let X, Y be set ;
let F be Functional_Sequence of X,Y;
let D be set ;
existence
ex b₁ being Functional_Sequence of X,Y st
for n being Nat holds b₁ . n = (F . n) | D uniqueness
for b₁, b₂ being Functional_Sequence of X,Y st ( for n being Nat holds b₁ . n = (F . n) | D ) & ( for n being Nat holds b₂ . n = (F . n) | D ) holds
b₁ = b₂

for X being non empty set
for F being Functional_Sequence of X,REAL
for x being Element of X
for D being set st x in D & F # x is convergent holds
(F || D) # x is convergent

for X, Y, D being set
for F being Functional_Sequence of X,Y st F is with_the_same_dom holds
F || D is with_the_same_dom

for X being non empty set
for F being Functional_Sequence of X,REAL
for D being set st D c= dom (F . 0) & ( for x being Element of X st x in D holds
F # x is convergent ) holds
(lim F) | D = lim (F || D)

for X being non empty set
for S being SigmaField of X
for E being Element of S
for F being Functional_Sequence of X,REAL
for n being Nat st F is with_the_same_dom & E c= dom (F . 0) & ( for m being Nat holds F . m is E -measurable ) holds
(F || E) . n is E -measurable

for seq being Real_Sequence holds Partial_Sums (R_EAL seq) = R_EAL (Partial_Sums seq)

for X being non empty set
for S being SigmaField of X
for E being Element of S
for F being Functional_Sequence of X,REAL st ( for x being Element of X st x in E holds
F # x is summable ) holds
for x being Element of X st x in E holds
(F || E) # x is summable

let X be non empty set ;
let F be Functional_Sequence of X,REAL;
existence
ex b₁ being Functional_Sequence of X,REAL st
( b₁ . 0 = F . 0 & ( for n being Nat holds b₁ . (n + 1) = (b₁ . n) + (F . (n + 1)) ) ) uniqueness
for b₁, b₂ being Functional_Sequence of X,REAL st b₁ . 0 = F . 0 & ( for n being Nat holds b₁ . (n + 1) = (b₁ . n) + (F . (n + 1)) ) & b₂ . 0 = F . 0 & ( for n being Nat holds b₂ . (n + 1) = (b₂ . n) + (F . (n + 1)) ) holds
b₁ = b₂

for X being non empty set
for F being Functional_Sequence of X,REAL holds Partial_Sums (R_EAL F) = R_EAL (Partial_Sums F)

for X being non empty set
for F being Functional_Sequence of X,REAL
for n, m being Nat
for z being set st z in dom ((Partial_Sums F) . n) & m <= n holds
( z in dom ((Partial_Sums F) . m) & z in dom (F . m) )

for X being non empty set
for F being Functional_Sequence of X,REAL holds R_EAL F is additive

for X being non empty set
for F being Functional_Sequence of X,REAL
for n being Nat holds dom ((Partial_Sums F) . n) = meet { (dom (F . k)) where k is Element of NAT : k <= n }

for X being non empty set
for F being Functional_Sequence of X,REAL
for n being Nat st F is with_the_same_dom holds
dom ((Partial_Sums F) . n) = dom (F . 0)

for X being non empty set
for F being Functional_Sequence of X,REAL
for n being Nat
for x being Element of X
for D being set st F is with_the_same_dom & D c= dom (F . 0) & x in D holds
(Partial_Sums (F # x)) . n = ((Partial_Sums F) # x) . n

for X being non empty set
for F being Functional_Sequence of X,REAL
for x being Element of X
for D being set st F is with_the_same_dom & D c= dom (F . 0) & x in D holds
( Partial_Sums (F # x) is convergent iff (Partial_Sums F) # x is convergent )

for X being non empty set
for F being Functional_Sequence of X,REAL
for f being PartFunc of X,REAL
for x being Element of X st F is with_the_same_dom & dom f c= dom (F . 0) & x in dom f & f . x = Sum (F # x) holds
f . x = lim ((Partial_Sums F) # x)

for X being non empty set
for S being SigmaField of X
for F being Functional_Sequence of X,REAL
for n being Nat st ( for m being Nat holds F . m is_simple_func_in S ) holds
(Partial_Sums F) . n is_simple_func_in S

for X being non empty set
for S being SigmaField of X
for E being Element of S
for F being Functional_Sequence of X,REAL
for m being Nat st ( for n being Nat holds F . n is E -measurable ) holds
(Partial_Sums F) . m is E -measurable

for X being non empty set
for F being Functional_Sequence of X,REAL st F is with_the_same_dom holds
Partial_Sums F is with_the_same_dom

for X being non empty set
for S being SigmaField of X
for E being Element of S
for F being Functional_Sequence of X,REAL st dom (F . 0) = E & F is with_the_same_dom & ( for n being Nat holds (Partial_Sums F) . n is E -measurable ) & ( for x being Element of X st x in E holds
F # x is summable ) holds
lim (Partial_Sums F) is E -measurable

for X being non empty set
for S being SigmaField of X
for M being sigma_Measure of S
for F being Functional_Sequence of X,REAL st ( for n being Nat holds F . n is_integrable_on M ) holds
for m being Nat holds (Partial_Sums F) . m is_integrable_on M

for X being non empty set
for f being PartFunc of X,COMPLEX
for A being set holds
( (Re f) | A = Re (f | A) & (Im f) | A = Im (f | A) )

for X being non empty set
for D being set
for F being Functional_Sequence of X,COMPLEX holds Re (F || D) = (Re F) || D

for X being non empty set
for D being set
for F being Functional_Sequence of X,COMPLEX holds Im (F || D) = (Im F) || D

for X being non empty set
for x being Element of X
for D being set
for F being Functional_Sequence of X,COMPLEX st F is with_the_same_dom & D c= dom (F . 0) & x in D & F # x is convergent holds
(F || D) # x is convergent

for X being non empty set
for F being Functional_Sequence of X,COMPLEX holds
( F is with_the_same_dom iff Re F is with_the_same_dom )

for X being non empty set
for F being Functional_Sequence of X,COMPLEX holds
( Re F is with_the_same_dom iff Im F is with_the_same_dom )

for X being non empty set
for D being set
for F being Functional_Sequence of X,COMPLEX st F is with_the_same_dom & D = dom (F . 0) & ( for x being Element of X st x in D holds
F # x is convergent ) holds
(lim F) | D = lim (F || D)

for X being non empty set
for S being SigmaField of X
for E being Element of S
for n being Nat
for F being Functional_Sequence of X,COMPLEX st F is with_the_same_dom & E c= dom (F . 0) & ( for m being Nat holds F . m is E -measurable ) holds
(F || E) . n is E -measurable

for X being non empty set
for S being SigmaField of X
for E being Element of S
for F being Functional_Sequence of X,COMPLEX st E c= dom (F . 0) & F is with_the_same_dom & ( for x being Element of X st x in E holds
F # x is summable ) holds
for x being Element of X st x in E holds
(F || E) # x is summable

let X be non empty set ;
let F be Functional_Sequence of X,COMPLEX;
existence
ex b₁ being Functional_Sequence of X,COMPLEX st
( b₁ . 0 = F . 0 & ( for n being Nat holds b₁ . (n + 1) = (b₁ . n) + (F . (n + 1)) ) ) uniqueness
for b₁, b₂ being Functional_Sequence of X,COMPLEX st b₁ . 0 = F . 0 & ( for n being Nat holds b₁ . (n + 1) = (b₁ . n) + (F . (n + 1)) ) & b₂ . 0 = F . 0 & ( for n being Nat holds b₂ . (n + 1) = (b₂ . n) + (F . (n + 1)) ) holds
b₁ = b₂

for X being non empty set
for F being Functional_Sequence of X,COMPLEX holds
( Partial_Sums (Re F) = Re (Partial_Sums F) & Partial_Sums (Im F) = Im (Partial_Sums F) )

for X being non empty set
for n, m being Nat
for z being set
for F being Functional_Sequence of X,COMPLEX st z in dom ((Partial_Sums F) . n) & m <= n holds
( z in dom ((Partial_Sums F) . m) & z in dom (F . m) )

for X being non empty set
for n being Nat
for F being Functional_Sequence of X,COMPLEX holds dom ((Partial_Sums F) . n) = meet { (dom (F . k)) where k is Element of NAT : k <= n }

for X being non empty set
for n being Nat
for F being Functional_Sequence of X,COMPLEX st F is with_the_same_dom holds
dom ((Partial_Sums F) . n) = dom (F . 0)

for X being non empty set
for n being Nat
for x being Element of X
for D being set
for F being Functional_Sequence of X,COMPLEX st F is with_the_same_dom & D c= dom (F . 0) & x in D holds
(Partial_Sums (F # x)) . n = ((Partial_Sums F) # x) . n

for X being non empty set
for F being Functional_Sequence of X,COMPLEX st F is with_the_same_dom holds
Partial_Sums F is with_the_same_dom

for X being non empty set
for x being Element of X
for D being set
for F being Functional_Sequence of X,COMPLEX st F is with_the_same_dom & D c= dom (F . 0) & x in D holds
( Partial_Sums (F # x) is convergent iff (Partial_Sums F) # x is convergent )

for X being non empty set
for x being Element of X
for F being Functional_Sequence of X,COMPLEX
for f being PartFunc of X,COMPLEX st F is with_the_same_dom & dom f c= dom (F . 0) & x in dom f & F # x is summable & f . x = Sum (F # x) holds
f . x = lim ((Partial_Sums F) # x)

for X being non empty set
for S being SigmaField of X
for n being Nat
for F being Functional_Sequence of X,COMPLEX st ( for m being Nat holds F . m is_simple_func_in S ) holds
(Partial_Sums F) . n is_simple_func_in S

for X being non empty set
for S being SigmaField of X
for E being Element of S
for m being Nat
for F being Functional_Sequence of X,COMPLEX st ( for n being Nat holds F . n is E -measurable ) holds
(Partial_Sums F) . m is E -measurable

for X being non empty set
for S being SigmaField of X
for E being Element of S
for F being Functional_Sequence of X,COMPLEX st dom (F . 0) = E & F is with_the_same_dom & ( for n being Nat holds (Partial_Sums F) . n is E -measurable ) & ( for x being Element of X st x in E holds
F # x is summable ) holds
lim (Partial_Sums F) is E -measurable

for X being non empty set
for S being SigmaField of X
for M being sigma_Measure of S
for F being Functional_Sequence of X,COMPLEX st ( for n being Nat holds F . n is_integrable_on M ) holds
for m being Nat holds (Partial_Sums F) . m is_integrable_on M

for X being non empty set
for S being SigmaField of X
for f being PartFunc of X,COMPLEX
for A being Element of S st f is_simple_func_in S holds
f is A -measurable

for X being non empty set
for S being SigmaField of X
for f being PartFunc of X,COMPLEX
for A being Element of S st f is_simple_func_in S holds
f | A is_simple_func_in S

for X being non empty set
for S being SigmaField of X
for f being PartFunc of X,COMPLEX st f is_simple_func_in S holds
dom f is Element of S by MESFUNC2:31;

for X being non empty set
for S being SigmaField of X
for f, g being PartFunc of X,COMPLEX st f is_simple_func_in S & g is_simple_func_in S holds
f + g is_simple_func_in S

for X being non empty set
for S being SigmaField of X
for f being PartFunc of X,COMPLEX
for c being Complex st f is_simple_func_in S holds
c (#) f is_simple_func_in S

for X being non empty set
for S being SigmaField of X
for M being sigma_Measure of S
for E being Element of S
for F being with_the_same_dom Functional_Sequence of X,ExtREAL
for P being PartFunc of X,ExtREAL st E = dom (F . 0) & E = dom P & ( for n being Nat holds F . n is E -measurable ) & P is_integrable_on M & ( for x being Element of X
for n being Nat st x in E holds
|.(F . n).| . x <= P . x ) & ( for x being Element of X st x in E holds
F # x is convergent ) holds
lim F is_integrable_on M

for X being non empty set
for S being SigmaField of X
for M being sigma_Measure of S
for E being Element of S
for F being with_the_same_dom Functional_Sequence of X,REAL
for P being PartFunc of X,REAL st E = dom (F . 0) & E = dom P & ( for n being Nat holds F . n is E -measurable ) & P is_integrable_on M & ( for x being Element of X
for n being Nat st x in E holds
|.(F . n).| . x <= P . x ) & ( for x being Element of X st x in E holds
F # x is convergent ) holds
lim F is_integrable_on M

for X being non empty set
for S being SigmaField of X
for M being sigma_Measure of S
for E being Element of S
for F being with_the_same_dom Functional_Sequence of X,REAL
for P being PartFunc of X,REAL st E = dom (F . 0) & E = dom P & ( for n being Nat holds F . n is E -measurable ) & P is_integrable_on M & ( for x being Element of X
for n being Nat st x in E holds
|.(F . n).| . x <= P . x ) holds
ex I being Real_Sequence st
( ( for n being Nat holds I . n = Integral (M,(F . n)) ) & ( ( for x being Element of X st x in E holds
F # x is convergent ) implies ( I is convergent & lim I = Integral (M,(lim F)) ) ) )

let X be set ;
let F be Functional_Sequence of X,REAL;

for X being non empty set
for S being SigmaField of X
for M being sigma_Measure of S
for E being Element of S
for F being with_the_same_dom Functional_Sequence of X,REAL st M . E < +infty & E = dom (F . 0) & ( for n being Nat holds F . n is E -measurable ) & F is uniformly_bounded & ( for x being Element of X st x in E holds
F # x is convergent ) holds
( ( for n being Nat holds F . n is_integrable_on M ) & lim F is_integrable_on M & ex I being ExtREAL_sequence st
( ( for n being Nat holds I . n = Integral (M,(F . n)) ) & I is convergent & lim I = Integral (M,(lim F)) ) )

let X be set ;
let F be Functional_Sequence of X,REAL;
let f be PartFunc of X,REAL;

for X being non empty set
for S being SigmaField of X
for M being sigma_Measure of S
for E being Element of S
for F being with_the_same_dom Functional_Sequence of X,REAL
for f being PartFunc of X,REAL st M . E < +infty & E = dom (F . 0) & ( for n being Nat holds F . n is_integrable_on M ) & F is_uniformly_convergent_to f holds
( f is_integrable_on M & ex I being ExtREAL_sequence st
( ( for n being Nat holds I . n = Integral (M,(F . n)) ) & I is convergent & lim I = Integral (M,f) ) )

for X being non empty set
for S being SigmaField of X
for M being sigma_Measure of S
for E being Element of S
for P being PartFunc of X,REAL
for F being with_the_same_dom Functional_Sequence of X,COMPLEX st E = dom (F . 0) & E = dom P & ( for n being Nat holds F . n is E -measurable ) & P is_integrable_on M & ( for x being Element of X
for n being Nat st x in E holds
|.(F . n).| . x <= P . x ) & ( for x being Element of X st x in E holds
F # x is convergent ) holds
lim F is_integrable_on M

for X being non empty set
for S being SigmaField of X
for M being sigma_Measure of S
for E being Element of S
for P being PartFunc of X,REAL
for F being with_the_same_dom Functional_Sequence of X,COMPLEX st E = dom (F . 0) & E = dom P & ( for n being Nat holds F . n is E -measurable ) & P is_integrable_on M & ( for x being Element of X
for n being Nat st x in E holds
|.(F . n).| . x <= P . x ) holds
ex I being Complex_Sequence st
( ( for n being Nat holds I . n = Integral (M,(F . n)) ) & ( ( for x being Element of X st x in E holds
F # x is convergent ) implies ( I is convergent & lim I = Integral (M,(lim F)) ) ) )

let X be set ;
let F be Functional_Sequence of X,COMPLEX;

for X being non empty set
for S being SigmaField of X
for M being sigma_Measure of S
for E being Element of S
for F being with_the_same_dom Functional_Sequence of X,COMPLEX st M . E < +infty & E = dom (F . 0) & ( for n being Nat holds F . n is E -measurable ) & F is uniformly_bounded & ( for x being Element of X st x in E holds
F # x is convergent ) holds
( ( for n being Nat holds F . n is_integrable_on M ) & lim F is_integrable_on M & ex I being Complex_Sequence st
( ( for n being Nat holds I . n = Integral (M,(F . n)) ) & I is convergent & lim I = Integral (M,(lim F)) ) )

let X be set ;
let F be Functional_Sequence of X,COMPLEX;
let f be PartFunc of X,COMPLEX;

for X being non empty set
for S being SigmaField of X
for M being sigma_Measure of S
for E being Element of S
for F being with_the_same_dom Functional_Sequence of X,COMPLEX
for f being PartFunc of X,COMPLEX st M . E < +infty & E = dom (F . 0) & ( for n being Nat holds F . n is_integrable_on M ) & F is_uniformly_convergent_to f holds
( f is_integrable_on M & ex I being Complex_Sequence st
( ( for n being Nat holds I . n = Integral (M,(F . n)) ) & I is convergent & lim I = Integral (M,f) ) )