Finite element method (FEM) applications – MCQs – EE

1. The Finite Element Method (FEM) is primarily used to:

(A) Solve partial differential equations numerically

(B) Only measure line current

(D) Perform load flow analysis

2. FEM divides a complex domain into:

(A) Finite elements or small subdomains

(B) Step response only

(D) Transformer windings

3. In FEM, unknowns are typically:

(A) Nodal values of field quantities

(B) Step response only

(D) Transformer voltages only

4. FEM is widely used in EE for:

(A) Electromagnetic field analysis in transformers and machines

(B) Step response only

(D) Load flow only

5. FEM can handle:

(A) Complex geometries and inhomogeneous materials

(B) Step response only

(D) Load flow only

6. FEM solves equations by:

(A) Approximating the field using shape functions

(B) Step response only

(D) Load flow only

7. The FEM system matrix is usually:

(A) Sparse and large

(B) Step response only

(D) Load flow matrix

8. FEM is particularly suitable for:

(A) Devices with irregular shapes and material variations

(B) Step response only

(D) Load flow only

9. In FEM, mesh refinement improves:

(A) Solution accuracy

(B) Step response only

(D) Load flow only

10. FEM applications in EE include:

(A) Transformer, motor, and generator modeling

(B) Step response only

(D) Load flow only

11. Boundary conditions in FEM are used to:

(A) Specify known field values or fluxes at edges

(B) Step response only

(D) Load flow only

12. FEM can analyze:

(A) Magnetic flux distribution in machines

(B) Step response only

(D) Load flow only

13. FEM is suitable for:

(A) Non-uniform material properties

(B) Step response only

(D) Load flow only

14. FEM requires:

(A) Discretization of the domain into elements

(B) Step response only

(D) Load flow nodes

15. In FEM, shape functions are used to:

(A) Approximate the field inside each element

(B) Step response only

(D) Load flow only

16. FEM can model:

(A) Electric machines, power transformers, and inductors

(B) Step response only

(D) Load flow only

17. FEM accuracy depends on:

(A) Mesh density and element type

(B) Step response only

(D) Load flow only

18. FEM is widely used for:

(A) Electromagnetic compatibility and device design

(B) Step response only

(D) Load flow only

19. FEM can handle:

(A) Nonlinear magnetic materials

(B) Step response only

(D) Load flow only

20. FEM results in:

(A) Approximate field distributions and forces

(B) Step response only

(D) Load flow only

21. FEM is a:

(A) Numerical method for solving PDEs

(B) Step response only

(D) Load flow method

22. FEM can analyze:

(A) Magnetic field in inductors and transformers

(B) Step response only

(D) Load flow only

23. FEM can calculate:

(A) Induced currents, flux density, and forces

(B) Step response only

(D) Load flow only

24. FEM meshing can be:

(A) Structured or unstructured

(B) Step response only

(D) Load flow only

25. FEM limitations include:

(A) High computational cost for fine meshes

(B) Step response only

(D) Load flow only

26. FEM can model:

(A) Coupled electromagnetic and thermal problems

(B) Step response only

(D) Load flow only

27. FEM is used in:

(A) Power system component design and analysis

(B) Step response only

(D) Load flow only

28. In FEM, increasing element order improves:

(A) Accuracy of the solution

(B) Step response only

(D) Load flow only

29. FEM helps to:

(A) Predict device behavior without extensive prototypes

(B) Step response only

(D) Load flow only

30. FEM can be combined with:

(A) Circuit simulators for co-simulation of devices

(B) Step response only

(D) Load flow only