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Chapter 13: Q33E (page 571)

Use the series in \((7)\) to verify that \({I_v}(x) = {i^{ - v}}{J_V}(ix)\) is a real function.

Short Answer

Expert verified

\({I_v}(x) = {i^{ - v}}{J_V}(ix)\) is a real function is verified.

Step by step solution

01

Define Bessel’s equation.

Let the Bessel equation be\({x^2}y'' + xy' + \left( {{x^2} - {v^2}} \right)y = 0\).A Bessel equation of the first kind,by using the coefficients\({c_{2n}}\)and\(r = v\), indicated by\({J_n}(x)\), is,

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

02

Derive a required function.

To verify the formula, \({I_v}(x) = {i^{ - v}}{J_V}(ix)\) …(1)

Which does not involve complex variables but gives a real function. Then, the series is,

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

\({J_v}(ix) = \sum\limits_{n = 0}^\infty {\frac{{{{( - 1)}^n}}}{{n!\Gamma (1 + v + n)}}} {\left( {\frac{{ix}}{2}} \right)^{2n + v}}\) … (2)

03

Derive for the real function.

Substitute the equation (2) into (1) which yields,

This implies that, \({I_v}(x)\) is a real function of all values of \(n\). Hence verified.

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Most popular questions from this chapter

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

In Problems 29 and 30 use (22) or (23) to obtain the given result.

\(\int_0^x r {J_0}(r)dr = x \times {J_1}(x)\)

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

(a) Use the second formula in (30) and Problem 32 to find the spherical Bessel functions \({y_1}(x)\) and \({y_2}(x)\).

(b) Use a graphing utility to plot the graphs of \({y_1}(x)\) and \({y_2}(x)\) in the same coordinate plane.

(a) Use the general solution obtained in Problem 37 to solve the IVP \(4x'' + tx = 0,x(0.1) = 1,x'(0.1) = - \frac{1}{2}\). Use a CAS to evaluate coefficients.

(b) Use a CAS to graph the solution obtained in part (a) for \(0 \le t \le 200\).
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