Difference between revisions of "2006 Romanian NMO Problems/Grade 10/Problem 1"
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− | + | ===Solution 1=== | |
+ | I claim that <math>f(A)=|A|</math>, for all <math>A\in \mathcal P(M)</math>. Clearly this function works; we must now show that it is the only function with the two given properties. We shall do this by proving that any such function <math>f</math> that satisfies both properties must be <math>f(A)=|A|</math>. | ||
− | ==See | + | We have <math>f(\emptyset) = f(\emptyset) + f(\emptyset)</math>, hence <math>f(\emptyset) = 0</math>. Also, if <math>A \subset B \subset M</math>, then <math>f(B) = f(A) + f(B-A)</math> since <math>B = B \cup A</math>, <math>A = B \cap A</math>, and <math>B-A = B\Delta A</math>. |
− | *[[2006 Romanian NMO Problems/Grade 9/Problem | + | |
− | *[[2006 Romanian NMO Problems/Grade | + | Let <cmath>A_{0} = \emptyset \subsetneq A_{1} \subsetneq \dotsb \subsetneq A_{n-1} \subsetneq A_{n} = M</cmath> be an increasing sequence of subsets of <math>M</math>, such that <math>A_{i} = A_{i-1} \cup \{a_{i}\}</math> for all <math>i=1,\dotsc,n</math>. Then <math>|A_{i}| = i</math> for all <math>i</math>. |
+ | |||
+ | Note that <math>f(a_{i}) \ge 1</math> for any <math>i</math>, from property (a). Hence <cmath>f(A_{0}) = 0 < f(A_{1}) < \dotsb < f(A_{n-1}) < f(A_{n}) \le n \;,</cmath> which implies <math>f(A_{i}) = i</math> for all <math>i</math>. | ||
+ | ===Solution 2=== | ||
+ | I claim that <math>f(A)=|A|</math>, for all <math>A\in \mathcal P(M)</math>. Clearly this function works; we must now show that it is the only function with the two given properties. We shall do this by constructing a function <math>f</math> that does satisfy both properties, and then showing that this function is in fact <math>f(A)=|A|</math>. | ||
+ | |||
+ | We have <math>f(\emptyset) = f(\emptyset) + f(\emptyset)</math>, hence <math>f(\emptyset) = 0</math>. Note that if <math>|A|=1</math>, then <math>f(A)\geq 1</math>, from property (a). Let <math>X=\{x\}</math> and <math>Y=\{x,y\}</math> for some <math>x,y\in M</math>. We then have from property <math>B</math> that <math>f(Y)=f(X)+f(Y\backslash X)</math>. Since <math>|X|=|Y\backslash X|=1</math>, <math>f(Y)\geq 2</math>. This shows that for all <math>Y</math> with <math>|Y|=2</math>, <math>f(Y)\geq 2</math>. | ||
+ | |||
+ | Lemma: <math>f(A)\geq |A|</math> for all <math>A\in \mathcal P(M)</math>. | ||
+ | Proof: We proceed by induction on <math>|A|</math>. Clearly <math>f(\phi)\geq 0</math> and <math>f(|A|)\geq 1</math> if <math>|A|=1</math> from property (a). This is our base case. | ||
+ | Now we do the inductive step. Assume that for all <math>i\leq k\leq n</math> for some positive integer <math>k</math>, <math>f(A)\leq |A|</math> if <math>|A|=i</math>. | ||
+ | Let <math>X</math> and <math>Y</math> be subsets of <math>M</math> such that <math>|X|=1</math>, <math>|Y|=k+1</math> and <math>X\subset Y</math>. | ||
+ | We then have from property 2 that <math>f(Y)=f(X)+f(Y\backslash X)</math>. From our inductive hypothesis, this sum is at least <math>k+1</math>. | ||
+ | This completes the inductive step, which completes the proof. | ||
+ | |||
+ | I shall now prove that <math>f(A)=|A|</math> for all <math>A\in \mathcal P(M)</math>. | ||
+ | |||
+ | Note that our lemma implies that <math>f(M)=n</math>. Consider a set <math>A\subset M</math> with cardinality <math>k</math>. We then have that <math>A \cup M=A</math> and <math> A \Delta M=M\backslash A</math>. We then have that <math>f(A)\geq k</math> and <math>f(M\backslash A)\geq n-k</math>, so their sum (which equals <math>f(M)</math> from property (b)) is at least <math>k+n-k=n</math>. This then implies that <math>f(A)=k</math> and <math>f(M\backslash A)=n-k</math> for all <math>A</math>. We defined <math>k</math> to be <math>|A|</math>, so <math>f(A)=|A|</math>. This completes the proof. | ||
+ | |||
+ | ==See Also== | ||
+ | *[[2006 Romanian NMO Problems/Grade 9/Problem 4 | Previous problem]] | ||
+ | *[[2006 Romanian NMO Problems/Grade 10/Problem 2 | Next problem]] | ||
*[[2006 Romanian NMO Problems]] | *[[2006 Romanian NMO Problems]] | ||
− | [[Category:Olympiad | + | [[Category:Olympiad Combinatorics Problems]] |
Latest revision as of 09:53, 8 May 2012
Problem
Let be a set composed of elements and let be its power set. Find all functions that have the properties
(a) , for ;
(b) , for all , where .
Solution
Solution 1
I claim that , for all . Clearly this function works; we must now show that it is the only function with the two given properties. We shall do this by proving that any such function that satisfies both properties must be .
We have , hence . Also, if , then since , , and .
Let be an increasing sequence of subsets of , such that for all . Then for all .
Note that for any , from property (a). Hence which implies for all .
Solution 2
I claim that , for all . Clearly this function works; we must now show that it is the only function with the two given properties. We shall do this by constructing a function that does satisfy both properties, and then showing that this function is in fact .
We have , hence . Note that if , then , from property (a). Let and for some . We then have from property that . Since , . This shows that for all with , .
Lemma: for all . Proof: We proceed by induction on . Clearly and if from property (a). This is our base case. Now we do the inductive step. Assume that for all for some positive integer , if . Let and be subsets of such that , and . We then have from property 2 that . From our inductive hypothesis, this sum is at least . This completes the inductive step, which completes the proof.
I shall now prove that for all .
Note that our lemma implies that . Consider a set with cardinality . We then have that and . We then have that and , so their sum (which equals from property (b)) is at least . This then implies that and for all . We defined to be , so . This completes the proof.