let V be ComplexLinearSpace; :: thesis: for v1, v2 being VECTOR of V
for L being C_Linear_Combination of {v1,v2} st v1 <> v2 & L is convex holds
( ex r1, r2 being Real st
( r1 = L . v1 & r2 = L . v2 & r1 >= 0 & r2 >= 0 ) & Sum L = ((L . v1) * v1) + ((L . v2) * v2) )
let v1, v2 be VECTOR of V; :: thesis: for L being C_Linear_Combination of {v1,v2} st v1 <> v2 & L is convex holds
( ex r1, r2 being Real st
( r1 = L . v1 & r2 = L . v2 & r1 >= 0 & r2 >= 0 ) & Sum L = ((L . v1) * v1) + ((L . v2) * v2) )
let L be C_Linear_Combination of {v1,v2}; :: thesis: ( v1 <> v2 & L is convex implies ( ex r1, r2 being Real st
( r1 = L . v1 & r2 = L . v2 & r1 >= 0 & r2 >= 0 ) & Sum L = ((L . v1) * v1) + ((L . v2) * v2) ) )
assume that
A1: v1 <> v2 and
A2: L is convex ; :: thesis: ( ex r1, r2 being Real st
( r1 = L . v1 & r2 = L . v2 & r1 >= 0 & r2 >= 0 ) & Sum L = ((L . v1) * v1) + ((L . v2) * v2) )
A3: Carrier L c= {v1,v2} by Def4;
A4: Carrier L <> {} by A2, Th77;
ex r1, r2 being Real st
( r1 = L . v1 & r2 = L . v2 & r1 >= 0 & r2 >= 0 ) hence ( ex r1, r2 being Real st
( r1 = L . v1 & r2 = L . v2 & r1 >= 0 & r2 >= 0 ) & Sum L = ((L . v1) * v1) + ((L . v2) * v2) ) by A1, Th15; :: thesis: verum