let X be ComplexNormSpace; :: thesis: for seq1, seq2 being sequence of X st seq1 is summable & seq2 is summable holds
( seq1 - seq2 is summable & Sum (seq1 - seq2) = (Sum seq1) - (Sum seq2) )
let seq1, seq2 be sequence of X; :: thesis: ( seq1 is summable & seq2 is summable implies ( seq1 - seq2 is summable & Sum (seq1 - seq2) = (Sum seq1) - (Sum seq2) ) )
assume A1: ( seq1 is summable & seq2 is summable ) ; :: thesis: ( seq1 - seq2 is summable & Sum (seq1 - seq2) = (Sum seq1) - (Sum seq2) )
A2: ( Partial_Sums seq1 is convergent & Partial_Sums seq2 is convergent ) by A1, Def2;
then A3: (Partial_Sums seq1) - (Partial_Sums seq2) is convergent by CLVECT_1:116;
A4: (Partial_Sums seq1) - (Partial_Sums seq2) = Partial_Sums (seq1 - seq2) by Th20;
Sum (seq1 - seq2) = lim ((Partial_Sums seq1) - (Partial_Sums seq2)) by Th20
.= (lim (Partial_Sums seq1)) - (lim (Partial_Sums seq2)) by A2, CLVECT_1:122 ;
hence ( seq1 - seq2 is summable & Sum (seq1 - seq2) = (Sum seq1) - (Sum seq2) ) by A3, A4, Def2; :: thesis: verum