[6] | 1 | # usage: |
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| 2 | # (x, y, z), t_write_all, filename_root |
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| 3 | # |
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| 4 | # (x, y, z) -> the data you want to see |
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| 5 | # You can specify all the data in the range of the problem |
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| 6 | # using '*' as a wildcard. You can specify a range using ':'. |
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| 7 | # For example, (*,*,10) represents the xy plane at z=10. |
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| 8 | # (8:16,*,*) represents the line of x ranging between 8 |
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| 9 | # and 16 inclusively. You can also combine these, such as: |
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| 10 | # (16:*,*) to represent the data from 16 to the end in the x |
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| 11 | # direction, and all of the data in the y and z directions. |
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| 12 | # |
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| 13 | # t_write_all -> how often you want to see it (in secs) |
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| 14 | # This can be an integer representing the number of seconds, |
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| 15 | # or an integer*dt representing the number of timesteps. |
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| 16 | # |
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| 17 | # filename_root -> root of the filename you want the output sent to. |
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| 18 | # For example, cfd3D will be used to generate outputfiles named |
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| 19 | # "cfd3D_XXXXXX" where XXXXXX is an integer representing the timestep |
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| 20 | # of the current output. All 3D output will be put in a directory |
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| 21 | # called output/3D/, so its a good idea to give every output line below |
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| 22 | # a unique filename root. |
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| 23 | |
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| 24 | # The entire cube of data, reported every 5 timesteps. |
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| 25 | # (*, *, *), 5*dt , cfd_3D |
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| 26 | |
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| 27 | # Samples: |
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| 28 | |
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| 29 | # The xy plane at z=10, output every 50 timesteps. |
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| 30 | (*,1,*),10*dt, cfd_2D |
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| 31 | |
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| 32 | # The line of data for 8<=x<=16 within the planes y=1 and z=10, |
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| 33 | # output every 10 timesteps. |
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