Difference between revisions of "Resolution"

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=Introduction=
 
One thing that even the average professional astronomer might not fully appreciate is that Spitzer's images are diffraction-limited.  Every telescope in space can produce images limited only by the effects of diffraction -- this effect is stronger for longer wavelengths and smaller telescopes -- but diffraction will only be noticed if the camera on the telescope samples the telescope's output finely enough.  Most of Spitzer's images of point sources show diffraction rings because of the telescope's small size (85 cm) and long observing wavelengths (3-160 um). The size of patch on the sky (pixel size) that Spitzer measures increases in size from 1.2" at 3.5 um to 15" at 160 um. In practice, what this means is that very bright sources, especially those seeen with MIPS, will appear to have rings around them - this is the first Airy ring, e.g., a result of the way the telescope responds to light of this wavelength.  It's not really a ring around the object.
 
  
[[Image:goods.jpg|right]]
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The spatial resolution matters a lot when comparing images across wavelengths, or even just between telescopes.  
In the picture on the right (taken from [http://www.spitzer.caltech.edu/Media/releases/ssc2004-10/index.shtml this press release]), you can see a (small) patch of sky imaged with Hubble (left) and Spitzer (right).  The original point of this image was to show how phenomenally sensitive Spitzer is - there is a thing in the center of the Spitzer frame that is not seen by Hubble.  There is something else you can learn from this image too.  Look at the upper right of the Hubble image.  See all the variations in size and shape of the galaxies there?  Look at the same region in the Spitzer image.  To Spitzer, they all look the same - similarly sized and shaped blobs.  Spitzer's telescope is small (just 85 cm) and the wavelengths of light Spitzer uses are long (comparatively), so the resolution of Spitzer is limited.  
 
  
=Comparing images of multiple wavelengths=
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=Most coherent, developed, tested materials=
  
When comparing images at different wavelengths, check that the spatial resolution is comparable! This matters, particularly for mid- and far-IR observations. You will notice this if you use images of different resolutions in a 3-color composite.
 
  
{| border="0"
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*[[Resolution Overview]] -- Dr. Luisa Rebull (created 2010, last substantially updated 2017)
| [[Image:m33vis.gif]]  
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*[[Resolution and YSOs]], examples and exercises (used to be integrated with the overview above) -- Dr. Luisa Rebull (created 2010, last substantially updated 2017)
| [[Image:m33vissmoothed.gif]]
 
| [[Image:m33vissmoothedcolor.gif]]
 
|-
 
| Original visible light image of  M33.
 
| The same visible light image, smoothed to resolutions typical of far-IR observations.
 
| The same smoothed visible light image, with intensities translated to colors ("false color"). Image colors are often selected to emphasize different details than are discernable in a black-and-white image.
 
|}
 
  
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*[[Resolution: Calibrating your expectations]] - worksheet addressing what sizes you expect to find in the sky and in images -- Dr. Luisa Rebull (2020 but refined over nearly 10 years)
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*[[Resolution: Slight improvements are possible]] -- Dr. Luisa Rebull (2020 but refined over nearly 10 years)
  
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=Other important CoolWiki pages=
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*[[FITS format]]
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*[[Mosaics]]
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*[[Astronomical imaging]]
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*[[Filters]]
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*[[Diffraction]]
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*[[Confusion]]
  
Related to this issue of resolution is the size of images that you can download using any of a number of online resources.  For surveys with low spatial resolution, often the default size of the image you can download is MUCH MUCH larger than the default size of an image you can download from a survey with high spatial resolution.
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=Less coherent, developed, tested materials=
  
[[image:Crisldn981.jpg]]
 
  
=Spitzer's resolution=
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=Useful Related Links=
 
 
Spitzer's resolution is a strong function of wavelength.  The following plot comes from the SOFIA website, and is from at least 2003 if not earlier.
 
 
 
[[image:sofiaspatial.gif]]
 
 
 
=Why does this matter to you? (general case)=
 
 
 
When you are comparing the same region of space over multiple wavelengths, even within Spitzer, you need to be aware of this issue.  The resolution element ("beam size") of Spitzer is so large that may in fact enclose more than one source. Because the resolution changes even within Spitzer's channels, you can find many examples of cases in which a 160 micron or 70 micron or even 24 micron source encompasses more than one IRAC source. If you look at the same region of space with something with much less spatial resolution (try IRAS or COBE/DIRBE archives), you can see that Spitzer was a huge improvement over those prior missions. If you look at the same region of space with something that has much higher spatial resolution (like HST), you will probably see some things (especially those in complicated regions) break into more pieces.  This kind of comparison is of course greatly complicated when you are also comparing across wavelengths, because even the same object at the same resolution can look very different at different wavelengths. Caution is warranted!
 
 
 
=Why does this matter to you? (specific case of YSOs)=
 
 
 
==Example 1.== 
 
  
We spend a lot of time in the study of YSOs talking about the rings of dust around the young stars, and how they can become more prominent at longer wavelengths. When you look at the same object as seen with IRAC and MIPS, it will seem as if the source is getting larger at MIPS, and if the source is bright, it may even look as if it has a ring around it.  See example here:
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JWST resolution 0.0000194 deg = 0.06984 arcsec - check this against actual in-flight measures, as fcn of wavelength
  
[[image:irac1396patch.png]] [[image:mips1396patch.png]] These two images are of the same tiny patch of sky, the left one using IRAC and the right using MIPS. Note that there are 'rings' around some of the sources seen in MIPS.
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[https://lco.global/spacebook/sky/using-angles-describe-positions-and-apparent-sizes-objects/ Angular meaures on the sky from LCOGT]
 
 
'''''THESE ARE NOT THE DUST RINGS AROUND THESE YOUNG STARS'''''.  I cannot emphasize this enough. There are only about 10 sources close enough to the Earth such that Spitzer can actually resolve the dusty disk.  ([http://www.spitzer.caltech.edu/images/1100-ssc2003-06i%20-Fomalhaut-Circumstellar-Disk here is one, Fomalhaut].) These are not those sources.  What you are seeing here is the difference in resolution between IRAC and MIPS, and the (complicated) shape of the MIPS point-spread-function (PSF, or the way that the telescope+instrument+detectors respond to a point source of light).
 
 
 
==Example 2.==
 
 
 
When you are trying to match the same source across multiple bands, ''this matters''. The apparently single point source that you see at 160 microns (or some other band, if you're grabbing non-Spitzer data from somewhere) may in fact combine flux from more than one source which is seen at IRAC bands. You have to be very careful in how you match up sources, assign flux matches for constructing SEDs, and/or apportion flux between two unresolved sources. (e.g., in theory you could put 50% of the 160 micron flux to one source and 50% to the other source. But what if the two sources are not the same brightness at 24 microns but they are at 8 microns? How do you decide how much of the 160 um flux to assign to one of the sources?  These are complicated issues, and you need to investigate them for the sources you care about, and see if you need to worry about this for your objects.
 
 
 
==Example 3.==
 
 
 
What if you find a cool source that has the right colors to be a young star, and it seems to be a point source at all the bands you have? What if we go and check it in other bands? Here is a real-life example. This object was detected at WISE bands 1, 2, 3, and 4 (3.4, 4.6, 12, and 22 microns), and I found it as having the right colors to be a YSO. The first thing to notice is how the resolution changes when you go even from 12-22 microns, much less 3.4 to 22 microns. This is all on the same scale. Just stare at those four for a while. The rest of the tiles here are the same object, on the same scale, seen at 2MASS (JHK), POSS (blue, red, IR), and Sloan (ugriz). What was a point source to WISE is very clearly a nice little elliptical galaxy once you see it in SDSS.  My color selection is successfully finding star formation, just not star formation ''here'' in our galaxy. 
 
 
 
[[image:multiwavegalaxy.png]]
 
 
 
=Useful Related Links=
 
  
 
[http://blogs.discovermagazine.com/badastronomy/2008/08/12/moon-hoax-why-not-use-telescopes-to-look-at-the-landers/ Article on resolution] from Bad Astronomy - this is in the context of debunking the moon hoax, but resolution issues are important for his discussion.
 
[http://blogs.discovermagazine.com/badastronomy/2008/08/12/moon-hoax-why-not-use-telescopes-to-look-at-the-landers/ Article on resolution] from Bad Astronomy - this is in the context of debunking the moon hoax, but resolution issues are important for his discussion.
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[http://blogs.discovermagazine.com/badastronomy/2010/06/10/resolving-the-iphone-resolution/ Another resolution discussion] from Bad Astronomy.
 
[http://blogs.discovermagazine.com/badastronomy/2010/06/10/resolving-the-iphone-resolution/ Another resolution discussion] from Bad Astronomy.
  
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[http://www.planetary.org/blogs/emily-lakdawalla/2013/02141014-hubble-galaxy-pluto.html Why can Hubble get detailed views of distant galaxies but not of Pluto?] by Emily Lakdawalla at the Planetary Society
  
=Questions to think about and things to try having to do with resolution=
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[https://www.explainxkcd.com/wiki/index.php/1276:_Angular_Size xkcd on angular size] (link is actually to the explainer, which has more information than just the comic.)
*What is the size of a typical HST image?  How does it compare to a single Spitzer image, or a 'typical' Spitzer ''mosaic'', or a single POSS plate, or the field of view of an optical telescope you have used, all compared with the size of the full moon?  How does that compare to the size of a recent comet that visited the inner Solar System? or  the size of a spiral arm of the Milky Way?  You will have to go find on the web things like the field of view of these telescopes and these objects.
 
*Can you create a 3-color mosaic using just Spitzer data where the different resolutions of the various cameras is noticeable and important?
 
*Bonus question: how does the ''spatial resolution'' of all those telescopes listed above compare?  (e.g., what is the smallest object you can resolve as more than a point source?)
 

Latest revision as of 16:05, 31 May 2022

The spatial resolution matters a lot when comparing images across wavelengths, or even just between telescopes.

Most coherent, developed, tested materials

  • Resolution Overview -- Dr. Luisa Rebull (created 2010, last substantially updated 2017)
  • Resolution and YSOs, examples and exercises (used to be integrated with the overview above) -- Dr. Luisa Rebull (created 2010, last substantially updated 2017)

Other important CoolWiki pages

Less coherent, developed, tested materials

Useful Related Links

JWST resolution 0.0000194 deg = 0.06984 arcsec - check this against actual in-flight measures, as fcn of wavelength

Angular meaures on the sky from LCOGT

Article on resolution from Bad Astronomy - this is in the context of debunking the moon hoax, but resolution issues are important for his discussion.

Another resolution discussion from Bad Astronomy.

Why can Hubble get detailed views of distant galaxies but not of Pluto? by Emily Lakdawalla at the Planetary Society

xkcd on angular size (link is actually to the explainer, which has more information than just the comic.)