Steps on the way to Lightcone cosmological calculator

In summary, The new A20 tabular calculator allows for the analysis of changing geometry up to 88 billion years in the future according to the standard LCDM cosmic model. The calculator provides a sample tabulation with three standard parameters that can be changed to observe their effects. The table spans from the present (S=1) to the distant future (S=0.01) in steps of ΔS=0.09, with options for smaller steps. The table shows the stretch, scale, time, Hubble time, and distances at present and in the distant future, providing insight into reachable galaxies and the growth of the reachable volume over time. However, the amount of matter in this reachable volume is expected to decline due to expansion
  • #71
Maybe it would be possible to get the neophyte to understand that because it is a speed-to-size ratio the natural type of units to express it in is Time-1.

Once that is understood Jorrie would have a fair amount of freedom in choosing the units compatibly.
 
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  • #72
Proposed updated LightCone 7 (standard units) and default column selections. The value H/Ho seems to fit best into the scheme of things...

[tex]{\scriptsize\begin{array}{|c|c|c|c|c|c|}\hline T_{Ho} (Gy) & T_{H\infty} (Gy) & S_{eq} & H_{0} & \Omega_\Lambda & \Omega_m\\ \hline 14.4&17.3&3400&67.9&0.693&0.307\\ \hline \end{array}}[/tex] [tex]{\scriptsize\begin{array}{|r|r|r|r|r|r|r|r|r|r|r|r|r|r|r|r|} \hline S&T (Gy)&R (Gly)&D_{now} (Gly)&D_{then}(Gly)&D_{hor}(Gly)&V_{gen}/c&H/Ho \\ \hline 1090.000&0.000373&0.000628&45.331596&0.041589&0.056714&21.023&22915.263\\ \hline 339.773&0.002496&0.003956&44.183524&0.130038&0.178562&10.712&3639.803\\ \hline 105.913&0.015309&0.023478&42.012463&0.396668&0.552333&5.791&613.344\\ \hline 33.015&0.090158&0.136321&38.051665&1.152552&1.651928&3.200&105.633\\ \hline 10.291&0.522342&0.785104&30.917756&3.004225&4.606237&1.782&18.342\\ \hline 3.208&2.977691&4.373615&18.247534&5.688090&10.827382&1.026&3.292\\ \hline 1.000&13.787206&14.399932&0.000000&0.000000&16.472274&1.000&1.000\\ \hline 0.312&32.884943&17.184900&11.117770&35.666086&17.224560&2.688&0.838\\ \hline 0.132&47.725063&17.291127&14.219438&107.785602&17.291127&6.313&0.833\\ \hline 0.056&62.598053&17.299307&15.535514&278.255976&17.299307&14.909&0.832\\ \hline 0.024&77.473722&17.299802&16.092610&681.060881&17.299802&35.227&0.832\\ \hline 0.010&92.349407&17.299900&16.328381&1632.838131&17.299900&83.237&0.832\\ \hline \end{array}}[/tex]

LightCone7 H-Ho.png
 
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  • #73
Jorrie said:
Proposed updated LightCone 7 (standard units) and default column selections. The value H/Ho seems to fit best into the scheme of things...
I have uploaded LightCone7s (the 's' for "standard units") if anyone wants to play with it. Not in my sig. yet, since some bug may still lurk somewhere. The main change in the user interface is that the chart options was transferred from LightCone7z and the "set default chart range" has disappeared - it is redundant now. It will also disappear in LightCone7z in due course.
-J
 
  • #74
I don't get it.

marcus said:
Note that the CEH is different from the Hubble radius. The Hubble radius is the distance that is growing at rate c. It is currently 13.9 Gly and the CEH (the reachable radius) is 15.6 Gly.
I think you know this but I'll say it just in case others read this.

why is the CEH different from the Hubble?? If the distance between Earth and a galaxy (proper distance) is greater than 13.88 billion light years then the expansion is greater than light can travel so it will never get there ?
 
  • #75
Gaz said:
I don't get it.
why is the CEH different from the Hubble?? If the distance between Earth and a galaxy (proper distance) is greater than 13.88 billion light years then the expansion is greater than light can travel so it will never get there ?
Consider that the Hubble radius is the reciprocal of the Hubble constant.
Now, what happens to a light signal at the present edge of the Hubble sphere if the Hubble constant goes down with time?
 
  • #76
so the Hubble constant is decreasing?
 
  • #77
Yes. Look at the table and graph in post #72 above.
The value of interest is ##H/H_0## and how it changes with time - this is the fractional change, so e.g. a value of 2 means twice the present value of ##H_0##, which is 67-ish km/s/Mpc.
 
  • #78
thanks it makes sense now =)
 
  • #79
Jorrie said:
I have uploaded LightCone7s (the 's' for "standard units") if anyone wants to play with it. Not in my sig. yet, since some bug may still lurk somewhere. The main change in the user interface is that the chart options was transferred from LightCone7z and the "set default chart range" has disappeared - it is redundant now. It will also disappear in LightCone7z in due course.
-J

Thanks Jorrie I'll have to update the link to my webpage when the product is finalized. It's unfortunate I can't use this on another forum I've been actively supporting. (More due to the other sites latex structure). Though I do advertise your product on that forum. I found they needed my help far more than here, as their is plenty of expertise on this forum. I've been of greater help on the other forum.

(If your looking at aspects to add, might I recommend adding density to temperature relations ie the thermodynamic relationships)
 
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  • #80
LightCone7s (for "standard"), now appears together with LightCone7z (for "zeit based") in my signature below. Both have the same "LCDM-engine", the only difference being the units being worked in. Billion years (Gy) for "version s" and zeit for "version z". One zeit is simply time divided by 17.3 Gy, a natural timescale of the LCDM model.

The update from '7' to '7s' is about flexibility in specifying the graph formats, as can be seen under the button "Open Cart Options" (the green area of the LightCone7 (partial) screen shot shown below).

Chart-Options-Lightcone7.png
 
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  • #81
Mordred said:
(If your looking at aspects to add, might I recommend adding density to temperature relations ie the thermodynamic relationships)
Eventually, there is a beta-test version available with some additions on density, density parameters and temperature. It is not the 'Forum official' version yet, but it has other interesting changes. E.g. inputs or now more standard - I have done away with Hubble times as input parameters, because they are not the ones used in the literature. Prime inputs are now the Hubble constant in conventional units, the total density parameter and the radiation-matter equality redshift parameters. The matter density parameter is then still a derived value.

The range of calculations are also requested as the more conventional redshift (z) in lieu of the simpler, but less well known "S" parameter. Lastly, the output scaling option for "Zeit" has been left out, since it is a potentially non-standard distraction. I hope the updates will enhance the use of the calculator in the educational field.

The latest beta-test version is available as: LightCone7-2017-01-26.

Edit: we found an error in Omega-calculations of this version. See the thread https://www.physicsforums.com/threads/evolution-of-the-energy-density-parameters.901681/
The corrected version is: LightCone 7, Cosmo-Calculator (2017-1).

Comments/suggestions welcome. I will start a new thread to discuss some of the more subtle aspects of the density parameter calculations.
 
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  • #82
The usage parameters such as ones found in intro level textbooks is probably the most familiar approach and the one that will probably gain the most usage. The parameters you mentioned being the key ones. People are more familiar with redshift than stretch for example. I agree the best approach should be literature based.

I should have time to help update the user manuals when the testing is done if you'd like my help again on that. I still remember how to edit and text on wikidot
 
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  • #83
After some more comments and further testing, it seems like the updated calculator has stabilized on this version: LightCone7-2017-01-30.
I suggest that we leave it for another week in 'testing mode' and then I will 'release' it into the same url as the previous release, so that no links/sig's need to be updated.
 
  • #84
I've been running various tests as time allows. I haven't found any issues that I can see thus far
 
  • #85
Mordred said:
I've been running various tests as time allows. I haven't found any issues that I can see thus far
Thanks for your effort, Mordred. I have used a specific set of columns as default to highlight the new features, but it may now be time to choose a more general set. It should still be limited so as to not being frightening to newcomers.

Any suggestions.
 
  • #86
I have now changed the link in my Sig below to the latest version that we have tested, with a very basic set of columns as the default, i.e.

[tex]{\small\begin{array}{|r|r|r|r|r|r|r|r|r|r|r|r|r|r|r|r|} \hline z&T (Gy)&R (Gly)&D_{now} (Gly)&Temp(K) \\ \hline 1.09e+3&3.72e-4&6.27e-4&4.53e+1&2.97e+3\\ \hline 3.39e+2&2.49e-3&3.95e-3&4.42e+1&9.27e+2\\ \hline 1.05e+2&1.53e-2&2.34e-2&4.20e+1&2.89e+2\\ \hline 3.20e+1&9.01e-2&1.36e-1&3.81e+1&9.00e+1\\ \hline 9.29e+0&5.22e-1&7.84e-1&3.09e+1&2.81e+1\\ \hline 2.21e+0&2.98e+0&4.37e+0&1.83e+1&8.74e+0\\ \hline 0.00e+0&1.38e+1&1.44e+1&0.00e+0&2.73e+0\\ \hline -6.88e-1&3.30e+1&1.73e+1&1.12e+1&8.49e-1\\ \hline -8.68e-1&4.79e+1&1.74e+1&1.43e+1&3.59e-1\\ \hline -9.44e-1&6.28e+1&1.74e+1&1.56e+1&1.52e-1\\ \hline -9.76e-1&7.77e+1&1.74e+1&1.61e+1&6.44e-2\\ \hline -9.90e-1&9.27e+1&1.74e+1&1.64e+1&2.73e-2\\ \hline \end{array}}[/tex]

There are now a total of 18 selectable columns, including the actual density against redshift and also the various density parameters (the Omegas).
It is very easy to change the default columns in the program, so please let me know if you want to see other columns as default.
The idea of a small selection is to not overwhelm newcomers with too much data.
 
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  • #87
marcus said:
The new A20 tabular calculator let's you look at changing geometry out to about 88 billion years according to the standard LCDM cosmic model (with usual estimates for the parameters.).
http://www.einsteins-theory-of-relativity-4engineers.com/CosmoLean_A20.html

It's pretty neat. Here is one sample tabulation. Red stuff is just the three standard parameters, estimated based on observation. No reason to change them, although in this calculator you CAN change them and play around to see the effects.
The blue stuff is what I put into give bounds and step size for the table I wanted it to generate
From the present (S=1) to the distant future (S=0.01) when distances are 100 times what they are today. In steps of ΔS = 0.09. those are just what I chose. If you choose a smaller step size like ΔS = 0.01 you get a table with more rows, like around 100 rows instead of only 12 rows. I won't bother to align the columns. It's probably legible as is.
===quote===

Hubble time now (Ynow) 13.9 Gy Change as desired (9 to 16 Gy)
Hubble time at infinity (Yinf) 16.3 Gy Change as desired (larger than Ynow)
Radiation and matter crossover (S_eq) 3350 Radiation influence (inverse: larger means less influence)

Upper limit of Stretch range (S_upper) 1.0 S value at the top row of the table (equal or larger than 1)
Lower limit of Stretch range (S_lower) 0.01 S value at the bottom row of table (S_lower smaller than S_upper)
Step size (S_step) 0.09 Step size for output display (equal or larger than 0.01)

Stretch (S) Scale (a) Time (Gy) T_Hubble (Gy) D_now (Gly) D_then (Gly)
1.000 1.000 13.769 13.896 0.000 0.000
0.910 1.099 15.104 14.387 -1.219 -1.339
0.820 1.220 16.630 14.829 -2.536 -3.093
0.730 1.370 18.374 15.221 -3.884 -5.320
0.640 1.563 20.402 15.545 -5.270 -8.234
0.550 1.818 22.772 15.812 -6.676 -12.138
0.460 2.174 25.618 16.006 -8.108 -17.627
0.370 2.703 29.120 16.143 -9.555 -25.825
0.280 3.571 33.629 16.233 -11.010 -39.323
0.190 5.263 39.934 16.278 -12.474 -65.650
0.100 10.000 50.390 16.296 -13.939 -139.393
0.010 100.000 87.919 16.300 -15.406 -1540.607

For the model used, see this thread on Physicsforums.
=====endqquote=====

what this tells you, among other things, is which of the galaxies out there you can reach if you flash a signal to them today.

It says ANYTHING THAT IS TODAY NEARER THAN 15.4 BILLION LY is a target you can reach if you flash a message today, and it will get there WITHIN 88 BILLION YEARS.

It also says that 88 billion years from now is when distances will be 100 times what they are today (cosmological distances, not dimensions of bound structures like a rock or solar system)

So if you select a galaxy which is today 15.4 billion LY and you flash a message today, when the message finally gets there the distance to the galaxy (and the message arriving at it) will be 1540 billion LY.
You can read that off the table too.

Is there anyone to whom this does NOT make sense. This is a great calculator and an interactive version of the standard cosmic model that is in professional use (LCDM) and there must be plenty of people who can explain if you find anything obscure about the table. Everybody should get so they understand the table outputs of this calculator both of past history and of the future, IMHO. They are basic.

This is the actual distance of the object (15.4 billion light years), not the distance we would observe it at, which would be nearer to 8 billion light years. The 15.4 Gly has already been corrected for the expansion of the universe since the light we currently can see was emitted.
 
<h2>1. What is a Lightcone cosmological calculator?</h2><p>A Lightcone cosmological calculator is a scientific tool used to calculate the distance and time between objects in the universe, taking into account the effects of the expansion of the universe. It is based on the concept of a lightcone, which is the path that light travels through space and time.</p><h2>2. How does a Lightcone cosmological calculator work?</h2><p>A Lightcone cosmological calculator uses mathematical equations and data from observations of the universe to calculate the distance and time between objects. It takes into account the expansion of the universe, which affects the speed of light and the distance between objects.</p><h2>3. What are the steps involved in using a Lightcone cosmological calculator?</h2><p>The first step is to gather data on the objects in question, such as their distance, velocity, and redshift. Then, the calculator uses this data to calculate the light travel time and distance between the objects. Finally, the results are interpreted and analyzed to gain insights into the structure and evolution of the universe.</p><h2>4. What are the applications of a Lightcone cosmological calculator?</h2><p>A Lightcone cosmological calculator is used in various fields of astronomy and cosmology, such as studying the large-scale structure of the universe, understanding the expansion of the universe, and investigating the properties of dark matter and dark energy. It can also help in the planning and interpretation of observations from telescopes and other instruments.</p><h2>5. Are there any limitations to a Lightcone cosmological calculator?</h2><p>Like any scientific tool, a Lightcone cosmological calculator has its limitations. It relies on the accuracy of the data and assumptions used in the calculations, and it may not be able to account for all the complexities and uncertainties in the universe. Additionally, it may not be able to accurately predict the behavior of objects beyond a certain distance or time, due to the limitations of our current understanding of the universe.</p>

1. What is a Lightcone cosmological calculator?

A Lightcone cosmological calculator is a scientific tool used to calculate the distance and time between objects in the universe, taking into account the effects of the expansion of the universe. It is based on the concept of a lightcone, which is the path that light travels through space and time.

2. How does a Lightcone cosmological calculator work?

A Lightcone cosmological calculator uses mathematical equations and data from observations of the universe to calculate the distance and time between objects. It takes into account the expansion of the universe, which affects the speed of light and the distance between objects.

3. What are the steps involved in using a Lightcone cosmological calculator?

The first step is to gather data on the objects in question, such as their distance, velocity, and redshift. Then, the calculator uses this data to calculate the light travel time and distance between the objects. Finally, the results are interpreted and analyzed to gain insights into the structure and evolution of the universe.

4. What are the applications of a Lightcone cosmological calculator?

A Lightcone cosmological calculator is used in various fields of astronomy and cosmology, such as studying the large-scale structure of the universe, understanding the expansion of the universe, and investigating the properties of dark matter and dark energy. It can also help in the planning and interpretation of observations from telescopes and other instruments.

5. Are there any limitations to a Lightcone cosmological calculator?

Like any scientific tool, a Lightcone cosmological calculator has its limitations. It relies on the accuracy of the data and assumptions used in the calculations, and it may not be able to account for all the complexities and uncertainties in the universe. Additionally, it may not be able to accurately predict the behavior of objects beyond a certain distance or time, due to the limitations of our current understanding of the universe.

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