set L = LKer f;
set vq = VectQuot V,(LKer f);
set Cv = CosetSet V,(LKer f);
set aCv = addCoset V,(LKer f);
set mCv = lmultCoset V,(LKer f);
set R = RKer f;
set wq = VectQuot W,(RKer f);
set Cw = CosetSet W,(RKer f);
set aCw = addCoset W,(RKer f);
set mCw = lmultCoset W,(RKer f);
defpred S1[ set , set , set ] means for v being Vector of V
for w being Vector of W st $1 = v + (LKer f) & $2 = w + (RKer f) holds
$3 = f . v,w;
A1: now
let A be Vector of (VectQuot V,(LKer f)); :: thesis: for B being Vector of (VectQuot W,(RKer f)) ex y being Element of the carrier of K st S1[A,B,y]
let B be Vector of (VectQuot W,(RKer f)); :: thesis: ex y being Element of the carrier of K st S1[A,B,y]
consider a being Vector of V such that
A2: A = a + (LKer f) by VECTSP10:23;
consider b being Vector of W such that
A3: B = b + (RKer f) by VECTSP10:23;
take y = f . a,b; :: thesis: S1[A,B,y]
now
let a1 be Vector of V; :: thesis: for b1 being Vector of W st A = a1 + (LKer f) & B = b1 + (RKer f) holds
y = f . a1,b1
let b1 be Vector of W; :: thesis: ( A = a1 + (LKer f) & B = b1 + (RKer f) implies y = f . a1,b1 )
assume A = a1 + (LKer f) ; :: thesis: ( B = b1 + (RKer f) implies y = f . a1,b1 )
then a in a1 + (LKer f) by A2, VECTSP_4:59;
then consider vv being Vector of V such that
A4: vv in LKer f and
A5: a = a1 + vv by VECTSP_4:57;
vv in the carrier of (LKer f) by A4, STRUCT_0:def 5;
then vv in leftker f by Def19;
then A6: ex aa being Vector of V st
( aa = vv & ( for w0 being Vector of W holds f . aa,w0 = 0. K ) ) ;
assume B = b1 + (RKer f) ; :: thesis: y = f . a1,b1
then b in b1 + (RKer f) by A3, VECTSP_4:59;
then consider ww being Vector of W such that
A7: ww in RKer f and
A8: b = b1 + ww by VECTSP_4:57;
ww in the carrier of (RKer f) by A7, STRUCT_0:def 5;
then ww in rightker f by Def20;
then A9: ex bb being Vector of W st
( bb = ww & ( for v0 being Vector of V holds f . v0,bb = 0. K ) ) ;
thus y = ((f . a1,b1) + (f . a1,ww)) + ((f . vv,b1) + (f . vv,ww)) by A5, A8, Th29
.= ((f . a1,b1) + (0. K)) + ((f . vv,b1) + (f . vv,ww)) by A9
.= ((f . a1,b1) + (0. K)) + ((0. K) + (f . vv,ww)) by A6
.= (f . a1,b1) + ((0. K) + (f . vv,ww)) by RLVECT_1:def 7
.= (f . a1,b1) + (f . vv,ww) by RLVECT_1:10
.= (f . a1,b1) + (0. K) by A6
.= f . a1,b1 by RLVECT_1:def 7 ; :: thesis: verum
end;
hence S1[A,B,y] ; :: thesis: verum
end;
consider ff being Function of [:the carrier of (VectQuot V,(LKer f)),the carrier of (VectQuot W,(RKer f)):],the carrier of K such that
A10: for A being Vector of (VectQuot V,(LKer f))
for B being Vector of (VectQuot W,(RKer f)) holds S1[A,B,ff . A,B] from BINOP_1:sch 3(A1);
 reconsider ff = ff as Form of (VectQuot V,(LKer f)),(VectQuot W,(RKer f)) ;
A11: CosetSet V,(LKer f) = the carrier of (VectQuot V,(LKer f)) by VECTSP10:def 6;
A12: now
let ww be Vector of (VectQuot W,(RKer f)); :: thesis: FunctionalSAF ff,ww is homogeneous
consider w being Vector of W such that
A13: ww = w + (RKer f) by VECTSP10:23;
set ffw = FunctionalSAF ff,ww;
now
let A be Vector of (VectQuot V,(LKer f)); :: thesis: for r being Element of K holds (FunctionalSAF ff,ww) . (r * A) = r * ((FunctionalSAF ff,ww) . A)
let r be Element of K; :: thesis: (FunctionalSAF ff,ww) . (r * A) = r * ((FunctionalSAF ff,ww) . A)
consider a being Vector of V such that
A14: A = a + (LKer f) by VECTSP10:23;
A15: ( the lmult of (VectQuot V,(LKer f)) = lmultCoset V,(LKer f) & (lmultCoset V,(LKer f)) . r,A = (r * a) + (LKer f) ) by A11, A14, VECTSP10:def 5, VECTSP10:def 6;
thus (FunctionalSAF ff,ww) . (r * A) = ff . (r * A),ww by Th10
.= f . (r * a),w by A10, A13, A15, VECTSP_1:def 24
.= r * (f . a,w) by Th32
.= r * (ff . A,ww) by A10, A13, A14
.= r * ((FunctionalSAF ff,ww) . A) by Th10 ; :: thesis: verum
end;
hence FunctionalSAF ff,ww is homogeneous by HAHNBAN1:def 12; :: thesis: verum
end;
A16: CosetSet W,(RKer f) = the carrier of (VectQuot W,(RKer f)) by VECTSP10:def 6;
A17: now
let vv be Vector of (VectQuot V,(LKer f)); :: thesis: FunctionalFAF ff,vv is homogeneous
consider v being Vector of V such that
A18: vv = v + (LKer f) by VECTSP10:23;
set ffv = FunctionalFAF ff,vv;
now
let A be Vector of (VectQuot W,(RKer f)); :: thesis: for r being Element of K holds (FunctionalFAF ff,vv) . (r * A) = r * ((FunctionalFAF ff,vv) . A)
let r be Element of K; :: thesis: (FunctionalFAF ff,vv) . (r * A) = r * ((FunctionalFAF ff,vv) . A)
consider a being Vector of W such that
A19: A = a + (RKer f) by VECTSP10:23;
A20: ( the lmult of (VectQuot W,(RKer f)) = lmultCoset W,(RKer f) & (lmultCoset W,(RKer f)) . r,A = (r * a) + (RKer f) ) by A16, A19, VECTSP10:def 5, VECTSP10:def 6;
thus (FunctionalFAF ff,vv) . (r * A) = ff . vv,(r * A) by Th9
.= f . v,(r * a) by A10, A18, A20, VECTSP_1:def 24
.= r * (f . v,a) by Th33
.= r * (ff . vv,A) by A10, A18, A19
.= r * ((FunctionalFAF ff,vv) . A) by Th9 ; :: thesis: verum
end;
hence FunctionalFAF ff,vv is homogeneous by HAHNBAN1:def 12; :: thesis: verum
end;
A21: now
let ww be Vector of (VectQuot W,(RKer f)); :: thesis: FunctionalSAF ff,ww is additive
consider w being Vector of W such that
A22: ww = w + (RKer f) by VECTSP10:23;
set ffw = FunctionalSAF ff,ww;
now
let A, B be Vector of (VectQuot V,(LKer f)); :: thesis: (FunctionalSAF ff,ww) . (A + B) = ((FunctionalSAF ff,ww) . A) + ((FunctionalSAF ff,ww) . B)
consider a being Vector of V such that
A23: A = a + (LKer f) by VECTSP10:23;
consider b being Vector of V such that
A24: B = b + (LKer f) by VECTSP10:23;
A25: ( the addF of (VectQuot V,(LKer f)) = addCoset V,(LKer f) & (addCoset V,(LKer f)) . A,B = (a + b) + (LKer f) ) by A11, A23, A24, VECTSP10:def 3, VECTSP10:def 6;
thus (FunctionalSAF ff,ww) . (A + B) = ff . (A + B),ww by Th10
.= f . (a + b),w by A10, A22, A25, RLVECT_1:5
.= (f . a,w) + (f . b,w) by Th27
.= (ff . A,ww) + (f . b,w) by A10, A22, A23
.= (ff . A,ww) + (ff . B,ww) by A10, A22, A24
.= ((FunctionalSAF ff,ww) . A) + (ff . B,ww) by Th10
.= ((FunctionalSAF ff,ww) . A) + ((FunctionalSAF ff,ww) . B) by Th10 ; :: thesis: verum
end;
hence FunctionalSAF ff,ww is additive by GRCAT_1:def 13; :: thesis: verum
end;
now
let vv be Vector of (VectQuot V,(LKer f)); :: thesis: FunctionalFAF ff,vv is additive
consider v being Vector of V such that
A26: vv = v + (LKer f) by VECTSP10:23;
set ffv = FunctionalFAF ff,vv;
now
let A, B be Vector of (VectQuot W,(RKer f)); :: thesis: (FunctionalFAF ff,vv) . (A + B) = ((FunctionalFAF ff,vv) . A) + ((FunctionalFAF ff,vv) . B)
consider a being Vector of W such that
A27: A = a + (RKer f) by VECTSP10:23;
consider b being Vector of W such that
A28: B = b + (RKer f) by VECTSP10:23;
A29: ( the addF of (VectQuot W,(RKer f)) = addCoset W,(RKer f) & (addCoset W,(RKer f)) . A,B = (a + b) + (RKer f) ) by A16, A27, A28, VECTSP10:def 3, VECTSP10:def 6;
thus (FunctionalFAF ff,vv) . (A + B) = ff . vv,(A + B) by Th9
.= f . v,(a + b) by A10, A26, A29, RLVECT_1:5
.= (f . v,a) + (f . v,b) by Th28
.= (ff . vv,A) + (f . v,b) by A10, A26, A27
.= (ff . vv,A) + (ff . vv,B) by A10, A26, A28
.= ((FunctionalFAF ff,vv) . A) + (ff . vv,B) by Th9
.= ((FunctionalFAF ff,vv) . A) + ((FunctionalFAF ff,vv) . B) by Th9 ; :: thesis: verum
end;
hence FunctionalFAF ff,vv is additive by GRCAT_1:def 13; :: thesis: verum
end;
then reconsider ff = ff as bilinear-Form of (VectQuot V,(LKer f)),(VectQuot W,(RKer f)) by A21, A12, A17, Def12, Def13, Def14, Def15;
take ff ; :: thesis: for A being Vector of (VectQuot V,(LKer f))
for B being Vector of (VectQuot W,(RKer f))
for v being Vector of V
for w being Vector of W st A = v + (LKer f) & B = w + (RKer f) holds
ff . A,B = f . v,w
thus for A being Vector of (VectQuot V,(LKer f))
for B being Vector of (VectQuot W,(RKer f))
for v being Vector of V
for w being Vector of W st A = v + (LKer f) & B = w + (RKer f) holds
ff . A,B = f . v,w by A10; :: thesis: verum