Hi all, I have pondered this for about 5 years. I was asked this once by a student who was stuck on this word problem in some class or another, and I have come up with more than one solution, and although he didn't like any of them, it was a good way to kill a couple of beers.
I found this board and thought I would share, and probably stick around as there is a lot of info here.
BobRodes, I originally envisioned the solution you proposed, but I had to discard it, simply because it creates too many pieces. I'm pretty sure that the original question was designed to elicit a similar answer regarding sine wave measurement though. You could stretch the semantics to say you would melt the two ends together, because that is not specifically prohibited in the problem, but then you could melt it into 7 smaller ingots and not make any cuts, so I'm going to push the "fail" buzzer on that one too.
I guess I should start by making an assumption on the wording of the problem. "Equal Pieces" has to be quantifiable. I'm going to assume that volume, or mass, or for our purposes weight, is keeping within the guidelines. This is very important. We'll assume the bar is 1 ounce for reference below.
Solution 1, we can modify your solution slightly, by cutting it in a sine wave, but in the middle, limiting the frequency to 1.5 wavelengths. That gives us 3 equal pieces of 1/7 oz and two ends of 2/7 oz each, if we've dome it correctly. Then we can stack the two ends and make one cut through them to divide them into 4 pieces of 1/7 oz each. 7 * 1/7 oz = 1 oz.
That was discarded because the stack-and-cut could be considered two cuts by itself depending on how you read it. No problem.
Solution 2, we don't cut all the way through, but more like we etch through the ingot or bar almost all the way. We still use our sine wave pattern, but this time 3 wavelengths so that we have 6 full "sine-pieces" with extra on the end. Now here is the tricky part, we turn the ingot in its edge, and slice down only in the middle, freeing the 6 pieces from the ingot, 1/7 oz each, and leaving a flat sheet with two partial pieces attached. If we calculated our cut depth and our sine frequency correctly by making it slightly longer, the two ends will be connected by a flattish sheet of leftover gold, still technically one piece, and weighing 1/7 oz total.
I liked that better but couldn't come up with enough math to convince my bud to use it, so I came up with yet another way.
Solution 3, the gold is in a cylindrical bar shape. Shape is critical here as I'll get to in a moment. We take our magic gold knife and start a cut only halfway through the bar to the centerline, and rotate the bar as we cut so that we get a spiral cut. The bar will still be in one piece at this point. Then we cut lengthwise, again halfway through to centerline, which causes the pieces to separate. It is not too different from cutting a spring across the coils; you end up with a bunch of rings at the end. I said shape was critical here, but it can be done. I spent awhile later on playing with modeling clay and a sharp knife. Try it.
Solution 4 came from solution 3, and assumes we start with a spring, or a thickish wire we can coil into a spring. Simply cut down the edge, one cut does it.
Those are what I came up with at the spur of the moment in June of 2000. It has haunted me ever since, LOL!
![[smarty]](/data/assets/smilies/smarty.gif "[smarty] [smarty]")
![[lol]](/data/assets/smilies/lol.gif "[lol] [lol]")
![[deadhorse]](/data/assets/smilies/deadhorse.gif "[deadhorse] [deadhorse]")
