It appears that bsxfun {syntax} was reborn under the name pagefun.. I noticed this piece of code in one of the functions of R2020b: Z = pagefun(@mtimes, X, Y);
I was missing this exact functionality in one of my codes... Now I can finally remove the UnimplementedCodeError I put there :)
What's strange is that this function appears to have been introduced way back in 2013, but I think it has a different behavior for gpuArrays vs doubles 0_o
I'll explain: a new function was introduced in R2020b: pagemtimes. This function is part of the "base MATLAB package". This functions is applicable to gpuArray inputs, in which case it calls pagefun under the hood. HOWEVER, pagefun cannot be called directly on double inputs...
@CrisLuengo I saw your comment in Linkedin on that image of the cell, that the authors "enhance" by just applying a trheshold after rescaling it x8 resolution using bicubic interpolation
Is that as bad as it sounds? I have not read the preprint, but sounds like I'd reject that paper only under how bad that figure is
Well, that's how any kind of "enhance" will work, right? Pulling out information out of nowhere. The question is whether the result is beneficial. Like, increasing accuracy without decreasing specificity
@AndrasDeak I mean if you know that these cells are supposed to be smooth almost-round blobs, then why not? This probably does not apply and I'm not defending their "invention", but sometimes you can actually make use of some prior knowledge.
@AndrasDeak I didn't watch/read the english versions, but in the german talk he said there were companies who used machines like this to digitize all incoming letters and only use the digital versions after that
@AnderBiguri it is bad because people will think the information obtained from the image is better. For example, you can measure the perimeter of the smooth outline quite precisely, however it will have the same actual precision as the result for low-res outline, it could be just as far off from the perimeter of the thing being imaged. The precision of the measurement is fake.
The ML approaches to interpolation have exactly the same problem. You’re filling out the image with data from elsewhere, but you don’t know what was supposed to be there. You might be right, and get good results, or you might be wrong and think you have good results.
@flawr Did you all hear about the image fakery by last year’s Nobel Prize winner in Medicine?
im here, all axious about being able to become an academic long term, because how hard it is to procude novel science, and Nobel price winners are there doign shenannigans
but I dont understand anything on that article, not the parts where they show why the data is fake at least
> All these copy-pasted gel bands are depressing. But even more depressing is the knowledge that none of these three journals is likely to retract them, or to do anything in the first place. Because Semenza won the Nobel Prize.
@CrisLuengo thanks for sharing
I found the part I quoted form above especially infuriating.
@AndrasDeak I've made that exact same graphic too. It's amazing how many people taking a PhD level course don't know the difference between accuracy and precision. How do you get though first-year statistics without learning that???
@AnderBiguri If you see two bands with the same noise on it, they've been copied. Just like the Xerox machine does. They're hiding ugly data, or worse, they're hiding data that say something different from what they wanted it to say.
I had the impression that it would be a lot more beneficial if stats/prob. theory was taught a little bit later when people know a little bit more about analysis calculus.
I remember the 1st year exercises of propagating errors though equations. Like a=F/m, you measure F and m, you estimate their errors, then determine what the error in the estimated a is. You need the Jacobian for that, and I remember not being very clear about what that was.
The difference is simple: if your measurement is imprecise but accurate, you can repeat it many times, the average will become a precise measurement. If your measurement is inaccurate, you're fucked. Simple!
No, I mean I visited a physics lecture with some other students and we always did it by transforming random variables (which would acatually be the exact thing to do), but approximating things using first degree taylors would probably be quite a bit easier:)
(none of us had the introduction where the physicists explained how they would do things like error propagation)
Also, because of this, just discarding obvious outliers (values that cannot be represented by your measurement tool), things get back to good behavior.
In any case, if your measurement doesn't have a mean, it cannot be called accurate. The definition of accurate is that the expected value corresponds to the correct measurement value.
I am having a bit of a problem figuring out how I could do a dot product for a whole matrix, each column to the same vector. Meaning, this is no problem:
p0 = [2; 3; 4];
N = [1 ; 2; 3];
dot(p0,N);
But If I have this matrix (I have one with 10095 columns and 3 rows):
R = [1 2 3 4 5 6 4 7; 1 4 5...