let A be non empty closed_interval Subset of REAL; for D1, MD1 being Division of A st MD1 = <*(lower_bound A)*> ^ D1 holds
delta MD1 = delta D1
let D1, MD1 be Division of A; ( MD1 = <*(lower_bound A)*> ^ D1 implies delta MD1 = delta D1 )
assume A1:
MD1 = <*(lower_bound A)*> ^ D1
; delta MD1 = delta D1
then A2:
vol (divset (MD1,1)) = 0
by Lm11;
delta D1 in rng (upper_volume ((chi (A,A)),D1))
by XXREAL_2:def 8;
then consider i being Element of NAT such that
A3:
i in dom (upper_volume ((chi (A,A)),D1))
and
A4:
(upper_volume ((chi (A,A)),D1)) . i = delta D1
by PARTFUN1:3;
delta MD1 in rng (upper_volume ((chi (A,A)),MD1))
by XXREAL_2:def 8;
then consider j being Element of NAT such that
A5:
j in dom (upper_volume ((chi (A,A)),MD1))
and
A6:
(upper_volume ((chi (A,A)),MD1)) . j = delta MD1
by PARTFUN1:3;
j in Seg (len (upper_volume ((chi (A,A)),MD1)))
by A5, FINSEQ_1:def 3;
then A7:
j in Seg (len MD1)
by INTEGRA1:def 6;
then A8:
j in dom MD1
by FINSEQ_1:def 3;
then A9:
delta MD1 = (upper_bound (rng ((chi (A,A)) | (divset (MD1,j))))) * (vol (divset (MD1,j)))
by A6, INTEGRA1:def 6;
A10:
delta MD1 <= delta D1
proof
per cases
( j = 1 or j <> 1 )
;
suppose
j <> 1
;
delta MD1 <= delta D1then
not
j in Seg 1
by FINSEQ_1:2, TARSKI:def 1;
then
not
j in Seg (len <*(lower_bound A)*>)
by FINSEQ_1:39;
then A11:
not
j in dom <*(lower_bound A)*>
by FINSEQ_1:def 3;
j in dom MD1
by A7, FINSEQ_1:def 3;
then consider k being
Nat such that A12:
k in dom D1
and A13:
j = (len <*(lower_bound A)*>) + k
by A1, A11, FINSEQ_1:25;
A14:
k in Seg (len D1)
by A12, FINSEQ_1:def 3;
then divset (
D1,
k) =
divset (
MD1,
(k + 1))
by A1, Lm10
.=
divset (
MD1,
j)
by A13, FINSEQ_1:39
;
then
delta MD1 = (upper_bound (rng ((chi (A,A)) | (divset (D1,k))))) * (vol (divset (D1,k)))
by A6, A8, INTEGRA1:def 6;
then A15:
delta MD1 = (upper_volume ((chi (A,A)),D1)) . k
by A12, INTEGRA1:def 6;
k in Seg (len (upper_volume ((chi (A,A)),D1)))
by A14, INTEGRA1:def 6;
then
k in dom (upper_volume ((chi (A,A)),D1))
by FINSEQ_1:def 3;
then
delta MD1 in rng (upper_volume ((chi (A,A)),D1))
by A15, FUNCT_1:def 3;
hence
delta MD1 <= delta D1
by XXREAL_2:def 8;
verum end;
end;
i in Seg (len (upper_volume ((chi (A,A)),D1)))
by A3, FINSEQ_1:def 3;
then A16:
i in Seg (len D1)
by INTEGRA1:def 6;
then
i in dom D1
by FINSEQ_1:def 3;
then
(len <*(lower_bound A)*>) + i in dom MD1
by A1, FINSEQ_1:28;
then A17:
i + 1 in dom MD1
by FINSEQ_1:39;
then
i + 1 in Seg (len MD1)
by FINSEQ_1:def 3;
then
i + 1 in Seg (len (upper_volume ((chi (A,A)),MD1)))
by INTEGRA1:def 6;
then A18:
i + 1 in dom (upper_volume ((chi (A,A)),MD1))
by FINSEQ_1:def 3;
i in dom D1
by A16, FINSEQ_1:def 3;
then delta D1 =
(upper_bound (rng ((chi (A,A)) | (divset (D1,i))))) * (vol (divset (D1,i)))
by A4, INTEGRA1:def 6
.=
(upper_bound (rng ((chi (A,A)) | (divset (MD1,(i + 1)))))) * (vol (divset (D1,i)))
by A1, A16, Lm10
.=
(upper_bound (rng ((chi (A,A)) | (divset (MD1,(i + 1)))))) * (vol (divset (MD1,(i + 1))))
by A1, A16, Lm10
;
then
delta D1 = (upper_volume ((chi (A,A)),MD1)) . (i + 1)
by A17, INTEGRA1:def 6;
then
delta D1 in rng (upper_volume ((chi (A,A)),MD1))
by A18, FUNCT_1:def 3;
then
delta D1 <= delta MD1
by XXREAL_2:def 8;
hence
delta MD1 = delta D1
by A10, XXREAL_0:1; verum