goredsox wrote:We actually agree on this issue a lot more than I realized. I think it would be a very useful exercise to literally go step by step like you just did, from detecting light-wavelength photons, detecting x-rays, detecting radio waves, detecting microwave radiation, detecting gamma, detecting spectra and red shifts, detecting lensing, detecting pulsating signals and bursts and so on. Really get down to the nitty gritty observations. Try to list them in chronologic order and SEPARATE THEM from all the theories that we use to interpret them. List all of the theories and the mathematics too, but go through it chronologically, and include alternative theories, side theories, and theories that have been discarded, and why. Then link the theories to the observations, but assess how firm (non-circular) each link is. Once in a while I think you get 3 or 4 weak links in a chain of theories without an independent observation bolster it. Also once in a while there will be a weak chain of links but suddenly, at the end, there WILL be an independent observation to boster it after the 4th link.
This would be a gargantuan task, but probably could be undertaken by a group of cosmologists, perhaps even in a forum like this one. I've done a lot of reading, but I haven't found anything quite like this out there. It would lay out a better foundation for discussion for all of us, and I think if it were all layed out (spoon fed, if you will) scientists of all persuations would be more likely to not only develop productive conversations in these forums but would probably come up with some really exciting, but useful, theories. The closest thing I have found so far is APOD, which is like a catalog of 4,300 observations. But an impartial assessment of the theories I find lacking.
A few random thoughts of what to look into ...
Scope: 'beyond the solar system' astronomy
Astronomy in any waveband other than the visual* didn't even start until after the two great (20th century) revolutions in physics were well established (quantum mechanics and relativity) ... radio astronomy began in the 1930s.
By the 1930s, the idea of finding something first in 'the heavens', and later 'on Earth' was well established; it's a history that goes back at least to Newton (Cavendish didn't do his famous - lab - experiment until the closing years of the 18th century), and includes helium; the discovery of the positron (around the same time as radio astronomy began) in cosmic rays a nice historical coincidence.
By the 1930s, the nature of stars as 'distant suns' was well established, though the details of what powered them were not worked out for another decade or so.
The 'distance ladder' was in place, albeit with some considerable inaccuracies in rungs above direct ('geometric') parallax.
The bifurcation of 'nebulae' into 'island universes' and {the rest} had become established only a decade earlier.
For our purposes, perhaps the most powerful legacy of astronomy, up until the 1930s, is General Relativity (GR), and
the strong equivalence principle, which is one aspect of a cosmological principle.
The great success of GR, in terms of passing specifically designed tests, has lead to a reluctance to develop ad hoc alternative theories. This is particularly pertinent wrt (non-baryonic) dark matter (DM): there
are alternative theories (to GR), but even the best (MOND, and its relativistic successors such as TeVeS) still requires some (non-baryonic) DM to account for relevant observations.
With a speed that is astonishing when compared to the pace of astronomy over the previous centuries, much of the rest of the electromagnetic spectrum became available to astronomers. Today, only very low frequency radio, some (small) parts of the far infrared (perhaps), and the gamma ray spectrum above a few TeV remain entirely unexplored.
For cosmology, the most exciting thing, these last 70 or so years, has been the CMB (cosmic microwave background). Scientifically, perhaps the most amazing thing has been how well modern LCDM (lambda cold dark matter) models can account for
all relevant observations!
Back to this:
Try to list them [the nitty gritty observations] in chronologic order and SEPARATE THEM from all the theories that we use to interpret them.
It's actually very easy to do, and doing so makes you realise just how poor astronomy would be without the relevant theories!
There's almost nothing you say, cosmologically speaking, if all you have is your unaided vision ... Olbers' paradox.
Telescopes may be considered (empirical) extensions of eyes, but their construction requires at least Newtonian theories (gravity and optics, for example).
Photographic plates may be considered (empirical) extensions of eyes, but you need at least some theory of light to interpret what they show (consider the UV, filters, and so on).
Spectra are meaningless without the quantum theory of the atom, especially all those prominent 'nebular lines' (initially thought to be an unknown element, nebulium).
And so on ... you even need GR to do at least one part of modern astronomy (VLBI radio astronomy; consider locations and clock synchronisation)!
In a nutshell, you need the Standard Model (of particle physics; SM), which incorporates the relevant quantum bits, and GR to do modern astronomy; not surprisingly, these are what's used to interpret the observations.
Finally (for now):
alternative theories, side theories, and theories that have been discarded, and why
To SM and GR? There aren't any ... at least, none that have survived testing in earthly labs.
What parts of these random notes would you like to dig deeper into goredsox?
*
This includes the portion of the UV between where the atmosphere becomes opaque and the blue limit of human vision; it also includes a portion of the near infrared, though this was not much used, by astronomers, up to then (IIRC).
That was hard to think. 
LOL "The univers on a single page by Doum." 
