Using double, integers exceeding 2^53 cannot be represented exactly, as is well known. However, it seems to be true in general that they are represented as integers (check mod(1e100,1)), even if not the correct integers (check 1e100==1e100-1).
That seems to make sense in terms of the internal representation as exponent and mantissa. But is it documented anywhere?
@beaker But that's an integer (albeit not the correct one), that's my point
>> mod(2^54+2^53,1)
ans =
0
I was trying to find some "big integer expression", like say 1e100+1e50, that produces a non-integer when represented as double, but I can't find any. All give mod(...,1) equal to 0
I was expecting to ramdomly type things liks 234234234234234346465 and get a non-integer as its double representation. But all are integers, in the sense that they don't have fractional part
right, you've got a sliding window of 53 bits, and once that sliding window goes to the left of the radix point, your number can only be an integer. there's not enough precision to put any bits to the right of the radix point.
Awesome, thanks. I appreciate it. Not that I really care about the rep at this point, but I hate that my answer is made to look dumb by a later edit to the answer
I can't see why they refuse to ask the symbolic thing (which is also interesting) in a different question
I created a game in MATLAB.
When a user wins the game I give him my username and password secretly. So that the user can connect to my Facebook account and download a file and then I remove the user from my account.
But now how can I connect user to my Facebook account by JAVA or MATLAB.
So t...
@AnderBiguri I mean as long as he's distributing his password "secretly" it should be fine right? At least he's using MATLAB for it's native purpose, as a game dev platform
Given an arbitrary (lets say 2D) triangular mesh, with known $(x_i,y_i)$ locations of points, and numerical values of a function $f$ on them (either in the nodes, or in the centroids of the triangles, doesn't matter) like this random example, how can I obtain a numerical approximation of the dire...
@LuisMendo how did you came up with this idea? Also those "frames" inside the spiral are very interesting, any idea what property of the primes is making such structured results?
ffs typhoid MATLAB >.< I wrote a code to do Luis' challenge step 1, works fine when I input a single number, but as soon as I encapsulate it in a loop to check for all numbers it goes into infinity mode, inside the original 1-number code
especially since for single numbers it works great, and then when I save that as a function and use a separate function where I call the first one in a loop, the inner function goes into infinity mode
not the outer one
even though I pass the inner function only single numbers
fucking MATLAB doesn't do primes correctly imo
I encounter problems at 1 and 2
I had to explicitly kick those two out, otherwise it borked. Stupid program
function [count] = PrimeSpiral(n)
for ii = n:-1:2
count(ii) = 0;
if ~isprime(ii)
idxnew = numel(primes(ii));
while 1
count(ii) = count(ii)+1;
if isprime(idxnew) || idxnew == 1 || idxnew == 0
break
end
idxnew = numel(primes(idxnew));
end
end
end
end
197 bytes
N=301;H=F(N^2);O=spiral(N);O=H(O);imagesc(O)
where F
function [c]=F(n)
for a=n:-1:2
c(a)=0;
if ~isprime(a)
b=numel(primes(a));
while 1
c(a)=c(a)+1;
if isprime(b)||b==1
break
end
b=numel(primes(b));
end
end
end
The script is 41 bytes, the function 156, so a combined total of 197 by...
@AnderBiguri I wanted to write a challenge about iterating the prime counting function. I tried two ideas, but the resulting sequences were in OEIS, and probably not very interesting.
I wanted to write a challenge about iterating the prime counting function. I tried two ideas, but the resulting sequences were in OEIS, and probably not very interesting.
So I tampered with the exit rule of the iteration and noticed that with the condition exit if either prime or 1 the resulting sequence had increasingly long runs of constant values. That gave me the idea that plotting it in a spiral would give a nice graph, and when seeing the graph the tree ring analogy.
The structure of those "rings" is indeed very interesting, and mysterious. As Erdős said, it will be another million years, at least, before we understand the primes
and that specific answer does not attempt at all to answer me :/ . I tried to understand what he wants, or how to formulate it, but he just basically tells me "aaaah you havent defined your prooobleeeem"
@AnderBiguri should've put that as two paragraphs one a single answer imo. I personally think there shouldn't be an option to answer a question twice; just use two headings with "APPROACH 1" and "APPROACH 2"
Don't sweat it, @AndrasDeak. I'm going to delete it anyhow. Although it's the only form of the "question" here that's actually answerable, it's certainly not an answer. It might be an answer to the question that OP probably should have asked (i.e., "How do I formulate a question about computing gradients of real-valued functions interpolated from values at mesh vertices?"), and OP now perhaps understands that, so it's served its purpose. — John Hughes25 secs ago
@Adriaan Yes it can be integrated: something like this (removing indentation and newline/semicolon
function F(n)
for a=2:n^2
c(a)=0;
if ~isprime(a)
b=nnz(primes(a));
while 1
c(a)=c(a)+1;
if isprime(b)||b==1
break
end
b=nnz(primes(b));
end
end
end
imagesc(c(spiral(n)))
@AndrasDeak ultimatelly, he did not answer any of my comments :( e.g.:
I honestly say this without any hostility: I have no idea how much of this answer/comments is you being mathematically anal about my words/problem and how much it is really relevant for the numerical problem at hand. I do understand what you mean, however I am in the same point as in my first comment: Yes, you are right, and at the same time we can find (with some constrains, for sure) robust numerical approximations for e.g. images. — Ander Biguri2 hours ago
@Ander I read his answers. I think his point is that your set of (xi,yi,f(xi,yi)) values don't specify a function a priori. Infinitely many smooth functions can be fit to those points, and the gradients are undefined. What he means is that when you do this for an image, you work with implicit assumptions as to the behaviour of the underlying function to make the answer unique. You have to try and figure out what implicit assumptions are made in the image case.
@Adriaan But it should be 2, not 1. The lines if ~isprime(a) and b=nnz(primes(a)); are similar to other two lines later on. Can't those lines be merged by initiallizing b to a os somthing?
I'd try looking at basic derivations of gradients for images or 2d functions. See how the Taylor series is being applied and whether there are any clear assumptions being made.
I'll try :/ Fact is, for now whatever simple stuff may solve the problem. I need to do some tests in flawrs answer (and the other one), but flawrs seems best, fit some initial data... I need to sit down and read a lot of maths
@AnderBiguri Is Basque known to have some influences from Arabic? Just noticed the word "Eskerrak" which has a very similar Arabic word with the same meaning
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@Adriaan The most convincing explanation I found is: if 1 were a prime, the prime factorizacion of any number would not be unique. For example, 21 = 3·7 = 1·3·7