let r be Real; :: thesis: ( 1 <= r & r <= sqrt 2 implies ( sin . (arcsec1 r) = (sqrt ((r ^2) - 1)) / r & cos . (arcsec1 r) = 1 / r ) )
set x = arcsec1 r;
assume that
A1: 1 <= r and
A2: r <= sqrt 2 ; :: thesis: ( sin . (arcsec1 r) = (sqrt ((r ^2) - 1)) / r & cos . (arcsec1 r) = 1 / r )
r in [.1,(sqrt 2).] by A1, A2;
then A3: arcsec1 r in dom (sec | [.0,(PI / 4).]) by Lm29, Th85;
PI / 4 < PI / 1 by XREAL_1:76;
then ( 0 in [.0,PI.] & PI / 4 in [.0,PI.] ) ;
then [.0,(PI / 4).] c= [.0,PI.] by XXREAL_2:def 12;
then A4: sin . (arcsec1 r) >= 0 by A3, Lm29, COMPTRIG:8;
A5: dom (sec | [.0,(PI / 4).]) c= dom sec by RELAT_1:60;
A6: r = (cos ^) . (arcsec1 r) by A1, A2, Th89
.= 1 / (cos . (arcsec1 r)) by A3, A5, RFUNCT_1:def 2 ;
r ^2 >= 1 ^2 by A1, SQUARE_1:15;
then A7: (r ^2) - 1 >= 0 by XREAL_1:48;
((sin . (arcsec1 r)) ^2) + ((cos . (arcsec1 r)) ^2) = 1 by SIN_COS:28;
then (sin . (arcsec1 r)) ^2 = 1 - ((cos . (arcsec1 r)) ^2)
.= 1 - ((1 / r) * (1 / r)) by A6
.= 1 - (1 / (r ^2)) by XCMPLX_1:102
.= ((r ^2) / (r ^2)) - (1 / (r ^2)) by A1, XCMPLX_1:60
.= ((r ^2) - 1) / (r ^2) ;
then sin . (arcsec1 r) = sqrt (((r ^2) - 1) / (r ^2)) by A4, SQUARE_1:def 2
.= (sqrt ((r ^2) - 1)) / (sqrt (r ^2)) by A1, A7, SQUARE_1:30
.= (sqrt ((r ^2) - 1)) / r by A1, SQUARE_1:22 ;
hence ( sin . (arcsec1 r) = (sqrt ((r ^2) - 1)) / r & cos . (arcsec1 r) = 1 / r ) by A6; :: thesis: verum