Home Topics in Analysis Analysis Elementary Linear Algebra Linear Algebra Analysis of Functions of Many Variables Linear Algebra and Analysis Complex Analysis Calculus of One And Many Variables Engineering Math One Variable Advanced Calculus Interrogation of Hiroshi Oshima

280 CHAPTER 10. THE ABSTRACT LEBESGUE INTEGRAL

Lemma 10.1.3 Let g be a decreasing nonnegative function defined on an interval [0,R] .Then ∫ R

0g∧Mdλ = sup

h>0

m(R,h)

∑i=1

(g(ih)∧M)h

where m(h,R) ∈ N satisfies R−h < hm(h,R)≤ R.

Proof: Since g∧M is a decreasing bounded function the lower sums converge to theintegral as h→ 0. Thus

∫ R

0g∧Mdλ = lim

h→0

(m(R,h)

∑i=1

(g(ih)∧M)h+(g(R)∧M)(R−hm(h,R))

)

Now the last term in the above is no more than Mh and so the above is

limh→0

(m(R,h)

∑i=1

(g(ih)∧M)h

)= sup

h>0

(m(R,h)

∑i=1

(g(ih)∧M)h

).■

10.1.2 The Lebesgue Integral for Nonnegative FunctionsHere is the definition of the Lebesgue integral of a function which is measurable and hasvalues in [0,∞].

Definition 10.1.4 Let (Ω,F , µ) be a measure space and suppose f : Ω→ [0,∞]is measurable. Then define

∫f dµ ≡

∫∞

0 µ ([ f > λ ])dλ which makes sense because λ →µ ([ f > λ ]) is nonnegative and decreasing.

Note that if f ≤ g, then∫

f dµ ≤∫

gdµ because µ ([ f > λ ])≤ µ ([g > λ ]) .For convenience ∑

0i=1 ai ≡ 0.

Lemma 10.1.5 In the above definition,∫

f dµ = suph>0 ∑∞i=1 µ ([ f > hi])h

Proof: Let m(h,R) ∈ N satisfy R−h < hm(h,R) ≤ R. Then limR→∞ m(h,R) = ∞ andso from Lemma 10.1.3,∫

f dµ ≡∫

0µ ([ f > λ ])dλ = sup

Msup

R

∫ R

0µ ([ f > λ ])∧Mdλ

= supM

supR>0

suph>0

m(h,R)

∑k=1

(µ ([ f > kh])∧M)h

Hence, switching the order of the sups, this equals

supR>0

suph>0

supM

m(h,R)

∑k=1

(µ ([ f > kh])∧M)h = supR>0

suph>0

limM→∞

m(h,R)

∑k=1

(µ ([ f > kh])∧M)h

= suph>0

supR

m(R,h)

∑k=1

(µ ([ f > kh]))h = suph>0

∑k=1

(µ ([ f > kh]))h. ■

280 CHAPTER 10. THE ABSTRACT LEBESGUE INTEGRALLemma 10.1.3 Let g be a decreasing nonnegative function defined on an interval {0, R} .Thenm(R,h)R| gA\Mdd = sup Y (s (ih) \M)h0 h>0 j=]where m(h,R) EN satisfies R—h < hm(h,R) <R.Proof: Since g A M is a decreasing bounded function the lower sums converge to theintegral as h + 0. ThusR m(R,h)[ gAMdd = lim ( y (g (ih) \M)h+(g(R) AM) (R—hm 0)0 h->0 j=]Now the last term in the above is no more than Mh and so the above ism(R,h) m(R,h)sn ( » (ayaa) wp ( y (008)i=1 h>0 i=110.1.2 The Lebesgue Integral for Nonnegative FunctionsHere is the definition of the Lebesgue integral of a function which is measurable and hasvalues in [0,9].Definition 10.1.4 Le (Q,F, b) be a measure space and suppose f : Q — [0,|is measurable. Then define { fdu = Jy U([f >A])dA which makes sense because 4 +L([f > A]) is nonnegative and decreasing.Note that if f <g, then f fdu < f gdu because pt ([f > A]) < w([g >A)).For convenience Y?_, a; = 0.Lemma 10.1.5 Jn the above definition, [ fd = supj.9 V2, UM (Lf > hil) hProof: Let m(h,R) € N satisfy R—h < hm(h,R) < R. Then limg_,.0m(h,R) = e andso from Lemma 10.1.3,[fan[wre adaa =supsup [u(r > ay aman0 M R /Om(h,R)sup sup sup yy (u (Lf > kh]) AM)hM R>O0h>0 f=]Hence, switching the order of the sups, this equalsm(h,R) m(h,R)sup sup sup yy (u ([f > kh]) AM)h= supsup | lim y (W([f > kh]) AM)hR>Oh>0 M j=] R>0h>0M>~ p=m(R,h) oo= supsup y? (uw (Lf > kh])) h=sup )(H ([f > kh]))h.h>O Re f=] h>0 k=