let f be PartFunc of REAL,REAL; :: thesis: for x0 being Real st f is_right_differentiable_in x0 & ex r0 being Real st
( r0 > 0 & ( for g being Real st g in dom f & g in [.x0,(x0 + r0).] holds
f . g <> 0 ) ) holds
( f ^ is_right_differentiable_in x0 & Rdiff ((f ^),x0) = - ((Rdiff (f,x0)) / ((f . x0) ^2)) )
let x0 be Real; :: thesis: ( f is_right_differentiable_in x0 & ex r0 being Real st
( r0 > 0 & ( for g being Real st g in dom f & g in [.x0,(x0 + r0).] holds
f . g <> 0 ) ) implies ( f ^ is_right_differentiable_in x0 & Rdiff ((f ^),x0) = - ((Rdiff (f,x0)) / ((f . x0) ^2)) ) )
A1: 0 + x0 = x0 ;
assume A2: f is_right_differentiable_in x0 ; :: thesis: ( for r0 being Real holds
( not r0 > 0 or ex g being Real st
( g in dom f & g in [.x0,(x0 + r0).] & not f . g <> 0 ) ) or ( f ^ is_right_differentiable_in x0 & Rdiff ((f ^),x0) = - ((Rdiff (f,x0)) / ((f . x0) ^2)) ) )
then consider r2 being Real such that
A3: 0 < r2 and
A4: [.x0,(x0 + r2).] c= dom f by Def3;
given r0 being Real such that A5: r0 > 0 and
A6: for g being Real st g in dom f & g in [.x0,(x0 + r0).] holds
f . g <> 0 ; :: thesis: ( f ^ is_right_differentiable_in x0 & Rdiff ((f ^),x0) = - ((Rdiff (f,x0)) / ((f . x0) ^2)) )
set r3 = min (r0,r2);
0 <= min (r0,r2) by A5, A3, XXREAL_0:15;
then A7: x0 <= x0 + (min (r0,r2)) by A1, XREAL_1:8;
min (r0,r2) <= r2 by XXREAL_0:17;
then A8: x0 + (min (r0,r2)) <= x0 + r2 by XREAL_1:9;
then x0 <= x0 + r2 by A7, XXREAL_0:2;
then A9: x0 in [.x0,(x0 + r2).] by XXREAL_1:1;
x0 + (min (r0,r2)) in { g where g is Real : ( x0 <= g & g <= x0 + r2 ) } by A7, A8;
then x0 + (min (r0,r2)) in [.x0,(x0 + r2).] by RCOMP_1:def 1;
then [.x0,(x0 + (min (r0,r2))).] c= [.x0,(x0 + r2).] by A9, XXREAL_2:def 12;
then A10: [.x0,(x0 + (min (r0,r2))).] c= dom f by A4, XBOOLE_1:1;
min (r0,r2) <= r0 by XXREAL_0:17;
then A11: x0 + (min (r0,r2)) <= x0 + r0 by XREAL_1:9;
then x0 <= x0 + r0 by A7, XXREAL_0:2;
then A12: x0 in [.x0,(x0 + r0).] by XXREAL_1:1;
x0 + (min (r0,r2)) in { g where g is Real : ( x0 <= g & g <= x0 + r0 ) } by A7, A11;
then x0 + (min (r0,r2)) in [.x0,(x0 + r0).] by RCOMP_1:def 1;
then A13: [.x0,(x0 + (min (r0,r2))).] c= [.x0,(x0 + r0).] by A12, XXREAL_2:def 12;
A14: [.x0,(x0 + (min (r0,r2))).] c= dom (f ^)
proof
assume not [.x0,(x0 + (min (r0,r2))).] c= dom (f ^) ; :: thesis: contradiction
then consider x being set such that
A15: x in [.x0,(x0 + (min (r0,r2))).] and
A16: not x in dom (f ^) by TARSKI:def 3;
reconsider x = x as Real by A15;
A17: not x in (dom f) \ (f " {0}) by A16, RFUNCT_1:def 8;
now
end;
hence contradiction ; :: thesis: verum
end;
A20: x0 in [.x0,(x0 + (min (r0,r2))).] by A7, XXREAL_1:1;
A21: for h being convergent_to_0 Real_Sequence
for c being V8() Real_Sequence st rng c = {x0} & rng (h + c) c= dom (f ^) & ( for n being Element of NAT holds h . n > 0 ) holds
( (h ") (#) (((f ^) /* (h + c)) - ((f ^) /* c)) is convergent & lim ((h ") (#) (((f ^) /* (h + c)) - ((f ^) /* c))) = - ((Rdiff (f,x0)) / ((f . x0) ^2)) )
proof
let h be convergent_to_0 Real_Sequence; :: thesis: for c being V8() Real_Sequence st rng c = {x0} & rng (h + c) c= dom (f ^) & ( for n being Element of NAT holds h . n > 0 ) holds
( (h ") (#) (((f ^) /* (h + c)) - ((f ^) /* c)) is convergent & lim ((h ") (#) (((f ^) /* (h + c)) - ((f ^) /* c))) = - ((Rdiff (f,x0)) / ((f . x0) ^2)) )
let c be V8() Real_Sequence; :: thesis: ( rng c = {x0} & rng (h + c) c= dom (f ^) & ( for n being Element of NAT holds h . n > 0 ) implies ( (h ") (#) (((f ^) /* (h + c)) - ((f ^) /* c)) is convergent & lim ((h ") (#) (((f ^) /* (h + c)) - ((f ^) /* c))) = - ((Rdiff (f,x0)) / ((f . x0) ^2)) ) )
assume that
A22: rng c = {x0} and
A23: rng (h + c) c= dom (f ^) and
A24: for n being Element of NAT holds h . n > 0 ; :: thesis: ( (h ") (#) (((f ^) /* (h + c)) - ((f ^) /* c)) is convergent & lim ((h ") (#) (((f ^) /* (h + c)) - ((f ^) /* c))) = - ((Rdiff (f,x0)) / ((f . x0) ^2)) )
A25: lim h = 0 by FDIFF_1:def 1;
A26: for m being Element of NAT holds c . m = x0
proof
let m be Element of NAT ; :: thesis: c . m = x0
c . m in rng c by VALUED_0:28;
hence c . m = x0 by A22, TARSKI:def 1; :: thesis: verum
end;
A27: (dom f) \ (f " {0}) c= dom f by XBOOLE_1:36;
rng (h + c) c= (dom f) \ (f " {0}) by A23, RFUNCT_1:def 8;
then A28: rng (h + c) c= dom f by A27, XBOOLE_1:1;
then A29: lim ((h ") (#) ((f /* (h + c)) - (f /* c))) = Rdiff (f,x0) by A2, A22, A24, Th15;
Rdiff (f,x0) = Rdiff (f,x0) ;
then A30: (h ") (#) ((f /* (h + c)) - (f /* c)) is convergent by A2, A22, A24, A28, Th15;
then A31: - ((h ") (#) ((f /* (h + c)) - (f /* c))) is convergent by SEQ_2:23;
x0 in dom (f ^) by A20, A14;
then A32: x0 in (dom f) \ (f " {0}) by RFUNCT_1:def 8;
rng c c= (dom f) \ (f " {0})
proof
let x be set ; :: according to TARSKI:def 3 :: thesis: ( not x in rng c or x in (dom f) \ (f " {0}) )
assume x in rng c ; :: thesis: x in (dom f) \ (f " {0})
hence x in (dom f) \ (f " {0}) by A22, A32, TARSKI:def 1; :: thesis: verum
end;
then A33: rng c c= dom (f ^) by RFUNCT_1:def 8;
then A34: f /* c is non-zero by RFUNCT_2:26;
now
let n be Element of NAT ; :: thesis: (h (#) ((h ") (#) ((f /* (h + c)) - (f /* c)))) . n = ((f /* (h + c)) - (f /* c)) . n
A35: h . n <> 0 by A24;
thus (h (#) ((h ") (#) ((f /* (h + c)) - (f /* c)))) . n = ((h (#) (h ")) (#) ((f /* (h + c)) - (f /* c))) . n by SEQ_1:22
.= ((h (#) (h ")) . n) * (((f /* (h + c)) - (f /* c)) . n) by SEQ_1:12
.= ((h . n) * ((h ") . n)) * (((f /* (h + c)) - (f /* c)) . n) by SEQ_1:12
.= ((h . n) * ((h . n) ")) * (((f /* (h + c)) - (f /* c)) . n) by VALUED_1:10
.= 1 * (((f /* (h + c)) - (f /* c)) . n) by A35, XCMPLX_0:def 7
.= ((f /* (h + c)) - (f /* c)) . n ; :: thesis: verum
end;
then A36: h (#) ((h ") (#) ((f /* (h + c)) - (f /* c))) = (f /* (h + c)) - (f /* c) by FUNCT_2:113;
A37: f /* (h + c) is non-zero by A23, RFUNCT_2:26;
then A38: (f /* (h + c)) (#) (f /* c) is non-zero by A34, SEQ_1:43;
now
let n be Element of NAT ; :: thesis: ((f /* c) + ((f /* (h + c)) - (f /* c))) . n = (f /* (h + c)) . n
thus ((f /* c) + ((f /* (h + c)) - (f /* c))) . n = ((f /* c) . n) + (((f /* (h + c)) - (f /* c)) . n) by SEQ_1:11
.= ((f /* c) . n) + (((f /* (h + c)) . n) - ((f /* c) . n)) by RFUNCT_2:6
.= (f /* (h + c)) . n ; :: thesis: verum
end;
then A39: (f /* c) + ((f /* (h + c)) - (f /* c)) = f /* (h + c) by FUNCT_2:113;
dom (f ^) = (dom f) \ (f " {0}) by RFUNCT_1:def 8;
then A40: dom (f ^) c= dom f by XBOOLE_1:36;
A41: for g being real number st 0 < g holds
ex n being Element of NAT st
for m being Element of NAT st n <= m holds
abs (((f /* c) . m) - (f . x0)) < g
proof
let g be real number ; :: thesis: ( 0 < g implies ex n being Element of NAT st
for m being Element of NAT st n <= m holds
abs (((f /* c) . m) - (f . x0)) < g )
assume A42: 0 < g ; :: thesis: ex n being Element of NAT st
for m being Element of NAT st n <= m holds
abs (((f /* c) . m) - (f . x0)) < g
take n = 0 ; :: thesis: for m being Element of NAT st n <= m holds
abs (((f /* c) . m) - (f . x0)) < g
let m be Element of NAT ; :: thesis: ( n <= m implies abs (((f /* c) . m) - (f . x0)) < g )
assume n <= m ; :: thesis: abs (((f /* c) . m) - (f . x0)) < g
abs (((f /* c) . m) - (f . x0)) = abs ((f . (c . m)) - (f . x0)) by A33, A40, FUNCT_2:185, XBOOLE_1:1
.= abs ((f . x0) - (f . x0)) by A26
.= 0 by ABSVALUE:def 1 ;
hence abs (((f /* c) . m) - (f . x0)) < g by A42; :: thesis: verum
end;
then A43: f /* c is convergent by SEQ_2:def 6;
then A44: lim (f /* c) = f . x0 by A41, SEQ_2:def 7;
A45: h is convergent by FDIFF_1:def 1;
then h (#) ((h ") (#) ((f /* (h + c)) - (f /* c))) is convergent by A30, SEQ_2:28;
then A46: f /* (h + c) is convergent by A43, A36, A39, SEQ_2:19;
lim (h (#) ((h ") (#) ((f /* (h + c)) - (f /* c)))) = (lim h) * (lim ((h ") (#) ((f /* (h + c)) - (f /* c)))) by A45, A30, SEQ_2:29
.= 0 by A25 ;
then 0 = (lim (f /* (h + c))) - (f . x0) by A43, A44, A36, A46, SEQ_2:26;
then A47: lim ((f /* (h + c)) (#) (f /* c)) = (f . x0) ^2 by A43, A44, A46, SEQ_2:29;
A48: lim ((f /* (h + c)) (#) (f /* c)) <> 0
proof
assume not lim ((f /* (h + c)) (#) (f /* c)) <> 0 ; :: thesis: contradiction
then f . x0 = 0 by A47, XCMPLX_1:6;
hence contradiction by A6, A4, A12, A9; :: thesis: verum
end;
now
let n be Element of NAT ; :: thesis: ((h ") (#) (((f ^) /* (h + c)) - ((f ^) /* c))) . n = ((- ((h ") (#) ((f /* (h + c)) - (f /* c)))) /" ((f /* (h + c)) (#) (f /* c))) . n
A49: ( (f /* (h + c)) . n <> 0 & (f /* c) . n <> 0 ) by A37, A34, SEQ_1:7;
thus ((h ") (#) (((f ^) /* (h + c)) - ((f ^) /* c))) . n = ((h ") . n) * ((((f ^) /* (h + c)) - ((f ^) /* c)) . n) by SEQ_1:12
.= ((h ") . n) * ((((f ^) /* (h + c)) . n) - (((f ^) /* c) . n)) by RFUNCT_2:6
.= ((h ") . n) * ((((f /* (h + c)) ") . n) - (((f ^) /* c) . n)) by A23, RFUNCT_2:27
.= ((h ") . n) * ((((f /* (h + c)) ") . n) - (((f /* c) ") . n)) by A33, RFUNCT_2:27
.= ((h ") . n) * ((((f /* (h + c)) . n) ") - (((f /* c) ") . n)) by VALUED_1:10
.= ((h ") . n) * ((((f /* (h + c)) . n) ") - (((f /* c) . n) ")) by VALUED_1:10
.= ((h ") . n) * ((1 / ((f /* (h + c)) . n)) - (((f /* c) . n) ")) by XCMPLX_1:217
.= ((h ") . n) * ((1 / ((f /* (h + c)) . n)) - (1 / ((f /* c) . n))) by XCMPLX_1:217
.= ((h ") . n) * (((1 * ((f /* c) . n)) - (1 * ((f /* (h + c)) . n))) / (((f /* (h + c)) . n) * ((f /* c) . n))) by A49, XCMPLX_1:131
.= ((h ") . n) * ((- (((f /* (h + c)) . n) - ((f /* c) . n))) / (((f /* (h + c)) (#) (f /* c)) . n)) by SEQ_1:12
.= ((h ") . n) * ((- (((f /* (h + c)) - (f /* c)) . n)) / (((f /* (h + c)) (#) (f /* c)) . n)) by RFUNCT_2:6
.= ((h ") . n) * (- ((((f /* (h + c)) - (f /* c)) . n) / (((f /* (h + c)) (#) (f /* c)) . n))) by XCMPLX_1:188
.= - (((h ") . n) * ((((f /* (h + c)) - (f /* c)) . n) / (((f /* (h + c)) (#) (f /* c)) . n)))
.= - ((((h ") . n) * (((f /* (h + c)) - (f /* c)) . n)) / (((f /* (h + c)) (#) (f /* c)) . n)) by XCMPLX_1:75
.= - ((((h ") (#) ((f /* (h + c)) - (f /* c))) . n) / (((f /* (h + c)) (#) (f /* c)) . n)) by SEQ_1:12
.= - ((((h ") (#) ((f /* (h + c)) - (f /* c))) . n) * ((((f /* (h + c)) (#) (f /* c)) . n) ")) by XCMPLX_0:def 9
.= - ((((h ") (#) ((f /* (h + c)) - (f /* c))) . n) * ((((f /* (h + c)) (#) (f /* c)) ") . n)) by VALUED_1:10
.= - ((((h ") (#) ((f /* (h + c)) - (f /* c))) /" ((f /* (h + c)) (#) (f /* c))) . n) by SEQ_1:12
.= (- (((h ") (#) ((f /* (h + c)) - (f /* c))) /" ((f /* (h + c)) (#) (f /* c)))) . n by SEQ_1:14
.= ((- ((h ") (#) ((f /* (h + c)) - (f /* c)))) /" ((f /* (h + c)) (#) (f /* c))) . n by SEQ_1:56 ; :: thesis: verum
end;
then A50: (h ") (#) (((f ^) /* (h + c)) - ((f ^) /* c)) = (- ((h ") (#) ((f /* (h + c)) - (f /* c)))) /" ((f /* (h + c)) (#) (f /* c)) by FUNCT_2:113;
A51: (f /* (h + c)) (#) (f /* c) is convergent by A43, A46, SEQ_2:28;
then lim ((h ") (#) (((f ^) /* (h + c)) - ((f ^) /* c))) = (lim (- ((h ") (#) ((f /* (h + c)) - (f /* c))))) / ((f . x0) ^2) by A38, A47, A48, A31, A50, SEQ_2:38
.= (- (Rdiff (f,x0))) / ((f . x0) ^2) by A30, A29, SEQ_2:24
.= - ((Rdiff (f,x0)) / ((f . x0) ^2)) by XCMPLX_1:188 ;
hence ( (h ") (#) (((f ^) /* (h + c)) - ((f ^) /* c)) is convergent & lim ((h ") (#) (((f ^) /* (h + c)) - ((f ^) /* c))) = - ((Rdiff (f,x0)) / ((f . x0) ^2)) ) by A38, A51, A48, A31, A50, SEQ_2:37; :: thesis: verum
end;
0 < min (r0,r2) by A5, A3, XXREAL_0:15;
hence ( f ^ is_right_differentiable_in x0 & Rdiff ((f ^),x0) = - ((Rdiff (f,x0)) / ((f . x0) ^2)) ) by A14, A21, Th15; :: thesis: verum