I got this challenging geometrical conundrum from a Russian geometrical magazine. It states:

(A. Soifer) Use six lines to cut a triangle into parts such that it is possible to compose seven congruent triangles from them.

In other words, given an arbitrary triangle, how can you use six straight cuts to dissect the triangle into some number of pieces, such that the pieces can be combined to form seven congruent triangles?

The solution must work for any given triangle. And, the six cuts must be made all at once (i.e. You can't make one cut, move the pieces around, then make another cut), though I wouldn't mind if anyone shared a solution with this methodology.

I found this problem extremely fun and rewarding to crack. Hope you guys enjoy it too!

  • $\begingroup$ Do the seven triangles have to use all different pieces, or can we use the same piece in two different triangles? $\endgroup$
    – Ankoganit
    Commented Aug 19, 2020 at 4:12
  • $\begingroup$ Must all the pieces be used? Because rot13( gurer vf n fvzcyr jnl gb phg vg vagb avar pbatehrag gevnatyrf jvgu fvk phgf, naq vs lbh bzvg bar phg lbh trg frira gevnatyrf naq na rkgen aba-gevnatyr cvrpr. ) $\endgroup$ Commented Aug 19, 2020 at 5:34
  • 1
    $\begingroup$ All pieces must be used, no pieces may be reused for different triangles. $\endgroup$ Commented Aug 19, 2020 at 5:52
  • $\begingroup$ Feel free to post such a dissection. $\endgroup$ Commented Aug 19, 2020 at 6:42

1 Answer 1


Here is a picture of the solution:

enter image description here

Only six of the lines of the underlying grid cut through the original triangle, so it can be dissected using only six cuts.

  • $\begingroup$ So this is a variation of the five times smaller square! I suspected so, but wasn't able to work it out. $\endgroup$ Commented Aug 19, 2020 at 7:58
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    $\begingroup$ @PaulPanzer Yes. The 5 times smaller square worked because $5$ can be written as the the sum of two squares $5=a^2+b^2$. For this triangle it works because $7$ can be written in the form $7=a^2+ab+b^2$ with integers $a$, $b$. $\endgroup$ Commented Aug 19, 2020 at 8:05
  • $\begingroup$ Nice! Indeed I was reminded of this problem upon seeing the square puzzle. $\endgroup$ Commented Aug 19, 2020 at 15:52
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    $\begingroup$ @PaulPanzer In the 5-times-smaller-square problem, the larger square splits into a central square and four right-triangles. If the triangles have legs $a$ and $b$ units in length, then the area of the whole square is $(a-b)^2+4(ab/2) = a^2+b^2$ square units. In this problem we have a central triangle surrounded by 3 triangles with legs of $a$ units along one axis and $b$ along another. These each have an area of $ab$ unit triangles, the centre triangle has an area of $(a-b)^2$ unit triangles, for a total of $a^2+ab+b^2$ unit triangles. $\endgroup$ Commented Aug 20, 2020 at 14:59
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    $\begingroup$ You are right however that we are not necessarily constrained to using the same number of cuts in each direction. We can use a triangular grid and scale it and skew it to make any three gridpoints match the vertices of the original triangle. By using different numbers of grid line cuts like this, you can divide the original triangle into pieces to make any number of smaller triangles, though those smaller triangles will no longer be similar in shape to the original, and I don't think you can create 7 unit triangles with just 6 cuts in any other way. $\endgroup$ Commented Aug 20, 2020 at 15:09

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