prove if $f$ is bounded in [a,b] and integrable in every [a+$epsilon$ , b] for every $epsilon$ > 0 then...











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I've started with showing that the improper integral in [a,b] is the limit when t goes to a+ (I've said that t=a+ $epsilon$ )
but now to say that the improper integral is defined I need to show that the limit exist and final.










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  • Use upper and lower sums
    – rubikscube09
    Nov 17 at 20:29










  • $f$ is bounded, $m >= f >= M$ so the limit is bounded by $(b-a)M$ and $(b-a)m$ is that enough?
    – Dor
    Nov 17 at 20:33












  • Almost. When you have epsilon really small, the integral over the epsilon region is going to be small too because the function is bounded. Hence if the a b - e integral converges, you add only a small amount of mass (say M*epsilon ) by integrating over the rest of the region.
    – rubikscube09
    Nov 17 at 20:40















up vote
1
down vote

favorite












I've started with showing that the improper integral in [a,b] is the limit when t goes to a+ (I've said that t=a+ $epsilon$ )
but now to say that the improper integral is defined I need to show that the limit exist and final.










share|cite|improve this question
























  • Use upper and lower sums
    – rubikscube09
    Nov 17 at 20:29










  • $f$ is bounded, $m >= f >= M$ so the limit is bounded by $(b-a)M$ and $(b-a)m$ is that enough?
    – Dor
    Nov 17 at 20:33












  • Almost. When you have epsilon really small, the integral over the epsilon region is going to be small too because the function is bounded. Hence if the a b - e integral converges, you add only a small amount of mass (say M*epsilon ) by integrating over the rest of the region.
    – rubikscube09
    Nov 17 at 20:40













up vote
1
down vote

favorite









up vote
1
down vote

favorite











I've started with showing that the improper integral in [a,b] is the limit when t goes to a+ (I've said that t=a+ $epsilon$ )
but now to say that the improper integral is defined I need to show that the limit exist and final.










share|cite|improve this question















I've started with showing that the improper integral in [a,b] is the limit when t goes to a+ (I've said that t=a+ $epsilon$ )
but now to say that the improper integral is defined I need to show that the limit exist and final.







integration improper-integrals






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share|cite|improve this question













share|cite|improve this question




share|cite|improve this question








edited Nov 17 at 20:30

























asked Nov 17 at 20:28









Dor

83




83












  • Use upper and lower sums
    – rubikscube09
    Nov 17 at 20:29










  • $f$ is bounded, $m >= f >= M$ so the limit is bounded by $(b-a)M$ and $(b-a)m$ is that enough?
    – Dor
    Nov 17 at 20:33












  • Almost. When you have epsilon really small, the integral over the epsilon region is going to be small too because the function is bounded. Hence if the a b - e integral converges, you add only a small amount of mass (say M*epsilon ) by integrating over the rest of the region.
    – rubikscube09
    Nov 17 at 20:40


















  • Use upper and lower sums
    – rubikscube09
    Nov 17 at 20:29










  • $f$ is bounded, $m >= f >= M$ so the limit is bounded by $(b-a)M$ and $(b-a)m$ is that enough?
    – Dor
    Nov 17 at 20:33












  • Almost. When you have epsilon really small, the integral over the epsilon region is going to be small too because the function is bounded. Hence if the a b - e integral converges, you add only a small amount of mass (say M*epsilon ) by integrating over the rest of the region.
    – rubikscube09
    Nov 17 at 20:40
















Use upper and lower sums
– rubikscube09
Nov 17 at 20:29




Use upper and lower sums
– rubikscube09
Nov 17 at 20:29












$f$ is bounded, $m >= f >= M$ so the limit is bounded by $(b-a)M$ and $(b-a)m$ is that enough?
– Dor
Nov 17 at 20:33






$f$ is bounded, $m >= f >= M$ so the limit is bounded by $(b-a)M$ and $(b-a)m$ is that enough?
– Dor
Nov 17 at 20:33














Almost. When you have epsilon really small, the integral over the epsilon region is going to be small too because the function is bounded. Hence if the a b - e integral converges, you add only a small amount of mass (say M*epsilon ) by integrating over the rest of the region.
– rubikscube09
Nov 17 at 20:40




Almost. When you have epsilon really small, the integral over the epsilon region is going to be small too because the function is bounded. Hence if the a b - e integral converges, you add only a small amount of mass (say M*epsilon ) by integrating over the rest of the region.
– rubikscube09
Nov 17 at 20:40










1 Answer
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up vote
0
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accepted










Let $M=sup_{[a,b]}| f|$.



We can assume $M>0$.



Given $epsilon>0$ small enough.



$f$ is integrable at $[a+frac{epsilon}{4M},b]$ thus by Cauchy criterion,



there exist a partition $sigma$ of $[a+frac{epsilon}{4M},b]$ such that



$$U(f,sigma)-L(f,sigma)<frac{epsilon}{2}$$



Put $$Sigma=sigma cup{a}$$



then



$$U(f,Sigma)-L(f,Sigma)le$$
$$2Mfrac{epsilon}{4M}+U(f,sigma)-L(f,sigma)$$
$$<epsilon$$



done.






share|cite|improve this answer























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    1 Answer
    1






    active

    oldest

    votes








    1 Answer
    1






    active

    oldest

    votes









    active

    oldest

    votes






    active

    oldest

    votes








    up vote
    0
    down vote



    accepted










    Let $M=sup_{[a,b]}| f|$.



    We can assume $M>0$.



    Given $epsilon>0$ small enough.



    $f$ is integrable at $[a+frac{epsilon}{4M},b]$ thus by Cauchy criterion,



    there exist a partition $sigma$ of $[a+frac{epsilon}{4M},b]$ such that



    $$U(f,sigma)-L(f,sigma)<frac{epsilon}{2}$$



    Put $$Sigma=sigma cup{a}$$



    then



    $$U(f,Sigma)-L(f,Sigma)le$$
    $$2Mfrac{epsilon}{4M}+U(f,sigma)-L(f,sigma)$$
    $$<epsilon$$



    done.






    share|cite|improve this answer



























      up vote
      0
      down vote



      accepted










      Let $M=sup_{[a,b]}| f|$.



      We can assume $M>0$.



      Given $epsilon>0$ small enough.



      $f$ is integrable at $[a+frac{epsilon}{4M},b]$ thus by Cauchy criterion,



      there exist a partition $sigma$ of $[a+frac{epsilon}{4M},b]$ such that



      $$U(f,sigma)-L(f,sigma)<frac{epsilon}{2}$$



      Put $$Sigma=sigma cup{a}$$



      then



      $$U(f,Sigma)-L(f,Sigma)le$$
      $$2Mfrac{epsilon}{4M}+U(f,sigma)-L(f,sigma)$$
      $$<epsilon$$



      done.






      share|cite|improve this answer

























        up vote
        0
        down vote



        accepted







        up vote
        0
        down vote



        accepted






        Let $M=sup_{[a,b]}| f|$.



        We can assume $M>0$.



        Given $epsilon>0$ small enough.



        $f$ is integrable at $[a+frac{epsilon}{4M},b]$ thus by Cauchy criterion,



        there exist a partition $sigma$ of $[a+frac{epsilon}{4M},b]$ such that



        $$U(f,sigma)-L(f,sigma)<frac{epsilon}{2}$$



        Put $$Sigma=sigma cup{a}$$



        then



        $$U(f,Sigma)-L(f,Sigma)le$$
        $$2Mfrac{epsilon}{4M}+U(f,sigma)-L(f,sigma)$$
        $$<epsilon$$



        done.






        share|cite|improve this answer














        Let $M=sup_{[a,b]}| f|$.



        We can assume $M>0$.



        Given $epsilon>0$ small enough.



        $f$ is integrable at $[a+frac{epsilon}{4M},b]$ thus by Cauchy criterion,



        there exist a partition $sigma$ of $[a+frac{epsilon}{4M},b]$ such that



        $$U(f,sigma)-L(f,sigma)<frac{epsilon}{2}$$



        Put $$Sigma=sigma cup{a}$$



        then



        $$U(f,Sigma)-L(f,Sigma)le$$
        $$2Mfrac{epsilon}{4M}+U(f,sigma)-L(f,sigma)$$
        $$<epsilon$$



        done.







        share|cite|improve this answer














        share|cite|improve this answer



        share|cite|improve this answer








        edited Nov 17 at 20:44

























        answered Nov 17 at 20:38









        hamam_Abdallah

        37k21534




        37k21534






























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