:: CONVEX3 semantic presentation
:: deftheorem Def1 defines ConvexComb CONVEX3:def 1 :
:: deftheorem Def2 defines ConvexComb CONVEX3:def 2 :
theorem Th1: :: CONVEX3:1
theorem Th2: :: CONVEX3:2
theorem Th3: :: CONVEX3:3
Lemma72:
for V being RealLinearSpace
for M being non empty Subset of V st { (Sum L) where L is Convex_Combination of M : L in ConvexComb V } c= M holds
M is convex
Lemma78:
for V being RealLinearSpace
for M being non empty Subset of V
for L being Convex_Combination of M st card (Carrier L) >= 2 holds
ex L1, L2 being Convex_Combination of M ex r being Real st
( 0 < r & r < 1 & L = (r * L1) + ((1 - r) * L2) & card (Carrier L1) = 1 & card (Carrier L2) = (card (Carrier L)) - 1 )
Lemma152:
for V being RealLinearSpace
for M being non empty Subset of V st M is convex holds
{ (Sum L) where L is Convex_Combination of M : L in ConvexComb V } c= M
theorem Th4: :: CONVEX3:4
theorem Th5: :: CONVEX3:5
:: deftheorem Def3 defines cone CONVEX3:def 3 :
theorem Th6: :: CONVEX3:6
theorem Th7: :: CONVEX3:7
Lemma163:
for V being RealLinearSpace
for M being Subset of V
for L being Linear_Combination of M st card (Carrier L) >= 1 holds
ex L1, L2 being Linear_Combination of M st
( Sum L = (Sum L1) + (Sum L2) & card (Carrier L1) = 1 & card (Carrier L2) = (card (Carrier L)) - 1 & Carrier L1 c= Carrier L & Carrier L2 c= Carrier L & ( for v being VECTOR of V st v in Carrier L1 holds
L1 . v = L . v ) & ( for v being VECTOR of V st v in Carrier L2 holds
L2 . v = L . v ) )
theorem Th8: :: CONVEX3:8
theorem Th9: :: CONVEX3:9