7.9 *Lebesgue's Criterion for Riemann Integrability 445Remarks 7.9.3 Let a > 0.(a) \:/nonempty A~ V(f), w1(A) 2'. 0.
(b) \:/nonempty A, B ~ V(f), A~ B::::} w1(A)::::; w1(B).
(c) \:/x E [a, b], w1(x) 2'. 0.(d) f is continuous at x 0 if and only if w1(x) = 0.
(e) \:/8 > 0, the set S 0 (!) = {x E V(f): w1(x) 2'. 8} is closed, hence compact.
(f) If S denotes the set of points of [a, b] where f is discontinuous, then
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S = {x E V(f): w1(x) > O} = U So(!)= U S1;n(f).
o>O n=lTheorem 7.9.4 Suppose f is Riemann integrable on [a, b], and let 8 > 0.
Then, Ve > 0, S 0 (!) can be covered by a finite coll ection of open intervals of
total length less than€. [Hence, S 0 (!) has measure O.]
Proof. Suppose f is Riemann integrable on [a, b], and let 8 > 0 b e fixed.
Let c > 0. Since f is integrable on [a, b], there is a partition P = { xo, x 1 , · · · , Xn}
of [a, b] such that
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S(f, P) - S..(f, P) <
2
.
Since P is a finite set, we can easily cover it by a finite collection of open
intervals of total length less than c/2; just use { Nc/sn(xi): i = 1, 2, · · · , n }. So,
the proof will be complete if we can show that S 0 (!) -P can be covered by a
finite collection of open intervals of total length less than c/2.
Let N = {i: (Xi-1,Xi) n So(!) -=I-0}. Then {(xi-1,Xi): i EN} is a finite
collection of open intervals covering S 0 (!) -P with total length L 6i, where
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6i = Xi -Xi-l · The proof will be complete if we can show that L 6i < c /2.
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Now, i EN::::} 3x E (xi-1,Xi) n So(!)
::::} w1(x) 2'. 8::::} Mi(!) - mi(!) 2'. 8where Mi(!) =sup f[xi-1, xi] and mi(!) =inf f[xi-1, xi].
Thus, L [Mi(!) - mi(f)]6i 2'. 8 L 6i. (46)
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On the other h and, L [Mi(!) - mi(f)]6i::::; S(f, P) - S..(f, P) < -
2
. (47)
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