let a, b, c be real number ; :: thesis: for f being PartFunc of REAL ,REAL st a <= b & ['a,b'] c= dom f & f is_integrable_on ['a,b'] & f | ['a,b'] is bounded & c in ['a,b'] & b <> c holds
( integral f,a,b = (integral f,a,c) + (integral f,c,b) & f is_integrable_on ['a,c'] & f is_integrable_on ['c,b'] )
let f be PartFunc of REAL ,REAL ; :: thesis: ( a <= b & ['a,b'] c= dom f & f is_integrable_on ['a,b'] & f | ['a,b'] is bounded & c in ['a,b'] & b <> c implies ( integral f,a,b = (integral f,a,c) + (integral f,c,b) & f is_integrable_on ['a,c'] & f is_integrable_on ['c,b'] ) )
assume that
A1: a <= b and
A2: ['a,b'] c= dom f and
A3: f is_integrable_on ['a,b'] and
A4: f | ['a,b'] is bounded and
A5: c in ['a,b'] and
A6: b <> c ; :: thesis: ( integral f,a,b = (integral f,a,c) + (integral f,c,b) & f is_integrable_on ['a,c'] & f is_integrable_on ['c,b'] )
A7: ['a,b'] = [.a,b.] by A1, INTEGRA5:def 4;
then A8: c <= b by A5, XXREAL_1:1;
then A9: ['c,b'] = [.c,b.] by INTEGRA5:def 4;
then A10: [.c,b.] = [.(lower_bound [.c,b.]),(upper_bound [.c,b.]).] by INTEGRA1:5;
then A11: upper_bound ['c,b'] = b by A9, INTEGRA1:6;
set FAB = f || ['a,b'];
set FAC = f || ['a,c'];
set FCB = f || ['c,b'];
A12: f || ['a,b'] is Function of ['a,b'],REAL by A2, Lm1;
A13: a <= c by A5, A7, XXREAL_1:1;
then A14: ['a,c'] = [.a,c.] by INTEGRA5:def 4;
then A15: [.a,c.] = [.(lower_bound [.a,c.]),(upper_bound [.a,c.]).] by INTEGRA1:5;
then A16: lower_bound ['a,c'] = a by A14, INTEGRA1:6;
A17: ['c,b'] c= ['a,b'] by A7, A13, A9, XXREAL_1:34;
then f | ['c,b'] is bounded by A4, RFUNCT_1:91;
then A18: (f || ['c,b']) | ['c,b'] is bounded by INTEGRA5:9;
A19: lower_bound ['c,b'] = c by A9, A10, INTEGRA1:6;
ex PS2 being DivSequence of ['c,b'] st
( delta PS2 is convergent & lim (delta PS2) = 0 & ex K being Element of NAT st
for i being Element of NAT st K <= i holds
ex S2i being Division of ['c,b'] st
( S2i = PS2 . i & 2 <= len S2i ) )
proof
c < b by A6, A8, XXREAL_0:1;
then vol ['c,b'] > 0 by A19, A11, XREAL_1:52;
then consider T being DivSequence of ['c,b'] such that
A20: ( delta T is convergent & lim (delta T) = 0 ) and
A21: for n being Element of NAT ex Tn being Division of ['c,b'] st
( Tn divide_into_equal n + 1 & T . n = Tn ) by Th16;
take T ; :: thesis: ( delta T is convergent & lim (delta T) = 0 & ex K being Element of NAT st
for i being Element of NAT st K <= i holds
ex S2i being Division of ['c,b'] st
( S2i = T . i & 2 <= len S2i ) )
now
let i be Element of NAT ; :: thesis: ( 2 <= i implies ex Tn being Division of ['c,b'] st
( Tn = T . i & 2 <= len Tn ) )
assume A22: 2 <= i ; :: thesis: ex Tn being Division of ['c,b'] st
( Tn = T . i & 2 <= len Tn )
consider Tn being Division of ['c,b'] such that
A23: Tn divide_into_equal i + 1 and
A24: T . i = Tn by A21;
reconsider Tn = Tn as Division of ['c,b'] ;
take Tn = Tn; :: thesis: ( Tn = T . i & 2 <= len Tn )
thus Tn = T . i by A24; :: thesis: 2 <= len Tn
len Tn = i + 1 by A23, INTEGRA4:def 1;
then i <= len Tn by NAT_1:11;
hence 2 <= len Tn by A22, XXREAL_0:2; :: thesis: verum
end;
hence ( delta T is convergent & lim (delta T) = 0 & ex K being Element of NAT st
for i being Element of NAT st K <= i holds
ex S2i being Division of ['c,b'] st
( S2i = T . i & 2 <= len S2i ) ) by A20; :: thesis: verum
end;
then consider PS2 being DivSequence of ['c,b'] such that
A25: ( delta PS2 is convergent & lim (delta PS2) = 0 ) and
A26: ex K being Element of NAT st
for i being Element of NAT st K <= i holds
ex S2i being Division of ['c,b'] st
( S2i = PS2 . i & 2 <= len S2i ) ;
consider K being Element of NAT such that
A27: for i being Element of NAT st K <= i holds
ex S2i being Division of ['c,b'] st
( S2i = PS2 . i & 2 <= len S2i ) by A26;
defpred S1[ set , set ] means ex n being Element of NAT ex e being Division of ['c,b'] st
( n = $1 & e = $2 & e = PS2 . (n + K) );
A28: for n being Element of NAT ex D being Element of divs ['c,b'] st S1[n,D]
proof
let n be Element of NAT ; :: thesis: ex D being Element of divs ['c,b'] st S1[n,D]
reconsider D = PS2 . (n + K) as Element of divs ['c,b'] by INTEGRA1:def 3;
take D ; :: thesis: S1[n,D]
thus S1[n,D] ; :: thesis: verum
end;
consider S2 being Function of NAT ,(divs ['c,b']) such that
A29: for n being Element of NAT holds S1[n,S2 . n] from FUNCT_2:sch 3(A28);
 reconsider S2 = S2 as DivSequence of ['c,b'] ;
defpred S2[ Element of NAT , set ] means ex S being Division of ['c,b'] st
( S = S2 . $1 & $2 = S /^ 1 );
A30: now
let i be Element of NAT ; :: thesis: ex S2i being Division of ['c,b'] st
( S2i = S2 . i & 2 <= len S2i )
ex n being Element of NAT ex e being Division of ['c,b'] st
( n = i & e = S2 . i & e = PS2 . (n + K) ) by A29;
hence ex S2i being Division of ['c,b'] st
( S2i = S2 . i & 2 <= len S2i ) by A27, NAT_1:11; :: thesis: verum
end;
A31: for i being Element of NAT ex T being Element of divs ['c,b'] st S2[i,T]
proof
let i be Element of NAT ; :: thesis: ex T being Element of divs ['c,b'] st S2[i,T]
consider S being Division of ['c,b'] such that
A32: S = S2 . i and
A33: 2 <= len S by A30;
set T = S /^ 1;
A34: 1 <= len S by A33, XXREAL_0:2;
2 - 1 <= (len S) - 1 by A33, XREAL_1:15;
then A35: 1 <= len (S /^ 1) by A34, RFINSEQ:def 2;
then len (S /^ 1) in Seg (len (S /^ 1)) ;
then len (S /^ 1) in dom (S /^ 1) by FINSEQ_1:def 3;
then (S /^ 1) . (len (S /^ 1)) = S . ((len (S /^ 1)) + 1) by A34, RFINSEQ:def 2;
then (S /^ 1) . (len (S /^ 1)) = S . (((len S) - 1) + 1) by A34, RFINSEQ:def 2;
then A36: (S /^ 1) . (len (S /^ 1)) = upper_bound ['c,b'] by INTEGRA1:def 2;
( rng S c= ['c,b'] & rng (S /^ 1) c= rng S ) by FINSEQ_5:36, INTEGRA1:def 2;
then A37: rng (S /^ 1) c= ['c,b'] by XBOOLE_1:1;
( not S /^ 1 is empty & S /^ 1 is increasing ) by A33, A35, INTEGRA1:36, XXREAL_0:2;
then S /^ 1 is Division of ['c,b'] by A37, A36, INTEGRA1:def 2;
then S /^ 1 is Element of divs ['c,b'] by INTEGRA1:def 3;
hence ex T being Element of divs ['c,b'] st S2[i,T] by A32; :: thesis: verum
end;
consider T2 being DivSequence of ['c,b'] such that
A38: for i being Element of NAT holds S2[i,T2 . i] from FUNCT_2:sch 3(A31);
 A39: for n being Element of NAT ex D being Division of ['c,b'] st
( D = T2 . n & ( for i being Element of NAT st i in dom D holds
c < D . i ) )
proof
let n be Element of NAT ; :: thesis: ex D being Division of ['c,b'] st
( D = T2 . n & ( for i being Element of NAT st i in dom D holds
c < D . i ) )
reconsider D = T2 . n as Division of ['c,b'] ;
take D ; :: thesis: ( D = T2 . n & ( for i being Element of NAT st i in dom D holds
c < D . i ) )
consider E being Division of ['c,b'] such that
A40: E = S2 . n and
A41: T2 . n = E /^ 1 by A38;
A42: ex E1 being Division of ['c,b'] st
( E1 = S2 . n & 2 <= len E1 ) by A30;
then A43: 2 - 1 <= (len E) - 1 by A40, XREAL_1:15;
A44: 1 <= len E by A40, A42, XXREAL_0:2;
then 1 in Seg (len E) ;
then A45: 1 in dom E by FINSEQ_1:def 3;
then ( rng E c= ['c,b'] & E . 1 in rng E ) by FUNCT_1:def 5, INTEGRA1:def 2;
then A46: c <= E . 1 by A9, XXREAL_1:1;
2 in Seg (len E) by A40, A42;
then 2 in dom E by FINSEQ_1:def 3;
then A47: E . 1 < E . 2 by A45, SEQM_3:def 1;
len D = (len E) - 1 by A41, A44, RFINSEQ:def 2;
then 1 in Seg (len D) by A43;
then A48: 1 in dom D by FINSEQ_1:def 3;
then A49: D . 1 = E . (1 + 1) by A41, A44, RFINSEQ:def 2;
then A50: c < D . 1 by A46, A47, XXREAL_0:2;
now
let i be Element of NAT ; :: thesis: ( i in dom D implies ( ( i <> 1 implies c < D . i ) & c < D . i ) )
assume A51: i in dom D ; :: thesis: ( ( i <> 1 implies c < D . i ) & c < D . i )
then A52: 1 <= i by FINSEQ_3:27;
hereby :: thesis: c < D . i
assume i <> 1 ; :: thesis: c < D . i
then 1 < i by A52, XXREAL_0:1;
then D . 1 < D . i by A48, A51, SEQM_3:def 1;
hence c < D . i by A50, XXREAL_0:2; :: thesis: verum
end;
hence c < D . i by A49, A46, A47, XXREAL_0:2; :: thesis: verum
end;
hence ( D = T2 . n & ( for i being Element of NAT st i in dom D holds
c < D . i ) ) ; :: thesis: verum
end;
set XAC = chi ['a,c'],['a,c'];
set XCB = chi ['c,b'],['c,b'];
consider T1 being DivSequence of ['a,c'] such that
A53: ( delta T1 is convergent & lim (delta T1) = 0 ) by INTEGRA4:11;
A54: for n being Element of NAT ex D being Division of ['c,b'] st
( D = T2 . n & 1 <= len D )
proof
let n be Element of NAT ; :: thesis: ex D being Division of ['c,b'] st
( D = T2 . n & 1 <= len D )
reconsider D = T2 . n as Division of ['c,b'] ;
take D ; :: thesis: ( D = T2 . n & 1 <= len D )
consider E being Division of ['c,b'] such that
A55: E = S2 . n and
A56: T2 . n = E /^ 1 by A38;
ex E1 being Division of ['c,b'] st
( E1 = S2 . n & 2 <= len E1 ) by A30;
then ( 1 <= len E & 2 - 1 <= (len E) - 1 ) by A55, XREAL_1:15, XXREAL_0:2;
hence ( D = T2 . n & 1 <= len D ) by A56, RFINSEQ:def 2; :: thesis: verum
end;
A57: integral f,c,b = integral f,['c,b'] by A8, INTEGRA5:def 5
.= integral (f || ['c,b']) ;
A58: integral f,a,c = integral f,['a,c'] by A13, INTEGRA5:def 5;
defpred S3[ Element of NAT , set ] means ex S1 being Division of ['a,c'] ex S2 being Division of ['c,b'] st
( S1 = T1 . $1 & S2 = T2 . $1 & $2 = S1 ^ S2 );
A59: [.a,b.] = [.(lower_bound [.a,b.]),(upper_bound [.a,b.]).] by A7, INTEGRA1:5;
then A60: upper_bound ['a,b'] = b by A7, INTEGRA1:6;
A61: for i being Element of NAT ex T being Element of divs ['a,b'] st S3[i,T]
proof
let i0 be Element of NAT ; :: thesis: ex T being Element of divs ['a,b'] st S3[i0,T]
reconsider S1 = T1 . i0 as Division of ['a,c'] ;
reconsider S2 = T2 . i0 as Division of ['c,b'] ;
set T = S1 ^ S2;
ex D being Division of ['c,b'] st
( D = T2 . i0 & 1 <= len D ) by A54;
then len S2 in Seg (len S2) ;
then A62: len S2 in dom S2 by FINSEQ_1:def 3;
A63: rng S1 c= ['a,c'] by INTEGRA1:def 2;
now
let i, j be Element of NAT ; :: thesis: ( i in dom (S1 ^ S2) & j in dom (S1 ^ S2) & i < j implies (S1 ^ S2) . i < (S1 ^ S2) . j )
assume that
A64: i in dom (S1 ^ S2) and
A65: j in dom (S1 ^ S2) and
A66: i < j ; :: thesis: (S1 ^ S2) . i < (S1 ^ S2) . j
A67: 1 <= i by A64, FINSEQ_3:27;
A68: j <= len (S1 ^ S2) by A65, FINSEQ_3:27;
A69: i <= len (S1 ^ S2) by A64, FINSEQ_3:27;
A70: now
j <= (len S1) + (len S2) by A68, FINSEQ_1:35;
then A71: j - (len S1) <= len S2 by XREAL_1:22;
assume A72: j > len S1 ; :: thesis: (S1 ^ S2) . i < (S1 ^ S2) . j
then A73: (S1 ^ S2) . j = S2 . (j - (len S1)) by A68, FINSEQ_1:37;
A74: (len S1) + 1 <= j by A72, NAT_1:13;
then consider m being Nat such that
A75: ((len S1) + 1) + m = j by NAT_1:10;
reconsider m = m as Element of NAT by ORDINAL1:def 13;
1 + m = j - (len S1) by A75;
then 1 <= 1 + m by A74, XREAL_1:21;
then 1 + m in Seg (len S2) by A75, A71;
then A76: j - (len S1) in dom S2 by A75, FINSEQ_1:def 3;
A77: now
i <= (len S1) + (len S2) by A69, FINSEQ_1:35;
then A78: i - (len S1) <= len S2 by XREAL_1:22;
A79: i - (len S1) < j - (len S1) by A66, XREAL_1:16;
assume A80: i > len S1 ; :: thesis: (S1 ^ S2) . i < (S1 ^ S2) . j
then A81: (len S1) + 1 <= i by NAT_1:13;
then consider m being Nat such that
A82: ((len S1) + 1) + m = i by NAT_1:10;
reconsider m = m as Element of NAT by ORDINAL1:def 13;
1 + m = i - (len S1) by A82;
then 1 <= 1 + m by A81, XREAL_1:21;
then 1 + m in Seg (len S2) by A82, A78;
then A83: i - (len S1) in dom S2 by A82, FINSEQ_1:def 3;
(S1 ^ S2) . i = S2 . (i - (len S1)) by A69, A80, FINSEQ_1:37;
hence (S1 ^ S2) . i < (S1 ^ S2) . j by A73, A76, A79, A83, SEQM_3:def 1; :: thesis: verum
end;
now
assume i <= len S1 ; :: thesis: (S1 ^ S2) . i < (S1 ^ S2) . j
then A84: i in dom S1 by A67, FINSEQ_3:27;
then (S1 ^ S2) . i = S1 . i by FINSEQ_1:def 7;
then (S1 ^ S2) . i in rng S1 by A84, FUNCT_1:def 5;
then A85: (S1 ^ S2) . i <= c by A14, A63, XXREAL_1:1;
ex DD being Division of ['c,b'] st
( DD = T2 . i0 & ( for k being Element of NAT st k in dom DD holds
c < DD . k ) ) by A39;
hence (S1 ^ S2) . i < (S1 ^ S2) . j by A73, A76, A85, XXREAL_0:2; :: thesis: verum
end;
hence (S1 ^ S2) . i < (S1 ^ S2) . j by A77; :: thesis: verum
end;
A86: 1 <= j by A65, FINSEQ_3:27;
now
assume A87: j <= len S1 ; :: thesis: (S1 ^ S2) . i < (S1 ^ S2) . j
then A88: j in dom S1 by A86, FINSEQ_3:27;
then A89: (S1 ^ S2) . j = S1 . j by FINSEQ_1:def 7;
i <= len S1 by A66, A87, XXREAL_0:2;
then A90: i in dom S1 by A67, FINSEQ_3:27;
then (S1 ^ S2) . i = S1 . i by FINSEQ_1:def 7;
hence (S1 ^ S2) . i < (S1 ^ S2) . j by A66, A90, A88, A89, SEQM_3:def 1; :: thesis: verum
end;
hence (S1 ^ S2) . i < (S1 ^ S2) . j by A70; :: thesis: verum
end;
then A91: S1 ^ S2 is non empty increasing FinSequence of REAL by SEQM_3:def 1;
rng S2 c= ['c,b'] by INTEGRA1:def 2;
then (rng S1) \/ (rng S2) c= ['a,c'] \/ ['c,b'] by A63, XBOOLE_1:13;
then (rng S1) \/ (rng S2) c= [.a,b.] by A13, A8, A14, A9, XXREAL_1:174;
then A92: rng (S1 ^ S2) c= ['a,b'] by A7, FINSEQ_1:44;
(S1 ^ S2) . (len (S1 ^ S2)) = (S1 ^ S2) . ((len S1) + (len S2)) by FINSEQ_1:35
.= S2 . (len S2) by A62, FINSEQ_1:def 7
.= upper_bound ['a,b'] by A60, A11, INTEGRA1:def 2 ;
then S1 ^ S2 is Division of ['a,b'] by A92, A91, INTEGRA1:def 2;
then S1 ^ S2 is Element of divs ['a,b'] by INTEGRA1:def 3;
hence ex T being Element of divs ['a,b'] st S3[i0,T] ; :: thesis: verum
end;
consider T being DivSequence of ['a,b'] such that
A93: for i being Element of NAT holds S3[i,T . i] from FUNCT_2:sch 3(A61);
 A94: lower_bound ['a,b'] = a by A7, A59, INTEGRA1:6;
A95: for i, k being Element of NAT
for S0 being Division of ['a,c'] st S0 = T1 . i & k in Seg (len S0) holds
divset (T . i),k = divset (T1 . i),k
proof
let i, k be Element of NAT ; :: thesis: for S0 being Division of ['a,c'] st S0 = T1 . i & k in Seg (len S0) holds
divset (T . i),k = divset (T1 . i),k
let S0 be Division of ['a,c']; :: thesis: ( S0 = T1 . i & k in Seg (len S0) implies divset (T . i),k = divset (T1 . i),k )
assume A96: S0 = T1 . i ; :: thesis: ( not k in Seg (len S0) or divset (T . i),k = divset (T1 . i),k )
reconsider S = T . i as Division of ['a,b'] ;
A97: divset (T1 . i),k = [.(lower_bound (divset (T1 . i),k)),(upper_bound (divset (T1 . i),k)).] by INTEGRA1:5;
consider S1 being Division of ['a,c'], S2 being Division of ['c,b'] such that
A98: S1 = T1 . i and
S2 = T2 . i and
A99: T . i = S1 ^ S2 by A93;
assume A100: k in Seg (len S0) ; :: thesis: divset (T . i),k = divset (T1 . i),k
then A101: k in dom S1 by A96, A98, FINSEQ_1:def 3;
len S = (len S1) + (len S2) by A99, FINSEQ_1:35;
then len S1 <= len S by NAT_1:11;
then Seg (len S1) c= Seg (len S) by FINSEQ_1:7;
then k in Seg (len S) by A96, A100, A98;
then A102: k in dom S by FINSEQ_1:def 3;
A103: divset (T . i),k = [.(lower_bound (divset (T . i),k)),(upper_bound (divset (T . i),k)).] by INTEGRA1:5;
A104: now
( k <= len S1 & k - 1 <= k - 0 ) by A96, A100, A98, FINSEQ_1:3, XREAL_1:12;
then A105: k - 1 <= len S1 by XXREAL_0:2;
assume A106: k <> 1 ; :: thesis: divset (T . i),k = divset (T1 . i),k
1 <= k by A100, FINSEQ_1:3;
then A107: 1 < k by A106, XXREAL_0:1;
then 1 + 1 <= k by NAT_1:13;
then A108: 2 - 1 <= k - 1 by XREAL_1:11;
k - 1 is Element of NAT by A107, NAT_1:20;
then k - 1 in Seg (len S1) by A105, A108;
then A109: k - 1 in dom S1 by FINSEQ_1:def 3;
thus divset (T . i),k = [.(S . (k - 1)),(upper_bound (divset (T . i),k)).] by A102, A103, A106, INTEGRA1:def 5
.= [.(S . (k - 1)),(S . k).] by A102, A106, INTEGRA1:def 5
.= [.(S . (k - 1)),(S1 . k).] by A99, A101, FINSEQ_1:def 7
.= [.(S1 . (k - 1)),(S1 . k).] by A99, A109, FINSEQ_1:def 7
.= [.(lower_bound (divset (T1 . i),k)),(S1 . k).] by A98, A101, A106, INTEGRA1:def 5
.= divset (T1 . i),k by A98, A101, A97, A106, INTEGRA1:def 5 ; :: thesis: verum
end;
now
assume A110: k = 1 ; :: thesis: divset (T . i),k = divset (T1 . i),k
hence divset (T . i),k = [.(lower_bound ['a,b']),(upper_bound (divset (T . i),k)).] by A102, A103, INTEGRA1:def 5
.= [.(lower_bound ['a,b']),(S . k).] by A102, A110, INTEGRA1:def 5
.= [.(lower_bound ['a,b']),(S1 . k).] by A99, A101, FINSEQ_1:def 7
.= [.(lower_bound (divset (T1 . i),k)),(S1 . 1).] by A94, A16, A98, A101, A110, INTEGRA1:def 5
.= divset (T1 . i),k by A98, A101, A97, A110, INTEGRA1:def 5 ;
:: thesis: verum
end;
hence divset (T . i),k = divset (T1 . i),k by A104; :: thesis: verum
end;
A111: upper_bound ['a,c'] = c by A14, A15, INTEGRA1:6;
A112: for i, k being Element of NAT
for S01 being Division of ['a,c']
for S02 being Division of ['c,b'] st S01 = T1 . i & S02 = T2 . i & k in Seg (len S02) holds
divset (T . i),((len S01) + k) = divset (T2 . i),k
proof
let i, k be Element of NAT ; :: thesis: for S01 being Division of ['a,c']
for S02 being Division of ['c,b'] st S01 = T1 . i & S02 = T2 . i & k in Seg (len S02) holds
divset (T . i),((len S01) + k) = divset (T2 . i),k
let S01 be Division of ['a,c']; :: thesis: for S02 being Division of ['c,b'] st S01 = T1 . i & S02 = T2 . i & k in Seg (len S02) holds
divset (T . i),((len S01) + k) = divset (T2 . i),k
let S02 be Division of ['c,b']; :: thesis: ( S01 = T1 . i & S02 = T2 . i & k in Seg (len S02) implies divset (T . i),((len S01) + k) = divset (T2 . i),k )
assume that
A113: S01 = T1 . i and
A114: S02 = T2 . i ; :: thesis: ( not k in Seg (len S02) or divset (T . i),((len S01) + k) = divset (T2 . i),k )
reconsider S = T . i as Division of ['a,b'] ;
consider S1 being Division of ['a,c'], S2 being Division of ['c,b'] such that
A115: S1 = T1 . i and
A116: S2 = T2 . i and
A117: T . i = S1 ^ S2 by A93;
assume A118: k in Seg (len S02) ; :: thesis: divset (T . i),((len S01) + k) = divset (T2 . i),k
then A119: k in dom S2 by A114, A116, FINSEQ_1:def 3;
then A120: (len S1) + k in dom S by A117, FINSEQ_1:41;
A121: divset (T2 . i),k = [.(lower_bound (divset (T2 . i),k)),(upper_bound (divset (T2 . i),k)).] by INTEGRA1:5;
A122: divset (T . i),((len S1) + k) = [.(lower_bound (divset (T . i),((len S1) + k))),(upper_bound (divset (T . i),((len S1) + k))).] by INTEGRA1:5;
A123: now
( k <= len S2 & k - 1 <= k - 0 ) by A114, A118, A116, FINSEQ_1:3, XREAL_1:12;
then A124: k - 1 <= len S2 by XXREAL_0:2;
assume A125: k <> 1 ; :: thesis: divset (T . i),((len S1) + k) = divset (T2 . i),k
A126: 1 <= k by A118, FINSEQ_1:3;
then A127: 1 < k by A125, XXREAL_0:1;
then 1 + 1 <= k by NAT_1:13;
then A128: 2 - 1 <= k - 1 by XREAL_1:11;
k - 1 is Element of NAT by A127, NAT_1:20;
then k - 1 in Seg (len S2) by A124, A128;
then A129: k - 1 in dom S2 by FINSEQ_1:def 3;
A130: 1 + 0 < k + (len S1) by A126, XREAL_1:10;
hence divset (T . i),((len S1) + k) = [.(S . (((len S1) + k) - 1)),(upper_bound (divset (T . i),((len S1) + k))).] by A120, A122, INTEGRA1:def 5
.= [.(S . (((len S1) + k) - 1)),(S . ((len S1) + k)).] by A120, A130, INTEGRA1:def 5
.= [.(S . ((len S1) + (k - 1))),(S2 . k).] by A117, A119, FINSEQ_1:def 7
.= [.(S2 . (k - 1)),(S2 . k).] by A117, A129, FINSEQ_1:def 7
.= [.(lower_bound (divset (T2 . i),k)),(S2 . k).] by A116, A119, A125, INTEGRA1:def 5
.= divset (T2 . i),k by A116, A119, A121, A125, INTEGRA1:def 5 ;
:: thesis: verum
end;
now
len S1 in Seg (len S1) by FINSEQ_1:5;
then A131: len S1 in dom S1 by FINSEQ_1:def 3;
assume A132: k = 1 ; :: thesis: divset (T . i),((len S1) + k) = divset (T2 . i),k
len S1 <> 0 ;
then A133: (len S1) + k <> 1 by A132;
hence divset (T . i),((len S1) + k) = [.(S . (((len S1) + k) - 1)),(upper_bound (divset (T . i),((len S1) + k))).] by A120, A122, INTEGRA1:def 5
.= [.(S1 . (len S1)),(upper_bound (divset (T . i),((len S1) + k))).] by A117, A132, A131, FINSEQ_1:def 7
.= [.(upper_bound ['a,c']),(upper_bound (divset (T . i),((len S1) + k))).] by INTEGRA1:def 2
.= [.(lower_bound ['c,b']),(S . ((len S1) + k)).] by A19, A111, A120, A133, INTEGRA1:def 5
.= [.(lower_bound ['c,b']),(S2 . k).] by A117, A119, FINSEQ_1:def 7
.= [.(lower_bound (divset (T2 . i),k)),(S2 . 1).] by A116, A119, A132, INTEGRA1:def 5
.= divset (T2 . i),k by A116, A119, A121, A132, INTEGRA1:def 5 ;
:: thesis: verum
end;
hence divset (T . i),((len S01) + k) = divset (T2 . i),k by A113, A115, A123; :: thesis: verum
end;
set XAB = chi ['a,b'],['a,b'];
A134: for i, k being Element of NAT
for S0 being Division of ['c,b'] st S0 = T2 . i & k in Seg (len S0) holds
divset (T2 . i),k c= ['c,b']
proof
let i, k be Element of NAT ; :: thesis: for S0 being Division of ['c,b'] st S0 = T2 . i & k in Seg (len S0) holds
divset (T2 . i),k c= ['c,b']
let S0 be Division of ['c,b']; :: thesis: ( S0 = T2 . i & k in Seg (len S0) implies divset (T2 . i),k c= ['c,b'] )
assume that
A135: S0 = T2 . i and
A136: k in Seg (len S0) ; :: thesis: divset (T2 . i),k c= ['c,b']
k in dom S0 by A136, FINSEQ_1:def 3;
hence divset (T2 . i),k c= ['c,b'] by A135, INTEGRA1:10; :: thesis: verum
end;
A137: ['a,c'] c= ['a,b'] by A7, A8, A14, XXREAL_1:34;
then f | ['a,c'] is bounded by A4, RFUNCT_1:91;
then A138: (f || ['a,c']) | ['a,c'] is bounded by INTEGRA5:9;
A139: for i, k being Element of NAT
for S0 being Division of ['a,c'] st S0 = T1 . i & k in Seg (len S0) holds
divset (T1 . i),k c= ['a,c']
proof
let i, k be Element of NAT ; :: thesis: for S0 being Division of ['a,c'] st S0 = T1 . i & k in Seg (len S0) holds
divset (T1 . i),k c= ['a,c']
let S0 be Division of ['a,c']; :: thesis: ( S0 = T1 . i & k in Seg (len S0) implies divset (T1 . i),k c= ['a,c'] )
assume that
A140: S0 = T1 . i and
A141: k in Seg (len S0) ; :: thesis: divset (T1 . i),k c= ['a,c']
k in dom S0 by A141, FINSEQ_1:def 3;
hence divset (T1 . i),k c= ['a,c'] by A140, INTEGRA1:10; :: thesis: verum
end;
A142: for i being Element of NAT holds upper_volume (f || ['a,b']),(T . i) = (upper_volume (f || ['a,c']),(T1 . i)) ^ (upper_volume (f || ['c,b']),(T2 . i))
proof
let i be Element of NAT ; :: thesis: upper_volume (f || ['a,b']),(T . i) = (upper_volume (f || ['a,c']),(T1 . i)) ^ (upper_volume (f || ['c,b']),(T2 . i))
reconsider F = upper_volume (f || ['a,b']),(T . i) as FinSequence of REAL ;
reconsider F1 = upper_volume (f || ['a,c']),(T1 . i) as FinSequence of REAL ;
reconsider F2 = upper_volume (f || ['c,b']),(T2 . i) as FinSequence of REAL ;
reconsider S = T . i as Division of ['a,b'] ;
consider S1 being Division of ['a,c'], S2 being Division of ['c,b'] such that
A143: S1 = T1 . i and
A144: S2 = T2 . i and
A145: T . i = S1 ^ S2 by A93;
A146: len F = len S by INTEGRA1:def 7
.= (len S1) + (len S2) by A145, FINSEQ_1:35
.= (len F1) + (len S2) by A143, INTEGRA1:def 7
.= (len F1) + (len F2) by A144, INTEGRA1:def 7 ;
A147: now
let k be Nat; :: thesis: ( k in dom F2 implies F . ((len F1) + k) = F2 . k )
assume A148: k in dom F2 ; :: thesis: F . ((len F1) + k) = F2 . k
then A149: k in Seg (len F2) by FINSEQ_1:def 3;
then 1 <= k by FINSEQ_1:3;
then A150: 1 + (len F1) <= k + (len F1) by XREAL_1:8;
k <= len F2 by A149, FINSEQ_1:3;
then A151: (len F1) + k <= len F by A146, XREAL_1:8;
1 <= 1 + (len F1) by NAT_1:11;
then 1 <= k + (len F1) by A150, XXREAL_0:2;
then k + (len F1) in Seg (len F) by A151;
then (len F1) + k in Seg (len S) by INTEGRA1:def 7;
then (len F1) + k in dom S by FINSEQ_1:def 3;
then A152: F . ((len F1) + k) = (upper_bound (rng ((f || ['a,b']) | (divset (T . i),((len F1) + k))))) * (vol (divset (T . i),((len F1) + k))) by INTEGRA1:def 7;
k in Seg (len F2) by A148, FINSEQ_1:def 3;
then A153: k in Seg (len S2) by A144, INTEGRA1:def 7;
then A154: k in dom S2 by FINSEQ_1:def 3;
len F1 = len S1 by A143, INTEGRA1:def 7;
then A155: divset (T . i),((len F1) + k) = divset (T2 . i),k by A112, A143, A144, A153;
then A156: divset (T . i),((len F1) + k) c= ['c,b'] by A134, A144, A153;
then divset (T . i),((len F1) + k) c= ['a,b'] by A17, XBOOLE_1:1;
then F . ((len F1) + k) = (upper_bound (rng ((f || ['c,b']) | (divset (T2 . i),k)))) * (vol (divset (T2 . i),k)) by A152, A155, A156, Th3;
hence F . ((len F1) + k) = F2 . k by A144, A154, INTEGRA1:def 7; :: thesis: verum
end;
A157: now
let k be Nat; :: thesis: ( k in dom F1 implies F . k = F1 . k )
assume k in dom F1 ; :: thesis: F . k = F1 . k
then A158: k in Seg (len F1) by FINSEQ_1:def 3;
then A159: k in Seg (len S1) by A143, INTEGRA1:def 7;
then A160: k in dom S1 by FINSEQ_1:def 3;
len F1 <= len F by A146, NAT_1:11;
then Seg (len F1) c= Seg (len F) by FINSEQ_1:7;
then k in Seg (len F) by A158;
then k in Seg (len S) by INTEGRA1:def 7;
then k in dom S by FINSEQ_1:def 3;
then A161: F . k = (upper_bound (rng ((f || ['a,b']) | (divset (T . i),k)))) * (vol (divset (T . i),k)) by INTEGRA1:def 7;
A162: divset (T . i),k = divset (T1 . i),k by A95, A143, A159;
then A163: divset (T . i),k c= ['a,c'] by A139, A143, A159;
then divset (T . i),k c= ['a,b'] by A137, XBOOLE_1:1;
then F . k = (upper_bound (rng ((f || ['a,c']) | (divset (T1 . i),k)))) * (vol (divset (T1 . i),k)) by A161, A162, A163, Th3;
hence F . k = F1 . k by A143, A160, INTEGRA1:def 7; :: thesis: verum
end;
dom F = Seg ((len F1) + (len F2)) by A146, FINSEQ_1:def 3;
hence upper_volume (f || ['a,b']),(T . i) = (upper_volume (f || ['a,c']),(T1 . i)) ^ (upper_volume (f || ['c,b']),(T2 . i)) by A157, A147, FINSEQ_1:def 7; :: thesis: verum
end;
A164: for i being Element of NAT holds Sum (upper_volume (f || ['a,b']),(T . i)) = (Sum (upper_volume (f || ['a,c']),(T1 . i))) + (Sum (upper_volume (f || ['c,b']),(T2 . i)))
proof
let i be Element of NAT ; :: thesis: Sum (upper_volume (f || ['a,b']),(T . i)) = (Sum (upper_volume (f || ['a,c']),(T1 . i))) + (Sum (upper_volume (f || ['c,b']),(T2 . i)))
upper_volume (f || ['a,b']),(T . i) = (upper_volume (f || ['a,c']),(T1 . i)) ^ (upper_volume (f || ['c,b']),(T2 . i)) by A142;
hence Sum (upper_volume (f || ['a,b']),(T . i)) = (Sum (upper_volume (f || ['a,c']),(T1 . i))) + (Sum (upper_volume (f || ['c,b']),(T2 . i))) by RVSUM_1:105; :: thesis: verum
end;
now
let i be Element of NAT ; :: thesis: (upper_sum (f || ['a,b']),T) . i = ((upper_sum (f || ['a,c']),T1) . i) + ((upper_sum (f || ['c,b']),T2) . i)
thus (upper_sum (f || ['a,b']),T) . i = upper_sum (f || ['a,b']),(T . i) by INTEGRA2:def 4
.= (upper_sum (f || ['a,c']),(T1 . i)) + (Sum (upper_volume (f || ['c,b']),(T2 . i))) by A164
.= ((upper_sum (f || ['a,c']),T1) . i) + (upper_sum (f || ['c,b']),(T2 . i)) by INTEGRA2:def 4
.= ((upper_sum (f || ['a,c']),T1) . i) + ((upper_sum (f || ['c,b']),T2) . i) by INTEGRA2:def 4 ; :: thesis: verum
end;
then A165: upper_sum (f || ['a,b']),T = (upper_sum (f || ['a,c']),T1) + (upper_sum (f || ['c,b']),T2) by SEQ_1:11;
A166: f || ['c,b'] is Function of ['c,b'],REAL by A2, A17, Lm1, XBOOLE_1:1;
then A167: lower_integral (f || ['c,b']) <= upper_integral (f || ['c,b']) by A18, INTEGRA1:51;
A168: now
let e be real number ; :: thesis: ( 0 < e implies ex m being Element of NAT st
for n being Element of NAT st m <= n holds
abs (((delta S2) . n) - 0 ) < e )
assume 0 < e ; :: thesis: ex m being Element of NAT st
for n being Element of NAT st m <= n holds
abs (((delta S2) . n) - 0 ) < e
then consider m being Element of NAT such that
A169: for n being Element of NAT st m <= n holds
abs (((delta PS2) . n) - 0 ) < e by A25, SEQ_2:def 7;
take m = m; :: thesis: for n being Element of NAT st m <= n holds
abs (((delta S2) . n) - 0 ) < e
hereby :: thesis: verum
let n be Element of NAT ; :: thesis: ( m <= n implies abs (((delta S2) . n) - 0 ) < e )
A170: n <= n + K by NAT_1:11;
assume m <= n ; :: thesis: abs (((delta S2) . n) - 0 ) < e
then m <= n + K by A170, XXREAL_0:2;
then abs (((delta PS2) . (n + K)) - 0 ) < e by A169;
then A171: abs ((delta (PS2 . (n + K))) - 0 ) < e by INTEGRA3:def 2;
ex k being Element of NAT ex e1 being Division of ['c,b'] st
( k = n & e1 = S2 . n & e1 = PS2 . (k + K) ) by A29;
hence abs (((delta S2) . n) - 0 ) < e by A171, INTEGRA3:def 2; :: thesis: verum
end;
end;
A172: now
let e be real number ; :: thesis: ( e > 0 implies ex m being Element of NAT st
for n being Element of NAT st m <= n holds
abs (((delta T2) . n) - 0 ) < e )
assume A173: e > 0 ; :: thesis: ex m being Element of NAT st
for n being Element of NAT st m <= n holds
abs (((delta T2) . n) - 0 ) < e
then consider m being Element of NAT such that
A174: for n being Element of NAT st m <= n holds
abs (((delta S2) . n) - 0 ) < e / 2 by A168, XREAL_1:217;
take m = m; :: thesis: for n being Element of NAT st m <= n holds
abs (((delta T2) . n) - 0 ) < e
A175: e / 2 < e by A173, XREAL_1:218;
now
let n be Element of NAT ; :: thesis: ( m <= n implies abs (((delta T2) . n) - 0 ) < e )
assume m <= n ; :: thesis: abs (((delta T2) . n) - 0 ) < e
then abs (((delta S2) . n) - 0 ) < e / 2 by A174;
then ( 0 <= delta (S2 . n) & abs (delta (S2 . n)) < e / 2 ) by INTEGRA3:def 2, INTEGRA3:9;
then A176: max (rng (upper_volume (chi ['c,b'],['c,b']),(S2 . n))) < e / 2 by ABSVALUE:def 1;
A177: for y being real number st y in rng (upper_volume (chi ['c,b'],['c,b']),(T2 . n)) holds
y < e
proof
reconsider D = T2 . n as Division of ['c,b'] ;
let y be real number ; :: thesis: ( y in rng (upper_volume (chi ['c,b'],['c,b']),(T2 . n)) implies y < e )
assume y in rng (upper_volume (chi ['c,b'],['c,b']),(T2 . n)) ; :: thesis: y < e
then consider x being set such that
A178: x in dom (upper_volume (chi ['c,b'],['c,b']),(T2 . n)) and
A179: y = (upper_volume (chi ['c,b'],['c,b']),(T2 . n)) . x by FUNCT_1:def 5;
reconsider i = x as Element of NAT by A178;
A180: x in Seg (len (upper_volume (chi ['c,b'],['c,b']),(T2 . n))) by A178, FINSEQ_1:def 3;
consider E1 being Division of ['c,b'] such that
A181: E1 = S2 . n and
A182: 2 <= len E1 by A30;
set i1 = i + 1;
consider E being Division of ['c,b'] such that
A183: E = S2 . n and
A184: T2 . n = E /^ 1 by A38;
A185: 1 <= len E1 by A182, XXREAL_0:2;
then A186: len D = (len E) - 1 by A183, A184, A181, RFINSEQ:def 2;
A187: len (upper_volume (chi ['c,b'],['c,b']),(T2 . n)) = len D by INTEGRA1:def 7;
then A188: dom (upper_volume (chi ['c,b'],['c,b']),(T2 . n)) = dom D by FINSEQ_3:31;
A189: now
len (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) = len E by A183, INTEGRA1:def 7;
then 2 in Seg (len (upper_volume (chi ['c,b'],['c,b']),(S2 . n))) by A183, A181, A182;
then 2 in dom (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) by FINSEQ_1:def 3;
then (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) . 2 in rng (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) by FUNCT_1:def 5;
then (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) . 2 <= max (rng (upper_volume (chi ['c,b'],['c,b']),(S2 . n))) by XXREAL_2:def 8;
then A190: (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) . 2 < e / 2 by A176, XXREAL_0:2;
assume A191: i = 1 ; :: thesis: y < e
then A192: 1 in dom D by A180, A187, FINSEQ_1:def 3;
len (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) = (len D) + 1 by A183, A186, INTEGRA1:def 7;
then len (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) = (len (upper_volume (chi ['c,b'],['c,b']),(T2 . n))) + 1 by INTEGRA1:def 7;
then 1 in Seg (len (upper_volume (chi ['c,b'],['c,b']),(S2 . n))) by A180, A191, FINSEQ_2:9;
then 1 in dom (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) by FINSEQ_1:def 3;
then (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) . 1 in rng (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) by FUNCT_1:def 5;
then (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) . 1 <= max (rng (upper_volume (chi ['c,b'],['c,b']),(S2 . n))) by XXREAL_2:def 8;
then A193: (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) . 1 < e / 2 by A176, XXREAL_0:2;
A194: 2 in dom E by A183, A181, A182, FINSEQ_3:27;
1 in Seg (len E) by A183, A181, A185;
then A195: 1 in dom E by FINSEQ_1:def 3;
divset (S2 . n),1 = [.(lower_bound (divset (S2 . n),1)),(upper_bound (divset (S2 . n),1)).] by INTEGRA1:5;
then A196: divset (S2 . n),1 = [.(lower_bound ['c,b']),(upper_bound (divset (S2 . n),1)).] by A183, A195, INTEGRA1:def 5;
then A197: [.(lower_bound ['c,b']),(upper_bound (divset (S2 . n),1)).] = [.(lower_bound [.(lower_bound ['c,b']),(upper_bound (divset (S2 . n),1)).]),(upper_bound [.(lower_bound ['c,b']),(upper_bound (divset (S2 . n),1)).]).] by INTEGRA1:5;
A198: divset (T2 . n),i = [.(lower_bound (divset (T2 . n),1)),(upper_bound (divset (T2 . n),1)).] by A191, INTEGRA1:5
.= [.(lower_bound ['c,b']),(upper_bound (divset (T2 . n),1)).] by A192, INTEGRA1:def 5
.= [.(lower_bound ['c,b']),(D . 1).] by A192, INTEGRA1:def 5
.= [.(lower_bound ['c,b']),(E . (1 + 1)).] by A183, A184, A181, A185, A192, RFINSEQ:def 2
.= [.(lower_bound ['c,b']),(upper_bound (divset (S2 . n),2)).] by A183, A194, INTEGRA1:def 5 ;
then [.(lower_bound ['c,b']),(upper_bound (divset (S2 . n),2)).] = [.(lower_bound [.(lower_bound ['c,b']),(upper_bound (divset (S2 . n),2)).]),(upper_bound [.(lower_bound ['c,b']),(upper_bound (divset (S2 . n),2)).]).] by INTEGRA1:5;
then A199: ( lower_bound ['c,b'] = lower_bound [.(lower_bound ['c,b']),(upper_bound (divset (S2 . n),2)).] & upper_bound (divset (S2 . n),2) = upper_bound [.(lower_bound ['c,b']),(upper_bound (divset (S2 . n),2)).] ) by A198, INTEGRA1:6;
y = vol (divset (T2 . n),1) by A178, A179, A188, A191, INTEGRA1:22;
then y = ((upper_bound (divset (S2 . n),2)) - (upper_bound (divset (S2 . n),1))) + ((upper_bound [.(lower_bound ['c,b']),(upper_bound (divset (S2 . n),1)).]) - (lower_bound ['c,b'])) by A191, A198, A199, A196;
then A200: y = ((upper_bound (divset (S2 . n),2)) - (upper_bound (divset (S2 . n),1))) + (vol (divset (S2 . n),1)) by A196, A197, INTEGRA1:6;
divset (S2 . n),2 = [.(lower_bound (divset (S2 . n),2)),(upper_bound (divset (S2 . n),2)).] by INTEGRA1:5;
then divset (S2 . n),2 = [.(E . (2 - 1)),(upper_bound (divset (S2 . n),2)).] by A183, A194, INTEGRA1:def 5;
then A201: divset (S2 . n),2 = [.(upper_bound (divset (S2 . n),1)),(upper_bound (divset (S2 . n),2)).] by A183, A195, INTEGRA1:def 5;
then [.(upper_bound (divset (S2 . n),1)),(upper_bound (divset (S2 . n),2)).] = [.(lower_bound [.(upper_bound (divset (S2 . n),1)),(upper_bound (divset (S2 . n),2)).]),(upper_bound [.(upper_bound (divset (S2 . n),1)),(upper_bound (divset (S2 . n),2)).]).] by INTEGRA1:5;
then y = (vol (divset (S2 . n),2)) + (vol (divset (S2 . n),1)) by A201, A200, INTEGRA1:6;
then y = ((upper_volume (chi ['c,b'],['c,b']),(S2 . n)) . 2) + (vol (divset (S2 . n),1)) by A183, A194, INTEGRA1:22;
then y = ((upper_volume (chi ['c,b'],['c,b']),(S2 . n)) . 2) + ((upper_volume (chi ['c,b'],['c,b']),(S2 . n)) . 1) by A183, A195, INTEGRA1:22;
then y < (e / 2) + (e / 2) by A190, A193, XREAL_1:10;
hence y < e ; :: thesis: verum
end;
A202: y = (upper_bound (rng ((chi ['c,b'],['c,b']) | (divset (T2 . n),i)))) * (vol (divset (T2 . n),i)) by A178, A179, A188, INTEGRA1:def 7;
now
len (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) = (len D) + 1 by A183, A186, INTEGRA1:def 7;
then len (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) = (len (upper_volume (chi ['c,b'],['c,b']),(T2 . n))) + 1 by INTEGRA1:def 7;
then A203: i + 1 in Seg (len (upper_volume (chi ['c,b'],['c,b']),(S2 . n))) by A180, FINSEQ_1:81;
then A204: i + 1 in dom (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) by FINSEQ_1:def 3;
A205: i + 1 in dom (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) by A203, FINSEQ_1:def 3;
A206: i in dom D by A180, A187, FINSEQ_1:def 3;
Seg ((len D) + 1) = Seg (len E) by A186;
then i + 1 in Seg (len E) by A180, A187, FINSEQ_1:81;
then A207: i + 1 in dom E by FINSEQ_1:def 3;
len (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) = len E by A183, INTEGRA1:def 7;
then A208: dom (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) = dom E by FINSEQ_3:31;
assume A209: i <> 1 ; :: thesis: y < e
i in Seg (len D) by A178, A187, FINSEQ_1:def 3;
then 1 <= i by FINSEQ_1:3;
then A210: 1 < i by A209, XXREAL_0:1;
then A211: i - 1 in Seg (len D) by A180, A187, FINSEQ_3:13;
then A212: i - 1 in dom D by FINSEQ_1:def 3;
reconsider i9 = i - 1 as Element of NAT by A211;
1 + 1 < i + 1 by A210, XREAL_1:10;
then A213: i + 1 <> 1 ;
divset (T2 . n),i = [.(lower_bound (divset (T2 . n),i)),(upper_bound (divset (T2 . n),i)).] by INTEGRA1:5
.= [.(D . (i - 1)),(upper_bound (divset (T2 . n),i)).] by A209, A206, INTEGRA1:def 5
.= [.(D . (i - 1)),(D . i).] by A209, A206, INTEGRA1:def 5
.= [.(E . (i9 + 1)),(D . i).] by A183, A184, A181, A185, A212, RFINSEQ:def 2
.= [.(E . ((i - 1) + 1)),(E . (i + 1)).] by A183, A184, A181, A185, A206, RFINSEQ:def 2
.= [.(E . ((i + 1) - 1)),(upper_bound (divset (S2 . n),(i + 1))).] by A183, A213, A207, INTEGRA1:def 5
.= [.(lower_bound (divset (S2 . n),(i + 1))),(upper_bound (divset (S2 . n),(i + 1))).] by A183, A213, A207, INTEGRA1:def 5
.= divset (S2 . n),(i + 1) by INTEGRA1:5 ;
then y = (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) . (i + 1) by A202, A183, A204, A208, INTEGRA1:def 7;
then y in rng (upper_volume (chi ['c,b'],['c,b']),(S2 . n)) by A205, FUNCT_1:def 5;
then y <= max (rng (upper_volume (chi ['c,b'],['c,b']),(S2 . n))) by XXREAL_2:def 8;
then y < e / 2 by A176, XXREAL_0:2;
hence y < e by A175, XXREAL_0:2; :: thesis: verum
end;
hence y < e by A189; :: thesis: verum
end;
max (rng (upper_volume (chi ['c,b'],['c,b']),(T2 . n))) in rng (upper_volume (chi ['c,b'],['c,b']),(T2 . n)) by XXREAL_2:def 8;
then ( 0 <= delta (T2 . n) & delta (T2 . n) < e ) by A177, INTEGRA3:9;
then abs (delta (T2 . n)) < e by ABSVALUE:def 1;
hence abs (((delta T2) . n) - 0 ) < e by INTEGRA3:def 2; :: thesis: verum
end;
hence for n being Element of NAT st m <= n holds
abs (((delta T2) . n) - 0 ) < e ; :: thesis: verum
end;
then A214: delta T2 is convergent by SEQ_2:def 6;
then A215: lim (delta T2) = 0 by A172, SEQ_2:def 7;
then A216: ( upper_sum (f || ['c,b']),T2 is convergent & lim (upper_sum (f || ['c,b']),T2) = upper_integral (f || ['c,b']) ) by A166, A18, A214, INTEGRA4:9;
A217: now
let e be real number ; :: thesis: ( 0 < e implies ex n being Element of NAT st
for m being Element of NAT st n <= m holds
abs (((delta T) . m) - 0 ) < e )
assume A218: 0 < e ; :: thesis: ex n being Element of NAT st
for m being Element of NAT st n <= m holds
abs (((delta T) . m) - 0 ) < e
then consider n1 being Element of NAT such that
A219: for m being Element of NAT st n1 <= m holds
abs (((delta T1) . m) - 0 ) < e by A53, SEQ_2:def 7;
consider n2 being Element of NAT such that
A220: for m being Element of NAT st n2 <= m holds
abs (((delta T2) . m) - 0 ) < e by A172, A218;
reconsider n = max n1,n2 as Element of NAT by XXREAL_0:16;
take n = n; :: thesis: for m being Element of NAT st n <= m holds
abs (((delta T) . m) - 0 ) < e
now
let m be Element of NAT ; :: thesis: ( n <= m implies abs (((delta T) . m) - 0 ) < e )
assume A221: n <= m ; :: thesis: abs (((delta T) . m) - 0 ) < e
n2 <= n by XXREAL_0:25;
then n2 <= m by A221, XXREAL_0:2;
then abs (((delta T2) . m) - 0 ) < e by A220;
then A222: abs (delta (T2 . m)) < e by INTEGRA3:def 2;
0 <= delta (T2 . m) by INTEGRA3:9;
then A223: max (rng (upper_volume (chi ['c,b'],['c,b']),(T2 . m))) < e by A222, ABSVALUE:def 1;
n1 <= n by XXREAL_0:25;
then n1 <= m by A221, XXREAL_0:2;
then abs (((delta T1) . m) - 0 ) < e by A219;
then A224: abs (delta (T1 . m)) < e by INTEGRA3:def 2;
0 <= delta (T1 . m) by INTEGRA3:9;
then A225: max (rng (upper_volume (chi ['a,c'],['a,c']),(T1 . m))) < e by A224, ABSVALUE:def 1;
A226: for r being real number st r in rng (upper_volume (chi ['a,b'],['a,b']),(T . m)) holds
r < e
proof
reconsider Tm = T . m as Division of ['a,b'] ;
let y be real number ; :: thesis: ( y in rng (upper_volume (chi ['a,b'],['a,b']),(T . m)) implies y < e )
assume y in rng (upper_volume (chi ['a,b'],['a,b']),(T . m)) ; :: thesis: y < e
then consider x being set such that
A227: x in dom (upper_volume (chi ['a,b'],['a,b']),(T . m)) and
A228: y = (upper_volume (chi ['a,b'],['a,b']),(T . m)) . x by FUNCT_1:def 5;
reconsider i = x as Element of NAT by A227;
A229: x in Seg (len (upper_volume (chi ['a,b'],['a,b']),(T . m))) by A227, FINSEQ_1:def 3;
then A230: 1 <= i by FINSEQ_1:3;
A231: len (upper_volume (chi ['a,b'],['a,b']),(T . m)) = len Tm by INTEGRA1:def 7;
then A232: i <= len Tm by A229, FINSEQ_1:3;
dom (upper_volume (chi ['a,b'],['a,b']),(T . m)) = dom Tm by A231, FINSEQ_3:31;
then A233: y = (upper_bound (rng ((chi ['a,b'],['a,b']) | (divset (T . m),i)))) * (vol (divset (T . m),i)) by A227, A228, INTEGRA1:def 7;
consider S1 being Division of ['a,c'], S2 being Division of ['c,b'] such that
A234: S1 = T1 . m and
A235: S2 = T2 . m and
A236: T . m = S1 ^ S2 by A93;
A237: len Tm = (len S1) + (len S2) by A236, FINSEQ_1:35;
per cases ( i <= len S1 or i > len S1 ) ;
suppose i <= len S1 ; :: thesis: y < e
then A238: i in Seg (len S1) by A230;
then A239: i in dom S1 by FINSEQ_1:def 3;
len (upper_volume (chi ['a,c'],['a,c']),(T1 . m)) = len S1 by A234, INTEGRA1:def 7;
then A240: i in dom (upper_volume (chi ['a,c'],['a,c']),(T1 . m)) by A238, FINSEQ_1:def 3;
A241: divset (T1 . m),i = divset (T . m),i by A95, A234, A238;
A242: divset (T1 . m),i c= ['a,c'] by A139, A234, A238;
then divset (T1 . m),i c= ['a,b'] by A137, XBOOLE_1:1;
then (chi ['a,c'],['a,c']) | (divset (T1 . m),i) = (chi ['a,b'],['a,b']) | (divset (T . m),i) by A241, A242, Th4;
then y = (upper_volume (chi ['a,c'],['a,c']),(T1 . m)) . i by A233, A234, A239, A241, INTEGRA1:def 7;
then y in rng (upper_volume (chi ['a,c'],['a,c']),(T1 . m)) by A240, FUNCT_1:def 5;
then y <= max (rng (upper_volume (chi ['a,c'],['a,c']),(T1 . m))) by XXREAL_2:def 8;
hence y < e by A225, XXREAL_0:2; :: thesis: verum
end;
suppose i > len S1 ; :: thesis: y < e
then A243: (len S1) + 1 <= i by NAT_1:13;
then consider k being Nat such that
A244: ((len S1) + 1) + k = i by NAT_1:10;
reconsider k = k as Element of NAT by ORDINAL1:def 13;
set i1 = 1 + k;
A245: i - (len S1) <= len S2 by A237, A232, XREAL_1:22;
1 + k = i - (len S1) by A244;
then 1 <= 1 + k by A243, XREAL_1:21;
then A246: 1 + k in Seg (len S2) by A244, A245;
then A247: 1 + k in dom S2 by FINSEQ_1:def 3;
A248: divset (T2 . m),(1 + k) = divset (T . m),((len S1) + (1 + k)) by A112, A234, A235, A246;
A249: divset (T2 . m),(1 + k) c= ['c,b'] by A134, A235, A246;
then divset (T2 . m),(1 + k) c= ['a,b'] by A17, XBOOLE_1:1;
then y = (upper_bound (rng ((chi ['c,b'],['c,b']) | (divset (T2 . m),(1 + k))))) * (vol (divset (T2 . m),(1 + k))) by A233, A244, A248, A249, Th4;
then A250: y = (upper_volume (chi ['c,b'],['c,b']),(T2 . m)) . (1 + k) by A235, A247, INTEGRA1:def 7;
len (upper_volume (chi ['c,b'],['c,b']),(T2 . m)) = len S2 by A235, INTEGRA1:def 7;
then 1 + k in dom (upper_volume (chi ['c,b'],['c,b']),(T2 . m)) by A246, FINSEQ_1:def 3;
then y in rng (upper_volume (chi ['c,b'],['c,b']),(T2 . m)) by A250, FUNCT_1:def 5;
then y <= max (rng (upper_volume (chi ['c,b'],['c,b']),(T2 . m))) by XXREAL_2:def 8;
hence y < e by A223, XXREAL_0:2; :: thesis: verum
end;
end;
end;
A251: 0 <= delta (T . m) by INTEGRA3:9;
max (rng (upper_volume (chi ['a,b'],['a,b']),(T . m))) in rng (upper_volume (chi ['a,b'],['a,b']),(T . m)) by XXREAL_2:def 8;
then delta (T . m) < e by A226;
then abs (delta (T . m)) < e by A251, ABSVALUE:def 1;
hence abs (((delta T) . m) - 0 ) < e by INTEGRA3:def 2; :: thesis: verum
end;
hence for m being Element of NAT st n <= m holds
abs (((delta T) . m) - 0 ) < e ; :: thesis: verum
end;
then A252: delta T is convergent by SEQ_2:def 6;
then A253: lim (delta T) = 0 by A217, SEQ_2:def 7;
(f || ['a,b']) | ['a,b'] is bounded by A4, INTEGRA5:9;
then A254: upper_integral (f || ['a,b']) = lim (upper_sum (f || ['a,b']),T) by A12, A252, A253, INTEGRA4:9;
A255: for i being Element of NAT holds lower_volume (f || ['a,b']),(T . i) = (lower_volume (f || ['a,c']),(T1 . i)) ^ (lower_volume (f || ['c,b']),(T2 . i))
proof
let i be Element of NAT ; :: thesis: lower_volume (f || ['a,b']),(T . i) = (lower_volume (f || ['a,c']),(T1 . i)) ^ (lower_volume (f || ['c,b']),(T2 . i))
reconsider F = lower_volume (f || ['a,b']),(T . i) as FinSequence of REAL ;
reconsider F1 = lower_volume (f || ['a,c']),(T1 . i) as FinSequence of REAL ;
reconsider F2 = lower_volume (f || ['c,b']),(T2 . i) as FinSequence of REAL ;
reconsider S = T . i as Division of ['a,b'] ;
consider S1 being Division of ['a,c'], S2 being Division of ['c,b'] such that
A256: S1 = T1 . i and
A257: S2 = T2 . i and
A258: T . i = S1 ^ S2 by A93;
A259: len F = len S by INTEGRA1:def 8
.= (len S1) + (len S2) by A258, FINSEQ_1:35
.= (len F1) + (len S2) by A256, INTEGRA1:def 8 ;
then A260: len F = (len F1) + (len F2) by A257, INTEGRA1:def 8;
A261: now
let k be Nat; :: thesis: ( k in dom F2 implies F . ((len F1) + k) = F2 . k )
assume k in dom F2 ; :: thesis: F . ((len F1) + k) = F2 . k
then A262: k in Seg (len F2) by FINSEQ_1:def 3;
then 1 <= k by FINSEQ_1:3;
then A263: 1 + (len F1) <= k + (len F1) by XREAL_1:8;
k <= len F2 by A262, FINSEQ_1:3;
then A264: (len F1) + k <= len F by A260, XREAL_1:8;
1 <= 1 + (len F1) by NAT_1:11;
then 1 <= k + (len F1) by A263, XXREAL_0:2;
then k + (len F1) in Seg (len F) by A264;
then (len F1) + k in Seg (len S) by INTEGRA1:def 8;
then (len F1) + k in dom S by FINSEQ_1:def 3;
then A265: F . ((len F1) + k) = (lower_bound (rng ((f || ['a,b']) | (divset (T . i),((len F1) + k))))) * (vol (divset (T . i),((len F1) + k))) by INTEGRA1:def 8;
A266: k in Seg (len S2) by A257, A262, INTEGRA1:def 8;
then A267: k in dom S2 by FINSEQ_1:def 3;
len F1 = len S1 by A256, INTEGRA1:def 8;
then A268: divset (T . i),((len F1) + k) = divset (T2 . i),k by A112, A256, A257, A266;
A269: divset (T2 . i),k c= ['c,b'] by A134, A257, A266;
then divset (T . i),((len F1) + k) c= ['a,b'] by A17, A268, XBOOLE_1:1;
then F . ((len F1) + k) = (lower_bound (rng ((f || ['c,b']) | (divset (T2 . i),k)))) * (vol (divset (T2 . i),k)) by A265, A268, A269, Th3;
hence F . ((len F1) + k) = F2 . k by A257, A267, INTEGRA1:def 8; :: thesis: verum
end;
A270: now
let k be Nat; :: thesis: ( k in dom F1 implies F . k = F1 . k )
len (lower_volume (f || ['a,b']),(T . i)) = len S by INTEGRA1:def 8;
then A271: dom (lower_volume (f || ['a,b']),(T . i)) = dom S by FINSEQ_3:31;
assume A272: k in dom F1 ; :: thesis: F . k = F1 . k
then k in Seg (len F1) by FINSEQ_1:def 3;
then A273: k in Seg (len S1) by A256, INTEGRA1:def 8;
then A274: k in dom S1 by FINSEQ_1:def 3;
len F1 <= len F by A259, NAT_1:11;
then dom F1 c= dom F by FINSEQ_3:32;
then A275: F . k = (lower_bound (rng ((f || ['a,b']) | (divset (T . i),k)))) * (vol (divset (T . i),k)) by A272, A271, INTEGRA1:def 8;
A276: ( divset (T . i),k = divset (T1 . i),k & divset (T1 . i),k c= ['a,c'] ) by A139, A95, A256, A273;
then divset (T . i),k c= ['a,b'] by A137, XBOOLE_1:1;
then F . k = (lower_bound (rng ((f || ['a,c']) | (divset (T1 . i),k)))) * (vol (divset (T1 . i),k)) by A275, A276, Th3;
hence F . k = F1 . k by A256, A274, INTEGRA1:def 8; :: thesis: verum
end;
dom F = Seg ((len F1) + (len F2)) by A260, FINSEQ_1:def 3;
hence lower_volume (f || ['a,b']),(T . i) = (lower_volume (f || ['a,c']),(T1 . i)) ^ (lower_volume (f || ['c,b']),(T2 . i)) by A270, A261, FINSEQ_1:def 7; :: thesis: verum
end;
A277: for i being Element of NAT holds Sum (lower_volume (f || ['a,b']),(T . i)) = (Sum (lower_volume (f || ['a,c']),(T1 . i))) + (Sum (lower_volume (f || ['c,b']),(T2 . i)))
proof
let i be Element of NAT ; :: thesis: Sum (lower_volume (f || ['a,b']),(T . i)) = (Sum (lower_volume (f || ['a,c']),(T1 . i))) + (Sum (lower_volume (f || ['c,b']),(T2 . i)))
lower_volume (f || ['a,b']),(T . i) = (lower_volume (f || ['a,c']),(T1 . i)) ^ (lower_volume (f || ['c,b']),(T2 . i)) by A255;
hence Sum (lower_volume (f || ['a,b']),(T . i)) = (Sum (lower_volume (f || ['a,c']),(T1 . i))) + (Sum (lower_volume (f || ['c,b']),(T2 . i))) by RVSUM_1:105; :: thesis: verum
end;
now
let i be Element of NAT ; :: thesis: (lower_sum (f || ['a,b']),T) . i = ((lower_sum (f || ['a,c']),T1) . i) + ((lower_sum (f || ['c,b']),T2) . i)
thus (lower_sum (f || ['a,b']),T) . i = lower_sum (f || ['a,b']),(T . i) by INTEGRA2:def 5
.= (lower_sum (f || ['a,c']),(T1 . i)) + (Sum (lower_volume (f || ['c,b']),(T2 . i))) by A277
.= ((lower_sum (f || ['a,c']),T1) . i) + (lower_sum (f || ['c,b']),(T2 . i)) by INTEGRA2:def 5
.= ((lower_sum (f || ['a,c']),T1) . i) + ((lower_sum (f || ['c,b']),T2) . i) by INTEGRA2:def 5 ; :: thesis: verum
end;
then A278: lower_sum (f || ['a,b']),T = (lower_sum (f || ['a,c']),T1) + (lower_sum (f || ['c,b']),T2) by SEQ_1:11;
A279: f || ['a,c'] is Function of ['a,c'],REAL by A2, A137, Lm1, XBOOLE_1:1;
then A280: ( f || ['a,c'] is upper_integrable & f || ['a,c'] is lower_integrable ) by A138, INTEGRA4:10;
A281: ( upper_sum (f || ['a,c']),T1 is convergent & lim (upper_sum (f || ['a,c']),T1) = upper_integral (f || ['a,c']) ) by A279, A138, A53, INTEGRA4:9;
then A282: (upper_integral (f || ['a,c'])) + (upper_integral (f || ['c,b'])) = upper_integral (f || ['a,b']) by A165, A216, A254, SEQ_2:20;
A283: ( lower_sum (f || ['a,c']),T1 is convergent & lim (lower_sum (f || ['a,c']),T1) = lower_integral (f || ['a,c']) ) by A279, A138, A53, INTEGRA4:8;
(f || ['a,b']) | ['a,b'] is bounded by A4, INTEGRA5:9;
then A284: lower_integral (f || ['a,b']) = lim (lower_sum (f || ['a,b']),T) by A12, A252, A253, INTEGRA4:8;
( lower_sum (f || ['c,b']),T2 is convergent & lim (lower_sum (f || ['c,b']),T2) = lower_integral (f || ['c,b']) ) by A166, A18, A214, A215, INTEGRA4:8;
then A285: (lower_integral (f || ['a,c'])) + (lower_integral (f || ['c,b'])) = lower_integral (f || ['a,b']) by A278, A283, A284, SEQ_2:20;
integral f,a,b = integral f,['a,b'] by A1, INTEGRA5:def 5
.= (integral (f || ['a,c'])) + (integral (f || ['c,b'])) by A165, A281, A216, A254, SEQ_2:20 ;
hence integral f,a,b = (integral f,a,c) + (integral f,c,b) by A58, A57; :: thesis: ( f is_integrable_on ['a,c'] & f is_integrable_on ['c,b'] )
f || ['a,b'] is integrable by A3, INTEGRA5:def 2;
then A286: upper_integral (f || ['a,b']) = lower_integral (f || ['a,b']) by INTEGRA1:def 17;
A287: ( f || ['c,b'] is upper_integrable & f || ['c,b'] is lower_integrable ) by A166, A18, INTEGRA4:10;
A288: lower_integral (f || ['a,c']) <= upper_integral (f || ['a,c']) by A279, A138, INTEGRA1:51;
then lower_integral (f || ['c,b']) = upper_integral (f || ['c,b']) by A286, A282, A285, A167, Th1;
then A289: f || ['c,b'] is integrable by A287, INTEGRA1:def 17;
lower_integral (f || ['a,c']) = upper_integral (f || ['a,c']) by A286, A282, A285, A288, A167, Th1;
then f || ['a,c'] is integrable by A280, INTEGRA1:def 17;
hence ( f is_integrable_on ['a,c'] & f is_integrable_on ['c,b'] ) by A289, INTEGRA5:def 2; :: thesis: verum