let n be non empty Nat; :: thesis: for J being non empty non void Signature
for T being non-empty MSAlgebra over J
for X being empty-yielding GeneratorSet of T
for S1 being non empty non void b₁ -extension n PC-correct QC-correct QCLangSignature over Union X
for L being non-empty Language of X extended_by ({}, the carrier of S1),S1
for G being QC-theory of L
for A, B being Formula of L
for x being Element of Union X st L is subst-correct & L is vf-qc-correct & A \imp B in G holds
(\for (x,A)) \imp (\for (x,B)) in G
let J be non empty non void Signature; :: thesis: for T being non-empty MSAlgebra over J
for X being empty-yielding GeneratorSet of T
for S1 being non empty non void J -extension n PC-correct QC-correct QCLangSignature over Union X
for L being non-empty Language of X extended_by ({}, the carrier of S1),S1
for G being QC-theory of L
for A, B being Formula of L
for x being Element of Union X st L is subst-correct & L is vf-qc-correct & A \imp B in G holds
(\for (x,A)) \imp (\for (x,B)) in G
let T be non-empty MSAlgebra over J; :: thesis: for X being empty-yielding GeneratorSet of T
for S1 being non empty non void J -extension n PC-correct QC-correct QCLangSignature over Union X
for L being non-empty Language of X extended_by ({}, the carrier of S1),S1
for G being QC-theory of L
for A, B being Formula of L
for x being Element of Union X st L is subst-correct & L is vf-qc-correct & A \imp B in G holds
(\for (x,A)) \imp (\for (x,B)) in G
let X be empty-yielding GeneratorSet of T; :: thesis: for S1 being non empty non void J -extension n PC-correct QC-correct QCLangSignature over Union X
for L being non-empty Language of X extended_by ({}, the carrier of S1),S1
for G being QC-theory of L
for A, B being Formula of L
for x being Element of Union X st L is subst-correct & L is vf-qc-correct & A \imp B in G holds
(\for (x,A)) \imp (\for (x,B)) in G
let S1 be non empty non void J -extension n PC-correct QC-correct QCLangSignature over Union X; :: thesis: for L being non-empty Language of X extended_by ({}, the carrier of S1),S1
for G being QC-theory of L
for A, B being Formula of L
for x being Element of Union X st L is subst-correct & L is vf-qc-correct & A \imp B in G holds
(\for (x,A)) \imp (\for (x,B)) in G
let L be non-empty Language of X extended_by ({}, the carrier of S1),S1; :: thesis: for G being QC-theory of L
for A, B being Formula of L
for x being Element of Union X st L is subst-correct & L is vf-qc-correct & A \imp B in G holds
(\for (x,A)) \imp (\for (x,B)) in G
let G be QC-theory of L; :: thesis: for A, B being Formula of L
for x being Element of Union X st L is subst-correct & L is vf-qc-correct & A \imp B in G holds
(\for (x,A)) \imp (\for (x,B)) in G
let A, B be Formula of L; :: thesis: for x being Element of Union X st L is subst-correct & L is vf-qc-correct & A \imp B in G holds
(\for (x,A)) \imp (\for (x,B)) in G
let x be Element of Union X; :: thesis: ( L is subst-correct & L is vf-qc-correct & A \imp B in G implies (\for (x,A)) \imp (\for (x,B)) in G )
assume A1: ( L is subst-correct & L is vf-qc-correct ) ; :: thesis: ( not A \imp B in G or (\for (x,A)) \imp (\for (x,B)) in G )
assume A \imp B in G ; :: thesis: (\for (x,A)) \imp (\for (x,B)) in G
then A2: \for (x,(A \imp B)) in G by Def39;
(\for (x,(A \imp B))) \imp ((\for (x,A)) \imp (\for (x,B))) in G by A1, Th109;
hence (\for (x,A)) \imp (\for (x,B)) in G by A2, Def38; :: thesis: verum