let Z be open Subset of REAL ; :: thesis: for f being PartFunc of REAL ,REAL st Z c= dom (ln * (exp_R + f)) & ( for x being Real st x in Z holds
f . x = 1 ) holds
( ln * (exp_R + f) is_differentiable_on Z & ( for x being Real st x in Z holds
((ln * (exp_R + f)) `| Z) . x = (exp_R . x) / ((exp_R . x) + 1) ) )
let f be PartFunc of REAL ,REAL ; :: thesis: ( Z c= dom (ln * (exp_R + f)) & ( for x being Real st x in Z holds
f . x = 1 ) implies ( ln * (exp_R + f) is_differentiable_on Z & ( for x being Real st x in Z holds
((ln * (exp_R + f)) `| Z) . x = (exp_R . x) / ((exp_R . x) + 1) ) ) )
assume that
A1: Z c= dom (ln * (exp_R + f)) and
A2: for x being Real st x in Z holds
f . x = 1 ; :: thesis: ( ln * (exp_R + f) is_differentiable_on Z & ( for x being Real st x in Z holds
((ln * (exp_R + f)) `| Z) . x = (exp_R . x) / ((exp_R . x) + 1) ) )
for y being set st y in Z holds
y in dom (exp_R + f) by A1, FUNCT_1:21;
then A3: Z c= dom (exp_R + f) by TARSKI:def 3;
then Z c= (dom exp_R ) /\ (dom f) by VALUED_1:def 1;
then A4: Z c= dom f by XBOOLE_1:18;
A5: for x being Real st x in Z holds
f . x = (0 * x) + 1 by A2;
then A6: ( f is_differentiable_on Z & ( for x being Real st x in Z holds
(f `| Z) . x = 0 ) ) by A4, FDIFF_1:31;
A7: exp_R is_differentiable_on Z by FDIFF_1:34, TAYLOR_1:16;
then A8: exp_R + f is_differentiable_on Z by A3, A6, FDIFF_1:26;
A9: for x being Real st x in Z holds
((exp_R + f) `| Z) . x = exp_R . x
proof
let x be Real; :: thesis: ( x in Z implies ((exp_R + f) `| Z) . x = exp_R . x )
assume A10: x in Z ; :: thesis: ((exp_R + f) `| Z) . x = exp_R . x
hence ((exp_R + f) `| Z) . x = (diff exp_R ,x) + (diff f,x) by A3, A6, A7, FDIFF_1:26
.= (exp_R . x) + (diff f,x) by SIN_COS:70
.= (exp_R . x) + ((f `| Z) . x) by A6, A10, FDIFF_1:def 8
.= (exp_R . x) + 0 by A4, A5, A10, FDIFF_1:31
.= exp_R . x ;
:: thesis: verum
end;
A11: for x being Real st x in Z holds
(exp_R + f) . x > 0
proof
let x be Real; :: thesis: ( x in Z implies (exp_R + f) . x > 0 )
assume A12: x in Z ; :: thesis: (exp_R + f) . x > 0
then (exp_R + f) . x = (exp_R . x) + (f . x) by A3, VALUED_1:def 1
.= (exp_R . x) + 1 by A2, A12 ;
hence (exp_R + f) . x > 0 by SIN_COS:59, XREAL_1:36; :: thesis: verum
end;
A13: for x being Real st x in Z holds
ln * (exp_R + f) is_differentiable_in x
proof
let x be Real; :: thesis: ( x in Z implies ln * (exp_R + f) is_differentiable_in x )
assume A14: x in Z ; :: thesis: ln * (exp_R + f) is_differentiable_in x
then A15: exp_R + f is_differentiable_in x by A8, FDIFF_1:16;
(exp_R + f) . x > 0 by A11, A14;
hence ln * (exp_R + f) is_differentiable_in x by A15, TAYLOR_1:20; :: thesis: verum
end;
then A16: ln * (exp_R + f) is_differentiable_on Z by A1, FDIFF_1:16;
for x being Real st x in Z holds
((ln * (exp_R + f)) `| Z) . x = (exp_R . x) / ((exp_R . x) + 1)
proof
let x be Real; :: thesis: ( x in Z implies ((ln * (exp_R + f)) `| Z) . x = (exp_R . x) / ((exp_R . x) + 1) )
assume A17: x in Z ; :: thesis: ((ln * (exp_R + f)) `| Z) . x = (exp_R . x) / ((exp_R . x) + 1)
then A18: (exp_R + f) . x = (exp_R . x) + (f . x) by A3, VALUED_1:def 1
.= (exp_R . x) + 1 by A2, A17 ;
A19: exp_R + f is_differentiable_in x by A8, A17, FDIFF_1:16;
(exp_R + f) . x > 0 by A11, A17;
then diff (ln * (exp_R + f)),x = (diff (exp_R + f),x) / ((exp_R + f) . x) by A19, TAYLOR_1:20
.= (((exp_R + f) `| Z) . x) / ((exp_R + f) . x) by A8, A17, FDIFF_1:def 8
.= (exp_R . x) / ((exp_R . x) + 1) by A9, A17, A18 ;
hence ((ln * (exp_R + f)) `| Z) . x = (exp_R . x) / ((exp_R . x) + 1) by A16, A17, FDIFF_1:def 8; :: thesis: verum
end;
hence ( ln * (exp_R + f) is_differentiable_on Z & ( for x being Real st x in Z holds
((ln * (exp_R + f)) `| Z) . x = (exp_R . x) / ((exp_R . x) + 1) ) ) by A1, A13, FDIFF_1:16; :: thesis: verum