A steady incompressible 2-D velocity field is expressed as follows:V = (2.4–3x + 0.5y)i + (0.45 +1.6x – 4.4y)j.-Determine the following at the location (x, y) = (-1,0).a. Particle acceleration. ā =v itv j+ 0v k.-16.77513.7b. Vorticity. =v i+ 0v j+ 1.1v k.c. The divergence of the velocity. div(V)-7.41/s.d. Where is the stagnation point for this flow? (x, y)stag( 0.86980.4185V ).%3D

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A steady incompressible 2-D velocity field is expressed as follows: V = (2.4– 3x + 0.5y)i + (0.45 +1.6x – – 4.4y)j. Determine the following at the location (x, y) = (-1,0). a. Particle acceleration. a v i+ 13.7 v j+ 0 -16.775 b. Vorticity. v i+ 0 v j+ 1.1 v k. c. The divergence of the velocity. div(V) -7.4 V 1/s. d. Where is the stagnation point for this flow? (x, y) stag ( 0.8698 0.4185 V ).

A steady incompressible 2-D velocity field is expressed as follows: V = (2.4– 3x + 0.5y)i + (0.45 +1.6x – – 4.4y)j. Determine the following at the location (x, y) = (-1,0). a. Particle acceleration. a v i+ 13.7 v j+ 0 -16.775 b. Vorticity. v i+ 0 v j+ 1.1 v k. c. The divergence of the velocity. div(V) -7.4 V 1/s. d. Where is the stagnation point for this flow? (x, y) stag ( 0.8698 0.4185 V ).

Elements Of Electromagnetics

7th Edition

ISBN:9780190698614

Author:Sadiku, Matthew N. O.

Publisher:Sadiku, Matthew N. O.

ChapterMA: Math Assessment

Section: Chapter Questions

Problem 1.1MA

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