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Lesson 3 Basic Concepts. Fundamentals Any continuous quantity (temperature, displacement, etc.) can be approximated by a discrete model composed of a.

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Presentation on theme: "Lesson 3 Basic Concepts. Fundamentals Any continuous quantity (temperature, displacement, etc.) can be approximated by a discrete model composed of a."— Presentation transcript:

1 Lesson 3 Basic Concepts

2 Fundamentals Any continuous quantity (temperature, displacement, etc.) can be approximated by a discrete model composed of a set of piecewise continuous functions Functions defined using values of continuous quantities at a finite number of points (nodes) The FEM is virtually independent of geometry and loading Different classes of problems can be analyzed using very similar programs Concepts are simple – details in software complex

3 Solving for 2-D Heat Transfer

4 2-D heat transfer cont.

5 Analytical approach – separation of variables Assume we wish to solve Laplace’s Eq. with the boundary conditions To obtain a solution by the Separations of Variables approach, assume Thus the original Laplace Eq. is transformed to the form Rearranging

6 continued Hence, The solution to Eq. (1) is with boundary conditions

7 continued The solutions to Eq. (2) is with boundary conditions

8 continued Consequently, Now one must find E n. Employ orthogonality of trigonometric functions Note that

9 continued Thus, the solution for T(x,y) is While analytical solutions exist for some problems, there are many that have no clear cut analytical forms.

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