let Z be open Subset of REAL; for f, f1 being PartFunc of REAL,REAL st Z c= dom (ln * f) & f = exp_R + (exp_R * f1) & ( for x being Real st x in Z holds
f1 . x = - x ) holds
( ln * f is_differentiable_on Z & ( for x being Real st x in Z holds
((ln * f) `| Z) . x = ((exp_R x) - (exp_R (- x))) / ((exp_R x) + (exp_R (- x))) ) )
let f, f1 be PartFunc of REAL,REAL; ( Z c= dom (ln * f) & f = exp_R + (exp_R * f1) & ( for x being Real st x in Z holds
f1 . x = - x ) implies ( ln * f is_differentiable_on Z & ( for x being Real st x in Z holds
((ln * f) `| Z) . x = ((exp_R x) - (exp_R (- x))) / ((exp_R x) + (exp_R (- x))) ) ) )
assume that
A1:
Z c= dom (ln * f)
and
A2:
f = exp_R + (exp_R * f1)
and
A3:
for x being Real st x in Z holds
f1 . x = - x
; ( ln * f is_differentiable_on Z & ( for x being Real st x in Z holds
((ln * f) `| Z) . x = ((exp_R x) - (exp_R (- x))) / ((exp_R x) + (exp_R (- x))) ) )
for y being object st y in Z holds
y in dom f
by A1, FUNCT_1:11;
then A4:
Z c= dom (exp_R + (exp_R * f1))
by A2, TARSKI:def 3;
then
Z c= (dom exp_R) /\ (dom (exp_R * f1))
by VALUED_1:def 1;
then A5:
Z c= dom (exp_R * f1)
by XBOOLE_1:18;
then A6:
exp_R * f1 is_differentiable_on Z
by A3, Th14;
A7:
exp_R is_differentiable_on Z
by FDIFF_1:26, TAYLOR_1:16;
then A8:
f is_differentiable_on Z
by A2, A4, A6, FDIFF_1:18;
A9:
for x being Real st x in Z holds
((exp_R + (exp_R * f1)) `| Z) . x = (exp_R x) - (exp_R (- x))
proof
let x be
Real;
( x in Z implies ((exp_R + (exp_R * f1)) `| Z) . x = (exp_R x) - (exp_R (- x)) )
assume A10:
x in Z
;
((exp_R + (exp_R * f1)) `| Z) . x = (exp_R x) - (exp_R (- x))
hence ((exp_R + (exp_R * f1)) `| Z) . x =
(diff (exp_R,x)) + (diff ((exp_R * f1),x))
by A4, A6, A7, FDIFF_1:18
.=
(exp_R . x) + (diff ((exp_R * f1),x))
by SIN_COS:65
.=
(exp_R . x) + (((exp_R * f1) `| Z) . x)
by A6, A10, FDIFF_1:def 7
.=
(exp_R . x) + (- (exp_R (- x)))
by A3, A5, A10, Th14
.=
(exp_R x) + (- (exp_R (- x)))
by SIN_COS:def 23
.=
(exp_R x) - (exp_R (- x))
;
verum
end;
A11:
for x being Real st x in Z holds
(exp_R + (exp_R * f1)) . x > 0
A14:
for x being Real st x in Z holds
ln * f is_differentiable_in x
then A15:
ln * f is_differentiable_on Z
by A1, FDIFF_1:9;
for x being Real st x in Z holds
((ln * f) `| Z) . x = ((exp_R x) - (exp_R (- x))) / ((exp_R x) + (exp_R (- x)))
proof
let x be
Real;
( x in Z implies ((ln * f) `| Z) . x = ((exp_R x) - (exp_R (- x))) / ((exp_R x) + (exp_R (- x))) )
assume A16:
x in Z
;
((ln * f) `| Z) . x = ((exp_R x) - (exp_R (- x))) / ((exp_R x) + (exp_R (- x)))
then A17:
f . x =
(exp_R . x) + ((exp_R * f1) . x)
by A2, A4, VALUED_1:def 1
.=
(exp_R . x) + (exp_R . (f1 . x))
by A5, A16, FUNCT_1:12
.=
(exp_R . x) + (exp_R . (- x))
by A3, A16
.=
(exp_R x) + (exp_R . (- x))
by SIN_COS:def 23
.=
(exp_R x) + (exp_R (- x))
by SIN_COS:def 23
;
(
f is_differentiable_in x &
f . x > 0 )
by A2, A8, A11, A16, FDIFF_1:9;
then diff (
(ln * f),
x) =
(diff (f,x)) / (f . x)
by TAYLOR_1:20
.=
((f `| Z) . x) / (f . x)
by A8, A16, FDIFF_1:def 7
.=
((exp_R x) - (exp_R (- x))) / ((exp_R x) + (exp_R (- x)))
by A2, A9, A16, A17
;
hence
((ln * f) `| Z) . x = ((exp_R x) - (exp_R (- x))) / ((exp_R x) + (exp_R (- x)))
by A15, A16, FDIFF_1:def 7;
verum
end;
hence
( ln * f is_differentiable_on Z & ( for x being Real st x in Z holds
((ln * f) `| Z) . x = ((exp_R x) - (exp_R (- x))) / ((exp_R x) + (exp_R (- x))) ) )
by A1, A14, FDIFF_1:9; verum