Difference between revisions of "Mechanical quadrature, method of"
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''method of mechanical cubature'' | ''method of mechanical cubature'' | ||
A method for solving integral equations, based on replacing an integral by a sum using quadrature (cubature) formulas. Consider the equation | A method for solving integral equations, based on replacing an integral by a sum using quadrature (cubature) formulas. Consider the equation | ||
| − | + | \[ x(t) = \int\limits_\Omega K(t,s) x(s) \, ds + y(t), \] | |
| − | where | + | where $ \Omega \subset \mathbf{R}^n $ is a bounded open domain. Using a quadrature (cubature) process |
| − | + | \[ \int\limits_\Omega z(s) \, ds = \sum_{j=1}^{n} \alpha_{jn} z(s_{jn}) + \phi_n(z) \] | |
one forms the system of linear equations | one forms the system of linear equations | ||
| − | + | \[ x_{in} = \sum_{j=1}^{n}\alpha_{jn} K(s_{in}, s_{jn})x_{jn} + y(s_{in}), \quad i = 1, \dots, n, \] | |
| − | where | + | where $ x_{in} \approx x(x_{in}) $, $ i = 1, \dots, n $. |
| − | Let the absolute term | + | Let the absolute term $ y $ and the kernel $ K $ be continuous on $ \overline\Omega $ and $ \overline\Omega\times \overline\Omega $, respectively ($ \overline\Omega $ is the closure of $ \Omega $), and let (1) have a unique solution $ x(t) $. Let $ \phi_n(z) \to 0 $ as $ n \to \infty $ for any continuous function $ z(t) $ on $ \overline\Omega $. Then for sufficiently large $ n $ the system (2) is uniquely solvable and |
| − | + | \[ c_1 \epsilon_n \le \max_{1\le i \le n}|x_{in} - x(s_{in})| \le c_2 \epsilon_n, \quad n \ge n_0, \] | |
| − | where | + | where $ c_1 $ and $ c_2 $ are positive constants and |
| − | + | \[ \epsilon_n = \max_{1\le i\le n} |\phi_n (K(s_{in}, s)x(s))| \to 0 \] | |
| − | as | + | as $ n\to \infty $. |
A mechanical quadrature method can be applied for the solution of non-linear integral equations [[#References|[3]]] and eigen value problems for linear operators. The method converges even for a certain class of equations with discontinuous kernels [[#References|[4]]]. | A mechanical quadrature method can be applied for the solution of non-linear integral equations [[#References|[3]]] and eigen value problems for linear operators. The method converges even for a certain class of equations with discontinuous kernels [[#References|[4]]]. | ||
Revision as of 03:29, 2 June 2013
method of mechanical cubature
A method for solving integral equations, based on replacing an integral by a sum using quadrature (cubature) formulas. Consider the equation
\[ x(t) = \int\limits_\Omega K(t,s) x(s) \, ds + y(t), \]
where $ \Omega \subset \mathbf{R}^n $ is a bounded open domain. Using a quadrature (cubature) process
\[ \int\limits_\Omega z(s) \, ds = \sum_{j=1}^{n} \alpha_{jn} z(s_{jn}) + \phi_n(z) \]
one forms the system of linear equations
\[ x_{in} = \sum_{j=1}^{n}\alpha_{jn} K(s_{in}, s_{jn})x_{jn} + y(s_{in}), \quad i = 1, \dots, n, \]
where $ x_{in} \approx x(x_{in}) $, $ i = 1, \dots, n $.
Let the absolute term $ y $ and the kernel $ K $ be continuous on $ \overline\Omega $ and $ \overline\Omega\times \overline\Omega $, respectively ($ \overline\Omega $ is the closure of $ \Omega $), and let (1) have a unique solution $ x(t) $. Let $ \phi_n(z) \to 0 $ as $ n \to \infty $ for any continuous function $ z(t) $ on $ \overline\Omega $. Then for sufficiently large $ n $ the system (2) is uniquely solvable and
\[ c_1 \epsilon_n \le \max_{1\le i \le n}|x_{in} - x(s_{in})| \le c_2 \epsilon_n, \quad n \ge n_0, \]
where $ c_1 $ and $ c_2 $ are positive constants and
\[ \epsilon_n = \max_{1\le i\le n} |\phi_n (K(s_{in}, s)x(s))| \to 0 \]
as $ n\to \infty $.
A mechanical quadrature method can be applied for the solution of non-linear integral equations [3] and eigen value problems for linear operators. The method converges even for a certain class of equations with discontinuous kernels [4].
References
| [1] | V.I. Krylov, V.V. Bobkov, P.I. Monastyrnyi, "Numerical methods" , 2 , Moscow (1977) (In Russian) |
| [2] | I.S. Berezin, N.P. Zhidkov, "Computing methods" , Pergamon (1973) (Translated from Russian) |
| [3] | M.A. Krasnosel'skii, G.M. Vainikko, P.P. Zabreiko, et al., "Approximate solution of operator equations" , Wolters-Noordhoff (1972) (Translated from Russian) |
| [4] | G.M. Vainikko, "On the convergence of the method of mechanical quadratures for integral equations with discontinuous kernels" Sib. Math. J. , 12 : 1 (1971) pp. 29–38 Sibirsk. Mat. Zh. , 12 : 1 (1971) pp. 40–53 |
| [5] | S.G. [S.G. Mikhlin] Michlin, S. Prössdorf, "Singular integral operators" , Springer (1986) (Translated from German) |
Comments
References
| [a1] | H. Brunner, P.J. van der Houwen, "The numerical solution of Volterra equations" , North-Holland (1986) |
| [a2] | C.T.H. Baker, "The numerical treatment of integral equations" , Clarendon Press (1977) pp. Chapt. 4 |
| [a3] | H. Engels, "Numerical quadrature and cubature" , Acad. Press (1980) |
| [a4] | K.E. Atkinson, "A survey of numerical methods for the solution of Fredholm integral equations of the second kind" , SIAM (1976) |
How to Cite This Entry:
Mechanical quadrature, method of. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Mechanical_quadrature,_method_of&oldid=29822
Mechanical quadrature, method of. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Mechanical_quadrature,_method_of&oldid=29822
This article was adapted from an original article by G.M. Vainikko (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article