Metamath Proof Explorer

Theorem lsslvec

Description: A vector subspace is a vector space. (Contributed by NM, 14-Mar-2015)

Ref Expression
Hypotheses lsslvec.x 
|- X = ( W |`s U )
lsslvec.s 
|- S = ( LSubSp ` W )
Assertion lsslvec 
|- ( ( W e. LVec /\ U e. S ) -> X e. LVec )

Proof

Step Hyp Ref Expression
1 lsslvec.x 
 |-  X = ( W |`s U )
2 lsslvec.s 
 |-  S = ( LSubSp ` W )
3 lveclmod 
 |-  ( W e. LVec -> W e. LMod )
4 1 2 lsslmod 
 |-  ( ( W e. LMod /\ U e. S ) -> X e. LMod )
5 3 4 sylan 
 |-  ( ( W e. LVec /\ U e. S ) -> X e. LMod )
6 eqid 
 |-  ( Scalar ` W ) = ( Scalar ` W )
7 1 6 resssca 
 |-  ( U e. S -> ( Scalar ` W ) = ( Scalar ` X ) )
8 7 adantl 
 |-  ( ( W e. LVec /\ U e. S ) -> ( Scalar ` W ) = ( Scalar ` X ) )
9 6 lvecdrng 
 |-  ( W e. LVec -> ( Scalar ` W ) e. DivRing )
10 9 adantr 
 |-  ( ( W e. LVec /\ U e. S ) -> ( Scalar ` W ) e. DivRing )
11 8 10 eqeltrrd 
 |-  ( ( W e. LVec /\ U e. S ) -> ( Scalar ` X ) e. DivRing )
12 eqid 
 |-  ( Scalar ` X ) = ( Scalar ` X )
13 12 islvec 
 |-  ( X e. LVec <-> ( X e. LMod /\ ( Scalar ` X ) e. DivRing ) )
14 5 11 13 sylanbrc 
 |-  ( ( W e. LVec /\ U e. S ) -> X e. LVec )