abs a >= 0 by COMPLEX1:132;
then A2: ((abs a) + (abs a)) + (abs a) >= 0 + (abs a) by XREAL_1:8;
assume W is bounded ; :: thesis: contradiction
then consider r being Real such that
A3: 0 < r and
A4: for x, y being Point of (Euclid 1) st x in W & y in W holds
dist x,y <= r by TBSP_1:def 9;
A5: (r + (abs a)) * (1.REAL 1) = (r + (abs a)) * <*1*> by EUCLID:69, FINSEQ_2:73
.= <*((r + (abs a)) * 1)*> by RVSUM_1:69 ;
then reconsider z2 = (r + (abs a)) * (1.REAL 1) as Point of (Euclid 1) by FINSEQ_2:151;
( a <= abs a & 0 + (abs a) < r + (abs a) ) by A3, ABSVALUE:11, XREAL_1:8;
then a < r + (abs a) by XXREAL_0:2;
then A6: (r + (abs a)) * (1.REAL 1) in W by A1, A5;
A7: (3 * (r + (abs a))) * (1.REAL 1) = (3 * (r + (abs a))) * <*1*> by EUCLID:69, FINSEQ_2:73
.= <*((3 * (r + (abs a))) * 1)*> by RVSUM_1:69 ;
then reconsider z1 = (3 * (r + (abs a))) * (1.REAL 1) as Point of (Euclid 1) by FINSEQ_2:151;
dist z1,z2 = |.(((3 * (r + (abs a))) * (1.REAL 1)) - ((r + (abs a)) * (1.REAL 1))).| by JGRAPH_1:45
.= |.(((((r + (abs a)) + (r + (abs a))) + (r + (abs a))) - (r + (abs a))) * (1.REAL 1)).| by EUCLID:54
.= (abs ((r + (abs a)) + (r + (abs a)))) * |.(1.REAL 1).| by TOPRNS_1:8
.= (abs ((r + (abs a)) + (r + (abs a)))) * (sqrt 1) by Th35 ;
then A8: (r + (abs a)) + (r + (abs a)) <= dist z1,z2 by ABSVALUE:11, SQUARE_1:83;
A9: 0 <= abs a by COMPLEX1:132;
then (r + (abs a)) + 0 < (r + (abs a)) + (r + (abs a)) by A3, XREAL_1:8;
then A10: r + (abs a) < dist z1,z2 by A8, XXREAL_0:2;
r + 0 <= r + (abs a) by A9, XREAL_1:8;
then A11: r < dist z1,z2 by A10, XXREAL_0:2;
3 * r > 0 by A3, XREAL_1:131;
then ( a <= abs a & 0 + (abs a) < (3 * r) + (3 * (abs a)) ) by A2, ABSVALUE:11, XREAL_1:10;
then a < 3 * (r + (abs a)) by XXREAL_0:2;
then (3 * (r + (abs a))) * (1.REAL 1) in W by A1, A7;
hence contradiction by A4, A6, A11; :: thesis: verum