Imaging the Sun with a Dwarf mini smartscope

There are two very low cost smart scopes that use the same form-factor, similar optics and the same sensor. These are the ZWO Seestar S30 and the Dwarflabs Dwarf mini.

Both have 30mm objectives and focal Lengths of 150 mm at f/5. They both use the Sony IMX662 (1920x1080) sensor. The Seestar S30 presents the image in portrait format whereas the Dwarf mini presents the image in landscape format. Both scopes are primarily intended for deep sky imaging, but both are capable of imaging the Moon and the Sun (using the provided solar filters). The solar (and lunar) images produced are rather small, but because at this focal length, the image is under-sampled. During stacking, a 1.5 x drizzle can be beneficial, and produce a more useful sized stacked image.

The philosophy of solar and lunar imaging with the Seestar S30 and the Dwarf mini are completely different. The Seestar S30 captures an 8 bit RAW AVI which can be several thousand frames and the Dwarf mini captures 16 bit RAW FITS files. The Dwarf mini defaults to capturing a mere 20 frames, although this can be increased arbitrarily, but because it is a slower process, inevitably far fewer frames will be captured. The Seestar approach is more suited to stochastic or so-called 'lucky imaging' that enables the selection of the best moments of seeing during frame selection and stacking.

There are a number of ways of approaching the analysis and stacking of the FITS files produced by the Dwarf mini. However, we believe that the following is the most economical and suitable method.

We did the data capture on a very poor day through gaps in the clouds. We captured just two sets of 20 FITS files with a number of them being affected to some extent by clouds. (on a better day, larger numbers of frames could be captured to the benefit of the quality of the final image).

The gain was set to zero and the shutter speed to 1/800s which produced a correctly exposed preview on the tablet screen. (With better transparency, faster shutter speeds may be more suitable).

The 40 FITS images that were captured were placed in a single folder (directory) and Autostakkert! 4.0.13 was used to debayer and stack the best 50% of the files.

The problem is that Autostakkert! expects the origin of an image to be top left, whereas the Dwarf mini places the origin at the bottom left. The FITS Keyword "ROWORDER" in the FITS header can be set to "TOP-DOWN" (origin top left)  or "BOTTOM-UP" (origin bottom left). This means that although the bayer pattern of the Sony IMX662 is RGGB, Autostakket! will by default debayer the image incorrectly. To correct this the image needs to be effectively flipped vertically, which in Autostakkert! can be achieved by forcing GBRG as the bayer pattern.

The problem is that the ROWORDER keyword is a non-standard but widely adopted FITS header extension in the amateur astronomy and astrophotography community. It is used to clarify whether an image's pixel data is written from the bottom of the image upward (BOTTOM-UP) or from the top downward (TOP-DOWN), preventing flipped images and incorrect color matrix (Bayer pattern) decoding. The rub is that neither the Seestar S30 nor the Dwarf mini write the ROWORDER into the FITS header. However, both of them write the bayer pattern into the Header. The Dwarf mini writes this: FITS Header.BAYERPAT,RGGB, FITS Header.TELESCOP,DWARF mini which is the correct bayer pattern for the Sony IMX662. The Seestar S30 on the other hand writes: FITS Header.INSTRUME,Seestar S30, FITS Header.BAYERPAT,GRBG which is not correct for the Sony IMX662. In the case of ZWO's Seestar S30, the combination of sensor orientation and their file-writing process shifts the indexing by exactly one row. A vertical shift of one row turns an RGGB pattern into a GRBG pattern. ZWO's standard driver architecture writes FITS images with a BOTTOM-UP row order. To ensure that processing programs debayer the colors correctly when loading these bottom-up files, the driver automatically translates the header's BAYERPAT string to GRBG.

The ROWORDER keyword was introduced in late 2020. While the official professional FITS standard (governed by the IAU) explicitly states that the first pixel in a FITS file should represent the lower-left corner (BOTTOM-UP), a massive influx of modern CMOS camera drivers, ASCOM, and INDI developments defaulted to writing data from the top-down. This discrepancy created massive problems for astrophotography software trying to automatically process color data. 

The ROWORDER keyword was co-created and introduced by Cyril Richard and team, the developers of Siril and Patrick Chevalley of CCDCiel and Cartes du Ciel.  They introduced ROWORDER (a string type keyword that takes the values TOP-DOWN or BOTTOM-UP) to allow capture software and processing software to handle image geometry seamlessly without forcing software developers to break compatibility with legacy data or calibration frames. Shortly after its introduction, other software developers—such as Han Kleijn (creator of ASTAP)—integrated and promoted its use across the amateur astronomy community.  It is a shame that neither of these smart telescopes incorporate the ROWORDER keyword into their FITS headers.

The best 50% of the RAW FITS files being debayered and stacked in Autostakkert!

Cropped square in GIMP3

The stacked, cropped image being white-balanced and wavelet sharpened in waveSharp 3, software developed by Cor Berrevoets et al to replace the wavelet functions of Registax.

The final image being temperature colourised in GIMP3

The final image having been flipped vertically to its correct orientation and given a gentle sharpening in ACDSee

Even with a small amount of data captured under less than ideal conditions, it was possible to produce an acceptable image of the Sun with a Dwarf mini.

A Bresser Messier AR 120xs f/4.51 achromatic ED refractor configured as a Ca K-line telescope

We configured a Bresser Messier AR 120xs f/4.51 achromatic ED refractor fitted with a skywatcher motor focuser and mounted on a Skywatcher Solar Quest solar finding and tracking mount, as a Ca K-line telecope by attaching an Antlia Solar Herschel Wedge with an integral 3nm Ca K-line filter. An Altair 678M camera with 3840 x 2160 pixel resolution was used. This gives a Dawes Limit of 1.14 arc/sec, a field of view of 0.96 x 0.54 degrees and a resolution of 0.9" x 0.9"/pixel. AstroDMx Capture was used with live flatfield correction to capture two overlapping 1500-frame SER files. The best 70% of frames in each SER file were stacked in Autostakkert 4, stitched with MS ICE, wavelet sharpened in waveSharp 3 and finished in Gimp3.

Bresser Messier AR 120xs f/4.51 achromatic ED refractor fitted with a skywatcher motor focuser and mounted on a Skywatcher Solar Quest solar finding and tracking mount

Antlia Solar Herschel Wedge with an integral 3nm Ca K-line filter

The Sun in Ca K-line light monochrome image

The Sun in Ca K-line light colourised image

Although the A Bresser Messier AR 120xs is a fast achromat, the fact that it is dealing with only a 3nm bandwidth in the UV means that the Ca K-line light is not subject to chromatic aberration when used in this configuration. Substantial amounts of the chromospheric network are visible.

Uncooled, magnified, deep sky imaging

For uncooled, magnified, deep sky imaging we used an Askar 71F quadruplet apochromatic astrograph refractor paired with a Player One Mars-C II OSC camera. The scope was fitted with an iOptron iEAF motor focuser and an Altair V2 magnetic 2” filter holder containing an Altair Quadband filter. An SVBONY SV165 guide-scope fitted with a QHY-5II-M guide camera was mounted on the imaging scope. The whole rig was mounted on a Celestron AVX GOTO EQ mount.

The Player One Mars-C II camera pairs excellently with the Askar 71F quadruplet apochromatic refractor. 

Because the Mars-C II features a small 1/2.8-inch Sony IMX662 sensor (5.6mm x 3.2mm), it will heavily crop the telescope’s native field of view. This configuration turns the wide-field telescope into a high-magnification setup suitable for small targets. 

The Askar 71F has a focal length of F=490 mm and an f ratio of f/6.9

The Player One Mars-C II camera with 2.9µm pixels at 1.22 arcseconds per pixel fits perfectly into the ideal sampling range (0.67"–2.0") for average atmospheric seeing with this telescope.

The field of View (FOV) of 0.66° x 0.37° is ideal for framing small deep-sky objects.

The Askar 71F provides a 44mm flat image circle. Since the Mars-C II sensor uses only the centre of the image circle (6.44mm diagonal), stars are perfectly pinpoint and aberration-free from corner to corner. 

The Mars-C II features STARVIS 2 technology with a 54ke- full-well capacity. This allows for long exposures during imaging without clipping star cores. The IMX662 sensor has zero amp-glow.

AstroDMx Capture for Linux x86_64 was used to capture the image data as FITS images with flats and matching darks.

53 x 1 minute exposures of M16 were used. The data were stacked and part processed in PixInsight and further processed in GraXpert, SetiAstroSuitePro and Gimp3.

Screenshot of AstroDMx Capture capturing M16 data

M16 HOO rendering

M16 RGB rendering

The 'pillars of creation' were magnified with this setup providing a good close-up of this feature.

45 x 1 minute exposures on each of M3 and M13 were used. The data were stacked and part processed in PixInsight and further processed in GraXpert and Gimp3.

AstroDMx Capture capturing M3 data

M3

AstroDMx Capture capturing M13 data

M13

The combination of the Askar 71F quadruplet apochromatic astrograph refractor and the Player One Mars-C II OSC camera proved to be a good combination for imaging small objects.

 

First light for a Windows ARM, Snapdragon powered laptop for astronomical imaging

 

Nicola has implemented AstroDMx Capture for Windows ARM natively on a Snapdragon powered laptop.

 The computer used was a Lenovo IdeaPad Slim 3x 15in Snapdragon X1-26-100 powered Windows ARM computer.

The imaging equipment used

For deep sky imaging we used an Askar 71F quadruplet apochromatic astrograph refractor paired with an SVBONY SV605CC OSC camera. The scope was fitted with an Altair V2 magnetic 2” filter holder containing an IR/UV cut filter and an iOptron iEAF motor focuser. An SVBONY SV165 guide-scope fitted with a QHY-5II-M guide camera was mounted on the imaging scope

Snapdragon X1-26-100 specifications

• Core Count: 8 Oryon CPU cores
• Clock Speed: Up to 2.97 GHz - 3.0 GHz
• Graphics:  Qualcomm Adreno GPU (1.7 TFLOPS)
• AI Performance:  45 TOPS Hexagon NPU

At the time of writing, the Snapdragon ARM processors have started to gain traction in the laptop and mini computer markets. Snapdragon laptops are characterised by being very power efficient and by being able to run for extended periods on battery power. From the astronomical imaging point of view, this is new technology and very few camera manufacturers have produced Windows ARM drivers or SDKs. This situation is bound to improve as these computers become more popular. 

For deep sky imaging we used an Askar 71F quadruplet apochromatic astrograph refractor paired with an SVBONY SV605CC OSC camera. The scope was fitted with an Altair V2 magnetic 2” filter holder containing an IR/UV cut filter.

In our deep sky imaging experiments we used AstroDMx Capture on the Snapdragon Windows laptop and controlled the SV605CC OSC camera as well as the mount and iEAF focuser via an INDI server running on a Fedora mini computer. Guiding was done by PHD2 autoguiding running on a separate Fedora Linux laptop. In our H-alpha solar imaging experiment we used a Touptek GPCMOS01200KPF OSC camera running natively and a Coronado Solarmax II 60, BF 15, H-alpha telescope.

Deep Sky Imaging

Screenshots of AstroDMx Capture imaging deep sky objects

Markarian's chain

M3

One hour's worth of 3 minute exposures was captured on each of the objects as FITS files. The data were processed in PixInsight, SetiAstroSuitePro, GraXpert and Gimp3

Markarian's Chain

M3

Solar H-alpha imaging

Lenovo Snapdragon powered laptop connected to the H-alpha imaging equipment

H-alpha scope and Touptek camera mounted on a Skywatcher Solar Quest solar finding and tracking mount.

Screenshot of AstroDMx Capture streaming H-alpha solar data

Two overlapping 1000-frame SER file panes were captured. The best 50% of the frames were debayered and stacked in Autostakkert!4, wavelet processed in waveSharp 3 and finished in Gimp3

The Solar disk in H-alpha

In conclusion, the first light tests of the Snapdragon powered Windows 11 computer were successful and showed that these relatively low cost, powerful and energy efficient laptops are very suitable for astronomical imaging, and would be very useful for imaging in the field. It seems to us that the future of laptop computing could lie with ARM powered machines. When astronomical camera manufacturers produce ARM drivers and SDKs it is likely that more astronomical imagers will switch to these types of machines as they upgrade their computing equipment.

First light for a Macbook Neo laptop for astronomical imaging

The Macbook Neo laptop (Running AstroDMx Capture)

The Apple MacBook Neo 13-inch Laptop with A18 Pro chip has a Liquid Retina Display, 8GB of Unified Memory, 256GB SSD Storage

The Apple A18 is a 3nm (TSMC N3E) 6-core System on a Chip. It features 2 performance cores (4.04--4.05 GHz) and 4 efficiency cores, a 5-core GPU, and a 16-core Neural Engine capable of 35 Trillion Operations Per Second (TOPS). It supports 8GB of LPDDR5X RAM on-package with 17% more memory bandwidth than previous generations, offers high energy efficiency (3-4W sustained), and is designed for on-device AI.

It has the same CPU performance as the A16 Bionic while consuming 30% less power. Due to its power efficiency the Macbook Neo has an extremely long battery life before requiring re-charging.

Single-Core Performance:

The A18 Pro often outperforming the most powerful x86 desktop processors. In Geekbench 6 tests, it achieves single-core scores around 3,400–3,500. This puts it ahead of top-tier desktop CPUs like the Intel Core i9-14900KS and the AMD Ryzen 9 9950X as well as The snapdragon ARM SOC in single-threaded tasks .

Multi-Core Performance:

Due to its 6-core architecture (2 performance, 4 efficiency cores), the A18 Pro falls behind high-end x86 desktop and laptop processors as well as the Snapdragon SOC in heavy multi-threaded workloads. With a multi-core score of approximately 8,500–9,100, its performance is comparable to mid-range mobile or older desktop x86_64 CPUs:

The Macbook Neo is the lowest cost laptop that Apple has ever released, but it retains the usual Apple build quality.

All of these factors make the Macbook Neo very suitable for astronomical imaging.

The Macbook Neo was used with two telescopes and two cameras to make initial tests of different aspects of astronomical imaging.

For deep sky imaging we used an Askar 71F quadruplet apochromatic astrograph refractor paired with an SVBONY SV405CC OSC camera. The scope was fitted with an Altair V2 magnetic 2” filter holder containing an IR/UV cut filter.

For lunar imaging we used a Skymax 127 Maksutov Cassegrain paired with an SVBONY SV505C OSC camera fitted with an IR/UV cut filter.

Deep Sky imaging

The equipment used

Screenshot of AstroDMx Capture capturing FITS images of M5

The data were debayered, stacked and part processed in PixInsight and further processed in GraXpert, SetiAstroSuitePro and Gimp3. This was the procedure followed for each of the three deep sky objects tested: M5, M3 and the Leo Triplet.

M5

M3

Screenshot of AstroDMx Capture capturing FITS images of The Leo Triplet

The Leo Triplet

Lunar imaging with a Skymax 127 Maksutov Cassegrain paired with an SV505C OSC camera.

1000 frame RAW 8 bit SER files were captured of 9 overlapping panes of the Moon.

AstroDMx Capture capturing RAW lunar SER files

An eight pane mosaic of the 68.5% waxing Moon was captured (we later found that only 8 panes were necessary). Each pane was a 1000 frame SER file captured by AstroDMx Capture running on the Macbook Neo through a Skymax 127 Maksutov using an SV705C OSC camera fitted with an IR/UV cut filter. Initially the SER files were transferred to another computer for stacking and processing. Each pane was a stack of the best 90% of the frames in the SER, stacked in Autostakkert!3. The 9 panes were stitched in MS ICE, wavelet processed in Registax6 and finished in Gimp3.

The final mosaic of the Moon

We then decided to find out how much of the data processing could have been done directly on the Macbook Neo. These were important tests, but it is normally our practice to transfer data to a desktop mini computer for processing and posting.

Planet Stacker X

Planet Stacker X is a native Apple silicon stacking and processing program.

Screenshot of a SER file loaded into Planet Stacker X

Stacking

Screenshot showing the stacking is completed and the opportunity to take the stacked image directly into the processing part of the program or be save to be loaded into this software later

Screenshot of the processing part of the software doing wavelet sharpening

The processed image exported as a 16 bit TIFF file

Planet Stacker X is a modern, native macOS successor to PlanetarySystemStacker (PSS), and was developed by Rain City Astro.

The relationship between the two is defined by their shared purpose and architectural evolution: The developer created Planet Stacker X out of frustration with running PSS on Apple Silicon (M1/M2/M3) Macs. Because PSS is a Python-based application, it requires complex dependency management and often relies on x64 emulation, which can be fragile and slow on newer Macs.

Planet Stacker X shares all the core features of PlanetarySystemStacker, and was built "from the ground up" specifically for macOS frameworks.

Unlike PSS, Planet Stacker X runs natively on Apple Silicon without emulation and utilises GPU acceleration and the Apple Neural Engine to significantly speed up analysis and stacking pipelines.

Planet Stacker X also includes image processing tools.

While PlanetarySystemStacker remains a powerful open-source tool for Windows, Linux, and older Macs, Planet Stacker X is a more user-friendly, high-performance alternative for the modern Mac Apple Silicon devices.

Panorama Stitcher

Panorama Stitcher was developed by Olga Kacher for macOS and iOS. It runs natively on Apple silicon. It is built on its own propitiatory engine and is not derived from other stitching software. It uses its own algorithms for automatic alignment and exposure levelling and it features fully automatic drag and drop for loading images.

Screenshot of Panorama Stitcher stitching two overlapping panes of lunar images

The images were stitched using planar motion and were saved as a 16 bit TIFF file.

All eight unprocessed panes were similarly stitched with Panorama Stitcher

The stitched image was processed in the Planet Stacker X image processor

Solar imaging

Equipment used

A William Optics ZenithStar 66 SD Apochromatic refractor fitted with an ICE ND 100000 solar filter was mounted on a Skywatcher Solar Quest solar finding and tracking mount. A Touptek Toupcam GPCMOS01200KPF OSC camera fitted with a UV/IR cut filter was used to capture the data.

Two overlapping panes of 1000-frame SER files were captured by AstroDMx Capture with the MacbookNeo.

For each pane, the best 50% of the frames in the SER file were stacked and wavelet processed in Planet Stacker X.

The two resulting panes were stitched as a panorama and cropped in Affinity

Deep Sky processing with Apple silicon

We installed and tested various software that is native Apple silicon.

Deep sky stacking and processing software

Affinity

Screenshot of Affinity stacking the M5 data

Affinity processing the stacked image

Affinity derives from the Serif Affinity Photo software. This was acquired by Canva and is now freeware. It retains the functionality of the original Serif software and has an Apple silicon version.

Siril

Screenshot of Siril processing the stacked M3 image

ASI Studio

Screenshot of ASI studio ASIDeepStack stacking the M3 data

PixInsight will also run on Apple silicon but we did not install it here.

Starnet++

Starnet++ can be installed as a command line version for macOS and works exactly as it does in Windows

Screenshot of Starnet++ running at the command line

Screenshot showing the starless version of the mono 16 bit test image

CosmicClaritySuite_apple_silicon standalone.

We tested three important functions of this software:

SetiAstroCosmicClarity_denoisemac

SetiAstroCosmicClaritymac for sharpening stellar and non-stellar parts of an image

Animation showing the normal and sharpened versions of an image

SetiAstroCosmicClarity_superres for upscaling an image 

General image processing software

GIMP3

Pinta 

We shall continue to test the Macbook Neo for astronomical imaging. However, so far, it has performed perfectly. This article was written on the Macbook Neo using Libre Office Writer which is an open source alternative to Apple's Pages, and runs natively on Apple silicon.