Chapter 12: Q1P (page 593)

To calculate the given system of equation. $\frac{d}{dx} [{(x)}^{p} J_{p} (x)] = {(x)}^{p} J_{p - 1} (x)$ .

Short Answer

Expert verified

It is proved that $\frac{d}{dx} [{(x)}^{p} J_{p} (x)] = {(x)}^{p} J_{p - 1} (x)$ .

Step by step solution

Concept of Bessel’s Equation:

The solution of Bessel's equation is $x^{2} y " + xy' + (x^{2} - n^{2}) y = 0$ .

$J_{n} (x) = \sum_{k = 0}^{\infty} \frac{{(- 1)}^{k}}{(k + 1) ⌜ (n + k + 1)} {(\frac{x}{2})}^{2 k + n}$

Differentiate the equation ddx[x-pJp(x)] with respect to x :

Differentiate the equation with respect to to obtain:

$\frac{d}{dx} [{(x)}^{- p} J_{p} (x)] = \frac{d}{dx} \sum_{n = 0}^{\infty} \frac{{(- 1)}^{n}}{⌜ (n + 1) ⌜ (n + 1 + p)} [\frac{{(x)}^{2 n}}{2^{2 n + p}}] = \sum_{n = 0}^{\infty} \frac{{(- 1)}^{n}}{⌜ (n + 1) ⌜ (n + 1 + p)} \frac{d}{dx} [\frac{{(x)}^{2 n}}{2^{2 n + p}}] = \sum_{n = 0}^{\infty} \frac{{(- 1)}^{n} (2 n)}{⌜ (n + 1) ⌜ (n + 1 + p)} [\frac{{(x)}^{2 n - 1}}{2^{2 n + p}}]$

Using the fact that $⌜ (n + 1) = n ⌜ (n)$ cancelling the factor 2and n to obtain:

localid="1659271537510" $\frac{d}{d x} [{(x)}^{- p} J_{p} (x)] = \sum_{n = 0}^{\infty} \frac{{(- 1)}^{n}}{⌜ (n) ⌜ (n + 1 + p)} [\frac{{(x)}^{2 n - 1}}{2^{2 n + p - 1}}]$

Multiplication of ddx[x-pJp(x)] on both sides with :

Multiply both sides of the equation with $x_{p}$ to obtain:

$x_{p} \frac{d}{dx} [{(x)}^{- p} J_{p} (x)] = x_{p} \sum_{n = 1}^{\infty} \frac{{(- 1)}^{n}}{⌜ (n) ⌜ (n + 1 + p)} [\frac{{(x)}^{2 n - 1}}{2^{2 n + p - 1}}] = \sum_{n = 1}^{\infty} \frac{{(- 1)}^{n}}{⌜ (n) ⌜ (n + 1 + p)} \frac{d}{dx} [\frac{{(x)}^{2 n} {(x)}^{2 n - 1}}{2^{2 n + p - 1}}] = \sum_{n = 0}^{\infty} \frac{{(- 1)}^{n}}{⌜ (n) ⌜ (n + 1 + p)} [\frac{{(x)}^{2 n - 1}}{2^{2 n + p}}] = \sum_{n = 1}^{\infty} \frac{{(- 1)}^{n}}{⌜ (n) ⌜ (n + 1 + p)} {[\frac{(x)}{2}]}^{2 n + p + 1}$

Therefore,

$x_{p} \frac{d}{dx} [{(x)}^{- p} J_{p} (x)] = - \sum_{n = 0}^{\infty} \frac{{(- 1)}^{(n + 1) - 1}}{⌜ (n) ⌜ (n + 1 + p)} {[\frac{(x)}{2}]}^{2 (n + 1) + p - 1}$

Replacement of n by n + 1 :

Replace n by n + 1 to obtain:

$x_{p} \frac{d}{dx} [{(x)}^{- p} J_{p} (x)] = - \sum_{n = 0}^{\infty} \frac{{(- 1)}^{(n)}}{⌜ (n) ⌜ ((n + 1) (1 + p))} {[\frac{x}{2}]}^{2 (n) + (p + 1)} = J_{(p + 1)} (x)$

Compare with given equation.

Multiply both sides with $x^{- p}$ to obtain:

$\frac{d}{dx} [{(x)}^{- p} J_{p} (x)] = {(- x)}^{- p} J_{p + 1} (x)$

Hence, proved.

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To calculate the given system of equation. $\frac{d}{dx} [{(x)}^{p} J_{p} (x)] = {(x)}^{p} J_{p - 1} (x)$ .

Short Answer

Step by step solution

Concept of Bessel’s Equation:

Differentiate the equation ddx[x-pJp(x)] with respect to x :

Multiplication of ddx[x-pJp(x)] on both sides with :

Replacement of n by n + 1 :

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To calculate the given system of equation.ddx[xpJp(x)]=(x)pJp-1(x).

Short Answer

Step by step solution

Concept of Bessel’s Equation:

Differentiate the equation ddx[x-pJp(x)] with respect to x :

Multiplication of ddx[x-pJp(x)] on both sides with :

Replacement of n by n + 1 :

One App. One Place for Learning.

Most popular questions from this chapter

Recommended explanations on Physics Textbooks

Magnetism

Force

Nuclear Physics

Magnetism and Electromagnetic Induction

Oscillations

Radiation

Study anywhere. Anytime. Across all devices.

To calculate the given system of equation. $\frac{d}{dx} [{(x)}^{p} J_{p} (x)] = {(x)}^{p} J_{p - 1} (x)$ .