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  • The Math Thread

    A thread for talking about math and enjoying its wonderfulness.

    Here's a fun little math challenge: Find uncountably many sets of integers such that the intersections of any two of them is finite.

  • #2
    Does 1 (1sf) + 1(1sf) = 2 (0dp) ?

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    • #3
      1sf? 0dp?

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      • #4
        Congrats. New(winning) thread.
        Life is not measured by the number of breaths you take, but by the moments that take your breath away.
        "Hating America is something best left to Mobius. He is an expert Yank hater.
        He also hates Texans and Australians, he does diversify." ~ Braindead

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        • #5
          Sorry, but "Does .9-repeating equal 1?" still retains its title as gayest math thread in all of existence.
          The cake is NOT a lie. It's so delicious and moist.

          The Weighted Companion Cube is cheating on you, that slut.

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          • #6
            We need a vote, DR. Do you think?
            Life is not measured by the number of breaths you take, but by the moments that take your breath away.
            "Hating America is something best left to Mobius. He is an expert Yank hater.
            He also hates Texans and Australians, he does diversify." ~ Braindead

            Comment


            • #7
              Re: The Math Thread

              Originally posted by civman2000
              A thread for talking about math and enjoying its wonderfulness.

              Here's a fun little math challenge: Find uncountably many sets of integers such that the intersections of any two of them is finite.
              Oooo.

              Tough.
              12-17-10 Mohamed Bouazizi NEVER FORGET
              Stadtluft Macht Frei
              Killing it is the new killing it
              Ultima Ratio Regum

              Comment


              • #8
                Re: The Math Thread

                Originally posted by civman2000
                Here's a fun little math challenge: Find uncountably many sets of integers such that the intersections of any two of them is finite.
                Does this work?

                Consider

                {a_1, a_2, a_3, ... : 0 <= a_i <= 9}

                That is, the set of all sequences of integers whose elements are between 0 and 9.

                These sequences obviously correspond to real numbers between 0 and 1 (by looking at the decimal representation .a_1 a_2 a_3 ...), and hence represent an uncountable collection. However, the intersection of any two such sequences is finite, because the elements of any two such sequences are contained in {0, 1, ... , 9}.
                "The avalanche has already started. It is too late for the pebbles to vote."
                -- Kosh

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                • #9
                  Originally posted by SlowwHand
                  We need a vote, DR. Do you think?
                  No, because I'm afraid of how they might try to tally the votes...
                  The cake is NOT a lie. It's so delicious and moist.

                  The Weighted Companion Cube is cheating on you, that slut.

                  Comment


                  • #10
                    Assuming that my previous reply is correct, here's another challenge:

                    Given any integer N, show that some integer multiple of N consists entirely of the digits 0 and 1.

                    For example,

                    2 x 5 = 10
                    3 x 37 = 111
                    4 x 25 = 100

                    etc.
                    "The avalanche has already started. It is too late for the pebbles to vote."
                    -- Kosh

                    Comment


                    • #11
                      Got it.

                      For every real number R there exists a sequence of rational numbers qn such that lim(n->inf)qn = R.

                      Now, any two distinct real numbers (R1 and R2) are separated by a distance |R1-R2| = d > 0 and have corresponding sequences qn and vn (respectively). Since qn converges to R1 there exists M1 s.t |R1 - qn| < d/2 when n>M1. Similarly, there exists M2 s.t. |R2-vn| < d/2 when n>M2. Therefore, if qm = vn either m < M1 or n < M2. Therefore {qn} intersection {vn} contains less than M1+M2 elements (specifically, the set {q1,...,qM1} union {v1,...vM2}). Now, this is finite. Also, there are uncountably many of these sets (since there are uncountably many reals). The only problem is that these are sets over the rationals, not the integers. Oh, wait! Cantor's diagonal theorem to the rescue. There exists a bijection between the rationals and the integers. Call this mapping b: Q -> I. Represent the aforementioned converging sequence of rationals to a real R as {qRn}. Our uncountable set of subsets is the union over all R of {b(qRn}}

                      EDIT: formatting
                      Last edited by KrazyHorse; November 19, 2006, 10:58.
                      12-17-10 Mohamed Bouazizi NEVER FORGET
                      Stadtluft Macht Frei
                      Killing it is the new killing it
                      Ultima Ratio Regum

                      Comment


                      • #12
                        Re: Re: The Math Thread

                        Originally posted by Petek


                        Does this work?

                        Consider

                        {a_1, a_2, a_3, ... : 0 <= a_i <= 9}

                        That is, the set of all sequences of integers whose elements are between 0 and 9.

                        These sequences obviously correspond to real numbers between 0 and 1 (by looking at the decimal representation .a_1 a_2 a_3 ...), and hence represent an uncountable collection. However, the intersection of any two such sequences is finite, because the elements of any two such sequences are contained in {0, 1, ... , 9}.
                        This answer makes no sense.
                        12-17-10 Mohamed Bouazizi NEVER FORGET
                        Stadtluft Macht Frei
                        Killing it is the new killing it
                        Ultima Ratio Regum

                        Comment


                        • #13
                          There are an infinite number of sequences of integers between 1 and 9. There are only a finite number of sets of integers between 1 and 9 (specifically 2^9)
                          12-17-10 Mohamed Bouazizi NEVER FORGET
                          Stadtluft Macht Frei
                          Killing it is the new killing it
                          Ultima Ratio Regum

                          Comment


                          • #14
                            This thread stopped making sense for me after I read "Find uncountably many".

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                            • #15
                              If it stopped making sense after that then you probably have a decent enough math background...
                              12-17-10 Mohamed Bouazizi NEVER FORGET
                              Stadtluft Macht Frei
                              Killing it is the new killing it
                              Ultima Ratio Regum

                              Comment

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