Fourier–Bessel series: Difference between revisions

In mathematics, Fourier–Bessel series is a particular kind of generalized Fourier series (an infinite series expansion on a finite interval) based on Bessel functions.

Fourier–Bessel series are used in the solution to partial differential equations, particularly in cylindrical coordinate systems.

The Fourier–Bessel series may be thought of as a Fourier expansion in the ρ coordinate of cylindrical coordinates. Just as the Fourier series is defined for a finite interval and has a counterpart, the continuous Fourier transform over an infinite interval, so the Fourier–Bessel series has a counterpart over an infinite interval, namely the Hankel transform.

Because Bessel functions are orthogonal with respect to a weight function ${\displaystyle x}$ on the interval ${\displaystyle [0,b]}$, they can be expanded in a Fourier–Bessel series defined by

${\displaystyle f(x)\sim \sum _{n=0}^{\infty }c_{n}J_{\alpha }(\lambda _{n}x/b)}$,

where ${\displaystyle \lambda _{n}}$ is the nth zero of ${\displaystyle J_{\alpha }(x)}$. This series is associated with the boundary condition ${\displaystyle f(b)=0}$.

From the orthogonality relationship

${\displaystyle \int _{0}^{1}xJ_{\alpha }(x\lambda _{m})\,J_{\alpha }(x\lambda _{n})\,dx={\frac {\delta _{mn}}{2}}[J_{\alpha +1}(\lambda _{n})]^{2}}$,

the coefficients are given by

${\displaystyle c_{n}={\frac {\int _{0}^{b}x\,J_{\alpha }(\lambda _{n}x/b)\,f(x)\,dx}{\int _{0}^{b}xJ_{\alpha }^{2}(\lambda _{n}x/b)dx}}={\frac {\langle f,J_{\alpha }(\lambda _{n}x/b)\rangle }{\|J_{\alpha }(\lambda _{n}x/b)\|^{2}}}.}$

The lower integral may be evaluated, yielding

${\displaystyle c_{n}={\frac {\int _{0}^{b}x\,J_{\alpha }(\lambda _{n}x/b)\,f(x)\,dx}{b^{2}J_{\alpha \pm 1}^{2}(\lambda _{n})/2}}}$,

where the plus or minus sign is equally valid.

The Fourier-Bessel series expansion employs aperiodic and decaying Bessel functions as the basis. The Fourier-Bessel series expansion has been successfully applied in diversified areas such as postural stability analysis, detection of voice onset time, separation of speech formants, EEG signal segmentation, speech enhancement, and speaker identification. The FB series expansion has also been used to reduce cross terms in the Wigner–Ville distribution (WVD).

A second Fourier–Bessel series, also known as Dini series, is associated with the Robin boundary condition

${\displaystyle bf'(b)+cf(b)=0}$, where ${\displaystyle c}$ is an arbitrary constant.

The Dini series can be defined by

${\displaystyle f(x)\sim \sum _{n=0}^{\infty }b_{n}J_{\alpha }(\gamma _{n}x/b)}$,

where ${\displaystyle \gamma _{n}}$ is the nth zero of ${\displaystyle xJ'_{\alpha }(x)+cJ_{\alpha }(x)}$.

The coefficients ${\displaystyle b_{n}}$ are given by

${\displaystyle b_{n}={\frac {2\gamma _{n}^{2}}{b^{2}(c^{2}+\gamma _{n}^{2}-\alpha ^{2})J_{\alpha }^{2}(\gamma _{n})}}\int _{0}^{b}J_{\alpha }(\gamma _{n}x/b)\,f(x)\,x\,dx}$.

• Smythe, William R. (1968). Static and Dynamic Electricity (3rd ed.). New York: McGraw-Hill.

• Magnus, Wilhelm; Oberhettinger, Fritz; Soni, Raj Pal (1966). Formulas and Theorems for Special Functions of Mathematical Physics. Berlin: Springer.

• R.B. Pachori and D. Hewson, Assessment of the effects of sensory perturbations using Fourier–Bessel expansion method for postural stability analysis, J. Intell. Syst. 20 (2011), 167–186.

• R.B. Pachori and S. V. Gangashetty, Detection of voice onset time using FB expansion and AM-FM model, Proc. IEEE 10th Int. Conf. Inf. Sci. Signal Process. Appl. (2010), 149–152.

• R.B. Pachori and P. Sircar, Analysis of multicomponent AM-FM signals using FB-DESA method, Digital Signal Process. 20 (2010), 42–62.

• R.B. Pachori and P. Sircar, EEG signal analysis using FB expansion and second order linear TVAR process, Signal Process. 88 (2008), 415–420.

• F.S. Gurgen and C. S. Chen, Speech enhancement by Fourier–Bessel coefficients of speech and noise, IEE Proc. Comm. Speech Vis. 137 (1990), 290–294.

• K. Gopalan, T. R. Anderson and E. J. Cupples, A comparison of speaker identification results using features based on cepstrum and Fourier–Bessel expansion, IEEE Trans. Speech Audio Process. 7 (1999), 289–294.

• R.B. Pachori and P. Sircar, A new technique to reduce cross terms in the Wigner distribution, Digital Signal Process. 17 (2007), 466–474.

• Weisstein, Eric. W. "Fourier-Bessel Series". From MathWorld--A Wolfram Web Resource.
• Fourier–Bessel series applied to Acoustic Field analysis on Trinnov Audio's research page

• Orthogonality
• Generalized Fourier series
• Hankel transform
• Neumann polynomial

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