Why go through all the trouble if you can just make a blog post, and possibly reach more people? Since he's probably not in academia anymore he doesn't have to count the publications...
I have published more than 560 blog posts here since 2006, and I estimate that about 98% of them started out as MATLAB scripts.Recently, I've started writing my blog posts as live scripts. Live... read more >>
@Adriaan no, it was something like "not considering the quality of the pavement and not respecting the weather conditions". The kid wasn't sure of the official wording but it was nonsense.
@AnderBiguri If we want to make a picture of a single slice using ct (one source), how does the resolution of the sensor influence the resolution of the reconstruction?
I guess more = better, but how exactly? I had the impression that the resolution of the reconstruction can somehow be chosen arbitrarily but there obviously must be some trade-off
generally speaking, for fan-beam type of CT (i.e. point source) your image resolution is, geometrically speaking detector_pixel_mm * distance_source_object/distance_source_detector
this last ratio is often logically named "magnification"
now, because there is a PFS to the source, the truth is that your real resolution is more determined by the source PFS than anything else. Then you just make sure that your image pixel size is at least 3 times smaller than more or less the FWHM of the gaussian (its poisson, but whatever) of the spot size
@flawr correct. So essentially you make your image pixels project into the detector 1-to-1
anything smaller you are just wasting computational power really, as you are not measuring it
going back to the PFS, this is generally something you don't worry (unless you have a very flexible machine) because detectors are generally designed such that the pixels are 3~5 the PFS.
@flawr mm yes, and this is true for many fan-beam medical CT machines, but in cone beam, detectors are flat
@flawr But then why not use a grid? It has been shown that “uniform random sampling” (sampling with a grid placed randomly in the domain) is a lot more efficient than random sampling (efficient == you need fewer samples to get the same amount of information out).
Yes, I have only skimmed over that post, will read it in detail later, but so far it looks like a grid with the samples ordered not in the easy sequence. I’m wondering what the benefit of that is.
because if you do a grid then its not really Monte Carlo anymore
I think its a way of better generating "random" samples for Monte Carlo experiments
so at samples->Inf the reandom and the ones that flwars shows are the same, thus MC techniques are still valid, but at lower number of samples, those are still random enough, yet sample better the ailable space
I imagine scrambling the order and allowing for infinitely many samples lets you stop the simulation at any time, or continue going as long as you want. With a grid you have to decide up front how many samples you want to draw.
...makes it harder to do p-hacking if you have to decide up front, an obvious problem.
yeah that makes sense. With these pseudo-random generators you can run it until some arbitrary, perhaps unknown, criteria, and stop, and the results would be valid, while with a grid you need to run the grid
So the Cauchy distribution has no mean and no variance, the student t with n=2 has a mean but no variance. Usually the definition of variance relies on the value of a mean, but could we generalize this definition and find a distribution that has no mean but a (generalized) variance?
but on the rationals you can also define the p-adic absolute value: any ratio can be writen as p^n * a/ b (where a,b are coprime and not divisible by n)
In number theory, Ostrowski's theorem, due to Alexander Ostrowski (1916), states that every non-trivial absolute value on the rational numbers
Q
{\displaystyle \mathbb {Q} }
is equivalent to either the usual real absolute value or a p-adic absolute value.
== Definitions ==
Raising an absolute value to a power less than 1 always results in another absolute value. Two absolute values
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{\displaystyle |\cdot |}
and...