The Nation Has Problems: Vol. 10

About Last Month

1. Find the last three digits of \(2011^{2012}\).

The first thing you might notice about this problem which can make it significantly easier is that \(2011\equiv 11 \pmod {1000}\) so we can consider the simpler problem of finding the last three digits of \(11^{2012}\).  From here,  I used the binomial theorem to write

$$11^{2012} = (10+1)^{2012} = \sum_{i=0}^{2012} \binom{2012}{i} 10^{i}1^{2012-i} $$

Notice that in the sum, anything with a \(10^3\) or higher will end in all zeros, so the last three digits are the last three digits of

$$\binom{2012}{2}10^2 + \binom{2012}{1}10 + \binom{2012}{0} = 202,306,600 + 20,120 +1$$

from which we can see the last 3 digits are 721.

2. Evaluate \(\sqrt{1 + \sqrt{ 1 + \sqrt{ 1 + \cdots } } } \)

Let \(x=\sqrt{1 + \sqrt{ 1 + \sqrt{ 1 + \cdots } } } \). Then we see that \(x=\sqrt{1+x}\) from which we get

$$x=\frac{1\pm\sqrt5}{2}$$

since \((1-\sqrt 5)/2\) is negative, the answer must be \((1+\sqrt 5)/2\) which is the golden ratio. Interestingly, the golden ratio is also equal to the continued fraction

$$1 + \cfrac{1}{1 + \cfrac{1}{1 + \cfrac{1}{1 + \ddots}}}$$

and the solution can be obtained in a very similar manner (in this case, \(x=1+\frac 1x\)).

The Problem

I'm low on inspiration this month, so I'm stealing another one for the Citadel's problem of the week.  I think there are probably a lot of ways to approach this one, so I'm curious to see what people can come up with!

1.  Lagrange proved that any positive integer can be written as the sum of four squares.  For instance, \(19=3^2+3^2+1^2+0^2\) and \(97=6^2+6^2+5^2+0^2\).  Express 2012 as the sum of four squares in two different ways--first, as the sum of squares where one number appears twice and second where all 4 numbers are different.

2. http://spikedmath.com/puzzle-006.html (I haven't worked this one out yet, so I don't know the answer!)

30 thoughts on “The Nation Has Problems: Vol. 10”

  1. To be honest, I feel like including the \(0^{2}\) term is cheating. I could say that any number can be written as the sum of 100 squares if 95 of them are \(0^{2}\).

    1. I don't think that the impressive part is supposed to be a large amount of squares. It's supposed to be how few squares it takes. For instance, each positive number cannot be written as the sum of three squares.

      1. That is correct.

        In most cases, I don't think the expression as a sum of 4 squares is unique. In most cases, there are many, many numbers that work. For instance, the solutions that Beau got above are both different than the two I got.

        Using 0 is sometimes necessary to make it work. For instance, \(3 = 1^2 + 1^2 + 1^2 + 0^2\) and that's the only way to do it.

        1. I get why \(0^{2}\) is useful, I just thought that it seemed like the rule should be "4 or fewer squares" instead of strictly 4 and using some filler.

    1. My first inclination that Player 2 was in the driver's seat due to there being an even number in each row was thwarted by the fact I still cannot parse instructions in math problems properly.

      1. That's my intuition, too.

        He just needs to stop the path at one spot, which doesn't seem too difficult. It seems like he'd want to try and force the larger numbers toward the outside as well, as that doesn't give the first player as many options.

    2. That site has put up some interesting math games. They're rather difficult, though.

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        1. It's exactly the same idea as what you have, just a bit simpler. I don't think there's a way around it.

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      2. Very nice. What about proving that the strategy is optimal? (It isn't really clear to me what is meant by "optimal" in this case.)

        1. No clue about what is meant by "optimal". I've almost completely solved this game.

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  2. Spoiler: part 2 SelectShow
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  3. Problem 1:

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