Wikipedia:Reference desk/Archives/Mathematics/2017 December 20

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December 20

Average sequences

Consider the (infinite) sequence a₁, a₂, a₃, a₄, ..., where the first two terms are integers and each term after is the average (arithmetic mean) of the two preceding terms. For which values of a₁ and a₂ is every term of the sequence an integer? GeoffreyT2000 (talk) 03:00, 20 December 2017 (UTC)[reply]

a₁ = a₂ and no other. ${\displaystyle |a_{i+2}-a_{i+1}|=2^{-i}|a_{2}-a_{1}|}$ . The only way to keep that an integer for all ${\displaystyle i}$  is to have ${\displaystyle |a_{2}-a_{1}|=0}$ .--108.52.27.203 (talk) 03:22, 20 December 2017 (UTC)[reply]

Infinite Product(2)

I need to find out how to convert an infinite series to an infinite product. The original formula is as follows, taking ${\displaystyle \epsilon _{0}}$  to be a constant:

${\displaystyle z=2e^{\frac {\epsilon _{0}}{4\tau }}\sum _{j=0}^{\infty }{\frac {j+{\frac {1}{2}}}{e^{{\frac {\epsilon _{0}}{\tau }}\left(j+{\frac {1}{2}}\right)^{2}}}}}$ 

In part one of this querry, I concluded that a this can be achieved for a function which is equivalent for ${\displaystyle \tau \geq 0}$ , through Weiestrass factorisation. This equivalent function was derived by making the original function even so as to create a function which is entire, without a pole at zero.

Initially, the new formula was presented as a triple sum, but has since been simplified to a double sum, which is presented below:

${\displaystyle z={\sqrt {2\pi }}e^{\frac {\epsilon _{0}}{4}}\sum _{j=0}^{\infty }\sum _{k=0}^{\infty }{\frac {\left(j+{\frac {1}{2}}\right)I_{{\frac {1}{2}}-k}\left(1\right)}{k!2^{k}e^{\epsilon _{0}\left(j+{\frac {1}{2}}\right)^{2}}}}\left(\tau ^{2}-1\right)^{k},\quad \tau \geq 0}$ 

How to proceed now that an entire function has been obtained? Plasmic Physics (talk) 08:27, 20 December 2017 (UTC)[reply]

Note that an infinite sum of entire functions is not necessarily entire. For example

${\displaystyle \sum _{k=0}^{\infty }x^{k}=(1-x)^{-1}}$ .

Bo Jacoby (talk) 19:27, 20 December 2017 (UTC).[reply]

Noted. Plasmic Physics (talk) 21:05, 20 December 2017 (UTC)[reply]

It was already noted above that the second formula is wrong as it has a zero at ${\displaystyle \tau =1}$  whereas the original function does not. Ruslik_Zero 19:35, 20 December 2017 (UTC)[reply]

That is not correct. Plot the partial z(1) using the second formula to prove it. WolframAlpha is quite useful for this. Plasmic Physics (talk) 20:21, 20 December 2017 (UTC)[reply]

Let ${\displaystyle x=e^{-{\frac {2\epsilon _{0}}{\tau }}}}$ . Then

${\displaystyle z=\sum _{j=0}^{\infty }(2j+1)x^{\frac {j(j+1)}{2}}=1+3x+5x^{3}+7x^{6}+9x^{10}+11x^{15}+13x^{21}+\cdots }$ 

This series is simpler than the double sum above. Bo Jacoby (talk) 01:36, 22 December 2017 (UTC).[reply]

In what way is this helpfull? Plasmic Physics (talk) 03:33, 22 December 2017 (UTC)[reply]

Your area of interest is ${\displaystyle {\frac {\epsilon _{0}}{\tau }}>0}$ . So ${\displaystyle 0<x<1}$ . The series converges for complex ${\displaystyle x}$  where ${\displaystyle |x|<1}$ . Choose a number ${\displaystyle N}$  such that the polynomial ${\displaystyle z_{N}(x)=\sum _{j=0}^{N}(2j+1)x^{\frac {j(j+1)}{2}}}$  of degree ${\displaystyle D={\frac {N(N+1)}{2}}}$  is a sufficiently good approximation to the power series ${\displaystyle z_{\infty }(x)=\sum _{j=0}^{\infty }(2j+1)x^{\frac {j(j+1)}{2}}}$  within your area of interest. The polynomial ${\displaystyle z_{N}(x)}$  has the ${\displaystyle D}$  complex roots ${\displaystyle r_{1},\cdots ,r_{D}}$ , and ${\displaystyle z_{\infty }(x)\approx z_{N}(x)=(2N+1)\prod _{j=1}^{D}(x-r_{j})}$ . This is a finite product. To obtain an infinite product, let ${\displaystyle N\rightarrow \infty }$ . Bo Jacoby (talk) 12:03, 22 December 2017 (UTC).[reply]

I am not sure that this limit exists. For example, ${\displaystyle \exp(x)}$  does not have zeros but any N-th order Taylor polynomial of it has N roots. Ruslik_Zero 20:36, 22 December 2017 (UTC)[reply]

The product representation of ${\displaystyle e^{x}}$  is ${\displaystyle \lim _{N\rightarrow \infty }\left(1+{\frac {x}{N}}\right)^{N}}$ . Bo Jacoby (talk) 20:58, 22 December 2017 (UTC).[reply]

It is true but what I said still holds. Ruslik_Zero 20:07, 23 December 2017 (UTC)[reply]

I should have emphasized that the roots depend on N: ${\displaystyle z_{N}(x)=(2N+1)\prod _{j=1}^{D}(x-r_{N,j})}$ . The limit ${\displaystyle z_{\infty }(x)=\lim _{N\rightarrow \infty }z_{N}(x)}$  certainly exists for ${\displaystyle |x|<1}$ . For example ${\displaystyle z_{7}(x)=15\prod _{j=1}^{28}(x-r_{7,j})}$  where ${\displaystyle r_{7,1}=-0.292929}$ , ${\displaystyle r_{7,2}=-0.0262713+0.709453i}$ , ${\displaystyle r_{7,3}=-0.0262713-0.709453i}$ , ${\displaystyle r_{7,4}=0.407881+0.745992i}$ , ${\displaystyle r_{7,5}=0.407881-0.745992i}$ , ${\displaystyle r_{7,6}=-0.909933+0.102748i}$ , ${\displaystyle r_{7,7}=-0.909933-0.102748i}$ , ${\displaystyle r_{7,8}=0.642708+0.659149i}$ , ${\displaystyle r_{7,9}=0.642708-0.659149i}$ , ${\displaystyle r_{7,10}=-0.66325+0.652759i}$ , ${\displaystyle r_{7,11}=-0.66325-0.652759i}$ , ${\displaystyle r_{7,12}=-0.305051+0.900312i}$ , ${\displaystyle r_{7,13}=-0.305051-0.900312i}$ , ${\displaystyle r_{7,14}=0.801119+0.536062i}$ , ${\displaystyle r_{7,15}=0.801119-0.536062i}$ , ${\displaystyle r_{7,16}=0.910997+0.377235i}$ , ${\displaystyle r_{7,17}=0.910997-0.377235i}$ , ${\displaystyle r_{7,18}=0.977577+0.194432i}$ , ${\displaystyle r_{7,19}=0.977577-0.194432i}$ , ${\displaystyle r_{7,20}=-0.878192+0.472676i}$ , ${\displaystyle r_{7,21}=-0.878192-0.472676i}$ , ${\displaystyle r_{7,22}=-1}$ , ${\displaystyle r_{7,23}=i}$ , ${\displaystyle r_{7,24}=-i}$ , ${\displaystyle r_{7,25}=0.317872+1.00891i}$ , ${\displaystyle r_{7,26}=0.317872-1.00891i}$ , ${\displaystyle r_{7,27}=-0.62899+0.853767i}$ , ${\displaystyle r_{7,28}=-0.62899-0.853767i}$ .

Bo Jacoby (talk) 08:15, 24 December 2017 (UTC).[reply]