let p be Point of (TOP-REAL 2); :: thesis:
let f be constant standard clockwise_oriented special_circular_sequence; :: thesis:
set g = Rotate (f,(N-min (L~ f)));
A1: L~ f = L~ (Rotate (f,(N-min (L~ f)))) by REVROT_1:33;
reconsider u = p as Point of (Euclid 2) by EUCLID:22;
assume p in RightComp f ; :: thesis:
then p in RightComp (Rotate (f,(N-min (L~ f)))) by REVROT_1:37;
then u in Int (RightComp (Rotate (f,(N-min (L~ f))))) by TOPS_1:23;
then consider r being Real such that
A2: r > 0 and
A3: Ball (u,r) c= RightComp (Rotate (f,(N-min (L~ f)))) by GOBOARD6:5;
reconsider r = r as Real ;
reconsider k = |[(p `1),((p `2) - (r / 2))]| as Point of (Euclid 2) by EUCLID:22;
dist (u,k) = (Pitag_dist 2) . (u,k) by METRIC_1:def 1
.= sqrt ((((p `1) - (|[(p `1),((p `2) - (r / 2))]| `1)) ^2) + (((p `2) - (|[(p `1),((p `2) - (r / 2))]| `2)) ^2)) by TOPREAL3:7
.= sqrt ((((p `1) - (p `1)) ^2) + (((p `2) - (|[(p `1),((p `2) - (r / 2))]| `2)) ^2))
.= sqrt (((p `2) - ((p `2) - (r / 2))) ^2)
.= r / 2 by A2, SQUARE_1:22 ;
then dist (u,k) < r / 1 by A2, XREAL_1:76;
then A4: k in Ball (u,r) by METRIC_1:11;
RightComp (Rotate (f,(N-min (L~ f)))) misses LeftComp (Rotate (f,(N-min (L~ f)))) by Th14;
then A5: not |[(p `1),((p `2) - (r / 2))]| in LeftComp (Rotate (f,(N-min (L~ f)))) by A3, A4, XBOOLE_0:3;
set x = |[(E-bound (L~ (SpStSeq (L~ (Rotate (f,(N-min (L~ f)))))))),((p `2) - (r / 2))]|;
A6: LSeg ((SE-corner (L~ (Rotate (f,(N-min (L~ f)))))),(NE-corner (L~ (Rotate (f,(N-min (L~ f))))))) c= L~ (SpStSeq (L~ (Rotate (f,(N-min (L~ f)))))) by TOPREAL6:35;
A7: proj2 . |[(E-bound (L~ (SpStSeq (L~ (Rotate (f,(N-min (L~ f)))))))),((p `2) - (r / 2))]| = |[(E-bound (L~ (SpStSeq (L~ (Rotate (f,(N-min (L~ f)))))))),((p `2) - (r / 2))]| `2 by PSCOMP_1:def 6
.= (p `2) - (r / 2) ;
N-min (L~ f) in rng f by SPRECT_2:39;
then A8: (Rotate (f,(N-min (L~ f)))) /. 1 = N-min (L~ (Rotate (f,(N-min (L~ f))))) by A1, FINSEQ_6:92;
then |[(p `1),((p `2) - (r / 2))]| `2 <= N-bound (L~ (Rotate (f,(N-min (L~ f))))) by A5, JORDAN2C:113;
then (p `2) - (r / 2) <= N-bound (L~ (Rotate (f,(N-min (L~ f))))) ;
then A9: |[(E-bound (L~ (SpStSeq (L~ (Rotate (f,(N-min (L~ f)))))))),((p `2) - (r / 2))]| `2 <= N-bound (L~ (Rotate (f,(N-min (L~ f))))) ;
A10: |[(E-bound (L~ (SpStSeq (L~ (Rotate (f,(N-min (L~ f)))))))),((p `2) - (r / 2))]| `1 = E-bound (L~ (Rotate (f,(N-min (L~ f))))) by SPRECT_1:61;
|[(p `1),((p `2) - (r / 2))]| `2 >= S-bound (L~ (Rotate (f,(N-min (L~ f))))) by A8, A5, JORDAN2C:112;
then (p `2) - (r / 2) >= S-bound (L~ (Rotate (f,(N-min (L~ f))))) ;
then A11: |[(E-bound (L~ (SpStSeq (L~ (Rotate (f,(N-min (L~ f)))))))),((p `2) - (r / 2))]| `2 >= S-bound (L~ (Rotate (f,(N-min (L~ f))))) ;
LSeg ((SE-corner (L~ (Rotate (f,(N-min (L~ f)))))),(NE-corner (L~ (Rotate (f,(N-min (L~ f))))))) = { q where q is Point of (TOP-REAL 2) : ( q `1 = E-bound (L~ (Rotate (f,(N-min (L~ f))))) & q `2 <= N-bound (L~ (Rotate (f,(N-min (L~ f))))) & q `2 >= S-bound (L~ (Rotate (f,(N-min (L~ f))))) ) } by SPRECT_1:23;
then |[(E-bound (L~ (SpStSeq (L~ (Rotate (f,(N-min (L~ f)))))))),((p `2) - (r / 2))]| in LSeg ((SE-corner (L~ (Rotate (f,(N-min (L~ f)))))),(NE-corner (L~ (Rotate (f,(N-min (L~ f))))))) by A9, A11, A10;
then ( proj2 .: (L~ (SpStSeq (L~ (Rotate (f,(N-min (L~ f))))))) is bounded_below & (p `2) - (r / 2) in proj2 .: (L~ (SpStSeq (L~ (Rotate (f,(N-min (L~ f))))))) ) by A6, A7, FUNCT_2:35;
then A12: lower_bound (proj2 .: (L~ (SpStSeq (L~ (Rotate (f,(N-min (L~ f)))))))) <= (p `2) - (r / 2) by SEQ_4:def 2;
r / 2 > 0 by A2, XREAL_1:139;
then A13: (p `2) - (r / 2) < (p `2) - 0 by XREAL_1:15;
( S-bound (L~ (SpStSeq (L~ (Rotate (f,(N-min (L~ f))))))) = S-bound (L~ (Rotate (f,(N-min (L~ f))))) & S-bound (L~ (SpStSeq (L~ (Rotate (f,(N-min (L~ f))))))) = lower_bound (proj2 .: (L~ (SpStSeq (L~ (Rotate (f,(N-min (L~ f)))))))) ) by SPRECT_1:44, SPRECT_1:59;
hence S-bound (L~ f) < p `2 by A1, A12, A13, XXREAL_0:2; :: thesis: