Multidimensional Inverse Problems for Differential EquationsSpringer, 15 Kas 2006 - 58 sayfa |
Kitabın içinden
13 sonuçtan 1-5 arası sonuçlar
Sayfa 3
... parameters characterizing the polar distance and eccentricity of the ellipse ; they are expressible in terms of x ° and t by ( 4a ) Formula ( 2 ) then becomes 2π , p = 1⁄2 ( 1 − c2 ) . - ( 5 ) u ( r cos , r sin ) d = v ( p , e ) v ( p ...
... parameters characterizing the polar distance and eccentricity of the ellipse ; they are expressible in terms of x ° and t by ( 4a ) Formula ( 2 ) then becomes 2π , p = 1⁄2 ( 1 − c2 ) . - ( 5 ) u ( r cos , r sin ) d = v ( p , e ) v ( p ...
Sayfa 4
... parameters is to be substituted in formula ( 4 ) when calculating an ellipse with parameters p and ε r . P , E Sp , denotes Applying the operator L repeatedly to the resultant equation ( 7 ) s u ( x , s ) xd Lv = S P , ε and denoting by ...
... parameters is to be substituted in formula ( 4 ) when calculating an ellipse with parameters p and ε r . P , E Sp , denotes Applying the operator L repeatedly to the resultant equation ( 7 ) s u ( x , s ) xd Lv = S P , ε and denoting by ...
Sayfa 5
... parameter E tend to zero in ( 8 ) . Each ellipse becomes a circle of radius P and the following relation results in the limit : ( 12 ) 2п Ju ( p . 4 ) 0 Su ( p , 4 ) cosky a4 = p ̃k [ Ľkv ] e = 0 . ( k = 0,1,2 , ... ) و For each fixed ...
... parameter E tend to zero in ( 8 ) . Each ellipse becomes a circle of radius P and the following relation results in the limit : ( 12 ) 2п Ju ( p . 4 ) 0 Su ( p , 4 ) cosky a4 = p ̃k [ Ľkv ] e = 0 . ( k = 0,1,2 , ... ) و For each fixed ...
Sayfa 9
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İçindekiler
1 | |
Linearized Inverse Dynamic Problem for the Telegraph | 22 |
Derivation of a Nonlinear Differential Equation for | 31 |
CHAPTER 4 | 39 |
CHAPTER 5 | 52 |
Diğer baskılar - Tümünü görüntüle
Multidimensional Inverse Problems for Differential Equations M. M. Lavrentiev,V. G. Romanov,V. G. Vasiliev Metin Parçacığı görünümü - 1970 |
Multidimensional Inverse Problems for Differential Equations M. M. Lavrentiev,V. G. Romanov,V. G. Vasiliev Metin Parçacığı görünümü - 1970 |
Multidimensional Inverse Problems for Differential Equations M. M. Lavrentiev,V. G. Romanov,V. G. Vasiliev Metin Parçacığı görünümü - 1970 |
Sık kullanılan terimler ve kelime öbekleri
absolutely integrable functions analytic function belong boundary conditions CAUCHY data chapter consider const construct continuous function corresponding Denote derive determining a function differential equation domain earth's ellipses ellipsoid of revolution exists expression family of curves following theorem function f(x,y functions u(r fundamental solution given GREEN'S function half-plane half-space HÖLDER condition hyperplane inequality 16 initial and boundary integral equation integral geometry integral-geometric problem Introduce the notation Inverse Kinematic Inverse Kinematic Problem inversion formula kernel L₁(D linearized inverse problem M₁ mean values multidimensional inverse problems obtain operator L defined parameters polar problem for equation problem of determining Q₂ R₂ relations right-hand side second kind sense of HADAMARD SM,t solution to equation space STURM-LIOUVILLE equations take FOURIER transforms telegraph equation travel-times two-parameter family u₁ M,M,t unique solution uniqueness theorem unit circle values over spheres variables VOLTERRA equation ду