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nt.number theory – In $ sum _ { substack {p leq x \ p, p + 2 text {twin primes}}} frac (( log p) ^ m} {p} $, in the assumption of the first Hardy-Littlewood conjecture

I was wondering, inspired by a result of (1) (Proposition 17) what the asymptotic behavior of the sequence should be, assuming the first Hardy-Littlewood conjecture,

$$ sum _ { substack { text {primes} p leq x \ text {such that} p + 2 text {is prime}}} frac { log ^ m p} {p} $$

how $ x to infty $, where $ m geq 1 $ denotes a fixed integer. So here $ p $ denotes the smallest of twin cousins (sequence A001359 of OEIS) and we assume that there is a First Hardy-Littlewood conjecture.

A reference to the first Hardy-Littlewood conjecture is this section of Wikipedia.

I don't know if this exercise is in the literature for any fixed integer $ m $. I would like to know the deduction for some integer $ m geq 1 $.

Question. Deduce by some integer $ m geq 1 $ And under the assumption that Hardy-Littlewood's first guess is true, what should be the asymptotic behavior of $$ sum _ { substack {p leq x \ p, p + 2 text {twin cousins}}} frac { log ^ m p} {p} $$
how $ x to infty $. If you are in the literature, feel free to refer the reference and try to find and read the result of the literature. Thank you.

References

(1) Christian Axler, About a family of functions defined on sums of cousins, Journal of Integer Sequences, Volume 22 (2019), Number 1, Article 19.5.7.

number theory: solve two variables for each n related to the Collatz conjecture

For this code, for each x I would like to solve all ranges of values for c1 and c2 in a bounded range, that is, c1 and c2 in the range of real numbers + -100 for c1 and c2 for each x, which combined give "Length (stepsForEachN) == nRangeToCheck – 1". Here is the code so far, I'm not sure how to solve the two variables c1 and c2 for each x:

(*stepsForEachN output is A006577={1,7,2,5,8,16,3,19} if c1=c2=1*)
c1 = 1; 
c2 = 1;
nRangeToCheck = 10;
stepsForEachNwithIndex = {};
stepsForEachN = {};
stepsForEachNIndex = {};
maxStepsToCheck = 10000;

c1ValuesForEachN = {};

For(x = 2, x <= nRangeToCheck, x++,

 n = x;

 For(i = 1, i <= maxStepsToCheck, i++,
  If(EvenQ(n), n = Floor((n/2)*c1),
   If(OddQ(n), n = Floor((3*n + 1)*c2))
   );

  If(n < 1.9,
   AppendTo(stepsForEachN, i);
   AppendTo(stepsForEachNIndex, x);
   AppendTo(stepsForEachNwithIndex, {x, i});
   i = maxStepsToCheck + 1
   )
  )
 )
Length(stepsForEachN) == nRangeToCheck - 1

graph theory: is this a characterization of a tournament score?

For all $ n in mathbb N $, $ Delta_n = (0,2,3, …, n) $,$ D_n = X + X ^ 2 + …. X ^ $ Y $ I_n = mathbb N cap (0, n) $

For all
$ f in mathbb N ^ {I_n} $ strictly growing, we say that $ P = Sigma_ {i in I_n} a_i.X ^ {s_i} en mathbb Z (X) $ is 1-equivalent to $ P = Sigma_ {i in I_n} a_i.X ^ {$} Y 2 equivalents to $ P = Sigma_ {i in I_n} to _ { sigma (i)}. X ^ s_i + D_ {s_n} $ For any $ sigma $ permutation of $ I_ {s_n} $

$ Z subset mathbb Z (X) $ is the kind of $ 0 $ according to him $ 3-equivalence $ Witch is defined as the equivalence ratio generated by these two superior equivalence relationships.

We say that $ P = Sigma_ {i in I_n} a_i.X ^ {i} en mathbb Z (X) $,have braquetting property yes for every positive integer $ k leq n $
we have

$ Sigma_ {i in I_k} a_i geq 0 $ Y $ Sigma_ {i in I_n} a_i = 0 $

We say he has the property score If any $ Q $ that is to say $ 3 equivalent $ to $ P $ have the braquetting property

One can show that the elements of $ Z $ have the property score, and the question is the reciprocal:

Is any $ P in mathbb Z (X) $ which has the property of punctuation, in Z?

Note that $ (a_0, a_1 + 1, a_2 + 2, …, a_n + n) $ it is the list of exits of a complete digraph (tournament) if and only if $ a_0 + a_1X + a_2X ^ 2 + …. + a_nX ^ n $ have the property score

nt.number theory – Fourier transform of $ I_Y $, $ Y = { text {numbers with many prime factors} } $

Leave $ Y $ be the set of integers $ N <n leq 2 N $ with more than $ D log log N $ prime factors We can consider, say, $ D = ( log log N) ^ {1- epsilon} $.

We have fairly accurate approximations for the size of $ Y $ (I know chapter II.6 of the Tenenbaum book and the references therein). I wonder what work is available in the Fourier transformation $ widehat {1_Y} $ of the characteristic function of $ Y $.

I would wait $ widehat {1_Y} $ have spikes in the main arches (i.e. arcs around rational $ a / q $ with small denominator). This is because $ Y $ obviously it is "biased towards divisibility," so it should be overrepresented in the congruence class $ 0 $ mod $ d $ For any $ d $, in relation to other congruence classes mod $ d $.
A calculation at the end of the envelope suggests that the value at the peak around $ a / q $ must be approximately proportional to $ c ^ { omega (q)} / q $. But what is known?

set theory – Infinite generalizations of HOD

Let's say a set is ordinal$ _ { kappa lambda} $-definable if it is definable by a formula in the infinite language $ mathcal {L} _ { kappa lambda} $ with parameters of $ mathsf {On} $. Leave $ HOD _ { kappa lambda} $ be the class of hereditary ordinal$ _ { kappa lambda} $-definable sets. Definitely $ HOD _ omega omega} = HOD $; for a simple argument given in the quotation below, $ HOD _ { infty infty} = V $.

What can we say about $ HOD _ { kappa lambda} $ for other values of $ kappa $ Y $ lambda $? Some questions that obviously arise: do we have $ mathsf {Con} (HOD _ { kappa ^ + omega} neq HOD _ { kappa omega}) $ for all $ kappa $? We have $ mathsf {Con} (HOD _ { kappa ^ + lambda} neq HOD _ { kappa lambda}) $ for all $ kappa, lambda $? We have $ mathsf {Con} (HOD _ { kappa lambda ^ +} neq HOD _ { kappa lambda}) $ for all $ kappa, lambda $?

(This question is inspired by the discussion in the Gödel Constructible Universe in Infinite Logic (A possible approach to the problem of HOD)).

test verification – Basic exercise on distribution theory

$ textbf {Exercise.} $ Allow $ u in mathfrak {D} & # 39; ( Omega) $ Y $ varphi in mathfrak {D} $ such that $ varphi | _ { text {supp} u} equiv 0 $. It is true that $ varphi u equiv 0 $?

It seems obviously true that $ varphi u equiv 0 $, but I would like to prove my intent because this exercise seems extremely simple to be an exercise. If I'm wrong, I'd like a clue to build a counterexample because I can't see how $ varphi u neq 0 $ in these hypotheses

What I thought is quite simple:

Case $ 1 $ – $ x in text {supp} u $:

$ ( varphi u) (x) = varphi (x) u (x) = 0 u (x) = 0 $.

Case $ 2 $ – $ x notin text {supp} u $:

$ ( varphi u) (x) = varphi (x) u (x) = varphi (x) 0 = 0 $,

Thus $ varphi u equiv 0 $. $ square $

complexity theory: is this equivalent to some famous problem of complete NP?

Consider a rectangular $ n times n $ array consisting of values $ x_ {ij} in {- 1, 1 } $. We want to minimize the following expression:

$$ sum_ {i, j} a_ {ij} x_ {ij} – sum_ {neighbors} x_ {ij} x_ {kl} $$

Where $ a_ {ij} $ the values (positive or negative) are input parameters and adding to the neighbors means that we only include vertices that are directly adjacent to each other, that is, $ k = i ± 1; j = l $ or $ k = i; j = l pm 1 $.

My question is: is this problem equivalent to any NP-complete problem "famous"? I could find a series of similar minimization questions for MAXCUT type tasks or for formulations of Ising models in physics, but it is never in particular.

Edit to clarify: by minimization, I meant finding an optimal set $ x_ {ij} $ (output) given a certain set of $ a_ {ij} $ (entry).

field theory: how to combine symmetric tensile expressions into a single expression in xAct

Let's say I have the following expression in xAct
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where covariant derivatives are commutative, $ epsilon $ Y $ h $ they are symmetric tensioners

As we can see, this expression is equivalent to

enter the description of the image here

If we simulate it with respect to the indices $ i, j, k, l $

Is there any way to express the first expression as the second with some kind of SymmetryGroup?

Theory of complexity: algorithm to find a simple route with a maximum weight less than a constant in DAG

Given a weighted directed acyclic graph $ G = (V, E, W) $, where the weights are at the vertices. I am looking for a simple route of maximum total weight, but this total weight should not exceed a given constant $ K $.

Maybe my question is elementary, but I can't find any solution. In fact, it is well known that finding a simple path with maximum weight in $ G $ It is polynomial, but by adding the fact that this total weight should not exceed a given constant $ K $Will the problem remain polynomial? because we need to maintain in each node the set of route lengths that can reach the next vertices.