for M being non empty MetrSpace
for S being non empty compact TopSpace
for T being NormedLinearTopSpace st S = TopSpaceMetr M & T is complete & T is finite-dimensional & dim T <> 0 holds
for G being Subset of (Funcs ( the carrier of M, the carrier of T))
for H being non empty Subset of (MetricSpaceNorm (R_NormSpace_of_ContinuousFunctions (S,T))) st G = H holds
( (MetricSpaceNorm (R_NormSpace_of_ContinuousFunctions (S,T))) | H is totally_bounded iff ( G is equibounded & G is equicontinuous ) )