In a measurable partition of an interval, the sum of the measures of the subsets in the partition equals the...











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I am working through A User-Friendly Introduction to Lebesgue Measure and Integration, by Gail S. Nelson. On page 67 Nelson defines a measurable partition of the interval $[a,b]$ to be finite collection $ {E_j }_{j=1}^{n}$ of subsets of $[a,b]$ such that: (1) $E_j$ is measurable for each $j$, (2) $bigcup_{j=1}^{n}E_j=[a,b]$, and (3) $m(E_i cap E_j)=0$ whenever $inot=j$. On page 68 she then remarks that given any measurable partition of $[a,b]$, we can convert it into a pairwise disjoint measurable partition like so: set $F_1=E_1$, and $F_j=E_j setminus(bigcup_{i=1}^{j-1}E_i)$ for $j=2,3,...n$. I can see why these sets are pairwise disjoint, and I can see how each one is measurable, but I'm unable to prove that (1) their union is $[a,b]$ and (2) that $m(E_j)=m(F_j)$ for each $j=2,3,...n$. I suspect I'm overlooking something simple. Any help is greatly appreciated!










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    I am working through A User-Friendly Introduction to Lebesgue Measure and Integration, by Gail S. Nelson. On page 67 Nelson defines a measurable partition of the interval $[a,b]$ to be finite collection $ {E_j }_{j=1}^{n}$ of subsets of $[a,b]$ such that: (1) $E_j$ is measurable for each $j$, (2) $bigcup_{j=1}^{n}E_j=[a,b]$, and (3) $m(E_i cap E_j)=0$ whenever $inot=j$. On page 68 she then remarks that given any measurable partition of $[a,b]$, we can convert it into a pairwise disjoint measurable partition like so: set $F_1=E_1$, and $F_j=E_j setminus(bigcup_{i=1}^{j-1}E_i)$ for $j=2,3,...n$. I can see why these sets are pairwise disjoint, and I can see how each one is measurable, but I'm unable to prove that (1) their union is $[a,b]$ and (2) that $m(E_j)=m(F_j)$ for each $j=2,3,...n$. I suspect I'm overlooking something simple. Any help is greatly appreciated!










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      I am working through A User-Friendly Introduction to Lebesgue Measure and Integration, by Gail S. Nelson. On page 67 Nelson defines a measurable partition of the interval $[a,b]$ to be finite collection $ {E_j }_{j=1}^{n}$ of subsets of $[a,b]$ such that: (1) $E_j$ is measurable for each $j$, (2) $bigcup_{j=1}^{n}E_j=[a,b]$, and (3) $m(E_i cap E_j)=0$ whenever $inot=j$. On page 68 she then remarks that given any measurable partition of $[a,b]$, we can convert it into a pairwise disjoint measurable partition like so: set $F_1=E_1$, and $F_j=E_j setminus(bigcup_{i=1}^{j-1}E_i)$ for $j=2,3,...n$. I can see why these sets are pairwise disjoint, and I can see how each one is measurable, but I'm unable to prove that (1) their union is $[a,b]$ and (2) that $m(E_j)=m(F_j)$ for each $j=2,3,...n$. I suspect I'm overlooking something simple. Any help is greatly appreciated!










      share|cite|improve this question













      I am working through A User-Friendly Introduction to Lebesgue Measure and Integration, by Gail S. Nelson. On page 67 Nelson defines a measurable partition of the interval $[a,b]$ to be finite collection $ {E_j }_{j=1}^{n}$ of subsets of $[a,b]$ such that: (1) $E_j$ is measurable for each $j$, (2) $bigcup_{j=1}^{n}E_j=[a,b]$, and (3) $m(E_i cap E_j)=0$ whenever $inot=j$. On page 68 she then remarks that given any measurable partition of $[a,b]$, we can convert it into a pairwise disjoint measurable partition like so: set $F_1=E_1$, and $F_j=E_j setminus(bigcup_{i=1}^{j-1}E_i)$ for $j=2,3,...n$. I can see why these sets are pairwise disjoint, and I can see how each one is measurable, but I'm unable to prove that (1) their union is $[a,b]$ and (2) that $m(E_j)=m(F_j)$ for each $j=2,3,...n$. I suspect I'm overlooking something simple. Any help is greatly appreciated!







      real-analysis lebesgue-integral lebesgue-measure






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      asked Nov 15 at 22:50









      Alex Sanger

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          1 Answer
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          Let's start with $(1)$. Since $F_j subset E_j subset [a,b]$, we only have to see that $[a,b] subset bigcup_j F_j$. Take $x in [a,b]$ and let $s = min{n : x in E_j}$. This is well defined because there exists some $j$ for which $x in E_j$ since the $E_j$s partition $[a,b]$. By construction, $x in E_s$ but necessarily, $x not in E_t$ when $t < s$. Hence,



          $$
          x in E_s setminus bigcup_{t < s}E_t = E_s setminus bigcup_{t=1}^{s-1}E_t = F_s.
          $$


          This proves that, in effect, $[a,b]$ is the disjoint union of $F_1, dots, F_n$.



          Finally, note that for each $j in [n]$,



          $$
          F_j = E_j setminus bigcup_{i=1}^{j-1}E_i = E_j setminus bigcup_{i=1}^{j-1}E_j cap E_i
          $$



          and so since everything here is measurable and of finite measure,



          $$
          |F_j| = |E_j| - left|bigcup_{i < j}E_j cap E_iright|. tag{$star$}
          $$



          However, by hypothesis we have that



          $$
          left|bigcup_{i < j}E_j cap E_iright| leq sum_{i < j}|E_j cap E_i| = 0,
          $$



          and so plugging that in $(star)$ proves that, in effect,



          $$
          |F_j| = |E_j|.
          $$



          The intuition here is that $F_i$ is $E_i$ except removing some of the intersections with other $E_j$, but since all of these are of zero measure by hypothesis, $F_i$ and $E_i$ have the same measure: the sets we have 'cropped' are (measure wise) negligible.






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            1 Answer
            1






            active

            oldest

            votes








            1 Answer
            1






            active

            oldest

            votes









            active

            oldest

            votes






            active

            oldest

            votes








            up vote
            1
            down vote



            accepted










            Let's start with $(1)$. Since $F_j subset E_j subset [a,b]$, we only have to see that $[a,b] subset bigcup_j F_j$. Take $x in [a,b]$ and let $s = min{n : x in E_j}$. This is well defined because there exists some $j$ for which $x in E_j$ since the $E_j$s partition $[a,b]$. By construction, $x in E_s$ but necessarily, $x not in E_t$ when $t < s$. Hence,



            $$
            x in E_s setminus bigcup_{t < s}E_t = E_s setminus bigcup_{t=1}^{s-1}E_t = F_s.
            $$


            This proves that, in effect, $[a,b]$ is the disjoint union of $F_1, dots, F_n$.



            Finally, note that for each $j in [n]$,



            $$
            F_j = E_j setminus bigcup_{i=1}^{j-1}E_i = E_j setminus bigcup_{i=1}^{j-1}E_j cap E_i
            $$



            and so since everything here is measurable and of finite measure,



            $$
            |F_j| = |E_j| - left|bigcup_{i < j}E_j cap E_iright|. tag{$star$}
            $$



            However, by hypothesis we have that



            $$
            left|bigcup_{i < j}E_j cap E_iright| leq sum_{i < j}|E_j cap E_i| = 0,
            $$



            and so plugging that in $(star)$ proves that, in effect,



            $$
            |F_j| = |E_j|.
            $$



            The intuition here is that $F_i$ is $E_i$ except removing some of the intersections with other $E_j$, but since all of these are of zero measure by hypothesis, $F_i$ and $E_i$ have the same measure: the sets we have 'cropped' are (measure wise) negligible.






            share|cite|improve this answer

























              up vote
              1
              down vote



              accepted










              Let's start with $(1)$. Since $F_j subset E_j subset [a,b]$, we only have to see that $[a,b] subset bigcup_j F_j$. Take $x in [a,b]$ and let $s = min{n : x in E_j}$. This is well defined because there exists some $j$ for which $x in E_j$ since the $E_j$s partition $[a,b]$. By construction, $x in E_s$ but necessarily, $x not in E_t$ when $t < s$. Hence,



              $$
              x in E_s setminus bigcup_{t < s}E_t = E_s setminus bigcup_{t=1}^{s-1}E_t = F_s.
              $$


              This proves that, in effect, $[a,b]$ is the disjoint union of $F_1, dots, F_n$.



              Finally, note that for each $j in [n]$,



              $$
              F_j = E_j setminus bigcup_{i=1}^{j-1}E_i = E_j setminus bigcup_{i=1}^{j-1}E_j cap E_i
              $$



              and so since everything here is measurable and of finite measure,



              $$
              |F_j| = |E_j| - left|bigcup_{i < j}E_j cap E_iright|. tag{$star$}
              $$



              However, by hypothesis we have that



              $$
              left|bigcup_{i < j}E_j cap E_iright| leq sum_{i < j}|E_j cap E_i| = 0,
              $$



              and so plugging that in $(star)$ proves that, in effect,



              $$
              |F_j| = |E_j|.
              $$



              The intuition here is that $F_i$ is $E_i$ except removing some of the intersections with other $E_j$, but since all of these are of zero measure by hypothesis, $F_i$ and $E_i$ have the same measure: the sets we have 'cropped' are (measure wise) negligible.






              share|cite|improve this answer























                up vote
                1
                down vote



                accepted







                up vote
                1
                down vote



                accepted






                Let's start with $(1)$. Since $F_j subset E_j subset [a,b]$, we only have to see that $[a,b] subset bigcup_j F_j$. Take $x in [a,b]$ and let $s = min{n : x in E_j}$. This is well defined because there exists some $j$ for which $x in E_j$ since the $E_j$s partition $[a,b]$. By construction, $x in E_s$ but necessarily, $x not in E_t$ when $t < s$. Hence,



                $$
                x in E_s setminus bigcup_{t < s}E_t = E_s setminus bigcup_{t=1}^{s-1}E_t = F_s.
                $$


                This proves that, in effect, $[a,b]$ is the disjoint union of $F_1, dots, F_n$.



                Finally, note that for each $j in [n]$,



                $$
                F_j = E_j setminus bigcup_{i=1}^{j-1}E_i = E_j setminus bigcup_{i=1}^{j-1}E_j cap E_i
                $$



                and so since everything here is measurable and of finite measure,



                $$
                |F_j| = |E_j| - left|bigcup_{i < j}E_j cap E_iright|. tag{$star$}
                $$



                However, by hypothesis we have that



                $$
                left|bigcup_{i < j}E_j cap E_iright| leq sum_{i < j}|E_j cap E_i| = 0,
                $$



                and so plugging that in $(star)$ proves that, in effect,



                $$
                |F_j| = |E_j|.
                $$



                The intuition here is that $F_i$ is $E_i$ except removing some of the intersections with other $E_j$, but since all of these are of zero measure by hypothesis, $F_i$ and $E_i$ have the same measure: the sets we have 'cropped' are (measure wise) negligible.






                share|cite|improve this answer












                Let's start with $(1)$. Since $F_j subset E_j subset [a,b]$, we only have to see that $[a,b] subset bigcup_j F_j$. Take $x in [a,b]$ and let $s = min{n : x in E_j}$. This is well defined because there exists some $j$ for which $x in E_j$ since the $E_j$s partition $[a,b]$. By construction, $x in E_s$ but necessarily, $x not in E_t$ when $t < s$. Hence,



                $$
                x in E_s setminus bigcup_{t < s}E_t = E_s setminus bigcup_{t=1}^{s-1}E_t = F_s.
                $$


                This proves that, in effect, $[a,b]$ is the disjoint union of $F_1, dots, F_n$.



                Finally, note that for each $j in [n]$,



                $$
                F_j = E_j setminus bigcup_{i=1}^{j-1}E_i = E_j setminus bigcup_{i=1}^{j-1}E_j cap E_i
                $$



                and so since everything here is measurable and of finite measure,



                $$
                |F_j| = |E_j| - left|bigcup_{i < j}E_j cap E_iright|. tag{$star$}
                $$



                However, by hypothesis we have that



                $$
                left|bigcup_{i < j}E_j cap E_iright| leq sum_{i < j}|E_j cap E_i| = 0,
                $$



                and so plugging that in $(star)$ proves that, in effect,



                $$
                |F_j| = |E_j|.
                $$



                The intuition here is that $F_i$ is $E_i$ except removing some of the intersections with other $E_j$, but since all of these are of zero measure by hypothesis, $F_i$ and $E_i$ have the same measure: the sets we have 'cropped' are (measure wise) negligible.







                share|cite|improve this answer












                share|cite|improve this answer



                share|cite|improve this answer










                answered Nov 15 at 23:10









                Guido A.

                6,7071730




                6,7071730






























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