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September 2003©2003 by H.L. Bertoni1 VIII. Further Aspects of Edge Diffraction Other Diffraction Coefficients Oblique Incidence Spherical Wave Diffraction.

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Presentation on theme: "September 2003©2003 by H.L. Bertoni1 VIII. Further Aspects of Edge Diffraction Other Diffraction Coefficients Oblique Incidence Spherical Wave Diffraction."— Presentation transcript:

1 September 2003©2003 by H.L. Bertoni1 VIII. Further Aspects of Edge Diffraction Other Diffraction Coefficients Oblique Incidence Spherical Wave Diffraction by an Edge Path Gain Diffraction by Two Edges Numerical Examples

2 September 2003©2003 by H.L. Bertoni2 Other Diffraction Coefficients Felsen’s Rigorous Solution for Absorbing Screen (  = 0 ) Conducting Screen     Reflected plane wave Incident plane wave RSB ISB

3 September 2003©2003 by H.L. Bertoni3 Comparison of Diffraction Coefficients D 1 : Kirchhoff -HuygensD 3 : Conductor for TE polarization D 2 : FelsenD 4 : 90  conducting wedge for TM polarization -90090180270 0 1 2 3 4 5 angle,  D1D1 D2D2 D3D3 D4D4 D  2  k RSB   ISB 90 o wedge  RSB  ISB Edge

4 September 2003©2003 by H.L. Bertoni4 Diffraction for Oblique Incidence Diffracted rays lie on a cone whose angle is the same as that between incident ray and edge. All waves have wave number k sin  along edge k cos  in (x,y) plane Replace k for normal incidence by k cos   y x z

5 September 2003©2003 by H.L. Bertoni5 Diffraction of an Incident Spherical Wave (for paths that are nearly perpendicular to the edge) Field incident on the edge Diffracted cylindrical wave dipole r  dA r0r0 00  dA  In the horizontal plane, rays spread as if they came from a point r 0 behind the edge.

6 September 2003©2003 by H.L. Bertoni6 Top and Side Views of the Diffracted Rays Dipole r 0   r W(  ) W(r) Dipole r 0   r L(  )  L(r) Top View Side View

7 September 2003©2003 by H.L. Bertoni7 Diffracted Field Amplitude Must Conserve Power in a Ray Tube dipole r  dA r0r0 00  dA 

8 September 2003©2003 by H.L. Bertoni8 Path Gain for Diffracted Field

9 September 2003©2003 by H.L. Bertoni9 UTD Diffraction for Perpendicular Incidence of Rays From a Point Source

10 September 2003©2003 by H.L. Bertoni10 Example of Path Gain for Diffracted Field   30° 2 m 20 m17.3 m 12 m f = 900 MHz,  =1/3 m, k =6  m -1

11 September 2003©2003 by H.L. Bertoni11 Diffraction of Point Source Rays Incident Oblique to the Edge dipole r  rcos  dA r0r0 00    dA     z

12 September 2003©2003 by H.L. Bertoni12 Field incident on the edge Diffracted cylindrical wave Diffraction of Point Source Rays Incident Oblique to the Edge - cont.

13 September 2003©2003 by H.L. Bertoni13 Path Gain for Paths Oblique to the Edge

14 September 2003©2003 by H.L. Bertoni14 UTD Diffraction for Oblique Incidence of Rays From a Point Source

15 September 2003©2003 by H.L. Bertoni15 Example of Diffraction on Oblique Paths Cordless telephones over a brick wall-perspective view Rx Located at (4,-1,15) z -7  ’ y Tx Located at (-7,-1.5,0) zwzw x r o  = 90 o -  r 15  ’’  = 90 o - 

16 September 2003©2003 by H.L. Bertoni16 Example of Diffraction on Oblique Paths Cordless telephones over a brick wall-end view y -7  4 x    Tx  ’ Rx (-7,-1.5) (4,-1) Band S|F(S)| 450 MHz2/31.5080.799 900 MHz1/33.015≈1 2.4 GHz1/88.0401

17 September 2003©2003 by H.L. Bertoni17 Diffraction on Oblique Paths - cont. Cordless telephones over a brick wall Band S|F(S)|PGL dB 450 MHz2/31.5080.7992.87x10 -7 65.4 900 MHz1/33.015≈14.50x10 -8 73.5 2.4 GHz1/88.04012.37x10 -9 86.3

18 September 2003©2003 by H.L. Bertoni18 Diffraction by Successive, Parallel Edges --Top and Side Views-- Top View Side View  r W(  W(r) Dipole r 0 r 1 r 0 r 1   r     )  L(r)

19 September 2003©2003 by H.L. Bertoni19 Diffraction of Vertical Dipole Fields by Successive, Parallel Edges r1r1 r0r0    r cylindrical wave near edge Assume the second edge is not near the shadow boundary of the fist edge.

20 September 2003©2003 by H.L. Bertoni20 Path Gain for Diffraction at Parallel Edges     30° 17.3 m 2 m   30° 2 m 60 m17.3 m 20 m f = 900 MHz  =1/3 m k =6  m -1

21 September 2003©2003 by H.L. Bertoni21 f = 450 MHz  =2/3 m k =3  m -1  tan -1 (10/5) =  1.107 rad 5 m 2 m 20 m 5 m 11.2 m 12 m Walk About Transmission Over a Building

22 September 2003©2003 by H.L. Bertoni22 Diffraction of Dipole Fields by Successive Perpendicular Edges r1r1  r0r0   r  cylindrical wave near edge

23 September 2003©2003 by H.L. Bertoni23 Path Gain for Perpendicular Edges 30° 60 m -30° 12 m 2 m 12 m 20 m f = 900 MHz  =1/3 m k =6  m -1

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