How to prove bessel function J1/2(x) = sqrt(2/πx)sinx;

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Discussion Overview

The discussion revolves around proving the relationship between the Bessel function \( J_{1/2}(x) \) and the expression \( \sqrt{\frac{2}{\pi x}} \sin x \). Participants explore methods of deriving this relationship using series expansions and the properties of the gamma function.

Discussion Character

  • Technical explanation, Mathematical reasoning, Debate/contested

Main Points Raised

  • One participant expresses uncertainty about where to insert the \( 1/2 \) into the Bessel function equation while using the Frobenius method.
  • Another participant suggests that using the series from the general case works and mentions the need to study a special case of the gamma function to simplify the factorial terms for \( m = 1/2 \).
  • A participant presents a series representation of \( J_{1/2}(x) \) and questions how it simplifies to \( \sin x \).
  • Another participant advises using the gamma function representation to simplify the factorial \( (n + 1/2)! \).
  • There is a query about whether the simplification leads to \( \sin x \) using the gamma function.
  • One participant confirms they have found a solution after receiving advice from others.

Areas of Agreement / Disagreement

Participants do not reach a consensus on the simplification process, and the discussion includes multiple approaches and uncertainties regarding the steps involved in proving the relationship.

Contextual Notes

Participants reference specific mathematical properties and functions, such as the gamma function and factorial simplifications, but do not resolve the details of these steps.

leyyee
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I really have no idea.

I started with the frobenius method. Until the recurrence formula.

I got that already. But I just don't know where to plug in the 1/2 into the equation. Can anyone help? I just need to know where to put in the 1/2?

Or can i use the normal bessel function which in general.

<br /> J_m(x) = \sum_{n=0}^{\infty} \frac{(-1)^n}{2^{m+2n}n!(n+m)!}x^{m+2n} = x^m \sum_{n=0}^{\infty} \frac{(-1)^n}{2^{m+2n}n!(n+m)!}(x^2)^n<br />

to prove that function?

need advice thanks..
 
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using series from the general case actually works.

to plug the 1/2 into this equation, you will need to study a special case of the gamma function for the factorial. Once you do this, the whole 2^(m+2n)∙n!∙(n+m)! should simplify nicely for m=1/2.

http://en.wikipedia.org/wiki/Particular_values_of_the_Gamma_function

to prove that J1/2(x) = sqrt(2/πx)sinx, you would better factorize x^(m-1) out of the sum and remain with x^(2n+1), this should simplify more easily.
 
the whole thing will become this . but how does it simplify to sinx? <br /> <br /> J_m(x) = \sum_{n=0}^{\infty} \frac{(-1)^n}{2^{1/2+2n}n!(n+1/2)!}x^{1/2+2n} = x^1/2 \sum_{n=0}^{\infty} \frac{(-1)^n}{2^{1/2+2n}n!(n+1/2)!}(x^2)^n<br /> <br />

i mean how to simplyfy the (n+1/2)!. thanks
 
just use (n+1/2)! = Γ(n+1/2 + 1 )
 
with that Γ(n+1/2 + 1 )

am I able to simplify it to sinx ?
 
thanks for the advice..

i have got the solutions.. thanks
 

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