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Chapter 13: Q19E (page 561)

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

\({J_0}(x) = {J_{ - 1}}(x) = {J_1}(x)\)

Short Answer

Expert verified

The obtained integral is \(J_0^'(x) = - {J_1}(x) = {J_{ - 1}}(x)\).

Step by step solution

01

Define differential recurrence relation.

Recurrence formulas that relate Bessel functions of different orders are important in theory and in applications.

\(\frac{d}{{dx}}\left( {{x^{ - v}}{J_v}(x)} \right) = - {x^{ - v}}{J_{v + 1}}(x)\)… (1)

\(\frac{d}{{dx}}\left( {{x^v}{J_v}(x)} \right) = {x^v}{J_{v - 1}}(x)\) … (2)

02

Obtain the integration.

Substitute the value\(v = 0\)in the equation (1).

\(\begin{array}{c}\frac{d}{{dx}}\left( {{x^0}{J_0}(x)} \right) = - {x^0}{J_{0 + 1}}(x)\\\frac{d}{{dx}}\left( {{J_0}(x)} \right) = {J_1}(x)\end{array}\)

\(J_0^'(x) = - {J_1}(x)\)… (3)

Substitute the value\(v = 0\)in the equation (2).

\(\begin{array}{c}\frac{d}{{dx}}\left( {{x^0}{J_0}(x)} \right) = {x^0}{J_{0 - 1}}(x)\\\frac{d}{{dx}}\left( {{J_0}(x)} \right) = {J_{ - 1}}(x)\end{array}\)

\(J_0^'(x) = {J_{ - 1}}(x)\)… (4)

From (3) and (4) yields the result,

\(J_0^'(x) = - {J_1}(x) = {J_{ - 1}}(x)\)

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Most popular questions from this chapter

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

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

Use the result in parts (a) and (b) of Problem 36 to express the general solution on \((0,\infty )\) of each of the two forms of Airy’s equation in terms of Bessel functions.

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

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

(a) Proceed as in Example \(6\(\) to show that \(xJ_v^'(x) = - v{J_v}(x) + x{J_{v - 1}}(x)\(\). (Hint: Write \(2n + v = 2(n + v) - v\(\).(\) (b) Use the result in part (a) to derive \((23)\(\).

(a) Use the general solution given in Example 5 to solve the IVP \(4x'' + {e^{ - 0.1t}}x = 0,x(0) = 1,x'(0) = - \frac{1}{2}\). Also use \(J_0^'(x) = - {J_1}(x)\) and \(Y_0^'(x) = - {Y_1}(x)\) along with Table 6.4.1 or a CAS to evaluate coefficients.

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