let k be Nat; :: thesis: cosec is (2 * PI ) * (k + 1) -periodic
defpred S1[ Nat] means cosec is (2 * PI ) * ($1 + 1) -periodic ;
A1: S1[ 0 ] by L3;
A2: for k being Nat st S1[k] holds
S1[k + 1]
proof
let k be Nat; :: thesis: ( S1[k] implies S1[k + 1] )
assume A3: cosec is (2 * PI ) * (k + 1) -periodic ; :: thesis: S1[k + 1]
cosec is (2 * PI ) * ((k + 1) + 1) -periodic
proof
for x being real number st x in dom cosec holds
( x + ((2 * PI ) * ((k + 1) + 1)) in dom cosec & x - ((2 * PI ) * ((k + 1) + 1)) in dom cosec & cosec . x = cosec . (x + ((2 * PI ) * ((k + 1) + 1))) )
proof
let x be real number ; :: thesis: ( x in dom cosec implies ( x + ((2 * PI ) * ((k + 1) + 1)) in dom cosec & x - ((2 * PI ) * ((k + 1) + 1)) in dom cosec & cosec . x = cosec . (x + ((2 * PI ) * ((k + 1) + 1))) ) )
assume x in dom cosec ; :: thesis: ( x + ((2 * PI ) * ((k + 1) + 1)) in dom cosec & x - ((2 * PI ) * ((k + 1) + 1)) in dom cosec & cosec . x = cosec . (x + ((2 * PI ) * ((k + 1) + 1))) )
then A9: ( x + ((2 * PI ) * (k + 1)) in dom cosec & x - ((2 * PI ) * (k + 1)) in dom cosec & cosec . x = cosec . (x + ((2 * PI ) * (k + 1))) ) by A3, Th1;
then ( x + ((2 * PI ) * (k + 1)) in (dom sin ) \ (sin " {0 }) & x - ((2 * PI ) * (k + 1)) in (dom sin ) \ (sin " {0 }) ) by RFUNCT_1:def 8;
then ( x + ((2 * PI ) * (k + 1)) in dom sin & not x + ((2 * PI ) * (k + 1)) in sin " {0 } & x - ((2 * PI ) * (k + 1)) in dom sin & not x - ((2 * PI ) * (k + 1)) in sin " {0 } ) by XBOOLE_0:def 5;
then B2: ( not sin . (x + ((2 * PI ) * (k + 1))) in {0 } & not sin . (x - ((2 * PI ) * (k + 1))) in {0 } ) by FUNCT_1:def 13;
then sin . (x + ((2 * PI ) * (k + 1))) <> 0 by TARSKI:def 1;
then sin . ((x + ((2 * PI ) * (k + 1))) + (2 * PI )) <> 0 by SIN_COS:83;
then not sin . ((x + ((2 * PI ) * (k + 1))) + (2 * PI )) in {0 } by TARSKI:def 1;
then ( (x + ((2 * PI ) * (k + 1))) + (2 * PI ) in dom sin & not (x + ((2 * PI ) * (k + 1))) + (2 * PI ) in sin " {0 } ) by FUNCT_1:def 13, SIN_COS:27;
then B3: x + ((2 * PI ) * ((k + 1) + 1)) in (dom sin ) \ (sin " {0 }) by XBOOLE_0:def 5;
sin . (x - ((2 * PI ) * ((k + 1) + 1))) = sin . ((x - ((2 * PI ) * ((k + 1) + 1))) + (2 * PI )) by L1, Th1, SIN_COS:27;
then ( x - ((2 * PI ) * ((k + 1) + 1)) in dom sin & not x - ((2 * PI ) * ((k + 1) + 1)) in sin " {0 } ) by B2, FUNCT_1:def 13, SIN_COS:27;
then B4: x - ((2 * PI ) * ((k + 1) + 1)) in (dom sin ) \ (sin " {0 }) by XBOOLE_0:def 5;
then B5: ( x + ((2 * PI ) * ((k + 1) + 1)) in dom cosec & x - ((2 * PI ) * ((k + 1) + 1)) in dom cosec ) by B3, RFUNCT_1:def 8;
cosec . (x + ((2 * PI ) * ((k + 1) + 1))) = (sin . ((x + ((2 * PI ) * (k + 1))) + (2 * PI ))) " by B5, RFUNCT_1:def 8
.= (sin . (x + ((2 * PI ) * (k + 1)))) " by SIN_COS:83
.= cosec . x by A9, RFUNCT_1:def 8 ;
hence ( x + ((2 * PI ) * ((k + 1) + 1)) in dom cosec & x - ((2 * PI ) * ((k + 1) + 1)) in dom cosec & cosec . x = cosec . (x + ((2 * PI ) * ((k + 1) + 1))) ) by B3, RFUNCT_1:def 8, B4; :: thesis: verum
end;
hence cosec is (2 * PI ) * ((k + 1) + 1) -periodic by Th1; :: thesis: verum
end;
hence S1[k + 1] ; :: thesis: verum
end;
for n being Nat holds S1[n] from NAT_1:sch 2(A1, A2);
 hence cosec is (2 * PI ) * (k + 1) -periodic ; :: thesis: verum