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BESSEL FUNCTIONS OF THE FIRST KIND, Jν (x ) 

Bessel functions appear in a wide variety of physical problems. Separation of the Helmholtz, or wave, equation in circular cylindrical coordinates led to Bessel’s equation.  we will see that the Helmholtz equation in spherical polar coordinates also leads to a form of Bessel’s equation. Bessel functions may also appear in integral form — integral representations. This may result from integral transforms or from the mathematical elegance of starting the study of Bessel functions with Hankel functions.
Bessel functions and closely related functions form a rich area of mathematical analysis with many representations, many interesting and useful properties, and many interrelations.  

 

Generating Function for Integral Order 

Although Bessel functions are of interest primarily as solutions of differential equations, it is instructive and convenient to develop them from a completely different approach, that of the generating function.1 This approach also has the advantage of focusing on the functions themselves rather than on the differential equations they satisfy. Let us introduce a function of two variables,

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET(11.1)

Expanding this function in a Laurent series, we obtain

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET       (11.2)

It is instructive to compare Eq. (11.2) with the equivalent Eqs. (11.23) and (11.25).
The coefficient of tn ,Jn (x ), is defined to be a Bessel function of the first kind, of integral order n. Expanding the exponentials, we have a product of Maclaurin series in xt /2 and −x/2t , respectively,

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

Here, the summation index r is changed to n, with n = r − s and summation limits n =−s to ∞, and the order of the summations is interchanged, which is justified by absolute convergence. The range of the summation over n becomes −∞ to ∞, while the summation over s extends from max(−n, 0) to ∞. For a given s we get tn (n ≥ 0) from r = n + s :

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

The coefficient of tn is then 2

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

This series form exhibits is behavior of the Bessel function Jn (x ) for small x and permits numerical evaluation of Jn (x ). The results for J0 ,J1 , and J2 are shown in Fig. 11.1. the error in using only a finite number of terms of this alternating series in numerical evaluation is less than the first term omitted. For instance, if we want Jn (x )

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

to ±1% accuracy, the first term alone of Eq. (11.5) will suffice, provided the ratio of the second term to the first is less than 1% (in magnitude) or x< 0.2(n + 1)1/2 . The Bessel functions oscillate but are not periodic — except in the limit as x →∞ (Section 11.6). The amplitude of Jn (x ) is not constant but decreases asymptotically as x −1/2 . (See Eq.(11.137) for this envelope.)

For n< 0, Eq. (11.5) gives

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

Since n is an integer (here), (s − n)!→∞ for s = 0,...,(n − 1). Hence the series may be considered to start with s = n. Replacing s by s + n, we obtain

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

showing immediately that Jn (x ) and J−n (x ) are not independent but are related by

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

These series expressions (Eqs. (11.5) and (11.6)) may be used with n replaced by ν to define Jν (x ) and J−ν (x ) for nonintegral ν (compare Exercise 11.1.7).


Recurrence Relations

The recurrence relations for Jn (x ) and its derivatives may all be obtained by operating on the series, Eq. (11.5), although this requires a bit of clairvoyance (or a lot of trial and error). Verification of the known recurrence relations is straightforward, Exercise 11.1.7.
Here it is convenient to obtain them from the generating function, g(x , t ). Differentiating both sides of Eq. (11.1) with respect to t , we find that

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

and substituting Eq. (11.2) for the exponential and equating the coefficients of like powers of t ,3 we obtain

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

This is a three-term recurrence relation. Given J0 and J1 , for example, J2 (and any other integral order Jn ) may be computed.

Differentiating Eq. (11.1) with respect to x ,wehave

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

Again, substituting in Eq. (11.2) and equating the coefficients of like powers of t , we obtain the result

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET     (11.12)

As a special case of this general recurrence relation,

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET(11.13)

Adding Eqs. (11.10) and (11.12) and dividing by 2, we have

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET  (11.14)

Multiplying by x n and rearranging terms produces

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET         (11.15)

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET (11.16)

Multiplying by x −n and rearranging terms, we obtain

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET (11.17)

 

Bessel’s Differential Equation 

Suppose we consider a set of functions Zν (x ) that satisfies the basic recurrence relations (Eqs. (11.10) and (11.12)), but with ν not necessarily an integer and Zν not necessarily given by the series (Eq. (11.5)). Equation (11.14) may be rewritten (n → ν) as

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET             (11.18)

On differentiating with respect to x ,wehave

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET          (11.19)

Multiplying by x and then subtracting Eq. (11.18) multiplied by ν gives us

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET        (11.20)

Now we rewrite Eq. (11.16) and replace n by ν − 1:

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET(11.21)

Using Eq. (11.21) to eliminate Zν −1 and Zν −1 from Eq. (11.20), we finally get

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET(11.22)

which is Bessel’s ODE. Hence any functions Zν (x ) that satisfy the recurrence relations (Eqs. (11.10) and (11.12), (11.14) and (11.16), or (11.15) and (11.17)) satisfy Bessel’s equation; that is, the unknown Zν are Bessel functions. In particular, we have shown that the functions Jn (x ), defined by our generating function, satisfy Bessel’s ODE. If the argument is kρ rather than x , Eq. (11.22) becomes

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

 

Integral Representation

A particularly useful and powerful way of treating Bessel functions employs integral representations. If we return to the generating function (Eq. (11.2)), and substitute t = e ,we get

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

in which we have used the relations

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

and so on.
In summation notation,

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

equating real and imaginary parts of Eq. (11.23).
By employing the orthogonality properties of cosine and sine,

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

in which n and m are positive integers (zero is excluded), we obtain

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

If these two equations are added together,

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

As a special case (integrate Eq. (11.25) over (0,π ) to get)

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

Noting that cos(x sin θ) repeats itself in all four quadrants, we may write Eq. (11.30) as

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

On the other hand, sin(x sin θ) reverses its sign in the third and fourth quadrants, so

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

Adding Eq. (11.30a) and i times Eq. (11.30b), we obtain the complex exponential representation

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

This integral representation (Eq. (11.29)) may be obtained somewhat more directly by employing contour integration (compare Exercise 11.1.16).6 Many other integral representations exist (compare Exercise 11.1.18).

 

Example 11.1.1 FRAUNHOFER DIFFRACTION,CIRCULAR APERTURE 

In the theory of diffraction through a circular aperture we encounter the integral

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

for φ, the amplitude of the diffracted wave. Here θ is an azimuth angle in the plane of the circular aperture of radius a , and α is the angle defined by a point on a screen below the circular aperture relative to the normal through the center point. The parameter b is given by

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET(11.32)

with λ the wavelength of the incident wave. The other symbols are defined by Fig. 11.2.
From Eq. (11.30c) we get8

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET            (11.33)

Equation (11.15) enables us to integrate Eq. (11.33) immediately to obtain

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET(11.34)

Note here that J1 (0) = 0. The intensity of the light in the diffraction pattern is proportional to φand

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET(11.35)

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

From Table 11.1, which lists the zeros of the Bessel functions and their first derivatives,  Eq. (11.35) will have a zero at

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET(11.36)

or

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET (11.37)

For green light, λ = 5.5 × 10−5 cm. Hence, if a = 0.5cm,

α ≈ sin α = 6.7 × 10−5 (radian) ≈ 14 seconds of arc, (11.38)

which shows that the bending or spreading of the light ray is extremely small. If this analysis had been known in the seventeenth century, the arguments against the wave theory of light would have collapsed. In mid-twentieth century this same diffraction pattern appears in the scattering of nuclear particles by atomic nuclei — a striking demonstration of the wave properties of the nuclear particles.

A further example of the use of Bessel functions and their roots is provided by the electromagnetic resonant cavity (Example 11.1.2) and the example and exercises of Section 11.2.

 

Example 11.1.2 CYLINDRICAL RESONANT CAVITY

The propagation of electromagnetic waves in hollow metallic cylinders is important in many practical devices. If the cylinder has end surfaces, it is called a cavity. Resonant cavities play a crucial role in many particle accelerators.

 

11.1 Bessel Functions of the First Kind, Jν (x )

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

 

FIGURE 11.3 Cylindrical resonant cavity.

We take the z-axis along the center of the cavity with end surfaces at z = 0 and z = l and use cylindrical coordinates suggested by the geometry. Its walls are perfect conductors, so the tangential electric field vanishes on them (as in Fig. 11.3):

Ez = 0 = Eϕ for ρ = a, Eρ = 0 = Eϕ for z = 0,l.

Inside the cavity we have a vacuum, so ε0 µ0 = 1/c2 . In the interior of a resonant cavity, electromagnetic waves oscillate with harmonic time dependence e−iωt , which follows from separating the time from the spatial variables in Maxwell’s equations (Section 1.9), so

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

With ∇ · E = 0 (vacuum, no charges) and Eq. (1.85), we obtain for the space part of the electric field

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

which is called the vector Helmholtz PDE.The z-component ( Ez , space part only) satisfies the scalar Helmholtz equation,

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET (11.39)

The transverse electric field components E⊥ = (Eρ ,Eϕ ) obey the same PDE but different boundary conditions, given earlier. Once Eis known, Maxwell’s equations determine Eϕ fully. 

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

This implies

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

Here, kis a separation constant, because the left- and right-hand sides depend on different variables. For w(z) we find the harmonic oscillator ODE with standing wave solution (not transients) that we seek,

w(z) = A sin kz + B cos kz,

with A, B constants. For v(ρ , ϕ ) we obtain

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

where the separation constant m2 must be an integer, because the angular solution φ = eimϕ of the ODE

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

must be periodic in the azimuthal angle.
This leaves us with the radial ODE

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

Dimensional arguments suggest rescaling ρ → r = γρ and dividing by γ2 , which yields

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

This is Bessel’s ODE for ν = m. We use the regular solution Jm (γ ρ ) because the (irregular) second independent solution is singular at the origin, which is unacceptable here. The complete solution is

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

where the constant γ is determined from the boundary condition Ez = 0 on the cavity surface ρ = a, that is, that γa be a root of the Bessel function Jm (see Table 11.1). This gives a discrete set of values γ = γmn , where n designates the nth root of J(see Table 11.1).

For the transverse magnetic or TM mode of oscillation with Hz = 0 Maxwell’s equations imply. (See again Resonant Cavities in J. D. Jackson’s Electrodynamics in Additional Readings.)

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

with

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET(11.43)

where αmn is the nth zero of Jm . The general solution

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

with constants Bmnp , now follows from the superposition principle.
The result of the two boundary conditions and the separation constant m2 is that the angular frequency of our oscillation depends on three discrete parameters:

Bessel`s Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET

 

These are the allowable resonant frequencies for our TM mode. 

 

Alternate Approaches

Bessel functions are introduced here by means of a generating function, Eq. (11.2). Other approaches are possible. Listing the various possibilities, we have:

  1. Generating function (magic), Eq. (11.2).
  2. Series solution of Bessel’s differential equation,
  3. Contour integrals: Some writers prefer to start with contour integral definitions of the Hankel functions, and develop the Bessel function Jν (x) from the Hankel functions.
  4. Direct solution of physical problems: Example 11.1.1. Fraunhofer diffraction with a circular aperture, illustrates this. Incidentally, Eq. (11.31) can be treated by series expansion, if desired. Feynman10 develops Bessel functions from a consideration of cavity resonators.

In case the generating function seems too arbitrary, it can be derived from a contour integral,  or from the Bessel function recurrence relations,
Note that the contour integral is not limited to integer ν , thus providing a starting point for developing Bessel functions.

The document Bessel's Special Function - 1 | Physics for IIT JAM, UGC - NET, CSIR NET is a part of the Physics Course Physics for IIT JAM, UGC - NET, CSIR NET.
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FAQs on Bessel's Special Function - 1 - Physics for IIT JAM, UGC - NET, CSIR NET

1. What is Bessel's special function and how is it related to physics?
Bessel's special function is a mathematical function that appears in a wide range of physical problems, particularly those involving wave phenomena. It is named after Friedrich Bessel, a German mathematician who studied these functions extensively in the 19th century. Bessel functions are used to describe various phenomena such as the behavior of light waves, heat conduction, electromagnetic fields, and the oscillatory behavior of systems in quantum mechanics.
2. How are Bessel's special functions defined and what are their properties?
Bessel's special functions, denoted as J(x) and Y(x), are solutions to Bessel's differential equation. They are defined using power series expansions or as linear combinations of simpler functions. These functions have several important properties, such as orthogonality, recurrence relations, and integral representations. They also have asymptotic behaviors at large and small values of x, which are useful in many practical applications.
3. What are the applications of Bessel's special functions in physics?
Bessel functions find widespread applications in physics. They are used to describe diffraction patterns in optics, the propagation of electromagnetic waves through cylindrical and spherical structures, and the behavior of acoustic and elastic waves in cylindrical and spherical systems. Bessel functions also appear in heat conduction problems, quantum mechanics, fluid dynamics, and many other areas of physics where wave-like phenomena are present.
4. How are Bessel's special functions related to Fourier series and Fourier transforms?
Bessel's special functions are closely related to Fourier series and Fourier transforms. In the context of Fourier series, Bessel functions appear as the coefficients that describe the amplitudes of the harmonics in the expansion of a periodic function. In Fourier transforms, Bessel functions arise when transforming functions defined on a finite interval. They provide a way to represent the transformed function in terms of a series of Bessel functions, which can be numerically evaluated or analytically approximated.
5. Are there any practical applications of Bessel's special functions outside of physics?
Yes, Bessel's special functions have practical applications beyond physics as well. They are used in engineering fields such as telecommunications, signal processing, and image analysis. Bessel functions are essential for characterizing the behavior of antennas, waveguides, and other devices that involve the propagation of electromagnetic waves. They also find applications in areas such as acoustics, vibrations, heat transfer, and even in mathematical finance for pricing options in financial markets.
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