Difference between revisions of "Manuals/calci/BESSELK"

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where α is the arbitary complex number.
 
where α is the arbitary complex number.
 
*But in most of the cases α is the non-negative real number.
 
*But in most of the cases α is the non-negative real number.
*The solutions of this equation are called Bessel Functions of order n. Bessel functions of the first kind, denoted as Jn(x), and
+
*The solutions of this equation are called Bessel Functions of order n.  
*The Bessel function of the first kind of order  can be expressed as:<math>Jn(x)=summation(k=0 to infinity){(-1)^k(x/2)^n+2k}/k!gamma(n+k+1)</math>.The Bessel function of the second kind  Yn(x).
+
*Bessel functions of the first kind, denoted as Jn(x), and The Bessel function of the first kind of order  can be expressed as:<math>Jn(x)=summation(k=0 to infinity){(-1)^k(x/2)^n+2k}/k!gamma(n+k+1)</math>.
 +
*The Bessel function of the second kind  Yn(x).
 
*The Bessel function of the 2nd kind of order  can be expressed as: Yn(x)=lt p tends to n {Jp(x)Cosp pi()- J-p(x)}/Sinp pi().
 
*The Bessel function of the 2nd kind of order  can be expressed as: Yn(x)=lt p tends to n {Jp(x)Cosp pi()- J-p(x)}/Sinp pi().
 
*So the form of the general solution is y(x)=c1 In(x)+c2 Kn(x). where In(x)=i^-nJn(ix) and Kn(x)=lt p tends to n  pi()/2[( I-p(x)-I p(x))/Sinp pi()] are the modified Bessel functions of the first and second kind respectively.This function will give the result as error when 1.x or n is non numeric
 
*So the form of the general solution is y(x)=c1 In(x)+c2 Kn(x). where In(x)=i^-nJn(ix) and Kn(x)=lt p tends to n  pi()/2[( I-p(x)-I p(x))/Sinp pi()] are the modified Bessel functions of the first and second kind respectively.This function will give the result as error when 1.x or n is non numeric

Revision as of 00:29, 2 December 2013

BESSELK(x,n)


  • Where is the value at which to evaluate the function
  • is the integer which is the order of the Bessel Function

Description

  • This function gives the value of the modified Bessel function when the arguments are purely imaginary.
  • Bessel functions is also called cylinder functions because they appear in the solution to Laplace's equation in cylindrical coordinates.
  • Bessel's Differential Equation is defined as:Failed to parse (MathML with SVG or PNG fallback (recommended for modern browsers and accessibility tools): Invalid response ("Math extension cannot connect to Restbase.") from server "https://wikimedia.org/api/rest_v1/":): {\displaystyle x^2 (d^2 y/dx^2) + x(dy/dx) + (x^2 - α^2)y =0}

where α is the arbitary complex number.

  • But in most of the cases α is the non-negative real number.
  • The solutions of this equation are called Bessel Functions of order n.
  • Bessel functions of the first kind, denoted as Jn(x), and The Bessel function of the first kind of order can be expressed as:.
  • The Bessel function of the second kind Yn(x).
  • The Bessel function of the 2nd kind of order can be expressed as: Yn(x)=lt p tends to n {Jp(x)Cosp pi()- J-p(x)}/Sinp pi().
  • So the form of the general solution is y(x)=c1 In(x)+c2 Kn(x). where In(x)=i^-nJn(ix) and Kn(x)=lt p tends to n pi()/2[( I-p(x)-I p(x))/Sinp pi()] are the modified Bessel functions of the first and second kind respectively.This function will give the result as error when 1.x or n is non numeric

2. n<0, because n is the order of the function.

Examples

  1. BESSELK(5,2)=0.005308944 (EXCEL)Kn(x) =0.0040446134(CALCI)K1(x)
  2. BESSELK(0.2,4)=29900.2492 (EXCEL)Kn(x)=4.7759725484(CALCI)K1(x)
  3. BESSELK(10,1)=0.000155369
  4. BESSELK(2,-1)=NAN

See Also

References

Absolute_value