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AME 60634 Int. Heat Trans.
D. B. Go 1
sinh Function
AME 60634 Int. Heat Trans.
D. B. Go 2
Fourier SeriesConsider a set of eigenfunctions ϕn that are orthogonal, where orthogonality is defined as
for m ≠ n
An arbitrary function f(x) can be expanded as series of these orthogonal eigenfunctions
or
Due to orthogonality, we thus know
all other ϕnAmϕm integrate to zero because m ≠ n
Thus, the constants in the Fourier series are
AME 60634 Int. Heat Trans.
D. B. Go 3
Cartesian Sturm-LiouvilleCharacteristic Value Problem p(x) = 1; q(x) = 0; w(x) = 1
homogeneous B.C.
After Applying Final B.C. Typical B.C.
Dirichlet
Neumann
Robin
AME 60634 Int. Heat Trans.
D. B. Go 4
Cartesian Sturm-Liouville Kakac & YennerHeat Conduction, 3rd Ed.
AME 60634 Int. Heat Trans.
D. B. Go 5
Cylindrical Sturm-LiouvilleCharacteristic Value Problem p(r) =r; q(r) = −ν2/r; w(r) = r
homogeneous B.C.
After Applying Final B.C. Typical B.C.
Dirichlet
Neumann
Robin
AME 60634 Int. Heat Trans.
D. B. Go 6
Cylindrical Sturm-Liouville
homogeneous B.C.
Typical B.C.
Dirichlet
Neumann
Robin
Special B.C. case: a = 0, b = r0
After Applying Final B.C.
AME 60634 Int. Heat Trans.
D. B. Go 7
Cylindrical Sturm-Liouville Kakac & YennerHeat Conduction, 3rd Ed.
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