let X be set ; :: thesis: for S being SigmaField of X
for M being sigma_Measure of S
for F being sequence of (COM (S,M))
for G being sequence of S ex H being sequence of (bool X) st
for n being Element of NAT holds H . n = (F . n) \ (G . n)
let S be SigmaField of X; :: thesis: for M being sigma_Measure of S
for F being sequence of (COM (S,M))
for G being sequence of S ex H being sequence of (bool X) st
for n being Element of NAT holds H . n = (F . n) \ (G . n)
let M be sigma_Measure of S; :: thesis: for F being sequence of (COM (S,M))
for G being sequence of S ex H being sequence of (bool X) st
for n being Element of NAT holds H . n = (F . n) \ (G . n)
let F be sequence of (COM (S,M)); :: thesis: for G being sequence of S ex H being sequence of (bool X) st
for n being Element of NAT holds H . n = (F . n) \ (G . n)
let G be sequence of S; :: thesis: ex H being sequence of (bool X) st
for n being Element of NAT holds H . n = (F . n) \ (G . n)
defpred S₁[ Element of NAT , set ] means for n being Element of NAT
for y being set st n = $1 & y = $2 holds
y = (F . n) \ (G . n);
A1: for t being Element of NAT ex A being Subset of X st S₁[t,A] ex H being sequence of (bool X) st
for t being Element of NAT holds S₁[t,H . t] from FUNCT_2:sch 3(A1);
then consider H being sequence of (bool X) such that
A2: for t, n being Element of NAT
for y being set st n = t & y = H . t holds
y = (F . n) \ (G . n) ;
take H ; :: thesis: for n being Element of NAT holds H . n = (F . n) \ (G . n)
thus for n being Element of NAT holds H . n = (F . n) \ (G . n) by A2; :: thesis: verum