|
|
Line 490: |
Line 490: |
| \end{alignat} | | \end{alignat} |
| </math> | | </math> |
| + | |
| + | ==See Also== |
| + | [[Form Factor:Octahedron]] |
Latest revision as of 16:59, 29 June 2014
Equations
For pyramid of base edge-length 2R, and height H. The angle of the pyramid walls is . If then the pyramid is truncated (flat top).
- Volume
- Projected (xy) surface area
Form Factor Amplitude
- where
Isotropic Form Factor Intensity
This can be computed numerically.
Derivations
Form Factor
For a pyramid of base-edge-length 2R, side-angle , truncated at H (along z axis), we note that the in-plane size of the pyramid at height z is:
Integrating with Cartesian coordinates:
A recurring integral is (c.f. cube form factor):
Which gives:
This can be simplified automated solving. For a regular pyramid, we obtain:
Form Factor near q=0
qy
When :
So:
qx
When :
Since sinc is an even function:
And:
qz
When :
So:
q
When :
So:
And:
qx and qy
When :
So:
To analyze the behavior in the limit of small and , we consider the limit of where . We replace the trigonometric functions by their expansions near zero (keeping only the first two terms):
Note that since is symmetric . When and are small (but not zero and not necessarily equal), many of the above arguments still apply. It remains that , and:
Isotropic Form Factor Intensity
To average over all possible orientations, we note:
and use:
Regular Pyramid
A regular pyramid (half of an octahedron) has faces that are equilateral triangles (each vertex is 60°). The 'corner-to-edge' distance along each triangular face is then:
This makes the height:
So that the pyramid face angle, is:
The square base of the pyramid has edges of length 2R. The distance from the center of the square to any corner is H, such that:
Surface Area
For a non-truncated, regular pyramid, each face is an equilateral triangle (each vertex is 60°). So each face:
The base is simply:
Total:
Volume
For a regular pyramid, the height and :
See Also
Form Factor:Octahedron