let C be connected compact non horizontal non vertical Subset of (TOP-REAL 2); :: thesis: for j, n being Element of NAT st j <= width (Gauge (C,n)) holds
cell ((Gauge (C,n)),0,j) c= UBD C
let j, n be Element of NAT ; :: thesis: ( j <= width (Gauge (C,n)) implies cell ((Gauge (C,n)),0,j) c= UBD C )
assume A1: j <= width (Gauge (C,n)) ; :: thesis: cell ((Gauge (C,n)),0,j) c= UBD C
A2: not C ` is empty by JORDAN2C:65, JORDAN2C:66;
A3: len (Gauge (C,n)) = width (Gauge (C,n)) by JORDAN8:def 1;
then A4: not cell ((Gauge (C,n)),0,j) is empty by A1, JORDAN1A:24;
cell ((Gauge (C,n)),0,j) misses C by A3, A1, JORDAN8:18;
then A5: cell ((Gauge (C,n)),0,j) c= C ` by SUBSET_1:23;
cell ((Gauge (C,n)),0,j) is connected by A3, A1, JORDAN1A:25;
then consider W being Subset of (TOP-REAL 2) such that
A6: W is_a_component_of C ` and
A7: cell ((Gauge (C,n)),0,j) c= W by A5, A2, A4, GOBOARD9:3;
not W is Bounded by A1, A7, Th36, JORDAN2C:12;
then W is_outside_component_of C by A6, JORDAN2C:def 3;
then W c= UBD C by JORDAN2C:23;
hence cell ((Gauge (C,n)),0,j) c= UBD C by A7, XBOOLE_1:1; :: thesis: verum