Astrophotography with a side of Raspberry Pi

Rob Pettengill - AAS
Astrophotography With A Side Of Raspberry Pi
Rob Pettengill (rcp@alumni.stanford.edu)
Austin Astronomical Society
11 April 2014
1

My Name Is Rob &
I Am Addicted To Astronomy
• I am not a professional
Astronomer
• Please do try this at home
• Follow your own
inspiration & needs
• Have fun
2

AGENDA
• Review Basic
Astrophotography
• Explore The Intersection Of
Internet Of Things &
Astronomy
!
1. Quick Context
• Astrophotography (Trade-Offs)
• Internet Of Things &
Raspberry Pi
2. What I Built
3. What I Learned Taking &
Processing Images
4. What's Next…
Christos Vasilas of Dash One
3
1st afocal RPi Cam astro images

Sensor
Telescope
Target
Match
Why not capture everything?
We must match Telescope & Sensor resolutions.
Example 89mm (3.5”) scope:
R = 4.56/D = 4.56/3.5 = 1.3 arc sec Dawes Limit
at prime focus 1.57º x 1.07º or 4348 x 2963 re or 12.9 MP
!
Dawes or Rayleigh Criterion gives resolution, you need 2X this to capture "the space
between” aka sampling theorem or 12.9 * 2 *2 = 52 MP!
!
For a 7” scope we need > 200 MP
!
With practical sensors, we can either maximize ﬁeld of view or resolution but not both!
4

Trading Off
FOV and
Resolution
• Sensor Choice
• Extended Deep Sky Objects - Large sensors with
larger pixels
• Solar System - small sensors with smaller pixels
• Modify telescope Focal Length
• Panoramas (at n squared times the work)
5

Sensor Size & Resolution Examples
6
Sensor Size
mm
Resolution
Pixel Size
um
Pixel FOV
arc sec
Sensor FOV
arc min
RPi CM 3.67 x 2.74 2592 x
1944
1.4 0.224 9.79 x 7.3
Sony
NEX-5N
23.4 x 15.6
4592 x
3056
5.0 0.8 62.4 x 41.6
Starlight Ex
SX814C
12.5 x 10.0
3388 x
2712
3.69 0.59 33.3 x 26.7
Meade DSI
Pro III
10.2 x 8.3
1360 x
1024
6.45 1.03 27.2 x 22.1
Orion
Starshoot
5.77 x 4.3
2592 x
1944
2.2 0.352 15.4 x 11.5
Philips
SOC900NC
4.6 x 3.97 640 x 480 5.6 0.96 10.2 x 7.66
89mm Objective 1280mm FL
ScaleOfViewPrimeFocus=206.3/FLmm arc sec/µm, ResolutionLimitDawes=114/Dmm arc sec

Astrophotography & FL
Camera (Rule of 500 / tripod, tracking
or piggyback mounts)
7
Prime Focus Reducer
Shortened Focal Length
Barlow
Extended Focal Length
Eyepiece Projection
Extended Focal Length
Afocal / Digiscoping
Extended Focal Lengthdrawings from Televue

Networked Computers so small and cheap
that they can be embedded in everything
!
Gartner - 26B by 2020
!
Astronomers have been pioneers
8
Microcontrollers
Arduino...
Network Connected PCs
• RPi ARM $30
• Arduino Due $50
• BeagleBone Black ARM $50
• Intel MinnoBoard Atom $200
Graphic from mobilemarketingwatch.com

Rob Pettengill - AAS 9
http://www.raspberrypi.org
http://beagleboard.org/Products/BeagleBone+Black
http://www.intel.com/content/www/us/en/do-it-yourself/edison.html

Internet Of Things And Astronomy
• Remote Observing downsized & updated.
• GoTo telescope control
• PushTo instrumentation and link to
planetarium software
• Automatic focusing.
• Guiding
• Camera control and enhancement.
• Plate solving.
10
http://vaticanobservatory.org
http://simonbox.info/index.php/astronomy
http://www.recantha.co.uk/blog/?p=3615
http://astrobeano.blogspot.com/2014/01/instrumented-telescope-with-raspberry.html

M a k i n g A s t ro p h o t o g r a p h y
A ff o rd a b l e P o r t a b l e & F l e x i b l e ?
DSLR (small screen/limited functionality)
alternatives require a computer.
• Largest component is the computer /
laptop
• Replace the computer with a small low
power wireless computer. ARM based
machines are powerful yet small and
low power.
• Replace the laptop display with a
wirelessly connected cell phone or
iPad. Better displays than many
laptops.
11
Terry Belia astrotex.com

R P i + C a m e r a M o d u l e +
Q u e s t a r C a m e r a A d a p t e r
C a n I t Wo r k ?
12
https://www.ﬂickr.com/photos/robpettengill/sets/72157635483690850/

Hang Me ’Til I’m Done
Astro RPi 2.0
13

Screw Me Up Tight
Astro RPi 3.0
Uses a T-ring as a nut to bolt mounting plate for camera to the
extension tubes
14

Acquisition Software Stack
IOT based model - smart devices, using web based
interfaces on the network, to talk to personal devices.
• On the Raspberry Pi
• Camera Interface (raspicam)
• Web Server - translate camera control from Web
requests to raspicam, serve up images for aiming
and focusing
• Image storage on local SD card
• Wireless ad hoc WiFi network for communication
• On a smartphone or tablet
• Web browser with camera control interface
• Last still image
• Streaming video
15

72 image Astro Raspberry Pi Lunar Panorama made with Hugin

BerryCam ready for Jupiter
imaging

Jupiter Io & Europa 240 of 500 images stacked & sharpened

Software
My environment Linux & OS X
Planning
• Stellarium
• AstroPlanner
Image acquisition:
Custom python web server on RPi front end to raspicam application. Motion JPEG & VLC streaming both
work.
Web browser or Berrycam app on iOS
Stacking & Preprocessing:
• Lynkeos - fast, powerful, easy to use (occasional crashes)
Nebulosity - powerful, robust, deep-sky oriented (also image acquisition)
Post processing
Photoshop
Hugin - amazing panorama tool
Gimp - powerful but not 16bit clean yet
19

Acquisition Lessons
• Good focus is essential! Bahtinov mask!
• It is hard to aim! Getting a bright planet in the ﬁeld of view of a small sensor
imager is hard!
• Image latency from the imager to the display really matters in ﬁnding and
focusing.
• Use video streaming for aiming and focusing.
• Realtime cropping focusing aids matter.
• Speed of wireless link is important (802.11n or ac needed)
• Use RAW format if you can, but you can do without it for bright Solar System
objects.
• Cell phone camera imagers can give excellent Solar System results
20

Preprocessing Lessons
• Stacking “lucky images” gives amazing results.
• Automatic image grading helps, but is not enough
• Ease of reviewing & selecting images is essential
• Dark and Flat frames are essential for deep sky but
"not so much" for bright Solar System objects
21

Post Processing Lessons
Post processing balances art and science as you iteratively reveal the data in the
image in a pleasing realistic way.
• Deconvolve before stretching.
• Iteratively stretch (mid & dark points) with levels tool more controllable than
curves.
• Layers and masks are your friends, learn to use them well. Masks reduce
sharpening artifacts.
• Unsharp mask appears to give a sharper image, deconvolution really does.
• Iteratively sharpen and ﬁlter noise. Avoid and reduce sharpening artifacts.
• Finish off with color enhancement (gamma, saturation, vibrance) and curve tweaks
to enhance contrast.
22

Quick Resolution Check
• Calculate angular
pixel size
• Down-sample image
to reference
resolutions
• Up-sample reference
images to original
size
• Compare original to
reference images
23

Drizzle - Stacking Of Under Sampled Images
A Hubble example of a drizzle stack of 12 images from
Wikipedia shows recovery of under sampled data
24
http://en.wikipedia.org/wiki/Drizzle_(image_processing)

30sec ISO 6400 APS-C sensor

7 stacked ISO 6400 30 sec, dark frames, & post

What's Next?
!
• Lack of drivers for high quality cooled astrophotography imagers is a barrier
for now. A few already provide Intel Linux drivers and some ARM Linux (Point
Grey).
• High speed wireless network protocols will enable wireless astrophotography.
• Headless GoTo and PushTo telescopes with wireless connections to tablet &
smart phone apps.
• Embedded computers have a bright future in Astronomy, with smart phones
or tablets replacing laptops for user interfaces. IOT devices like Raspberry Pi
make it easier for amateurs to lead the way.
27

Astrophotography with a side of Raspberry Pi

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