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Prof. David R. Jackson ECE Dept.

ECE 6341 . Spring 2014. Prof. David R. Jackson ECE Dept. Notes 39. Finite Source. For a phased current sheet:. Recall that. Finite Source (cont.). Hence. Note:. Wavenumber plane. Spatial coordinates. TEN Model for . We can also write. Comparing with the previous result, we have.

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Prof. David R. Jackson ECE Dept.

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  1. ECE 6341 Spring 2014 Prof. David R. Jackson ECE Dept. Notes 39

  2. Finite Source For a phased current sheet: Recall that

  3. Finite Source (cont.) Hence Note: Wavenumber plane Spatial coordinates

  4. TEN Model for We can also write Comparing with the previous result, we have Similarly, This motivates the following identifications:

  5. TEN Model (cont.)

  6. TEN Model (cont.)

  7. TEN Model (cont.)

  8. Example Find

  9. Example (cont.) Hence

  10. Example (cont.)

  11. Dyadic Green’s Function where due to the unit-amplitude electric dipole at From superposition: We assume here that the currents are located on a planar surface. where

  12. Dyadic Green’s Function (cont.) This is recognized as a 2D convolution: Taking the 2D Fourier transform of both sides, where

  13. Dyadic Green’s Function (cont.) Assuming we wish the x component of the electric field due to an x-directed current Jsx (x , y ), we have In order to indentify , we use

  14. Dyadic Green’s Function (cont.) Recall that Hence

  15. Dyadic Green’s Function (cont.) We the have The other eight components could be found in a similar way. (The sources in the TEN that correspond to all possible sources are given on the next slide, and from these we can determine any component of the spectral-domain Green’s function that we wish, for either an electric current or a magnetic current.)

  16. Summary of Results for All Sources These results are derived in Notes 44. Definition of “vertical planar currents”:

  17. Sources used in Modeling • Vi = voltage due to 1[A] parallel current source • Ii = current due to 1[A] parallel current source • Vv = voltage due to 1[V] series voltage source • Iv = current due to 1[V] series voltage source + -

  18. Sources used in Modeling (cont.) • Vi = voltage due to 1[A] parallel current source • Ii = current due to 1[A] parallel current source • Vv = voltage due to 1[V] series voltage source • Iv = current due to 1[V] series voltage source + -

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