let Z be open Subset of REAL; :: thesis:
assume B1: ( Z c= dom ((#Z 2) * arccot) & Z c= ].(- 1),1.[ ) ; :: thesis:
then A2: Z c= dom ((1 / 2) (#) ((#Z 2) * arccot)) by VALUED_1:def 5;
then A1: Z c= dom (- ((1 / 2) (#) ((#Z 2) * arccot))) by VALUED_1:8;
A3: (1 / 2) (#) ((#Z 2) * arccot) is_differentiable_on Z by A2, B1, SIN_COS9:94;
then A4: (- 1) (#) ((1 / 2) (#) ((#Z 2) * arccot)) is_differentiable_on Z by A1, FDIFF_1:28, A;
A6: ( (#Z 2) * arccot is_differentiable_on Z & ( for x being Real st x in Z holds
(((#Z 2) * arccot) `| Z) . x = - ((2 * ((arccot . x) #Z (2 - 1))) / (1 + (x ^2))) ) ) by B1, SIN_COS9:92;
for x being Real st x in Z holds
((- ((1 / 2) (#) ((#Z 2) * arccot))) `| Z) . x = (arccot . x) / (1 + (x ^2))

proof

let x be Real; :: thesis:
assume A7: x in Z ; :: thesis:
then A8: (1 / 2) (#) ((#Z 2) * arccot) is_differentiable_in x by A3, FDIFF_1:16;
A9: (#Z 2) * arccot is_differentiable_in x by A6, A7, FDIFF_1:16;
((- ((1 / 2) (#) ((#Z 2) * arccot))) `| Z) . x = diff ((- ((1 / 2) (#) ((#Z 2) * arccot))),x) by A4, A7, FDIFF_1:def 8
.= (- 1) * (diff (((1 / 2) (#) ((#Z 2) * arccot)),x)) by A8, FDIFF_1:23, A
.= (- 1) * ((1 / 2) * (diff (((#Z 2) * arccot),x))) by A9, FDIFF_1:23, A
.= (- 1) * ((1 / 2) * ((((#Z 2) * arccot) `| Z) . x)) by A6, A7, FDIFF_1:def 8
.= (- 1) * ((1 / 2) * (- ((2 * ((arccot . x) #Z (2 - 1))) / (1 + (x ^2))))) by B1, A7, SIN_COS9:92
.= (- 1) * (- ((1 / 2) * ((2 * ((arccot . x) #Z 1)) / (1 + (x ^2)))))
.= (- 1) * (- ((1 / 2) * ((2 * (arccot . x)) / (1 + (x ^2))))) by PREPOWER:45
.= (arccot . x) / (1 + (x ^2)) ;
hence ((- ((1 / 2) (#) ((#Z 2) * arccot))) `| Z) . x = (arccot . x) / (1 + (x ^2)) ; :: thesis:

end;

hence ( - ((1 / 2) (#) ((#Z 2) * arccot)) is_differentiable_on Z & ( for x being Real st x in Z holds
((- ((1 / 2) (#) ((#Z 2) * arccot))) `| Z) . x = (arccot . x) / (1 + (x ^2)) ) ) by A1, A3, FDIFF_1:28, A; :: thesis: