s (single frame), 3x3 binning, C Filter
2009-03-22, 12" LX200R  (at f/5.7) + ST-10XME
CCD Image (50% size reduction)
Image details as left

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Flat Framing Trials - M95 (2009-03-26)

 

M95 - Flat Framing Trials
M95 (dark subtracted / no flat frame)
notice vignetting and large dust mote
Image
CCD Image (50% size reduction)
120s (single frame), 3x3 binning, C Filter
2009-03-22, 12" LX200R  (at f/5.7) + ST-10XME
 
M95 - reduced with 'Compromised' 'Master' flat frame 
(Dawn Flats)
vignetting and large dust mote fainter but still obvious
 Compromised 'Master' flat frame' (Dawn Flats)
low noise, should be good for flat fielding !
' double normalised ?'
(Mode Value : 43500 ADU)
Image Image
CCD Image (50% size reduction)
Image details as above

Flat Frame (50% size reduction)
19 x 0.5s exposure (normalised & median average combined)
  3x3 binning, C Filter
2009-03-26, 12" LX200R  (at f/5.7) + ST-10XME
 
M95 - reduced with Single flat frame (Dawn Flat)
vignetting and dust mode removed
but a top to bottom gradient is present
 'Single flat frame' (Dawn Flat)
more noisy flat, should work as well as Master ?
(Mode Value : 36500 ADU)
Image Image
CCD Image (50% size reduction)
Image details as above
Flat Frame (50% size reduction)
0.5s exposure (single frame), 3x3 binning, C Filter
2009-03-26, 12" LX200R  (at f/5.7) + ST-10XME
 
M95 - reduced with 'New Master Flat' (Dawn Flat)
vignetting and dust mode removed
but a top to bottom gradient is present 
(more obvious than with single frame ?)
 New 'Master' flat frame' (Dawn Flats)
Average 18 frames
(Highest ADU frame dropped)
(Mode Value : 33500 ADU)
Image Image
CCD Image (50% size reduction)
Image details as above
Flat Frame (50% size reduction)
18 x 0.5s exposure (normalised & average combined)
  3x3 binning, C Filter
2009-03-26, 12" LX200R  (at f/5.7) + ST-10XME
 
M95 - reduced with 'New Master Flat' (Dawn Flat)
and Gradient Corrected
Image
CCD Image (50% size reduction)
Image details as above

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Filter Flats (2009-03-26)

In addition to flat filter sets for making Master Flats (C filter),  small sets of 3 flat frames (2x2 binning) where taken through each filter to examine differences between different Filter Flats.
These are shown in the montage below,.

These showed that B,V,R Filters flats were relatively similar to the the Clear Filter Flats, though there were differences associated with the diffuse/fainter motes associated with particles and dirt on individual the filters themselves.  However some filters showed additional differences.

The Red Filter show a brightened area that is repeatable. However the bright feature is not seen on the R Flat filter, suggesting a slight defect/issue with the Red filter, rather than a wavelength dependant feature.

More noticeable was a blotched patterns on U Filter Flats. At first it was thought this was due to a very dirty or otherwise defective U filter. However it was noticed that I (infrared) Filter Flats also showed similar shaped blotches, but they were fainter and 'opposite' in magnitude (ie dark areas on U filter flats where lighter on I filter flats and vice versa).  This suggests that there is some material 'grease?' on the surface of the CCD or Camera Window, that absorbs light in one wavelength band  (U or I ) and re-transmits it in the other wavelength band. 

Image
Montage of Flat Frames by Filter
3 frame stacks (average combine), 2x2 binning
2009-03-26, 12" LX200R  (at f/5.7) + ST-10XME

 

The blotching see on the U and I filter whilst fainter is still just recognisable on the B and Blue Filter Flats.  Since the material is probably difficult to see (though UV light source might show it), it might be difficult to know what surface to clean or whether cleaning was effective and therefore I will hold off from trying to perform any remedial treatment.

Since the U filter will be used for imaging bright targets such the Moon and Venus, without saturating the ST-10XME camera at the minimum exposure of 0.12 sec, it will be obviously be important to use U Filter Flats.  My existing Moon filter is not sufficiently light blocking to bring the exposure levels within the > 0.12sec range.  Whilst stopping down the front of the telescope would work, this operation is obviously inconvenient for remote/automated operation of the scope for imaging multiple targets.

U and I Filter Flats - Detail Compared
Image
Montage of Cropped Flat Frames taken through U and I filters
3 frame stacks (average combine), 2x2 binning
U filter : 3 x 3 sec exposure / I filter : 3 x 0.2 sec exposure
2009-03-26,  12" LX200R  (at f/5.7) + ST-10XME

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CCD Edge Effects

Images taken with ST-10XME suffer from some minor edge effects, which may produce anomalies lines along the top, bottom and sides of certain images. These lines are noticeable on flat frames as shown below.  The brightening is presumed to be due to light reflecting off slightly raised edges to the CCD chip.

CCD Image Effects
Image
Master Flat Frame
15 x1 s sec exposure (median average combine), 1x1 binning, C Filter
2009-03-26,  12" LX200R  (at f/5.7) + ST-10XME

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