Vitali set: Difference between revisions

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The term '''Vitali set''' describes any set obtained by a particular mathematical construction. In fact, the construction uses the [[axiom of choice]] and the result given by an existence theorem is not uniquely determined. Vitali sets have many important applications in pure mathematics, most notable being a proof of existence of Lebesgue non-measurable sets in the [[measure theory]]. The name was given after the Italian mathematician [[Giuseppe Vitali]].
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The term '''Vitali set''' describes any set obtained by a particular mathematical construction. The construction uses the [[axiom of choice]] and its result given by an existence theorem is not uniquely determined. Vitali sets have many important applications in mathematics, most notable being a proof of existence of Lebesgue non-measurable sets in [[measure theory]]. The name was given after the Italian mathematician [[Giuseppe Vitali]].


== Formal construction ==
== Formal construction ==
We begin by defining the following [[relation]] on the real line. Two real numbers ''x'' and ''y'' are said to be equivalent if and only if the difference ''x-y'' is rational. In symbols,
We begin by defining the following [[relation]] on the real line. Two real numbers ''x'' and ''y'' are said to be equivalent if and only if the difference ''x-y'' is rational. In symbols,
:<math> x \sim y \iff x-y \in \mathbb{Q}.</math>
:<math> x \sim y \iff x-y \in \mathbb{Q}.</math>
It is easy to verify that it is in fact an [[equivalence relation]]. Thus, it yields the partition the set of reals into its equivalence classes. By the axiom of choice we can select a representative of each single class. The Vitali set ''V'' is defined to be the union all selected representatives.  
It is easy to verify that it is in fact an [[equivalence relation]]. Thus, it yields a partition of the set of reals into its equivalence classes. By the axiom of choice we can select a representative of each single class. The Vitali set ''V'' is defined to be the set of all selected representatives.  


Since for any real ''x'' the elements of the set <math>\{ x+i:\;\;i\in \mathbb{Z} \}</math> are in the same equivalence class, me may (and do) additionaly require that <math>V\subset [0,1]</math> (indeed, ''x+i'' belong to [0,1]  for some ''i'').
Since for any real ''x'' the elements of the set <math>\{ x+i:\;\;i\in \mathbb{Z} \}</math> are in the same equivalence class, me may (and do) additionally require that <math>V\subset [0,1]</math> (indeed, ''x+i'' belong to [0,1]  for some ''i'').


== Application to measure theory ==
== Application to measure theory ==
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In particular, this presumes that any translation of any measurable set is measurable. We will show that <math>V\notin \Sigma.</math>
In particular, this presumes that any translation of any measurable set is measurable. We will show that <math>V\notin \Sigma.</math>


Observe that for any rational <math>q\not=0</math> the sets ''V+q'' and ''V'' are disjoint. Indeed, if there is any <math>x\in (V+q)\cap V</math> then at the same time <math>x-q\in V</math> and <math>x\in V</math>. In other words ''V'' contains two distinct representatives of the same equivalence class, which contradicts the definition of ''V''.
Observe that for any rational <math>q\not=0</math> the sets ''V+q'' and ''V'' are disjoint. This is because if there is any <math>x\in (V+q)\cap V</math> then at the same time <math>x-q\in V</math> and <math>x\in V</math>. In other words ''V'' contains two distinct representatives of the same equivalence class, which contradicts the definition of ''V''.


Let <math>q_1,q_2,...</math> be an enumeration of the rationals from [-1,1] and define  
Let <math>q_1,q_2,...</math> be an enumeration of the rationals from [-1,1] and define  
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Then, clearly  
Then, clearly  
:<math> [0,1]\subset W\subset [-1,2].</math>
:<math> [0,1]\subset W\subset [-1,2].</math>
Indeed, the second inclusion follows directly from the fact that <math>V\subset[0,1]</math> and <math>q_n\in[-1,1].</math> For the first one, observe that for any <math>x\in [0,1]</math>, the class of equivalence of ''x'' has its uniqe representative ''y''  in ''V''. Therefore ''x-y'' is rational and, by the fact that <math>V\subset[0,1]</math> we have <math>x-y\in [-1,1]</math>. In other words, <math> x-y=q_n</math> for some ''n'' and so <math>x\in V+q_n\subset W</math>.
Indeed, the second inclusion follows directly from the fact that <math>V\subset[0,1]</math> and <math>q_n\in[-1,1].</math> For the first one, observe that for any <math>x\in [0,1]</math>, the class of equivalence of ''x'' has its unique representative ''y''  in ''V''. Therefore ''x-y'' is rational and, by the fact that <math>V\subset[0,1]</math>, we have <math>x-y\in [-1,1]</math>. In other words, <math> x-y=q_n</math> for some ''n'' and so <math>x\in V+q_n\subset W</math>.


Now suppose that the set ''V'' is measurable (and so are <math>V+q_n</math>). Recall that by definition any measure is supposed to be countably additive. It follows that
Now suppose that the set ''V'' is measurable (and so are <math>V+q_n</math>). Recall that by definition any measure is supposed to be countably additive. It follows that
:<math> \mu(W) = \mu (\bigcup_{n=1}^\infty (V+q_n)) = \sum_{n=1}^\infty \mu(V+q_n).</math>
:<math> \mu(W) = \mu (\bigcup_{n=1}^\infty (V+q_n)) = \sum_{n=1}^\infty \mu(V+q_n).</math>
since <math>(V+q_n)_{n=1..\infty}</math> is a family of pairwise disjoint sets. Further, by tranlation invariance of ''&mu;'' this is equal to <math> \sum_{n=1}^\infty \mu(V).</math>
since <math>(V+q_n)_{n=1..\infty}</math> is a family of pairwise disjoint sets. Further, by translation invariance of ''&mu;'' this is equal to <math> \sum_{n=1}^\infty \mu(V).</math>
Since ''W'' contains the interval [0,1] we clearly have  
Since ''W'' contains the interval [0,1] we clearly have  
<math>\mu(W) \ge \mu([0,1])=1,</math>
<math>\mu(W) \ge \mu([0,1])=1,</math>
which implies that <math>\mu(V)</math> is strictly positive. At the same time, the infinite sum is bounded by <math>\mu([-1,2]) = 3</math>, which is a contradiction. Consequently, <math>V\notin \Sigma.</math>
which implies that <math>\mu(V)</math> is strictly positive. At the same time, the infinite sum is bounded by <math>\mu([-1,2]) = 3</math>, which is a contradiction. Consequently, <math>V\notin \Sigma.</math>


 
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The term Vitali set describes any set obtained by a particular mathematical construction. The construction uses the axiom of choice and its result given by an existence theorem is not uniquely determined. Vitali sets have many important applications in mathematics, most notable being a proof of existence of Lebesgue non-measurable sets in measure theory. The name was given after the Italian mathematician Giuseppe Vitali.

Formal construction

We begin by defining the following relation on the real line. Two real numbers x and y are said to be equivalent if and only if the difference x-y is rational. In symbols,

It is easy to verify that it is in fact an equivalence relation. Thus, it yields a partition of the set of reals into its equivalence classes. By the axiom of choice we can select a representative of each single class. The Vitali set V is defined to be the set of all selected representatives.

Since for any real x the elements of the set are in the same equivalence class, me may (and do) additionally require that (indeed, x+i belong to [0,1] for some i).

Application to measure theory

A Vitali set can not be included in the family of measurable sets for any translation invariant measure. In particular it is not Lebesgue measurable.

More precisely, suppose that a measure μ defined over a σ-algebra Σ of subsets of the real line satisfies

In particular, this presumes that any translation of any measurable set is measurable. We will show that

Observe that for any rational the sets V+q and V are disjoint. This is because if there is any then at the same time and . In other words V contains two distinct representatives of the same equivalence class, which contradicts the definition of V.

Let be an enumeration of the rationals from [-1,1] and define

Then, clearly

Indeed, the second inclusion follows directly from the fact that and For the first one, observe that for any , the class of equivalence of x has its unique representative y in V. Therefore x-y is rational and, by the fact that , we have . In other words, for some n and so .

Now suppose that the set V is measurable (and so are ). Recall that by definition any measure is supposed to be countably additive. It follows that

since is a family of pairwise disjoint sets. Further, by translation invariance of μ this is equal to Since W contains the interval [0,1] we clearly have which implies that is strictly positive. At the same time, the infinite sum is bounded by , which is a contradiction. Consequently,