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Plain-Strip |
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If one figure can be transformed into an element that tills the
plain strip with its repeating element, and the other figure can tills
the plain strip, too. Then we can superpose these two strips such that
the width of one strip is coincident with the width of the element of
another strip. We called this technique the “plain-strip”
or “P-strip”, technique (Frederickson, 1997).
In fact, it is a variation of tessellation technique for the
strips can repeat non-edge-to-edge to till the plane. One example shown
below is the crossposition for strips of pentagon and square. The strip
of pentagons is composed of filling a parallelogram in a plain strip and
the strip of squares are composed of repeating squares to a strip. The
width of strip of squares is coincident with the width of the element of
pentagon.
The limitation of plain strip technique occurs when the width of
the first strip is greater then the width of the element in the second
strip. Since the areas of these two figures are the same, the width of
the second strip will greater then the width of the first element in its
strip. This would not possible to make a crossposition for these strips.
But it doesn’t involve a special case that the two strips have the
same width and their widths of elements are the same. We may cover one
strip paralleled with the other strip.
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Parallelogram strips |
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_cross.gif) |
{5} to {4} (6) | ||
| Non-parallelogram strips | ||||
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_cross.gif) |
{6/2} to {4} (5) | ||
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_cross.gif) |
{5/2} to {4} (7) | ||
| Optimized strips | ||||
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_cross.gif) |
{8} to {6} (8) | ||
| Customized strips | ||||
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_cross.gif) |
{10} to {4} (7) | ||
| Bumpy plain strips | ||||
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_cross.gif) |
{12/2} to {4} (8) | ||
-1_6.gif)
-1_4.gif)
-1_cross.gif)
_5.gif)
_4.gif)
_6.gif)
_4.gif)
_cross.gif)
_6m2.gif)
_4.gif)
_5m2.gif)
_4.gif)
_8.gif)
_6.gif)
_10.gif)
_4.gif)
_12m2.gif)
_4.gif)