The last several nights have been overcast and even some desperately needed rain, so no images of the comet. The comet and tail keep getting smaller and fainter. The estimated magnitude of the comet is now +9.0. It was +8.3 when last viewed on Monday. I am only showing images from the Stellina telescope since the Vespera telescopes are fitted with filters for viewing emission nebulae.
Deep Sky Objects
I’ve started a new set of multi-night emission nebula observations. The Singularity application only allows five multi-night observations on each instrument. The new targets will be the Dumbbell Nebula (M27), The Ghost of Cassiopeia Nebula (IC 59), the Fossil Footprint Nebula (NGC 1491, SH2-206), the Northern Trifid Nebula (NGC 1579), and the Christmas Tree Nebula (NGC 2264). The full moon is no longer a problem, however intermittent clouds keep interfering with the observations and prevented the last two targets. The Vespera Pro started M27 on a previous night.
Number of New Stacked Images. (Total including Previous Nights).
The comet and tail keep getting smaller and fainter. The estimated magnitude of the comet was +8.5. I am only showing images from the Stellina telescope since the Vespera telescopes are fitted with filters for viewing emission nebulae.
Singularity Multi-Night Observations
One of the new features with the Singularity software application used to operate the Vaonis telescopes is Multi-Night Observations. The mosaic image composite process is continued from the previous observation session to afford improved image quality. The software permits up to five different mosaic images to be continued for more than one night. At the end of each multi-night observation, the final image and the settings to continue the observation for the target is stored with the instrument as the starting point for the next multi-night observation. The settings include whether a filter is used (and would be required for subsequent multi-night observations). It is recommended that the object be between 25° and 75° during the multi-night observation.
Helix Nebula (NGC 7293)
The Helix Nebula is a planetary emission nebula located in the constellation Aquarius. It is relatively low (maximum about 28°) above the southern horizon early in the evening, so the first target for the night.
Stellina (no Filter)
Observation of the Helix Nebula (NGC 7293) over four nights using the Stellina telescope with no filter. The mosaic size for the observation was set to 1.1° x 1.1°. Total of 741 stacked images, 02h 03m 30s). I’ve included both an unprocessed jpg image and one that was processed (Capture One for brightness and contrast, Topaz AI to remove noise).
Vespera Classic with Dual Filter
Observation of the Helix Nebula (NGC 7293) over four nights using the Vespera Classic telescope with a Dual (H-α, O-III) filter. The mosaic size for the observation was set to 1.6° x 1.6°. Total of 1766 stacked images (04h 54m 20s). The slideshow shows the image improve (increased brightness, decreased sensor noise) as the number of stacked images increases (1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, 1765, 1766). The full 1.6° x 1.6° (1967 x 1936 pixel) mosaic field was filled after 128 stacked images. The mosaic was in the 6th pass when the observation was stopped for the night. The image after the slideshow was processed (Capture One for brightness and contrast, Topaz AI to remove noise). Compared with the processed image from the Stellina, this one is brighter due to the Dual filter and the larger number of stacked images.
Vespera Passengers with Dual Band Filter
Observation of the Helix Nebula (NGC 7293) over four nights using the Vespera Passengers telescope with a Dual band (H-α, O-III) filter. The mosaic size for the observation was set to 1.6° x 1.6°. Total of 1199 stacked images (03h 19m 50s). The slideshow shows the image improve (increased brightness, decreased sensor noise) as the number of stacked images increases (1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, 1198, 1199). The full 1.6° x 1.6° (1956 x 1934 pixel) mosaic field was filled after 32 stacked images. The mosaic was in the 8th pass when the observation was paused. The image after the slideshow was processed (Capture One for brightness and contrast, Topaz AI to remove noise).
Vespera II with CLS Filter
Observation of the Helix Nebula (NGC 7293) over four nights using the Vespera II telescope with a CLS (city light suppression) filter. The mosaic size for the observation was set to 2.5° x 2.6°. Total of 1446 stacked images (04h 01m 00s). The slideshow shows the image improve (increased brightness, decreased sensor noise) as the number of stacked images increases (1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, 1445, 1446). The full 2.5° x 2.6° (3791 x 3840 pixel) mosaic field was filled after 128 stacked images. The mosaic was in the 6th pass when the observation was paused. Even though there are more stacked images, the unprocessed jpg image from the Vespera-II telescope is not a bright as the ones from the Vespera Classic, or Vespera Passengers telescopes. This may be due to the different filters used (CLS vs Dual). The image after the slideshow was processed (Capture One for brightness and contrast, Topaz AI to remove noise).
Dumbbell Nebula (M27)
The Dumbbell Nebula (M27, NGC 6853) is a planetary nebula in the constellation Vulpecula. Vespera Pro was not able to locate/lock onto the Helix nebula, so I selected the Dumbbell nebula as an alternative multi-night target. On this date, it remains above 25° above the horizon until about 22:00.
Vespera Pro with Dual Band Filter
Observation of the Dumbell Nebula (M27) over two nights using the Vespera Pro telescope with a Dual Band (H-α, O-III) filter. The mosaic size for the observation was set to 1.6° x 1.6°. Total of 801 stacked images (02h 13m 30s). The slideshow shows the image improve (increased brightness and contrast as well as decreased sensor noise) as the number of stacked images increases (1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 800, 801). The full 1.6° x 1.6° (3559 x 3571 pixel) mosaic field was filled after 64 stacked images. The mosaic was in the 6th pass when the observation was paused. The image has been processed using Capture One for brightness and contrast adjustments, and Topaz AI for noise reduction. The use of a dual-band filter significantly enhances the visibility of the nebula. Additionally, some faint red areas can be observed around the nebula.
Crescent Nebula (NGC 6888)
The Crescent Nebula (NGC 6888, Caldwell 27, Sharpless 105) is an emission nebula in the constellation Cygnus. On this date, it remains above 25° above the horizon until about 22:00. I selected this as my second deep sky object for multi-night target for the night.
Stellina (no Filter)
Observation of the Crescent Nebula (NGC 6888) over four nights using the Stellina telescope with no filter. The mosaic size for the observation was set to 1.1° x 1.1°. Total of 1624 stacked images, 04h 30m 40s). I’ve included both an unprocessed jpg image and one that was processed (Capture One for brightness and contrast, Topaz AI to remove noise). In this section of the sky there are lots of stars. Even with the processing, it is difficult to clearly see the faint red nebula.
Vespera Classic with Dual Band Filter
Observation of the Crescent Nebula (NGC 6888) over four nights using the Vespera Classic telescope with a Dual band (H-α, O-III) filter. The mosaic size for the observation was set to 1.6° x 1.6°. Total of 2236 stacked images (06h 12m 40s). The slideshow shows the image improve (increased brightness, decreased sensor noise) as the number of stacked images increases (1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, 2048, 2235, 2226). The full 1.6° x 1.6° (1900 x 1924 pixel) mosaic field was filled after 256 stacked images. The mosaic was in the 7th pass when the observation was paused. The image has been processed using Capture One for brightness and contrast adjustments, and Topaz AI for noise reduction. The use of a dual-band filter significantly enhances the visibility of the nebula. Additionally, some faint red areas can be observed above the nebula.
Vespera Passengers with Dual Band Filter
Observation of the Crescent Nebula (NGC 6888) over four nights using the Vespera Passengers telescope with a Dual Band (H-α, O-III) filter. The mosaic size for the observation was set to 1.6° x 1.6°. Total of 2016 stacked images (05h 36m 00s). The slideshow shows the image improve (increased brightness, decreased sensor noise) as the number of stacked images increases (1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, 2015, 2016). The full 1.6° x 1.6° (1949 x 1938 pixel) mosaic field was filled after 32 stacked images. The mosaic was in the 14th pass when the observation was paused. The image has been processed using Capture One for brightness and contrast adjustments, and Topaz AI for noise reduction. The use of a dual-band filter significantly enhances the visibility of the nebula. Additionally, some faint red areas can be observed around the nebula.
Vespera II with CLS Filter
Observation of the Crescent Nebula (NGC 6888) over four nights using the Vespera II telescope with a CLS (city light suppression) filter. The mosaic size for the observation was set to 2.5° x 2.6°. Total of 2168 stacked images (06h 01m 20s). The slideshow shows the image improve (increased brightness, decreased sensor noise) as the number of stacked images increases (1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, 2048, 2167, 2168). The full 2.5° x 2.6° (3694 x 3840 pixel) mosaic field was filled after 256 stacked images. The mosaic was in the 11th pass when the observation was paused. Even though there are more stacked images, the unprocessed jpg image from the Vespera-II telescope is not a bright as the ones from the Vespera Classic, or Vespera Passengers telescopes. This may be due to the different filters used (CLS vs Dual). The image after the slideshow was processed (Capture One for brightness and contrast, Topaz AI to remove noise). Lots of stars in this region of the sky.
Vespera Pro with Dual Band Filter
Observation of the Crescent Nebula (NGC 6888) over four nights using the Vespera Pro telescope with a Dual Band (H-α, O-III) filter. The mosaic size for the observation was set to 1.6° x 1.6°. Total of 2638 stacked images (07h 19m 40s). The slideshow shows the image improve (increased brightness, decreased sensor noise) as the number of stacked images increases (1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, 2048, 2637, 2638). The full 1.6° x 1.6° (3559 x 3543 pixel) mosaic field was filled after 64 stacked images. The mosaic was in the 17th pass when the observation was paused. The image has been processed using Capture One for brightness and contrast adjustments, and Topaz AI for noise reduction. The use of a dual-band filter significantly enhances the visibility of the nebula. Additionally, some faint red areas can be observed around the nebula.
Waning Gibbous Moon
The waning gibbous moon is 89% illuminated. For the remainder of the night the Stellina telescope recorded images of the moon that were used to create the following time-lapse video. I did a quick review of the images and didn’t see any object passing in front of the moon. Let me know if you see something. The telescope takes ~ 40 images/minute. The time-lapse video was created using Photoshop (720p, 30fps)
Packman Nebula (NGC 281)
The Packman Nebula (NGC 281, IC 11 or Sh2-184) is a bright emission nebula in the Cassiopea constellation and is part of the Milky Way.
Vespera Classic with Dual Band Filter
Observation of the Packman Nebula (NGC 281) over four nights using the Vespera Classic telescope with a Dual band (H-α, O-III) filter. The mosaic size for the observation was set to 1.6° x 1.6°. Total of 2534 stacked images (07h 02m 20s). The slideshow shows the image improve (increased brightness, decreased sensor noise) as the number of stacked images increases (1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, 2048, 2533, 2534). The full 1.6° x 1.6° (1924 x 1972 pixel) mosaic field was filled after 256 stacked images. The mosaic was in the 8th pass when the observation was paused. The image has been processed using Capture One for brightness and contrast adjustments, and Topaz AI for noise reduction. The use of a dual-band filter significantly enhances the visibility of the nebula.
Vespera Passengers with Dual Band Filter
Observation of the Packman Nebula (NGC 281) over four nights using the Vespera Passengers telescope with a Dual Band (H-α, O-III) filter. The mosaic size for the observation was set to 1.6° x 1.6°. Total of 2373 stacked images (06h 53m 30s). The slideshow shows the image improve (increased brightness, decreased sensor noise) as the number of stacked images increases (1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, 2372, 2373). The full 1.6° x 1.6° (1891 x 1938 pixel) mosaic field was filled after 64 stacked images. The mosaic was in the 15th pass when the observation was paused. The image has been processed using Capture One for brightness and contrast adjustments, and Topaz AI for noise reduction. The use of a dual-band filter significantly enhances the visibility of the nebula.
Vespera II with CLS Filter
Observation of the Packman Nebula (NGC 281) over four nights using the Vespera II telescope with a CLS (city light suppression) filter. The mosaic size for the observation was set to 2.5° x 2.6°. Total of 2632 stacked images (07h 18m 40s). The slideshow shows the image improve (increased brightness, decreased sensor noise) as the number of stacked images increases (1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, 2048, 2631, 2632). The full 2.6° x 2.6° (3833 x 3855 pixel) mosaic field was filled after 256 stacked images. The mosaic was in the 11th pass when the observation was paused. The image after the slideshow was processed (Capture One for brightness and contrast, Topaz AI to remove noise). Lots of stars in this region of the sky.
Vespera Pro with Dual Band Filter
Observation of the Packman Nebula (NGC 281) over four nights using the Vespera Pro telescope with a Dual Band (H-α, O-III) filter. The mosaic size for the observation was set to 1.6° x 1.6°. Total of 2629 stacked images (07h 18m 10s). The slideshow shows the image improve (increased brightness, decreased sensor noise) as the number of stacked images increases (1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, 2048, 2628, 2629). The full 1.6° x 1.6° (3559 x 3543 pixel) mosaic field was filled after 64 stacked images. The mosaic was in the 16th pass when the observation was paused. The image has been processed using Capture One for brightness and contrast adjustments, and Topaz AI for noise reduction. The use of a dual-band filter significantly enhances the visibility of the nebula.
Rosette Nebula (NGC 2237) and Cluster (NGC 2244)
The Rosette Nebula and Cluster (NGC 22237, Caldwell 49, NGC 2244, Caldwell 50) is a bright emission nebula in the Monoceros region of the Milky Way Galaxy. I did the observations between 03:00 and 05:30 (astronomical dawn). The observations of the Jellyfish Nebula (IC 443), Horsehead Nebula (IC 434), and Flame Nebula (NGC 2024) were washed out due to the bright moon.
Vespera Classic with Dual Band Filter
Observation of the Rosette Nebula (NGC 2237) and Cluster (NGC 2244) over four nights using the Vespera Classic telescope with a Dual band (H-α, O-III) filter. The mosaic size for the observation was set to 2.3° x 2.4°. Total of 2101 stacked images (05h 50m 10s). The slideshow shows the image improve (increased brightness, decreased sensor noise) as the number of stacked images increases (1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, 2048, 2100, 2101). The full 2.3° x 2.4° (2811 x 2950 pixel) mosaic field was filled after 512 stacked images. The mosaic was in the 4th pass when the observation was paused. The image has been processed using Capture One for brightness and contrast adjustments, and Topaz AI for noise reduction. The use of a dual-band filter significantly enhances the visibility of the neb
Vespera Passengers with Dual Band Filter
Observation of the Rosette Nebula (NGC 2237) and Cluster (NGC 2244) over four nights using the Vespera Passengers telescope with a Dual Band (H-α, O-III) filter. The mosaic size for the observation was set to 2.4° x 2.4°. Total of 1747 stacked images (04h 51m 10s). The slideshow shows the image improve (increased brightness, decreased sensor noise) as the number of stacked images increases (1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, 1756, 1747). The full 2.4° x 2.4° (2887 x 2851 pixel) mosaic field was filled after 128 stacked images. The mosaic was in the 8th pass when the observation was paused. The image has been processed using Capture One for brightness and contrast adjustments, and Topaz AI for noise reduction. The use of a dual-band filter significantly enhances the visibility of the nebula.
Vespera II with CLS Filter
Observation of the Rosette Nebula (NGC 2237) and Cluster (NGC 2244) over four nights using the Vespera II telescope with a CLS (city light suppression) filter. The mosaic size for the observation was set to 2.6° x 2.7°. Total of 2656 stacked images (07h 22m 40s). The slideshow shows the image improve (increased brightness, decreased sensor noise) as the number of stacked images increases (1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, 2048, 2655, 2656). The full 2.6° x 2.7° (3854 x 3972 pixel) mosaic field was filled after 256 stacked images. The mosaic was in the 11th pass when the observation was paused. The image after the slideshow was processed (Capture One for brightness and contrast, Topaz AI to remove noise). Lots of stars in this region of the sky. The nebula is not as bright with the CLS filter vs. the Dual filter.
Vespera Pro with Dual Band Filter
Observation of the Rosette Nebula (NGC 2237) and Cluster (NGC 2244) over four nights using the Vespera Pro telescope with a Dual Band (H-α, O-III) filter. The mosaic size for the observation was set to 2.4° x 2.4°. Total of 2894 stacked images (07h 18m 10s). The slideshow shows the image improve (increased brightness, decreased sensor noise) as the number of stacked images increases (1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, 2048, 2893, 2894). The full 2.4° x 2.4° (5304 x 5304 pixel) mosaic field was filled after 128 stacked images. The mosaic was in the 12th pass when the observation was paused. The image has been processed using Capture One for brightness and contrast adjustments, and Topaz AI for noise reduction. The use of a dual-band filter significantly enhances the visibility of the nebula.
Even though it didn’t rain Tuesday night, the sky was too overcast for any observations of the comet (or any other objects). Today it was clear and sunny most of the day with some high-level clouds appearing towards evening. During the day, the Stellina telescope was fitted with a solar filter to observe the sun and sunspots. The images were used to create a time-lapse video.
Comet C/2023 A3 (Tsuchinshan–ATLAS)
I wasn’t sure if it would clear up again in time for the telescopes to observe the comet. Whether doing single observations or automated observation plans, initialization of the Stellina and Vespera telescopes require clear enough sky to see some stars to run the automated initialization routine (sky alignment and focus).
My workflow for doing observations of the comet goes as follows. First, I use the Stellarium software package to look up the RA (right ascension) and Dec (declination) data for Comet C/2023 A3 for my location and time of the observation (19:00 to 20:30). The RA/dec data is used to create manual observation targets in the Vaonis Singularity application. The manual observation targets are then used to create an observation plan. Since the comet is moving relative to stars, I set up a sequence of 15-minute observations from the point it is dark enough for the telescopes to initialize until the comet falls behind the trees toward the western horizon (~19:00 to 20:30). The observation plan is saved and uploaded to the telescope.
Once the plan is started the device does not need to remain connected to the telescope. The telescope waits until it is dark enough to initialize, then runs the observation plan. The observation data is collected and stored in temporary memory within the telescope. When the observation plan is complete (and before the sun comes up) the telescope closes and shuts down.
As long as the device running the Singularity application is connected to the internet, the manual targets and observation plans are stored in the cloud (within your Singularity account). I make use of this so I can share and run the same manual targets and observation plans on multiple Stellina and Vespera telescopes. Note that you need share the information before making the ad hock WiFi connection between the device running Singularity and the telescope. (Note: I use separate devices for each telescope).
I set up the telescopes and started the observation plan, still not sure if the sky would clear. After dinner when I checked the telescopes (~20:00), four out of five initialized and started observations of the comet even though there still were some clouds. During an observation, the telescopes only saves and stacks images when the view is not obstructed. So, in this case when the comet was blocked by clouds the telescope stopped collecting images until the sky was clear again. I am not sure why the Vespera Passengers telescope didn’t initialize. The comet is getting fainter, and the tail shorter.
After the comet dropped below the tree line, the telescopes were set to continue or start multi-night mosaic observations of the Veil Nebulae (NGC 6960 and NGC 6992), the Heart and Fish head Nebulae (IC 1805 and IC 1795), and the Horse Head and Flame Nebulae (IC 434 and NGC 2024). Three of the telescopes (Vespera Classic, Vespera Passenger, and Vespera Pro) were fitted with dual narrow band Hα/OIII (hydrogen alpha/oxygen III) interference filters. The CLS filter remained on the Vespera II telescope, and no filter was used on the Stellina telescope.
Combined Heart and Fish Head Nebula (IC 1805)
Four nights of observation data from a Vespera Pro Telescope (250 mm, f/5, 10 sec exposures) using a Dual band H-alpha, O-III filter. The composite mosaic (2.4° x 2.4°) was created from 3541 images (9h 50m 10s) using the new multi-night capability of the instrument. I am not sure if the green streak near the Fish Head Nebula is a meteor. The slideshow shows the progression of the image
The sky was partly cloudy during the day. The Stellina telescope was fitted with a solar filter to observe the sun and sunspots. After the system locks onto the sun, it takes about 40 images a minute. I believe each exposure is 1/4000 second. In the past I have captured silhouettes of birds or planes passing in front of the sun. 15-September-2023 Since we are in a solar maximum period there are lots of sunspots. In the time-lapse video clouds and jet contrails pass in front of the sun.
By evening, the sky clouded over so no observations of the comet tonight. We really need some rain.
Comet C/2023 A3 (Tsuchinshan–ATLAS) over New Jersey
Another clear night. It has been very dry this fall with few clouds. All five telescopes were out tonight. First viewing the comet. Note several of the images have faint jet or satellite trails crossing the comet. I am guessing that they are satellite trails. The jpg images were processed to increase the brightness (Capture One Pro) and reduce the noise (Topaz AI).
After the comet dropped below the tree line, the telescopes were set to continue or start multi-night mosaic observations of the Veil Nebulae (NGC 6960 and NGC 6992), the Heart and Fish Head Nebulae (IC 1805 and IC 1795), and the Horse Head and Flame Nebulae (IC 434 and NGC 2024). Three of the telescopes Vespera Classic, Vespera Passenger, and Vespera Pro) were fitted with a dual narrowband interference Hα/OIII (hydrogen alpha/oxygen III) filter. The CLS filter remained on the Vespera II telescope, and no filter was used on the Stellina telescope.