let n be Element of NAT ; :: thesis: for C being Simple_closed_curve
for i, j, k being Element of NAT st 1 < j & j <= k & k < len (Gauge C,n) & 1 <= i & i <= width (Gauge C,n) & n > 0 & (Gauge C,n) * k,i in Upper_Arc (L~ (Cage C,n)) & (Gauge C,n) * j,i in Lower_Arc (L~ (Cage C,n)) holds
LSeg ((Gauge C,n) * j,i),((Gauge C,n) * k,i) meets Upper_Arc C
let C be Simple_closed_curve; :: thesis: for i, j, k being Element of NAT st 1 < j & j <= k & k < len (Gauge C,n) & 1 <= i & i <= width (Gauge C,n) & n > 0 & (Gauge C,n) * k,i in Upper_Arc (L~ (Cage C,n)) & (Gauge C,n) * j,i in Lower_Arc (L~ (Cage C,n)) holds
LSeg ((Gauge C,n) * j,i),((Gauge C,n) * k,i) meets Upper_Arc C
let i, j, k be Element of NAT ; :: thesis: ( 1 < j & j <= k & k < len (Gauge C,n) & 1 <= i & i <= width (Gauge C,n) & n > 0 & (Gauge C,n) * k,i in Upper_Arc (L~ (Cage C,n)) & (Gauge C,n) * j,i in Lower_Arc (L~ (Cage C,n)) implies LSeg ((Gauge C,n) * j,i),((Gauge C,n) * k,i) meets Upper_Arc C )
assume that
A1: 1 < j and
A2: j <= k and
A3: k < len (Gauge C,n) and
A4: 1 <= i and
A5: i <= width (Gauge C,n) and
A6: n > 0 and
A7: (Gauge C,n) * k,i in Upper_Arc (L~ (Cage C,n)) and
A8: (Gauge C,n) * j,i in Lower_Arc (L~ (Cage C,n)) ; :: thesis: LSeg ((Gauge C,n) * j,i),((Gauge C,n) * k,i) meets Upper_Arc C
A9: L~ (Lower_Seq C,n) = Lower_Arc (L~ (Cage C,n)) by A6, JORDAN1G:64;
L~ (Upper_Seq C,n) = Upper_Arc (L~ (Cage C,n)) by A6, JORDAN1G:63;
hence LSeg ((Gauge C,n) * j,i),((Gauge C,n) * k,i) meets Upper_Arc C by A1, A2, A3, A4, A5, A7, A8, A9, Th33; :: thesis: verum