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indi-allsky

indi-allsky is software used to manage a Linux-based All Sky Camera using the INDI framework. Theoretically, any INDI supported CCD/CMOS camera can be functional.

Pictured: SpaceX Cargo Dragon (over Georgia) headed for splashdown off the coast of Florida

New Features

  • Moon Overlay
    • Realtime accurate representation of illumination of the moon
  • Satellite Tracking
  • ADS-B Aircraft Tracking
    • Use a SDR to tag aircraft that appear in your camera
  • Mini-Timelapses
    • Create videos of specific events captured with your camera
  • Weather API
    • OpenWeather Map API
    • Weather Underground API
  • Native Fan controller support
    • Standard
    • PWM Controlled
  • Native Dew Heater support
    • Standard
    • PWM Controlled
  • Native Temperature Sensor support
    • DS18B20 1-wire
    • DHT11/22
    • BMP180
    • BME280 (i2c & SPI)
    • BME680 (i2c & SPI)
    • Si7021
    • SHT3x
    • SHT40/41/45
    • AHT10/20
    • LM35 via ADS1x15 ADC
    • TMP36 via ADS1x15 ADC
    • MLX90614 Sky Temperature
    • MLX90640 Thermal Camera
  • Light (Lux) Sensors
    • TSL2561
    • TSL2591
    • VEML7700
    • BH1750
    • SI1145
    • LTR390
  • Generic GPIO controls
  • MQTT Broker sensors
    • Subscribe to topics as sensor input
  • Mechanical focuser support
    • 28BYJ-48 Stepper
  • Use star metrics (in addition to ADU) for star trails generation
  • Generate thumbnails to reduce load time in Timelapse view
  • Panorama timelapse generation
  • Fish-eye to Panoramic perspective
  • Upload timelapse videos directly to YouTube
  • Cardinal direction labels
  • Satellite tracking and visibility info
  • Wildfire smoke reporting (North America only)
  • Aurora prediction and Kp-index reporting

Features

  • RAW data is the default and preferred input
    • INDI - 16-bit FITS data
    • libcamera - 16-bit DNG data
    • Also supports 8-bit RGB, PNG, and JPEG input
  • Multiple camera vendor support
    • ZWO
    • Svbony
    • QHY
    • Altair
    • ToupTek
    • Starlight Xpress
    • Player One Astronomy
    • Raspberry Pi Camera Modules
      • HQ Camera (IMX477)
      • IMX378
      • Camera Module v3 (IMX708)
      • AI Camera (IMX500)
      • IMX283 Klarity/OneInchEye
      • IMX519
      • IMX462
      • IMX327
      • 64mp HawkEye (IMX682)
      • 64mp OwlSight (OV64A40)
      • other libcamera supported modules
    • DSLRs
    • Generic web cameras
    • More to come
  • Image stretching (16-bit)
    • Standard Deviation Cutoff (Original)
    • Midtone Transfer Function
  • Multi-image stacking
  • Dark calibration frames to remove hot pixels
  • Camera temperature control (for cameras with active cooling)
  • Timelapse video generation
  • GPS support
  • Images tagged with EXIF data (JPEG only)
  • TrueType font support for image labels
  • Remote web portal
  • Network file transfers - Upload images and videos to remote site
    • S3 Object Storage support
      • Amazon Web Services
      • Google Cloud Storage
      • Oracle OCI Storage
  • Publish data to an MQTT service for monitoring
    • Home Assistant Auto-Discovery integration
  • Keograms
  • Star Trails
  • Automatic meteor/plane/satellite detection
  • Docker containerization support
  • Images display local hour angle of sun and moon
  • Moon mode - reduced gain when the moon is overhead
  • Remote INDI server operation - operate camera remotely over the network
  • Pseudo-Sky Quality Meter - Use your all sky camera to measure sky brightness/quality
  • Relational database stores image and timelapse information
    • SQLite (default)
    • MySQL/MariaDB

Frequently Asked Questions

https://github.com/aaronwmorris/indi-allsky/wiki/FAQ

Requirements

  • A computer running a modern Linux distribution, such as a Raspberry Pi
    • Multicore is recommended
      • ARM
      • x86_64
    • 2GB RAM recommended, 1GB minimum
      • 512MB is adequate for image acquisition, but not enough to generate timelapse videos with ffmpeg
    • 64GB of storage minimum to store 2 months of videos and 30 days of JPEG images.
    • (Optional) Internet connectivity for image uploading
  • Camera
    • Most INDI supported astro/planetary cameras will work
    • libcamera - Raspberry Pi camera module

Distibution support

Distribution Arch Note
Raspberry Pi OS 12 (bookworm) aarch64 (64-bit) RECOMMENDED
Compile INDI with build_indi.sh
Use libcamera or indi_pylibcamera for Raspberry PI HQ camera
Raspberry Pi OS 12 armhf (32-bit) (DO NOT USE) WARNING: Currently has package dependency problems, please use 64-bit
Raspberry Pi OS 11 (bullseye) aarch64/armhf Compile INDI with build_indi.sh
Raspberry Pi OS 10 (buster) armhf (NOT RECOMMENDED) Compile INDI with build_indi.sh
Debian 12 (bookworm) x86_64 Compile INDI with build_indi.sh
Debian 11 (bullseye) x86_64 Compile INDI with build_indi.sh
Debian 10 (buster) x86_64 (NOT RECOMMENDED) Compile INDI with build_indi.sh
Ubuntu 24.04 (noble) Requires INDI 2.0.8 or newer for pyindi-client
INDI installed from ppa:mutlaqja/ppa
Compile libcamera with build_libcamera.sh
Python 3.11 installed from ppa:deadsnakes/ppa (due to problems with Python 3.12 and pyindi-client)
Ubuntu 22.04 (focal) aarch64 INDI installed from ppa:mutlaqja/ppa
Ubuntu 22.04 armhf Compile INDI with build_indi.sh
Ubuntu 22.04 x86_64 INDI installed from ppa:mutlaqja/ppa
Ubuntu 20.04 (bionic) x86_64 INDI installed from ppa:mutlaqja/ppa
Ubuntu 20.04 aarch64 Compile INDI with build_indi.sh
Armbian aarch64/armhf Compile INDI with build_indi.sh
https://github.com/aaronwmorris/indi-allsky/wiki/Armbian-Tuning
Astroberry Server 2.0 armhf (DO NOT USE) The Astroberry appears to be abandoned and is no longer supported with indi-allsky

INDI support

Version Note
v2.1.0 Recommended
v2.0.9
v2.0.8 Minimum for Ubuntu 24.04 (pyindi-client)
v2.0.7 Minimum for ASI676MC
v2.0.6
v2.0.5 Requires upgrade to indi-allsky v7.7
ZWO ASI problem
v2.0.4 Typo in indibash.h prevents building pyindi-client
Svbony support is broken
v2.0.3
v2.0.2
v2.0.1

Single Board Computer support

Board Note
Raspberry Pi 5 Requires bookworm (12)
Raspberry Pi 4 Recommend 64-bit bookworm (12)
Raspberry Pi 3 Recommend 64-bit bookworm (12), recommend 1GB of swap
Raspberry Pi Zero 2 Recommend 64-bit bookworm (12), memory constrained
Raspberry Pi Zero Recommend 32-bit bullseye, memory constrained
Rock Pi
Libre Computer (Le Potato)
Orange Pi
Orange Pi PC Plus Requires 2GB swap (and patience) to build all python modules
Banana Pi
BeagleBone

Memory Requirements for Timelapses

Memory requirements are primarily driven by the resolution of the timelapse generated by the FFMPEG utility. A higher resolution camera can be used on lower memory system by scaling the output resolution of the FFMPEG process.

Output Resolution Recommended Memory Minimum Memory FFMPEG Process Memory
1280 x 960 (1.2MP) 2GB 1GB with 1GB swap 0.4GB
1920 x 1080 (2MP) 2GB 1GB with 1GB swap 0.6GB
3840 x 2160 (8MP) 4GB 2GB with 1GB swap 1.7GB
3008 x 3008 (9MP) 4GB 2GB with 1GB swap 1.8GB
4056 x 3040 (12MP) 4GB 2.5GB
6224 x 4168 (26MP) 8GB 5.0GB
9152 x 6944 (64MP) 16GB 12.0GB

Installation

The process for installing indi-allsky is documented in the wiki.

https://github.com/aaronwmorris/indi-allsky/wiki/Getting-Started

Docker Containerization

indi-allsky has full support for running in a containerized environment. Check out the docker/ folder for the Docker assets.

https://github.com/aaronwmorris/indi-allsky/wiki/Docker

Logs

  • When indi-allsky is run from the command line, logs are sent to STDERR by default.
  • When the indi-allsky service is started, logs are sent to syslog via facility local6. Logs are stored in /var/log/indi-allsky/indi-allsky.log and rotated daily.
    • Web interface logs are located at /var/log/indi-allsky/webapp-indi-allsky.log

Updating

indi-allsky updates are designed to be rolling releases. I do everything I can to prevent breaking changes. Most changes only require pulling updates from GitHub and re-running setup.sh.

https://github.com/aaronwmorris/indi-allsky/wiki/Updating-indi-allsky

Security

In an effort to increase security, I am trying to do a better job of tracking security issues in indi-allsky and the associated Software Bill of Materials. GitHub Dependabot alerts are enabled which help track things like vulnerable Python modules.

https://github.com/aaronwmorris/indi-allsky/wiki/Security-considerations

https://github.com/aaronwmorris/indi-allsky/wiki/Security-Notifications

libcamera support

libcamera is a new camera interface designed to replace the legacy camera interfaces such as V4L2.

Proper libcamera support is only working on Raspberry Pi OS 11 (bullseye) on Raspberry Pi 3 & 4.

https://github.com/aaronwmorris/indi-allsky/wiki/libcamera-enablement

Note: Genererating and processing raw (dng) files on a system with less than 1GB of memory and libcamera will cause out-of-memory conditions. There is an option to generate JPEG or PNG files with libcamera which solves this issue.

Dark frames

indi-allsky fully automates the capture and processing of master dark calibration frames. Currently, sigma clipping and average methods are supported.

https://github.com/aaronwmorris/indi-allsky/wiki/Dark-Calibration-Frames

Moon mode

This is a special night time operating mode intended to reduce gain when the moon is more illuminated and above the horizon

Keograms

Keograms are a visual representation of the entire timelapse video in a single frame. Every image is rotated so that the vertical aligns to the meridian and then the center-vertical column is extraced from each frame and compiled into the keogram. The rotation parameter in the config is KEOGRAM_ANGLE

https://github.com/aaronwmorris/indi-allsky/wiki/Keogram-Rotation

Below you can see perodic clouds passed over between 8-9pm and again between 4-5am. If you look closely enough, you can see the Pleiades star cluster and the Orion constellation as it passed through the meridian in this example keogram.

Note: The horizontal lines are just hot pixels that were subtracted by the dark frame.

Star Trails

Star trail images stack the stars from each frame to show their progression across the sky.

Star Trails Timelapse

Video of the star trails being stacked in real-time!

YouTube

Smoke reporting

indi-allsky polls data from NOAA Office of Satellite And Product Operations to report the level of smoke coverage in your location. The OSPO provides KML map data for their Hazard Mapping System Fire and Smoke Product [HMS]. indi-allsky processes the smoke polygons in the KML map data and checks if your location (~35 mile radius) is contained within the smoke areas.

Smoke data is updated every 3 hours from NOAA. Smoke data is also published with the MQTT data.

Note: Data is only available for North America.

Aurora & Kp-index

indi-allsky utilizes data from NOAA Space Weather Prediction Center to predict the possibility of Aurora in your location. The SWPC provides data using the Ovation Aurora Model for aurora predictions. indi-allsky uses the Ovation data to create an aggregate score within a ~500 mile radius around your location.

The current Kp-index value is also polled from NOAA. This is the measurement of the disturbance of the Earth's magnetic field, ranging from 0-9. Values higher than 5 are good indicators of stronger solor storm activity which creates aurora.

The Kp-index data, combined with the Ovation data, gives an objective prediction of the visibility of Aurora for your location.

Aurora data is updated every 60 minutes from NOAA. Aurora data is also published with the MQTT data.

Satellite Tracking

Satellite tracking data is used to track the visibility of specific satellites like the International Space Station and Hubble Space Telesope. Rise, transit, and set times are available in the Astropanel view.

Orbital data is downloaded in TLE format from CelesTrak

Star Detection

indi-allsky utilizes OpenCV pattern matching to detect and count the number of stars in the view. Star counts are a good objective measurement of sky conditions.

Star and meteor detection support using detection masks to customize your Region of Interest if there are obstructions in your view. https://github.com/aaronwmorris/indi-allsky/wiki/Detection-Masks

Meteor Detection

Using OpenCV Canny edge detection and Hough Line Transform, indi-allsky is able to perform basic line detection to detect meteor and fireball trails in the view. Airplane and satellite trails are also detected using this method. Images are tagged with an asterisk in the image viewer if a trail has been detected.

Focus Mode

Focus mode is a special setting that generates images more often and implements a Variance of Laplacian scoring algorithm on the image to assist with focusing the camera. Images are not saved when focus mode is enabled.

Stacking

indi-allsky supports image stacking to increase details and contrast in the image.

The following stacking modes are provided:

  • Maximum - The maximum value of each pixel in the stack is used. Increases contrast of stars and sky overall. Extends the effect of satellite/airplane trails, meteors, and other phenomena.
  • Average - The average value of each pixel is used in the resulting image.
  • Minimum - The minimum value of each pixel is used. This has the effect of removing airplane and satellite trails (and meteors).

The Stack split screen option will split the image into two panes. The left pane will show the original image data and the right pane will contain the stacked data.

Regarding performance, stacking does have an impact to memory and CPU utilization. indi-allsky stores the RAW images used for the stack in memory. A single 1920x1080 (1K) image is approximately 8MB. Four 1K images will require 32MB of memory. A single 4056x3040 (4K) RAW image is ~25MB, four would require 100MB of memory (at all times).

CPU utilization and memory is reasonable for stacking 1K images on Raspberry Pi 3 (1GB) hardware, but 4K stacking starts to significantly impact response times. Strongly recommend Raspberry Pi 4 with 2+GB of memory for 4K images.

Registration (alignment) requires significantly more CPU time and doubles the memory requirement since the registered images must also be stored in memory. Registering one 1920x1080 (1K) image (reference + image) requires 2-3 seconds on Raspberry Pi 3 hardware.

Web Interface

The indi-allsky web interface is built on the Flask MVC framework. It is designed to be a dashboard for your sky. Included is the ability to fully manage the camera configuration without having to manually edit from the command line.

Most views do not require authentication. Credentials for accessing the privileged areas are defined upon the first setup of the software.

Home Page

Charts

Early evening, the sun was still going down, but a cloud passed by, increasing the average brightness and lowering the star count.

A large cloud passed over significantly increasing the brightness of the sky and blocking out almost all of the stars.

Image viewer

Historical images browsing. Pictured: A small satellite flare.

Timelapse viewer

Historical Star trails and Keograms. The Keogram image is linked directly to the timelapse video for the night.

System Info

Database

All media generated are logged in a local SQLite database stored in /var/lib/indi-allsky/indi-allsky.sqlite This database is used as the source of images for timelapse and keogram generation, as well as, for displaying images via the web interfaces.

The database is managed via the python modules SQLAlchemy and alembic to provide migrations (schema upgrades) automatically in the setup.sh script.

Remote Web Portal - SyncAPI

An on-premises indi-allsky system can synchronize images and timelapses to a cloud-based indi-allsky web server instance using the built in SyncAPI. Remote users can browse the remote indi-allsky web instance without touching the system running the camera. Images are synced in real-time.

In effect, the indi-allsky web interface is its own remote web portal.

A remote indi-allsky instance can support multiple clients using SyncAPI with a single instance. Users can easily switch between the cameras in the web interface. The SyncAPI can also be combined with the S3 Object Storage functionality to offload image storage to a cloud service.

Home Hosting

The indi-allsky web interface is designed to be directly exposed to the Internet, if you have sufficient bandwidth on your home Internet connection. A simple, yet effective, access control system is implemented to let anonymous (or authenticated) users safely browse images and videos without exposing privileged controls. Only users with assigned administrative authority can make changes.

https://github.com/aaronwmorris/indi-allsky/wiki/Security-considerations

It is also possible to use cloud security offerings like Cloudflare Tunnel to further protect your indi-allsky site.

Sensor support

indi-allsky supports reading sensors natively on single board computers like Raspberry Pi.

https://github.com/aaronwmorris/indi-allsky/wiki/Sensors

Dew Heater support

Native dew heater support is built in for standard and PWM controlled dew heaters.

https://github.com/aaronwmorris/indi-allsky/wiki/Dew-Heater-Support

Fan Controller support

Native fan controller support is built in for standard and PWM controlled fans.

https://github.com/aaronwmorris/indi-allsky/wiki/Fan-Control

Focuser support

If you built your system with a focuser, it is now possible to control the focuser within the Focus view. 28BYJ-48 steppers are currently supported.

https://github.com/aaronwmorris/indi-allsky/wiki/Focuser-Device

YouTube support

indi-allsky supports being able to upload timlapse and star trail videos directly to YouTube

https://github.com/aaronwmorris/indi-allsky/wiki/Youtube-Uploads

S3 Object Storage

You may choose to upload images and timelapse files to an S3 bucket. Once the images are in the bucket, images and videos in the web interface will be loaded directly from S3 instead of the local indi-allsky web server. You could easy host the web interface from your home internet connection and just have the large media files served from S3.

Currently, only Amazon Web Services is supported, but other providers could be easily be added. Just open an issue.

Estimated cost for an allsky camera holding 90 days of timelapses and 30 days of images on AWS (day and night): ~$2.00 (USD) per month (50GB of data + 180,000 requests)

AWS S3 and GCP Storage are currently supported.

Note: As of writing this, the AWS free tier for S3 supports 5GB and 2000 requests per month. In a single night, I achieved 80% of the requests limit (8 hours of images every 15 seconds is 1920 upload requests). The free tier is only sufficient for basic testing, but not long term usage.

GPS

GPS support is provided through indi_gpsd and GPSd integration. Any GPS hardware supported by GPSd will work.

JPEG and FITS Images exported [optional] by indi-allsky will be properly tagged with Geographic (latitude/longitude) and Astrometric (RA/dec) information in the headers. Tags include geographic location regardless of GPS support, but the information will be much more precise with the GPS module.

Performance

indi-allsky itself is written in python, but python is just the glue between the different libraries, most of which are C based which makes indi-allsky extremely fast. A 1920 x 1080 image can be dark frame calibrated, debayered, histogram processed, text applied, and compressed to a JPG in less than 0.5 seconds on Raspberry Pi 3 class hardware. PNG processing is a little more taxing, but usually only takes a few seconds.

ffmpeg video processing is considerably more expensive. A 2 minute 1920x1080 h.264 encoded video compiled from 3,000 frames requires ~20 minutes on Raspberry Pi 3 (4 core) hardware. Encoding takes place in a separate process from image aqcuisition and image processing and is run at the lowest CPU priority so image acquision is not impacted.

Software Dependencies

Function Software URL
Camera interface INDI https://indilib.org/
pyindi-client https://github.com/indilib/pyindi-client
libcamera https://libcamera.org/
Image processing OpenCV https://opencv.org/
opencv-python https://github.com/opencv/opencv-python
Pillow https://pillow.readthedocs.io/
piexif https://piexif.readthedocs.io/
astropy https://www.astropy.org/
astroalign https://astroalign.quatrope.org/
ccdproc https://ccdproc.readthedocs.io/
numpy https://numpy.org/
Video processing ffmpeg https://www.ffmpeg.org/
Astrometry pyephem https://rhodesmill.org/pyephem/
File transfer pycurl http://pycurl.io/
paramiko http://www.paramiko.org/
paho-mqtt https://www.eclipse.org/paho/
requests https://requests.readthedocs.io/en/latest/
S3 Object Storage boto3 https://boto3.amazonaws.com/v1/documentation/api/latest/index.html
apache-libcloud https://libcloud.apache.org/
google-cloud-storage https://cloud.google.com/python/docs/reference/storage/latest
Database SQLite https://www.sqlite.org/
SQLAlchemy https://www.sqlalchemy.org/
alembic https://alembic.sqlalchemy.org/
mysql-connector-python https://dev.mysql.com/doc/connector-python/en/
PyMySQL https://pymysql.readthedocs.io/en/latest/
GPS GPSd https://gpsd.gitlab.io/gpsd/
Web interface Flask https://flask.palletsprojects.com/
WTForms https://wtforms.readthedocs.io/
flask-login https://flask-login.readthedocs.io/
Gunicorn https://gunicorn.org/
Apache https://httpd.apache.org/
NGINX https://www.nginx.com/
Hardware Sensors Circuit Python https://circuitpython.org/ GitHub

Architecture

indi-allsky utilizes python's multiprocessing library to enable parallelizing tasks so that image processing does not interfere with image aquisition, etc.

Configuration

All configuration is read from the database. Almost all of the configuration is managed via the web interface. You may use the config.py utility to manipulate the configuration from the command line.

Tested Hardware

3-4 weeks of constant runtime with no intervention are common. The only reason I restart my cameras are code updates (or power failures).

The hardware below has at least been plugged in and tested for correct detection and CFA decoding.

Vendor Model Rating Notes
ZWO ASI120MC-S B https://github.com/aaronwmorris/indi-allsky/wiki/ASI120MC-S-Camera-Issues
ZWO ASI678MC A
ZWO ASI676MC A This camera was designed for all sky systems
ZWO ASI585MC A
ZWO ASI178MC/MM A
ZWO ASI290MC/MM A
ZWO ASI385MC A
ZWO ASI174MM A
ZWO ASI533MC/MM A
ZWO ASI183MC/MM A
QHY QHY5III485C A Needs newer fxload utility for firmware
QHY QHY5LII-M A
Svbony SV305 B ~20% of frames require double the configured exposure time to complete. Likely a firmware bug.
Altair Hypercam 178C A Needs config for full resolution
Altair GPCAM3 290C A Needs config for full resolution
Altair GPCAM3 224C A Needs config for full resolution
Altair GPCAM2 290M A
Touptek G3CMOS06300KPA (IMX178) A
Touptek G-1200-KMB A
Player One Mars-C A
Player One Neptune-C A
Starlight Xpress Superstar A Fixed gain. Using stretching and/or contrast enhance
Datyson T7C A Using indi_asi_ccd driver
Recommend ASI120MC Linux compatibility firmware
Raspberry Pi HQ Camera imx477 (libcamera) A
Raspberry Pi CM3 imx708 (libcamera) A Minimum 1GB of memory is needed to process RAW images with dark calibration frames
Raspberry Pi HQ Camera (indi_pylibcamera) A https://github.com/scriptorron/indi_pylibcamera
Waveshare imx378 (libcamera) A
ArduCam imx462 (libcamera) A
ArduCam 64MP HawkEye A Recommend at least 4GB of RAM for full resolution 9152x6944. Options available to reduce image size.
Canon 550D (Rebel T2i) A Camera resolution and pixel size have to be manually defined in config
Canon 1300D (Rebel T6) A Camera resolution and pixel size have to be manually defined in config
IP Cameras indi_webcam_ccd C Needs config for operation
Webcams indi_v4l2_ccd B
Webcams indi_webcam_ccd D No gain controls. Little control over image quality.
indi indi_simulator_ccd CCD Simulator. Install GSC to generate sample images.

If you have an INDI supported camera from a vendor not listed, open an enhancement request and I can work with you to support the camera.

Gotchas

Common problems you might run into.

  • The indi-allsky python processes consume ~500MB of RAM.
    • 1K (1920x1080) h.264 encoding with ffmpeg requires an additional ~500MB of RAM. 1GB of RAM should be the bare minimum system memory. You should also have 100-500MB of additional swap space to prevent running out of memory during encoding. 2GB of RAM recommended.
    • 4K (3840x2160) h.264 encoding requires an additional 2+GB of RAM. 4GB of RAM recommended.
    • 8K resolution (ArduCam 64MP HawkEye) requires 8GB of RAM for full resolution video processing.
  • In Raspberry Pi OS 10, the h.264 codec in ffmpeg has a maximum frame size of 4096×2304 (AVC level 5.1). If your camera generates higher resolution images, you will need to scale the video or use the Region of Interest (RoI) options to reduce the frame size.
    • NEW: indi-allsky now has the ability to scale the native resolution images during the ffmpeg encoding phase, so you do not need to pre-scale your images.
    • The RaspberryPi HQ camera has a bin1 image size of 4056x3040. Setting IMAGE_SCALE to 75 in the config results in a image size of 3042x2280. Alternatively, you can center crop the image using IMAGE_CROP_ROI set to [0, 368, 4056, 2672] for an image size of 4056×2304.
  • ffmpeg in Raspberry Pi OS 11 enables AVC level 6.0+ which permits h.264 resolutions up to 8192×4320 (you must have sufficient system memory)

File Transfer

indi-allsky supports several file transfer methods.

https://github.com/aaronwmorris/indi-allsky/wiki/File-transfers

Protocol Port
ftp 21
ftpes 21
ftps 990
sftp 22
webdav (https) 443

MQTT Publishing

indi-allsky supports publishing all sky data to an MQTT service for monitoring.

For more info, see the wiki page: https://github.com/aaronwmorris/indi-allsky/wiki/MQTT-Broker-Publishing

Blogs, Articles, and Links

Please let me know if you want to make an addition or correction.

Alternatives

Commercial hardware

Acknowledgements

Donate

If you would like to fund equipment purchases for testing (or more Dr Pepper), you can use this link.

However, I would rather you to donate something to charity. As a suggestion, the Ronald McDonald House has helped my family in the past. I would love to hear if you give, please let me know!