Friday (15-September-2023) — New Jersey

Backyard Day and Nighttime Sky Over New Jersey.

With the sky clear, I set up the Vespera Observation station with a solar filter during the day to observe sunspots. When I reviewed the images, I found one with a silhouette of a bird (Turkey Vulture?) flying in front of the sun. In the past I have capture images of planes, and sometimes satellites transiting the solar disk. While on Semester at Sea voyages, we had an informal contest to capture images of ships at the horizon passing in front of the sun at sunset (or sunrise).

Silhouette of bird flying in front of the Sun. (David J Mathre)
Silhouette of bird flying in front of the Sun. Image taken with a Vespera Observation Station (50 mm lens, 200 mm focal length, f/4, 1/4000 sec) fitted with a solar filter. Image processed with Topaz Photo AI. (David J Mathre)

Once it got dark out, I set up both the Vespera and Stellina observation stations to observe deep sky objects (galaxies, nebulae, star clusters). The Vespera was fitted with a dual band (H-alpha and O-III) filter. The Vespera captured images of NGC 6960: Western Veil Nebula, Witch’s Broom Nebula; IC 1396: Elephant’s Trunk Nebula; and IC 1795: Fish Head Nebula. The final one didn’t go to completion due to condensation on the lens.

NGC 6960: Western Veil Nebula, Witch's Broom Nebula. (David J Mathre)
NGC 6960: Western Veil Nebula, Witch’s Broom Nebula. Composite of 407 10 second exposures taken with a Vespera Observation Station (50 mm lens, 200 mm focal length, f/4, 4070 sec) using a dual band (H-alpha, O-III) filter. Image processed with Topaz Photo AI. (David J Mathre)
IC 1396 Emission Nebula (Elephant's Trunk Nebula). (David J Mathre)
IC 1396 Emission Nebula (Elephant’s Trunk Nebula). Composite of 623 10 second exposures taken with a Vespera Observation Station (50 mm lens, 200 mm focal length, f/4, 6230 sec) using a dual band (H-alpha, O-III) filter. Image processed with Topaz Photo AI. (David J Mathre)
IC 1795 Emission Nebula (Fish Head Nebula). (David J Mathre)
IC 1795 Emission Nebula (Fish Head Nebula). Composite of 175 10 second exposures taken with a Vespera Observation Station (50 mm lens, 200 mm focal length, f/4, 1750 sec) using a dual band (H-alpha, O-III) filter. Image processed with Topaz Photo AI. Note: Observation did not run to completion. (David J Mathre)

For the Stellina, I used the “Plan My Night” option to collect images of Messier 29 Open Cluster (M29, NGC 6913); NGC 6946 (Fireworks Galaxy); NGC 7331 Spiral Galaxy (Caldwel 30); Messier 31 Spiral Galaxy (Andromeda Galaxy, NGC 224); Messier 74 Spiral Galaxy (M74, NGC 628, Phantom Galaxy); Messier 110 Dwarf Elliptical Galaxy (M10, NGC 205); IC 342: The Hidden Galaxy in Camelopardalis. The system was set to collect images for about an hour for each object. For some reason, the telescope did not automatically close at the end of the collection. I am not sure if the external Anker Power USB power supply ran out. The lens was covered with dew. The Stellina system has a lens heater that is supposed to prevent condensation so may be the reason the power bank ran out. The Vespera system does not have the lens heater option installed.

Messier 29 Open Cluster (M29, NGC 6913). (David J Mathre)
Messier 29 Open Cluster (M29, NGC 6913). Composite of 131 exposures taken with a Stellina Observation Station (80 mm lens, 400 mm focal length, f/5, 1310 sec). Image processed with Topaz Photo AI. (David J Mathre)
NGC 6946 (Fireworks Galaxy). (David J Mathre)
NGC 6946 (Fireworks Galaxy). Composite of 220 10 second exposures taken with a Stellina Observation Station (80 mm lens, 400 mm focal length, f/5, 2200 sec). Image processed with Topaz Photo AI. (David J Mathre)
NGC 7331 Spiral Galaxy (Caldwel 30). (David J Mathre)
NGC 7331 Spiral Galaxy (Caldwel 30). Composite of 143 10 second exposures taken with a Stellina Observation Station (80 mm lens, 400 mm focal length, f/5, 1430 sec). Image processed with Topaz Photo AI. (David J Mathre)
Messier 31 Spiral Galaxy (Andromeda Galaxy, NGC 224). (David J Mathre)
Messier 31 Spiral Galaxy (Andromeda Galaxy, NGC 224). Composite of 601 10 second exposures taken with a Stellina Observation Station (80 mm lens, 400 mm focal length, f/5, 6150 sec). Image processed with Topaz Photo AI. (David J Mathre)
Messier 74 Spiral Galaxy (M74, NGC 628, Phantom Galaxy). (David J Mathre)
Messier 74 Spiral Galaxy (M74, NGC 628, Phantom Galaxy). Composite of 203 10 second exposures taken with a Stellina Observation Station (80 mm lens, 400 mm focal length, f/5, 2030 sec). Image processed with Topaz Photo AI. (David J Mathre)
Messier 110 Dwarf Elliptical Galaxy (M10, NGC 205). (David J Mathre)
Messier 110 Dwarf Elliptical Galaxy (M10, NGC 205). Composite of 367 10 second exposures taken with a Stellina Observation Station (80 mm lens, 400 mm focal length, f/5, 3670 sec). Image processed with Topaz Photo AI. Located near the Andromeda galaxy (bottom right corner). (David J Mathre)
IC 342: The Hidden Galaxy in Camelopardalis. (David J Mathre)
IC 342: The Hidden Galaxy in Camelopardalis. Composite of 239 10 second exposures taken with a Stellina Observation Station (80 mm lens, 400 mm focal length, f/5, 2390 sec). Image processed with Topaz Photo AI. (David J Mathre)

Daily Electric Energy Used (46.5 kWh) from Sense. Daily Solar Electric Energy Produced (51.7 kWh) from Sense. Sunny. Surplus of 5.2 kWh.

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Sunday (15-January-2023) — New Jersey

Backyard Nighttime Sky Over New Jersey.

After several days of clouds and rain, the skies finally cleared. I had both the Stellina and Vespera systems out. There currently several active sunspots. During the night I captured images of the Andromeda Galaxy (M31), Orion Galaxy (M42), Rosette Nebula (NBC 2237), Satellite Cluster (NGC 2244), Pinwheel Galaxy (M101), and the Moon. Also, I used the manual mode to search for the Comet C/2022 E3 (ZTF). It was finally high enough to be viewed to the northeast over the house from my patio. I used the Sky Live website to get the location, and then just plugged the numbers into the Singularity application. Within minutes, both the Stellina and Vespera systems had the comet centered and started taking images.

For the following images, I processed the final JPG image with Topaz AI, followed by Capture One Pro. For the raw TIFF images, I needed to use Capture One Pro first, followed by Topaz AI. Follow the link to my PhotoShelter Gallery for larger views of the images. The nebulae images taken using the dual H-alpha, O-III filter are more vivid.


Vespera Deep Sky Observations. JPG images processed with Topaz AI, followed by Capture One Pro. Individual images in the slideshow are available in my PhotoShelter Gallery.


Vespera Deep Sky Observations. TIF images processed with Capture One Pro followed by Topaz AI. Individual images in the slideshow are available in my PhotoShelter Gallery.

Since it was a dark night, I also set up a camera to capture images for a composite star and jet trails view looking north. Polaris isn’t exactly at the celestial north point. The file size is 11656 x 8742 (403.4MB).

alt_title. (David J Mathre)
Star and Jet Trails looking north. Composite of 110 images taken with a Hasselblad X2d camera and 30 mm f/3.5 lens (ISO 64, 30 mm, f/8, 323 sec). Raw images processed with Phocus and Capture One Pro. Composite created with Photoshop (scripts, statistics, maximum). (David J Mathre)

Daily Electric Energy Used (92.8 kWh) from Sense. Daily Solar Electric Energy Produced (33.3 kWh) from Sense. Sunny. Deficit of 59.6 kWh.

Weekly Electric Energy Used (618 kWh) from Sense. Weekly Solar Electric Energy Produced (121 kWh) from Sense. Deficit of 497 kWh.

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Monday (19-December-2022) — New Jersey

Backyard Nighttime Sky Over New Jersey.

I spent my first night with the Vespera (automated deep sky camera) capturing images of several objects. I set the Vespera up on a tripod in my back patio which has a view of the sky southeast to southwest, and to the north elevations above the house. Both east and west are blocked by trees. The Vespera is controlled via WiFi by the Singularity app running on an android (or iOS) device. Unfortunately, there is not a Window or web-based app. Also, the WiFi uses an open (not secured) connection between the notepad and Vespera.  Once the WiFi connection is established the Singularity app controls the instrument. It takes 10-15 minutes to initialize the Vespera. During this time the camera points to the sky, determines its position and focuses the camera. After that it is just a matter of selecting the objects to view. The Singularity app has the location of several hundred objects (stars, clusters, nebulae, galaxies, and planets) pre-programed in its database along with recommendations for the length of image/data collection.

During the night I captured images of the Triangulum Galaxy (M33), Helix Nebula (NGC 7293), Pleiades Cluster (M45), Orion Nebula (M42), an open cluster (NGC 1502), Bode’s Galaxy (M81), Cigar Galaxy (M82), Polaris (North Star), Andromeda Galaxy (M31), a double cluster (NGC 884, NGC 869), Caroline’s Rose Cluster (NGC 7789), Rosette Nebula (NGC 2244), and the Seagull Nebula (IC 2177). I also had it view Jupiter; however, the disk is small, and I was not able to see Jupiter’s moons.

For most of the objects I did short 5-to-10-minute data collections just to get an idea of how the Vespera worked. This was shorter than the times recommended, but still provided decent images. The Vespera camera has a 200 mm focal length, f/4 aperture, and takes 10 second exposures. The camera uses a Sony IMX462 back-illuminated CMOS sensor (1920×1080) optimized for low light capture. The Vespera automatically processes (aligning and stacking) the images. Over time, the signal/noise ratio increases providing improved image quality. The default output from the Vespera is a JPG image every ~10 seconds (integrated stacked composite) displayed on the notepad screen. At the end of the observation the composite raw image can be saved as a TIFF file. The camera also has the ability to store individual raw images (FITS) that can be processed offline using more sophisticated software. The Vespera does not have a port (USB, ethernet) or memory card slot (SD, CF) to download the data collected by the onboard computer. The data needs to be downloaded by FTP via WiFi. The Vespera has 10 GB of onboard memory for storing images. You need to remember to remove/delete images after downloading to free up space for the next night of observations.

For the following images, I processed the final JPG image of the object with Topaz AI, followed by Capture One Pro. For the raw TIFF images, I needed to use Capture One Pro first, followed by Topaz AI.


Vespera Deep Sky Observations. JPG images processed with Topaz AI, followed by Capture One Pro. Individual images in the slideshow are available in my PhotoShelter Gallery.


Vespera Deep Sky Observations. TIF images processed with Capture One Pro followed by Topaz AI. Individual images in the slideshow are available in my PhotoShelter Gallery.

Daily Electric Energy Used (95.7 kWh) from Sense. Daily Solar Electric Energy Produced (19.5 kWh) from Sense. Sun and clouds. Deficit of 76.2 kWh.


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