| Here's the mechanism for shrinking in 2 dimensions:
_
|
|
<----------------|
| | |
| V |
|-> <-|
| _ |
| | |
|---------------->
|
|
V
Add the third dimension, so each line becomes a wall. We want to add front and
back walls that can shrink too. Nestle the back wall into the corner formed
by the top and right-hand walls above, so those walls can extend behind the
back wall. The bottom and left-hand walls will move across the face of the
back wall. Similarly, nestle the front wall into the opposite corner, formed
by the bottom and left-hand walls above, so that those walls (which touch
the face of the back wall) can extend beyond the front wall.
_
|
FFFFFFFFFF|FFF
F | F
<----------------| F
BBB|FBBBB|BBBB| F
B |F V B| F
B |-> <-| F
B |F _ B| F
B |FFFFF|FFFF|FFF
B |---------------->
B | B
BBB|BBBBBBBBBB
|
V
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| Ah, but do your front and back walls approach one another?
I should mention that when the hero of the tale begins to get
squashed, he finds a message written low down on one wall by the
designer of the cell, who was incarcerated in the cell himself as soon
as he had completed the construction. The designer was not able to find
a way out, nor does he reveal in his anguished little paragraph how
he solved the design problem.
Cheers,
Andrew
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|
I seem to recall a movie hero (batman ? James Bond ?) saving himself and
the beautiful girl, when they were about to be crushed by some sort of
scrap metal compactor.
I won't tell you how they did it, in case you see the movie.
Only kidding, I'll tell you right now. The hero pulls out his combination
pen-radio and merely holds it horizontally, and it stops the walls !
/Eric
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| > Ah, but do your front and back walls approach one another?
Yes, why can't they? The front wall pushes only on two other walls that can
slide past the back wall, and vice versa.
Or were you asking about the mechanism outside the walls to make them move
in the proper paths? When the size is zero, each wall has one corner touching
the center. The wall needs to move in a straight line toward that position,
with speeds such that they all reach it at the same time.
|
| Let the cell be cubic, and have vertices at the eight points given
by ( {0,1}, {0,1}, {0,1} ). The cell floor is bounded by ( {0,1}, {0,1}
). We will shrink the cell to the origin:
floor: stationary
N wall: (-1,-1,0) diagonal slide SW
E wall: (-1,0,0) slide W
S wall: (0,0,-1) sinks downwards into floor
W wall: (0,-1,-1) sinks downwards into floor, while slide S
ceiling: (-1,-1,-1) sinks downwards to floor, while slide SW
One problem with this is that the roof may fall off part way through.
One way to fix this is to have another wall like the S wall, but
located (0,-1,0) (ie. to the W). This takes the weight of the roof as
it slides SW. The W wall slides between the two S facing walls.
Thus you end up with a cross-shaped trench, which is angled at the N
end.
Cheers,
Andrew
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