Geometry problems ...

jon-nyc

I almost posted that I was making that assumption, which may not be valid given the warning on the diagram.

Klaus

From my geometric method one can also derive an analytic solution. The formula is a little complicated, but the exact solution for X in the second problem is square root of 71, or 8.426149773176359.

Now I'm curious what Ax came up with.

89th

I feel dumb reading this thread. Most math (sorry, Maths, for Phibes) concepts have long since left my brain.

Horace

well the length of the line from the bottom left vertex to the top right vertex can be computed directly as the hypotenuse of a right triangle with the other two sides of length 8 and 4. That length gives you two lengths of a right triangle - 4 and that length in A, or 3 and that length in B. The third length is x. it's then an algebra problem using pythagoras. That method should work for both problems. Not elegant but not too complicated.

Klaus

@Horace said in Geometry problems ...:

well the length of the line from the bottom left vertex to the top right vertex can be computed directly as the hypotenuse of a right triangle with the other two sides of length 8 and 4.

I don't think so. Why should the length of the other side be 8?

Horace

I'm sliding the length 4 segment (the one in the middle) down the length 5 segment by 3 units so the length 4 segment touches the left vertical. That gives a right triangle of side lengths 4, 8, and sqrt(80). sqrt(80) is the hypotenuse of the right triangle with other lengths y and x, where y is either 3 or 4 in the two problems and x is the answer.

Klaus

Now I understand. Yes, that seems to work! That's actually the analytic solution that corresponds to my geometric solution.

Horace

Ax's method for problem A probably starts with the 8/4 right triangle idea and from there finds that x must be 8 because there are then two symmetric right triangles with their hypotenuses, er hypoteni, in common, and we know both have equal lengths of 4 for the short side and they must also have equal length for the long non-hypotenuse side, which in that case is 8, by the original idea of constructing the 8/4 triangle.

Axtremus

My solution to Variation-A:

The black outline polygon ABCDE is the information provided in the problem.

• Use the information from the BCDE line segments to construct the BF(D)E triangle.
• Realize that the BAE triangle is congruent to the BFE triangle.
• Hence the length of FE equals the length of AE, x = 8

Axtremus

My solution for Variation-B, as mentioned before, need to apply the Pythagorean Theorem twice, but it is essentially the same as already described by @Horace (4 posts above, and 6 posts above).

Some one made YouTube video that very nicely illustrated that solution:

Link to video

I got these two problems from that YouTube video.

Horace

In fairness, I also anticipated what your solution to variation A was, in my last post.

Klaus

That was a nice puzzle. Initially I made it way more complicated than it needed to be. I'm a little proud I found a solution that doesn't require Pythagoras or, for that matter, any formula at all