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Chapter 14: Q12E (page 627)

Proceed as on page \(269\) to derive the elementary form of \({J_{ - 1/2}}(x)\) given in \((27)\).

Short Answer

Expert verified

The elementary form is \({J_{ - 1/2}}(x) = \sqrt {\frac{2}{{x\pi }}} cosx\).

Step by step solution

01

Define Bessel’s equation.

Let the Bessel equation be\({x^2}y'' + xy' + \left( {{x^2} - {n^2}} \right)y = 0\). This equation hastwo linearly independent solutionsfor a fixed value of\(n\).A Bessel equation of the first kind,indicated by\({J_n}(x)\), is one of these solutions that may be derived usingFrobinous approach.

\(\begin{array}{l}{y_1} = {x^a}{J_p}\left( {b{x^c}} \right)\\{y_2} = {x^a}{J_{ - p}}\left( {b{x^c}} \right)\end{array}\)

At\(x = 0\), this solution is regular. The second solution, which is singular at\(x = 0\), is represented by\({Y_n}(x)\)and is calleda Bessel function of the second kind.

\({y_3} = {x^a}\left( {\frac{{cosp\pi {J_p}\left( {b{x^c}} \right) - {J_{ - p}}\left( {b{x^c}} \right)}}{{sinp\pi }}} \right)\)

02

Determine the Bessel’s function of first kind.

Let the Bessel’s function of first kind be \({J_v} = \sum\limits_{n = 0}^\infty {\frac{{{{( - 1)}^n}}}{{n!\Gamma (1 + v + n)}}} {\left( {\frac{x}{2}} \right)^{2n + v}}\).

Substitute \(v = - 1/2\) in it yields,

\({J_{ - 1/2}} = \sum\limits_{n = 0}^\infty {\frac{{{{( - 1)}^n}}}{{n!\Gamma \left( {1 - \frac{1}{2} + n} \right)}}} {\left( {\frac{x}{2}} \right)^{2n - 1/2}}\)

\({J_{ - 1/2}} = \sum\limits_{n = 0}^\infty {\frac{{{{( - 1)}^n}}}{{n!\Gamma \left( {\frac{1}{2} + n} \right)}}} {\left( {\frac{x}{2}} \right)^{2n - 1/2}}\) … (1)

03

Find the gamma function.

Let the gamma function be,

\(\begin{array}{l}n = 0,\Gamma \left( {\frac{1}{2}} \right) = \sqrt \pi \\n = 1,\Gamma \left( {\frac{3}{2}} \right) = \frac{{2!}}{{{2^2}1!}}\sqrt \pi \\n = 2,\Gamma \left( {\frac{5}{2}} \right) = \frac{{4!}}{{{2^4}2!}}\sqrt \pi \\n = 3,\Gamma \left( {\frac{7}{2}} \right) = \frac{{6!}}{{{2^6}3!}}\sqrt \pi \end{array}\)

Then, \(\Gamma \left( {\frac{1}{2} + n} \right) = \frac{{(2n)!}}{{{2^{2n}}n!}}\) … (2)

04

Obtain the elementary form.

Substitute the equation (2) into (1).

\(\begin{array}{c}{J_{ - 1/2}} = \sum\limits_{n = 0}^\infty {\frac{{{{( - 1)}^n}}}{{x!\frac{{(2n)!}}{{{2^{2n}}{{\cancel{{}}}^{2n}}}}\sqrt \pi }}} {\left( {\frac{x}{2}} \right)^{2n - 1/2}}\\ = \frac{1}{{\sqrt \pi }}\sum\limits_{n = 0}^\infty {\frac{{{{( - 1)}^n}{2^{2n}}}}{{(2n)!}}} {\left( {\frac{x}{2}} \right)^{2n - 1/2}}\\ = \sqrt \pi \sum\limits_{n = 0}^\infty {\frac{{{{( - 1)}^n}{2^{2n}}}}{{(2n)!}}} {x^{2n - 1/2}} \cdot {2^{ - 2n + 1/2}}\\ = \frac{1}{{\sqrt \pi }}\sum\limits_{n = 0}^\infty {\frac{{{{( - 1)}^n}{2^{2n}}}}{{(2n)!}}} {x^{2n}} \cdot {x^{ - 1/2}} \cdot {2^{2\pi }} \cdot {2^{1/2}}\\ = \frac{1}{{\sqrt \pi }}\sum\limits_{n = 0}^\infty {\frac{{{{( - 1)}^n}}}{{(2n)!}}} {x^{2n}} \cdot \sqrt {\frac{2}{x}} \\ = \sqrt {\frac{2}{{x\pi }}} \sum\limits_{n = 0}^\infty {\frac{{{{( - 1)}^n}}}{{(2n)!}}} {x^{2n}}\\ = \sqrt {\frac{2}{{x\pi }}} \cos x\end{array}\)

Hence verified.

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Most popular questions from this chapter

In Problems \(23 - 26\) first use \((20)\) to express the general solution of the given differential equation in terms of Bessel functions. Then use \((26)\) and \((27)\) to express the general solution in terms of elementary functions.

\(16{x^2}y'' + 32xy' + \left( {{x^4} - 12} \right)y = 0\)

What conclusion would be appropriate for an upper tailed chi-squared test in each of the following situations?

\(\begin{array}{l}a.\alpha = .05,df = 4,{\chi ^2} = 12.25\\b.\alpha = .01,df = 3,{\chi ^2} = 8.54\\c.\alpha = .10,df = 2,{\chi ^2} = 4.36\\d.\alpha = .01,k = 6,{\chi ^2} = 10.20\end{array}\)

(a) Use the explicit solutions \({y_1}(x)\) and \({y_2}(x)\) of Legendre’s equation given in \((32)\) and the appropriate choice of \({c_0}\) and \({c_1}\) to find the Legendre polynomials \({P_6}(x)\) and \({P_7}(x)\).

(b) Write the differential equations for which \({P_6}(x)\) and \({P_7}(x)\) are particular solutions.

Show that \(y = {x^{1/2}}w\left( {\frac{2}{3}\alpha {x^{3/2}}} \right)\) is a solution of the given form of Airy’s differential equation whenever w is a solution of the indicated Bessel’s equation. (Hint: After differentiating, substituting, and simplifying, then let \(t = \frac{2}{3}\alpha {x^{3/2}}\))

(a) \(y'' + {\alpha ^2}xy = 0,x > 0;{t^2}w'' + tw' + \left( {{t^2} - \frac{1}{9}w} \right) = 0,t > 0\)

(b) \(y'' - {\alpha ^2}xy = 0,x > 0;{t^2}w'' + tw' - \left( {{t^2} - \frac{1}{9}w} \right) = 0,t > 0\)

Assume that b in equation (20) can be pure imaginary, that is, . Use this assumption to express the general solution of the given differential equation in terms of the modified Bessel functions In and Kn.

(a) y0 2 x2y 5 0

(b) xy0 1 y9 2 7x3
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