then p = (0. (TOP-REAL 2)) + (1 * ((G * 1,1) - |[1,0 ]|)) by A2, EUCLID:33
.= 1 * ((G * 1,1) - |[1,0 ]|) by EUCLID:31
.= (G * 1,1) - |[1,0 ]| by EUCLID:33 ;
hence p in {((G * 1,1) - |[1,0 ]|)} by TARSKI:def 1; :: thesis: verum

then 1 - r > 0 by XREAL_1:52;
then (G * 1,1) `2 < ((G * 1,1) `2 ) + (1 - r) by XREAL_1:31;
then A4: ((G * 1,1) `2 ) - (1 - r) < (G * 1,1) `2 by XREAL_1:21;
A5: G * 1,1 = |[((G * 1,1) `1 ),((G * 1,1) `2 )]| by EUCLID:57;
(G * 1,1) `1 < ((G * 1,1) `1 ) + 1 by XREAL_1:31;
then A6: ((G * 1,1) `1 ) - 1 < (G * 1,1) `1 by XREAL_1:21;
A7: Int (cell G,0 ,0 ) = { |[r9,s9]| where r9, s9 is Real : ( r9 < (G * 1,1) `1 & s9 < (G * 1,1) `2 ) } by Th21;
p = (((1 - r) * (G * 1,1)) - ((1 - r) * |[1,1]|)) + (r * ((G * 1,1) - |[1,0 ]|)) by A2, EUCLID:53
.= (((1 - r) * (G * 1,1)) - ((1 - r) * |[1,1]|)) + ((r * (G * 1,1)) - (r * |[1,0 ]|)) by EUCLID:53
.= ((r * (G * 1,1)) + (((1 - r) * (G * 1,1)) - ((1 - r) * |[1,1]|))) - (r * |[1,0 ]|) by EUCLID:49
.= (((r * (G * 1,1)) + ((1 - r) * (G * 1,1))) - ((1 - r) * |[1,1]|)) - (r * |[1,0 ]|) by EUCLID:49
.= (((r + (1 - r)) * (G * 1,1)) - ((1 - r) * |[1,1]|)) - (r * |[1,0 ]|) by EUCLID:37
.= ((G * 1,1) - ((1 - r) * |[1,1]|)) - (r * |[1,0 ]|) by EUCLID:33
.= ((G * 1,1) - |[((1 - r) * 1),((1 - r) * 1)]|) - (r * |[1,0 ]|) by EUCLID:62
.= ((G * 1,1) - |[(1 - r),(1 - r)]|) - |[(r * 1),(r * 0 )]| by EUCLID:62
.= |[(((G * 1,1) `1 ) - (1 - r)),(((G * 1,1) `2 ) - (1 - r))]| - |[r,0 ]| by A5, EUCLID:66
.= |[((((G * 1,1) `1 ) - (1 - r)) - r),((((G * 1,1) `2 ) - (1 - r)) - 0 )]| by EUCLID:66
.= |[(((G * 1,1) `1 ) - 1),(((G * 1,1) `2 ) - (1 - r))]| ;
hence p in Int (cell G,0 ,0 ) by A4, A6, A7; :: thesis: verum