let X be non empty set ; for S being SigmaField of X
for M being sigma_Measure of S
for f, g being PartFunc of X,COMPLEX
for B being Element of S st f is_integrable_on M & g is_integrable_on M & B c= dom (f + g) holds
( f + g is_integrable_on M & Integral_on M,B,(f + g) = (Integral_on M,B,f) + (Integral_on M,B,g) )
let S be SigmaField of X; for M being sigma_Measure of S
for f, g being PartFunc of X,COMPLEX
for B being Element of S st f is_integrable_on M & g is_integrable_on M & B c= dom (f + g) holds
( f + g is_integrable_on M & Integral_on M,B,(f + g) = (Integral_on M,B,f) + (Integral_on M,B,g) )
let M be sigma_Measure of S; for f, g being PartFunc of X,COMPLEX
for B being Element of S st f is_integrable_on M & g is_integrable_on M & B c= dom (f + g) holds
( f + g is_integrable_on M & Integral_on M,B,(f + g) = (Integral_on M,B,f) + (Integral_on M,B,g) )
let f, g be PartFunc of X,COMPLEX ; for B being Element of S st f is_integrable_on M & g is_integrable_on M & B c= dom (f + g) holds
( f + g is_integrable_on M & Integral_on M,B,(f + g) = (Integral_on M,B,f) + (Integral_on M,B,g) )
let B be Element of S; ( f is_integrable_on M & g is_integrable_on M & B c= dom (f + g) implies ( f + g is_integrable_on M & Integral_on M,B,(f + g) = (Integral_on M,B,f) + (Integral_on M,B,g) ) )
assume that
A1:
f is_integrable_on M
and
A2:
g is_integrable_on M
and
A3:
B c= dom (f + g)
; ( f + g is_integrable_on M & Integral_on M,B,(f + g) = (Integral_on M,B,f) + (Integral_on M,B,g) )
A4:
Re f is_integrable_on M
by A1, Def4;
then
(Re f) | B is_integrable_on M
by MESFUNC6:91;
then A5:
Re (f | B) is_integrable_on M
by Th7;
then A6:
Integral M,(Re (f | B)) < +infty
by MESFUNC6:90;
A7:
Im f is_integrable_on M
by A1, Def4;
then
(Im f) | B is_integrable_on M
by MESFUNC6:91;
then A8:
Im (f | B) is_integrable_on M
by Th7;
then A9:
-infty < Integral M,(Im (f | B))
by MESFUNC6:90;
A10:
Integral M,(Im (f | B)) < +infty
by A8, MESFUNC6:90;
-infty < Integral M,(Re (f | B))
by A5, MESFUNC6:90;
then reconsider R1 = Integral M,(Re (f | B)), I1 = Integral M,(Im (f | B)) as Real by A6, A9, A10, XXREAL_0:14;
f | B is_integrable_on M
by A5, A8, Def4;
then A11:
Integral M,(f | B) = R1 + (I1 * <i> )
by Def5;
A12:
Im g is_integrable_on M
by A2, Def4;
then
(Im g) | B is_integrable_on M
by MESFUNC6:91;
then A13:
Im (g | B) is_integrable_on M
by Th7;
then A14:
-infty < Integral M,(Im (g | B))
by MESFUNC6:90;
A15:
Re g is_integrable_on M
by A2, Def4;
then
(Re g) | B is_integrable_on M
by MESFUNC6:91;
then A16:
Re (g | B) is_integrable_on M
by Th7;
then A17:
Integral M,(Re (g | B)) < +infty
by MESFUNC6:90;
B c= dom (Im (f + g))
by A3, COMSEQ_3:def 4;
then A18:
B c= dom ((Im f) + (Im g))
by Th5;
then
Integral_on M,B,((Im f) + (Im g)) = (Integral_on M,B,(Im f)) + (Integral_on M,B,(Im g))
by A7, A12, MESFUNC6:103;
then A19:
Integral M,((Im (f + g)) | B) = (Integral M,((Im f) | B)) + (Integral M,((Im g) | B))
by Th5;
A20:
Integral M,(Im (g | B)) < +infty
by A13, MESFUNC6:90;
-infty < Integral M,(Re (g | B))
by A16, MESFUNC6:90;
then reconsider R2 = Integral M,(Re (g | B)), I2 = Integral M,(Im (g | B)) as Real by A17, A14, A20, XXREAL_0:14;
g | B is_integrable_on M
by A16, A13, Def4;
then A21:
Integral M,(g | B) = R2 + (I2 * <i> )
by Def5;
A22:
Integral M,((Im g) | B) = I2
by Th7;
(Im f) + (Im g) is_integrable_on M
by A7, A12, A18, MESFUNC6:103;
then A23:
Im (f + g) is_integrable_on M
by Th5;
then
(Im (f + g)) | B is_integrable_on M
by MESFUNC6:91;
then A24:
Im ((f + g) | B) is_integrable_on M
by Th7;
then A25:
-infty < Integral M,(Im ((f + g) | B))
by MESFUNC6:90;
B c= dom (Re (f + g))
by A3, COMSEQ_3:def 3;
then A26:
B c= dom ((Re f) + (Re g))
by Th5;
then
Integral_on M,B,((Re f) + (Re g)) = (Integral_on M,B,(Re f)) + (Integral_on M,B,(Re g))
by A4, A15, MESFUNC6:103;
then A27:
Integral M,((Re (f + g)) | B) = (Integral M,((Re f) | B)) + (Integral M,((Re g) | B))
by Th5;
(Re f) + (Re g) is_integrable_on M
by A4, A15, A26, MESFUNC6:103;
then A28:
Re (f + g) is_integrable_on M
by Th5;
then
(Re (f + g)) | B is_integrable_on M
by MESFUNC6:91;
then A29:
Re ((f + g) | B) is_integrable_on M
by Th7;
then A30:
Integral M,(Re ((f + g) | B)) < +infty
by MESFUNC6:90;
A31:
Integral M,(Im ((f + g) | B)) < +infty
by A24, MESFUNC6:90;
-infty < Integral M,(Re ((f + g) | B))
by A29, MESFUNC6:90;
then reconsider R = Integral M,(Re ((f + g) | B)), I = Integral M,(Im ((f + g) | B)) as Real by A30, A25, A31, XXREAL_0:14;
A32:
Integral M,((Re g) | B) = R2
by Th7;
Integral M,((Im f) | B) = I1
by Th7;
then
R_EAL I = (R_EAL I1) + (R_EAL I2)
by A19, A22, Th7;
then A33:
I = I1 + I2
by SUPINF_2:1;
Integral M,((Re f) | B) = R1
by Th7;
then
R_EAL R = (R_EAL R1) + (R_EAL R2)
by A27, A32, Th7;
then A34:
R = R1 + R2
by SUPINF_2:1;
(f + g) | B is_integrable_on M
by A29, A24, Def4;
then Integral_on M,B,(f + g) =
R + (I * <i> )
by Def5
.=
(Integral_on M,B,f) + (Integral_on M,B,g)
by A34, A33, A11, A21
;
hence
( f + g is_integrable_on M & Integral_on M,B,(f + g) = (Integral_on M,B,f) + (Integral_on M,B,g) )
by A28, A23, Def4; verum