:: Directed Geometrical Bundles and Their Analytical Representation :: by Grzegorz Lewandowski, Krzysztof Pra\.zmowski and Bo\.zena Lewandowska environ vocabularies XBOOLE_0, ANALOAF, SUBSET_1, STRUCT_0, ZFMISC_1, TDGROUP, DIRAF, BINOP_1, FUNCT_1, ALGSTR_0, SUPINF_2, ARYTM_3, RLVECT_1, ARYTM_1, VECTSP_1, MCART_1, PBOOLE, RELAT_1, TARSKI, AFVECT0; notations TARSKI, ZFMISC_1, SUBSET_1, STRUCT_0, ALGSTR_0, ANALOAF, TDGROUP, FUNCT_1, FUNCT_2, XTUPLE_0, MCART_1, BINOP_1, RELAT_1, VECTSP_1, RLVECT_1; constructors BINOP_1, DOMAIN_1, TDGROUP, RELSET_1, XTUPLE_0; registrations XBOOLE_0, SUBSET_1, RELSET_1, STRUCT_0, VECTSP_1, TDGROUP, RELAT_1, XTUPLE_0; requirements SUBSET, BOOLE; definitions RLVECT_1, ALGSTR_0; equalities STRUCT_0, BINOP_1, ALGSTR_0; expansions STRUCT_0; theorems DOMAIN_1, TDGROUP, FUNCT_1, FUNCT_2, MCART_1, RELAT_1, TARSKI, RLVECT_1, ANALOAF, XBOOLE_0, VECTSP_1, STRUCT_0; schemes BINOP_1, FUNCT_2; begin definition let IT be non empty AffinStruct; attr IT is WeakAffVect-like means :Def1: (for a,b,c being Element of IT st a ,b // c,c holds a=b) & (for a,b,c,d,p,q being Element of IT st a,b // p,q & c,d // p,q holds a,b // c,d) & (for a,b,c being Element of IT ex d being Element of IT st a,b // c,d) & (for a,b,c,a9,b9,c9 being Element of IT st a,b // a9,b9 & a ,c // a9,c9 holds b,c // b9,c9) & (for a,c being Element of IT ex b being Element of IT st a,b // b,c) & for a,b,c,d being Element of IT st a,b // c,d holds a,c // b,d; end; registration cluster strict WeakAffVect-like for non trivial AffinStruct; existence proof set AFV = the strict AffVect; reconsider AS = AFV as non empty AffinStruct; A1: ( for a,b,c being Element of AS ex d being Element of AS st a,b // c,d )& for a,b,c,a9,b9,c9 being Element of AS st a,b // a9,b9 & a,c // a9,c9 holds b,c // b9,c9 by TDGROUP:16; A2: ( for a,c being Element of AS ex b being Element of AS st a,b // b,c)& for a,b,c,d being Element of AS st a,b // c,d holds a,c // b,d by TDGROUP:16; ( for a,b,c being Element of AS st a,b // c,c holds a=b)& for a,b,c,d, p,q being Element of AS st a,b // p,q & c,d // p,q holds a, b // c,d by TDGROUP:16; then AS is WeakAffVect-like by A1,A2; hence thesis; end; end; definition mode WeakAffVect is WeakAffVect-like non trivial AffinStruct; end; registration cluster AffVect-like -> WeakAffVect-like for non empty AffinStruct; coherence by TDGROUP:def 5; end; reserve AFV for WeakAffVect; reserve a,b,c,d,e,f,a9,b9,c9,d9,f9,p,q,r,o,x99 for Element of AFV; :: :: Properties of Relation of Congruence of Vectors :: theorem Th1: a,b // a,b proof ex d st a,b // b,d by Def1; hence thesis by Def1; end; theorem a,a // a,a by Th1; theorem Th3: a,b // c,d implies c,d // a,b proof assume A1: a,b // c,d; c,d // c,d by Th1; hence thesis by A1,Def1; end; theorem Th4: a,b // a,c implies b = c proof assume a,b // a,c; then a,a // b,c by Def1; then b,c // a,a by Th3; hence thesis by Def1; end; theorem Th5: a,b // c,d & a,b // c,d9 implies d = d9 proof assume a,b // c,d & a,b // c,d9; then c,d // a,b & c,d9 // a,b by Th3; then c,d // c,d9 by Def1; hence thesis by Th4; end; theorem Th6: for a,b holds a,a // b,b proof let a,b; consider p such that A1: a,a // b,p by Def1; b,p // a,a by A1,Th3; hence thesis by A1,Def1; end; theorem Th7: a,b // c,d implies b,a // d,c proof assume A1: a,b // c,d; a,a // c,c by Th6; hence thesis by A1,Def1; end; theorem a,b // c,d & a,c // b9,d implies b = b9 proof assume that A1: a,b // c,d and A2: a,c // b9,d; a,c // b,d by A1,Def1; then b,d // a,c by Th3; then A3: d,b // c,a by Th7; b9,d // a,c by A2,Th3; then d,b9 // c,a by Th7; then d,b // d,b9 by A3,Def1; hence thesis by Th4; end; theorem b,c // b9,c9 & a,d // b,c & a,d9 // b9,c9 implies d = d9 proof assume that A1: b,c // b9,c9 and A2: a,d // b,c and A3: a,d9 // b9,c9; b9,c9 // b,c by A1,Th3; then a,d // b9,c9 by A2,Def1; then a,d // a,d9 by A3,Def1; hence thesis by Th4; end; theorem a,b // a9,b9 & c,d // b,a & c,d9 // b9,a9 implies d = d9 proof assume that A1: a,b // a9,b9 and A2: c,d // b,a and A3: c,d9 // b9,a9; a9,b9 // a,b by A1,Th3; then b9,a9 // b,a by Th7; then c,d // b9,a9 by A2,Def1; then c,d // c,d9 by A3,Def1; hence thesis by Th4; end; theorem a,b // a9,b9 & c,d // c9,d9 & b,f // c,d & b9,f9 // c9,d9 implies a,f // a9,f9 proof assume that A1: a,b // a9,b9 and A2: c,d // c9,d9 and A3: b,f // c,d and A4: b9,f9 // c9,d9; b9,f9 // c,d by A2,A4,Def1; then A5: b,f // b9,f9 by A3,Def1; b,a // b9,a9 by A1,Th7; hence thesis by A5,Def1; end; theorem Th12: a,b // a9,b9 & a,c // c9,b9 implies b,c // c9,a9 proof assume that A1: a,b // a9,b9 and A2: a,c // c9,b9; consider d such that A3: c9,b9 // a9,d by Def1; a9,d // c9,b9 by A3,Th3; then a,c // a9,d by A2,Def1; then A4: b,c // b9,d by A1,Def1; c9,a9 // b9,d by A3,Def1; hence thesis by A4,Def1; end; :: :: Relation of Maximal Distance :: definition let AFV; let a,b; pred MDist a,b means a,b // b,a & a <> b; irreflexivity; symmetry by Th3; end; theorem ex a,b st a<>b & not MDist a,b proof consider p,q such that A1: p <> q by STRUCT_0:def 10; now consider r such that A2: p,r // r,q by Def1; A3: now A4: now assume MDist p,r; then A5: p,r // r,p; r,q // p,r by A2,Th3; then q,r // r,p by Th7; then p,r // q,r by A5,Def1; hence thesis by A1,Th4,Th7; end; assume p <> r; hence thesis by A4; end; now assume A6: p = r; then r,q // p,p by A2,Th3; hence thesis by A1,A6,Def1; end; hence thesis by A3; end; hence thesis; end; theorem MDist a,b & MDist a,c implies b = c or MDist b,c proof assume that A1: MDist a,b and A2: MDist a,c; A3: a,b // b,a by A1; A4: a,c // c,a by A2; consider d such that A5: c,a // b,d by Def1; b,d // c,a by A5,Th3; then a,c // b,d by A4,Def1; then A6: b,c // a,d by A3,Def1; c,b // a,d by A5,Def1; then b,c // c,b by A6,Def1; hence thesis; end; theorem MDist a,b & a,b // c,d implies MDist c,d proof assume that A1: MDist a,b and A2: a,b // c,d; A3: a,b // b,a by A1; A4: c,d // a,b by A2,Th3; then d,c // b,a by Th7; then d,c // a,b by A3,Def1; then c,d // d,c by A4,Def1; then c <> d implies thesis; hence thesis by A1,A2,Def1; end; :: :: Midpoint Relation :: definition let AFV; let a,b,c; pred Mid a,b,c means :Def3: a,b // b,c; end; theorem Th16: Mid a,b,c implies Mid c,b,a proof assume Mid a,b,c; then a,b // b,c; then b,a // c,b by Th7; then c,b // b,a by Th3; hence thesis; end; theorem Mid a,b,b iff a = b by Def1,Th6; theorem Th18: Mid a,b,a iff a = b or MDist a,b by Th6; theorem Th19: ex b st Mid a,b,c proof consider b such that A1: a,b // b,c by Def1; Mid a,b,c by A1; hence thesis; end; theorem Th20: Mid a,b,c & Mid a,b9,c implies b =b9 or MDist b,b9 proof assume that A1: Mid a,b,c and A2: Mid a,b9,c; A3: a,b // b,c by A1; consider d such that A4: b9,c // b,d by Def1; A5: b,d // b9,c by A4,Th3; then b,b9 // d,c by Def1; then A6: b9,b // c,d by Th7; a,b9 // b9,c by A2; then a,b9 // b,d by A5,Def1; then b,b9 // c,d by A3,Def1; then b,b9 // b9,b by A6,Def1; hence thesis; end; theorem Th21: ex c st Mid a,b,c proof consider c such that A1: a,b // b,c by Def1; Mid a,b,c by A1; hence thesis; end; theorem Th22: Mid a,b,c & Mid a,b,c9 implies c = c9 proof assume that A1: Mid a,b,c and A2: Mid a,b,c9; a,b // b,c9 by A2; then A3: b,c9 // a,b by Th3; a,b // b,c by A1; then b,c // a,b by Th3; then b,c // b,c9 by A3,Def1; hence thesis by Th4; end; theorem Th23: Mid a,b,c & MDist b,b9 implies Mid a,b9,c proof assume that A1: Mid a,b,c and A2: MDist b,b9; A3: b,b9 // b9,b by A2; a,b // b,c by A1; then A4: b,a // c,b by Th7; consider d such that A5: b9,b // c,d by Def1; c,d // b9,b by A5,Th3; then b,b9 // c,d by A3,Def1; then A6: a,b9 // b,d by A4,Def1; b9,c // b,d by A5,Def1; then a,b9 // b9,c by A6,Def1; hence thesis; end; theorem Th24: Mid a,b,c & Mid a,b9,c9 & MDist b,b9 implies c = c9 proof assume that A1: Mid a,b,c and A2: Mid a,b9,c9 and A3: MDist b,b9; Mid a,b9,c by A1,A3,Th23; hence thesis by A2,Th22; end; theorem Th25: Mid a,p,a9 & Mid b,p,b9 implies a,b // b9,a9 proof assume that A1: Mid a,p,a9 and A2: Mid b,p,b9; consider d such that A3: b9,p // a9,d by Def1; a,p // p,a9 by A1; then A4: p,a // a9,p by Th7; b,p // p,b9 by A2; then A5: p,b // b9,p by Th7; a9,d // b9,p by A3,Th3; then p,b // a9,d by A5,Def1; then A6: a,b // p,d by A4,Def1; b9,a9 // p,d by A3,Def1; hence thesis by A6,Def1; end; theorem Mid a,p,a9 & Mid b,q,b9 & MDist p,q implies a,b // b9,a9 proof assume that A1: Mid a,p,a9 and A2: Mid b,q,b9 and A3: MDist p,q; Mid a,q,a9 by A1,A3,Th23; hence thesis by A2,Th25; end; :: :: Point Symmetry :: definition let AFV; let a,b; func PSym(a,b) -> Element of AFV means :Def4: Mid b,a,it; correctness by Th21,Th22; end; theorem PSym(p,a) = b iff a,p // p,b by Def3,Def4; theorem Th28: PSym(p,a) = a iff a = p or MDist a,p proof A1: now assume a = p or MDist a,p; then Mid a,p,a by Th18; hence PSym(p,a) = a by Def4; end; now assume PSym(p,a) = a; then Mid a,p,a by Def4; hence a = p or MDist a,p; end; hence thesis by A1; end; theorem Th29: PSym(p,PSym(p,a)) = a proof Mid a,p,PSym(p,a) by Def4; then Mid PSym(p,a),p,a by Th16; hence thesis by Def4; end; theorem Th30: PSym(p,a) = PSym(p,b) implies a = b proof assume A1: PSym(p,a) = PSym(p,b); PSym(p,PSym(p,a)) = a by Th29; hence thesis by A1,Th29; end; theorem ex a st PSym(p,a) = b proof PSym(p,PSym(p,b)) = b by Th29; hence thesis; end; theorem Th32: a,b // PSym(p,b),PSym(p,a) proof Mid a,p,PSym(p,a) & Mid b,p,PSym(p,b) by Def4; hence thesis by Th25; end; theorem Th33: a,b // c,d iff PSym(p,a),PSym(p,b) // PSym(p,c),PSym(p,d) proof A1: now assume A2: PSym(p,a),PSym(p,b) // PSym(p,c),PSym(p,d); d,c // PSym(p,c),PSym(p,d) by Th32; then d,c // PSym(p,a),PSym(p,b) by A2,Def1; then A3: c,d // PSym(p,b),PSym(p,a) by Th7; a,b // PSym(p,b),PSym(p,a) by Th32; hence a,b // c,d by A3,Def1; end; now A4: PSym(p,b),PSym(p,a) // a,b by Th3,Th32; assume A5: a,b // c,d; PSym(p,d),PSym(p,c) // c,d by Th3,Th32; then PSym(p,d),PSym(p,c) // a,b by A5,Def1; then PSym(p,b),PSym(p,a) // PSym(p,d),PSym(p,c) by A4,Def1; hence PSym(p,a),PSym(p,b) // PSym(p,c),PSym(p,d) by Th7; end; hence thesis by A1; end; theorem MDist a,b iff MDist PSym(p,a),PSym(p,b) by Th30,Th33; theorem Th35: Mid a,b,c iff Mid PSym(p,a),PSym(p,b),PSym(p,c) by Th33; theorem Th36: PSym(p,a) = PSym(q,a) iff p = q or MDist p,q proof A1: now assume A2: MDist p,q; Mid a,p,PSym(p,a) & Mid a,q,PSym(q,a) by Def4; hence PSym(p,a) = PSym(q,a) by A2,Th24; end; now assume A3: PSym(p,a) = PSym(q,a); Mid a,p,PSym(p,a) & Mid a,q,PSym(q,a) by Def4; hence p = q or MDist p,q by A3,Th20; end; hence thesis by A1; end; theorem Th37: PSym(q,PSym(p,PSym(q,a))) = PSym(PSym(q,p),a) proof Mid PSym(q,a),p,PSym(p,PSym(q,a)) by Def4; then Mid PSym(q,PSym(q,a)),PSym(q,p),PSym(q,PSym(p,PSym(q,a))) by Th35; then PSym(q,PSym(p,PSym(q,a)))=PSym(PSym(q,p),PSym(q,PSym(q,a))) by Def4; hence thesis by Th29; end; theorem PSym(p,PSym(q,a)) = PSym(q,PSym(p,a)) iff p = q or MDist p,q or MDist q,PSym(p,q) proof A1: now assume PSym(p,PSym(q,a))=PSym(q,PSym(p,a)); then PSym(p,PSym(q,PSym(p,a)))=PSym(q,a) by Th29; then PSym(PSym(p,q),a)=PSym(q,a) by Th37; then q=PSym(p,q) or MDist q,PSym(p,q) by Th36; then A2: Mid q,p,q or MDist q,PSym(p,q) by Def4; hence p = q or MDist q,p or MDist q,PSym(p,q); thus p = q or MDist p,q or MDist q,PSym(p,q) by A2,Th18; end; now assume p = q or MDist p,q or MDist q,PSym(p,q); then Mid q,p,q or MDist q,PSym(p,q) by Th18; then PSym(PSym(p,q),a)=PSym(q,a) by Def4,Th36; then PSym(p,PSym(q,PSym(p,a)))=PSym(q,a) by Th37; hence PSym(p,PSym(q,a))=PSym(q,PSym(p,a)) by Th29; end; hence thesis by A1; end; theorem Th39: PSym(p,PSym(q,PSym(r,a))) = PSym(r,PSym(q,PSym(p,a))) proof p,a // PSym(r,a),PSym(r,p) & PSym(q,PSym(r,p)),PSym(q,PSym(r,a)) // PSym(r,a ),PSym(r,p) by Th3,Th32; then A1: p,a // PSym(q,PSym(r,p)),PSym(q,PSym(r,a)) by Def1; p,a // PSym(p,a),PSym(p,p) & PSym(q,PSym(p,p)),PSym(q,PSym(p,a)) // PSym(p,a ),PSym(p,p) by Th3,Th32; then A2: p,a // PSym(q,PSym(p,p)),PSym(q,PSym(p,a)) by Def1; PSym(q,p),PSym(r,p) // PSym(r,PSym(r,p)),PSym(r,PSym(q,p)) by Th32; then PSym(q,p),PSym(r,p) // p,PSym(r,PSym(q,p)) by Th29; then A3: p,PSym(r,PSym(q,p)) // PSym(q,p),PSym(r,p) by Th3; PSym(q,PSym(r,p)),p // PSym(q,p),PSym(q,PSym(q,PSym(r,p))) by Th32; then PSym(q,PSym(r,p)),p // PSym(q,p),PSym(r,p) by Th29; then PSym(q,PSym(r,p)),p // p,PSym(r,PSym(q,p)) by A3,Def1; then Mid PSym(q,PSym(r,p)),p,PSym(r,PSym(q,p)); then PSym(p,PSym(q,PSym(r,p))) = PSym(r,PSym(q,p)) by Def4; then A4: PSym(p,PSym(q,PSym(r,p))) = PSym(r,PSym(q,PSym(p,p))) by Th28; PSym(r,PSym(q,PSym(p,a))),PSym(r,PSym(q,PSym(p,p))) // PSym(q,PSym(p,p) ),PSym(q,PSym(p,a)) by Th3,Th32; then A5: PSym(r,PSym(q,PSym(p,a))),PSym(r,PSym(q,PSym(p,p))) // p,a by A2,Def1; PSym(p,PSym(q,PSym(r,a))),PSym(p,PSym(q,PSym(r,p))) // PSym(q,PSym(r,p) ),PSym(q,PSym(r,a)) by Th3,Th32; then PSym(p,PSym(q,PSym(r,a))),PSym(p,PSym(q,PSym(r,p))) // p,a by A1,Def1; then PSym(p,PSym(q,PSym(r,a))),PSym(p,PSym(q,PSym(r,p))) // PSym(r,PSym(q, PSym(p,a))),PSym(p,PSym(q,PSym(r,p))) by A4,A5,Def1; hence thesis by Th4,Th7; end; theorem ex d st PSym(a,PSym(b,PSym(c,p))) = PSym(d,p) proof consider e such that A1: Mid a,e,c by Th19; consider d such that A2: Mid b,e,d by Th21; c = PSym(e,a) by A1,Def4; then PSym(c,PSym(d,p)) = PSym(PSym(e,a),PSym(PSym(e,b),p)) by A2,Def4 .= PSym(PSym(e,a),PSym(e,PSym(b,PSym(e,p)))) by Th37 .= PSym(e,PSym(a,PSym(e,PSym(e,PSym(b,PSym(e,p)))))) by Th37 .= PSym(e,PSym(a,PSym(b,PSym(e,p)))) by Th29 .= PSym(e,PSym(e,PSym(b,PSym(a,p)))) by Th39 .= PSym(b,PSym(a,p)) by Th29; then PSym(d,p) = PSym(c,PSym(b,PSym(a,p))) by Th29; hence thesis by Th39; end; theorem ex c st PSym(a,PSym(c,p)) = PSym(c,PSym(b,p)) proof consider c such that A1: Mid a,c,b by Th19; PSym(b,p) = PSym(PSym(c,a),p) by A1,Def4 .= PSym(c,PSym(a,(PSym(c,p)))) by Th37; then PSym(c,PSym(b,p)) = PSym(a,(PSym(c,p))) by Th29; hence thesis; end; :: :: Addition on the carrier :: definition let AFV,o; let a,b; func Padd(o,a,b) -> Element of AFV means :Def5: o,a // b,it; correctness by Def1,Th5; end; notation let AFV,o; let a; synonym Pcom(o,a) for PSym(o,a); end; Lm1: Pcom(o,a) = b iff a,o // o,b by Def4,Def3; definition let AFV,o; func Padd(o) -> BinOp of the carrier of AFV means :Def6: for a,b holds it.(a ,b) = Padd(o,a,b); existence proof deffunc F(Element of AFV, Element of AFV) = Padd(o,$1,$2); consider O being BinOp of the carrier of AFV such that A1: for a,b holds O.(a,b) = F(a,b) from BINOP_1:sch 4; take O; thus thesis by A1; end; uniqueness proof set X = the carrier of AFV; let o1,o2 be BinOp of the carrier of AFV such that A2: for a,b holds o1.(a,b) = Padd(o,a,b) and A3: for a,b holds o2.(a,b) = Padd(o,a,b); for x being Element of [:X,X:] holds o1.x = o2.x proof let x be Element of [:X,X:]; consider x1,x2 being Element of X such that A4: x = [x1,x2] by DOMAIN_1:1; o1.x = o1.(x1,x2) by A4 .= Padd(o,x1,x2) by A2 .= o2.(x1,x2) by A3 .= o2.x by A4; hence thesis; end; hence thesis by FUNCT_2:63; end; end; definition let AFV,o; func Pcom(o) -> UnOp of the carrier of AFV means :Def7: for a holds it.a = Pcom(o,a); existence proof deffunc F(Element of AFV) = Pcom(o,$1); consider O being UnOp of the carrier of AFV such that A1: for a holds O.a = F(a) from FUNCT_2:sch 4; take O; thus thesis by A1; end; uniqueness proof set X = the carrier of AFV; let o1,o2 be UnOp of the carrier of AFV such that A2: for a holds o1.a = Pcom(o,a) and A3: for a holds o2.a = Pcom(o,a); for x being Element of X holds o1.x = o2.x proof let x be Element of X; o1.x = Pcom(o,x) by A2 .= o2.x by A3; hence thesis; end; hence thesis by FUNCT_2:63; end; end; definition let AFV,o; func GroupVect(AFV,o) -> strict addLoopStr equals addLoopStr(#the carrier of AFV,Padd(o),o#); correctness; end; registration let AFV,o; cluster GroupVect(AFV,o) -> non empty; coherence; end; theorem the carrier of GroupVect(AFV,o) = the carrier of AFV & the addF of GroupVect(AFV,o) = Padd(o) & 0.GroupVect(AFV,o) = o; reserve a,b,c for Element of GroupVect(AFV,o); theorem for a,b being Element of GroupVect(AFV,o), a9,b9 being Element of AFV st a=a9 & b=b9 holds a + b = (Padd(o)).(a9,b9); Lm2: a+b = b+a proof reconsider a9=a,b9=b as Element of AFV; reconsider c9=(a+b) as Element of AFV; c9= Padd(o,a9,b9) by Def6; then o,a9 // b9,c9 by Def5; then o,b9 // a9,c9 by Def1; then c9 = Padd(o,b9,a9) by Def5 .= b + a by Def6; hence thesis; end; Lm3: (a+b)+c = a+(b+c) proof reconsider a9=a,b9=b,c9=c as Element of AFV; set p= b+c,q=a+b; reconsider p9=p,q9=q as Element of AFV; reconsider x9=(a+p) ,y9=(q+c) as Element of AFV; consider x99 such that A1: x9,p9 // c9,x99 by Def1; x9= Padd(o,a9,p9) by Def6; then o,a9 // p9,x9 by Def5; then A2: a9,o // x9,p9 by Th7; c9,x99 // x9,p9 by A1,Th3; then A3: a9,o // c9,x99 by A2,Def1; q9= Padd(o,a9,b9) by Def6; then o,a9 // b9,q9 by Def5; then o,b9 // a9,q9 by Def1; then A4: a9,q9 // o,b9 by Th3; p9= Padd(o,b9,c9) by Def6; then o,b9 // c9,p9 by Def5; then c9,p9 // o,b9 by Th3; then a9,q9 // c9,p9 by A4,Def1; then A5: q9,o // p9,x99 by A3,Def1; x9,c9 // p9,x99 by A1,Def1; then q9,o // x9,c9 by A5,Def1; then o,q9 // c9,x9 by Th7; then A6: c9,x9 // o,q9 by Th3; y9= Padd(o,q9,c9) by Def6; then o,q9 // c9,y9 by Def5; then c9,y9 // o,q9 by Th3; then c9,y9 // c9,x9 by A6,Def1; hence thesis by Th4; end; Lm4: a + (0.(GroupVect(AFV,o))) = a proof reconsider a9=a as Element of AFV; reconsider x9=(a + (0.(GroupVect(AFV,o)))) as Element of AFV; x9= Padd(o,a9,o) by Def6; then o,a9 // o,x9 by Def5; hence thesis by Th4; end; Lm5: GroupVect(AFV,o) is Abelian add-associative right_zeroed proof thus for a,b holds a+b = b+a by Lm2; thus for a,b,c holds (a+b)+c = a+(b+c) by Lm3; thus for a holds a + 0.GroupVect(AFV,o) = a by Lm4; end; Lm6: GroupVect(AFV,o) is right_complementable proof let s be Element of GroupVect(AFV,o); reconsider s9 = s as Element of AFV; reconsider t = (Pcom(o)).s9 as Element of GroupVect(AFV,o); take t; Pcom(o,o) = o by Th28; then o,s9 // Pcom(o,s9),o by Th32; then A1: Padd(o,s9,Pcom(o,s9)) = o by Def5; thus s + t = (Padd(o)).(s9,(Pcom(o,s9))) by Def7 .= 0.GroupVect(AFV,o) by A1,Def6; end; registration let AFV,o; cluster GroupVect(AFV,o) -> Abelian add-associative right_zeroed right_complementable; coherence by Lm5,Lm6; end; theorem Th44: for a being Element of GroupVect(AFV,o), a9 being Element of AFV st a=a9 holds -a = (Pcom(o)).a9 proof let a be Element of GroupVect(AFV,o), a9 be Element of AFV; assume A1: a=a9; reconsider aa = (Pcom(o)).a9 as Element of GroupVect(AFV,o); Pcom(o,o) = o & o,a9 // Pcom(o,a9),Pcom(o,o) by Th28,Th32; then A2: Padd(o,a9,Pcom(o,a9)) = o by Def5; a + aa = (Padd(o)).(a,(Pcom(o,a9))) by Def7 .= 0.GroupVect(AFV,o) by A1,A2,Def6; hence thesis by RLVECT_1:def 10; end; theorem 0.GroupVect(AFV,o) = o; reserve a,b for Element of GroupVect(AFV,o); theorem Th46: for a ex b st b + b = a proof let a; reconsider a99=a as Element of AFV; consider b9 being Element of AFV such that A1: o,b9 // b9,a99 by Def1; reconsider b=b9 as Element of GroupVect(AFV,o); a99 = Padd(o,b9,b9) by A1,Def5 .= b+b by Def6; hence thesis; end; registration let AFV,o; cluster GroupVect(AFV,o) -> Two_Divisible; coherence proof for a ex b st b + b = a by Th46; hence thesis by TDGROUP:def 1; end; end; :: :: Representation Theorem for Directed Geometrical Bundles :: reserve AFV for AffVect, o for Element of AFV; theorem Th47: for a being Element of GroupVect(AFV,o) st a + a = 0.(GroupVect( AFV,o)) holds a = 0.(GroupVect(AFV,o)) proof let a be Element of GroupVect(AFV,o) such that A1: a + a = 0.(GroupVect(AFV,o)); reconsider a99=a as Element of AFV; o = Padd(o,a99,a99) by A1,Def6; then A2: o,a99 // a99,o by Def5; o,o // o,o by Th1; hence thesis by A2,TDGROUP:16; end; registration let AFV,o; cluster GroupVect(AFV,o) -> Fanoian; coherence proof for a being Element of GroupVect(AFV,o) st a + a = 0.(GroupVect(AFV,o) ) holds a = 0.(GroupVect(AFV,o)) by Th47; hence thesis by VECTSP_1:def 18; end; end; registration cluster strict non trivial for Uniquely_Two_Divisible_Group; existence proof set X = G_Real; X is non trivial by TDGROUP:6; hence thesis; end; end; definition mode Proper_Uniquely_Two_Divisible_Group is non trivial Uniquely_Two_Divisible_Group; end; theorem GroupVect(AFV,o) is Proper_Uniquely_Two_Divisible_Group; registration let AFV,o; cluster GroupVect(AFV,o) -> non trivial; coherence; end; theorem Th49: for ADG being Proper_Uniquely_Two_Divisible_Group holds AV(ADG) is AffVect proof let ADG be Proper_Uniquely_Two_Divisible_Group; ex a,b being Element of ADG st a<>b by STRUCT_0:def 10; hence thesis by TDGROUP:17; end; registration let ADG be Proper_Uniquely_Two_Divisible_Group; cluster AV(ADG) -> AffVect-like non trivial; coherence by Th49; end; theorem Th50: for AFV being strict AffVect holds for o being Element of AFV holds AFV = AV(GroupVect(AFV,o)) proof let AFV be strict AffVect; let o be Element of AFV; set X = GroupVect(AFV,o); now let x,y be object; set xy = [x,y]; A1: now set V = the carrier of AFV; assume A2: xy in the CONGR of AFV; set VV = [:V,V:]; xy`2 = y; then A3: y in VV by A2,MCART_1:10; then A4: y = [y`1,y`2] by MCART_1:21; xy`1 = x; then A5: x in VV by A2,MCART_1:10; then reconsider x1 = x`1, x2 = x`2, y1 = y`1, y2 = y`2 as Element of AFV by A3,MCART_1:10 ; reconsider x19 = x1, x29 = x2, y19 = y1, y29 = y2 as Element of X; A6: x = [x`1,x`2] by A5,MCART_1:21; then A7: x1,x2 // y1,y2 by A2,A4,ANALOAF:def 2; x19 # y29 = x29 # y19 proof reconsider z1=x19#y29,z2=x29#y19 as Element of AFV; z1 = Padd(o,x1,y2) by Def6; then o,x1 // y2,z1 by Def5; then x1,o // z1,y2 by Th7; then A8: o,x2 // y1,z1 by A7,Th12; z2 = Padd(o,x2,y1) by Def6; hence thesis by A8,Def5; end; hence [x,y] in CONGRD(X) by A6,A4,TDGROUP:def 2; end; now set V = the carrier of X; assume A9: xy in CONGRD(X); set VV = [:V,V:]; xy`2 = y; then A10: y in VV by A9,MCART_1:10; then A11: y = [y`1,y`2] by MCART_1:21; xy`1 = x; then A12: x in VV by A9,MCART_1:10; then reconsider x19 = x`1, x29 = x`2, y19 = y`1, y29 = y`2 as Element of X by A10, MCART_1:10; set z19 = x19 # y29, z29 = x29 # y19; reconsider x1 = x19, x2 = x29, y1 = y19, y2 = y29 as Element of AFV; reconsider z1=z19,z2=z29 as Element of AFV; A13: z2 = Padd(o,x2,y1) by Def6; z1 = Padd(o,x1,y2) by Def6; then A14: o,x1 // y2,z1 by Def5; A15: x = [x`1,x`2] by A12,MCART_1:21; then z19=z29 by A9,A11,TDGROUP:def 2; then o,x2 // y1,z1 by A13,Def5; then x1,x2 // y1,y2 by A14,Th12; hence xy in the CONGR of AFV by A15,A11,ANALOAF:def 2; end; hence [x,y] in CONGRD(X) iff [x,y] in the CONGR of AFV by A1; end; then the carrier of AV(X) = the carrier of AFV & CONGRD(X) = the CONGR of AFV by RELAT_1:def 2,TDGROUP:4; hence thesis by TDGROUP:4; end; theorem for AS being strict AffinStruct holds (AS is AffVect iff ex ADG being Proper_Uniquely_Two_Divisible_Group st AS = AV(ADG) ) proof let AS be strict AffinStruct; now assume AS is AffVect; then reconsider AS9 = AS as AffVect; set o = the Element of AS9; take ADG = GroupVect(AS9,o); AS9 = AV(ADG) by Th50; hence ex ADG being Proper_Uniquely_Two_Divisible_Group st AS = AV(ADG); end; hence thesis; end; definition let X,Y be non empty addLoopStr; let f be Function of the carrier of X,the carrier of Y; pred f is_Iso_of X,Y means f is one-to-one & rng(f) = the carrier of Y & for a,b being Element of X holds f.(a+b) = (f.a)+(f.b) & f.(0.X) = 0.Y & f. (-a) = -(f.a); end; definition let X,Y be non empty addLoopStr; pred X,Y are_Iso means ex f being Function of the carrier of X,the carrier of Y st f is_Iso_of X,Y; end; reserve ADG for Proper_Uniquely_Two_Divisible_Group; reserve f for Function of the carrier of ADG,the carrier of ADG; theorem Th52: for o9 being Element of ADG, o being Element of AV(ADG) st (for x being Element of ADG holds f.x = o9+x) & o=o9 holds for a,b being Element of ADG holds f.(a+b) =(Padd(o)).(f.a,f.b) & f.(0.ADG) = 0.(GroupVect(AV(ADG),o)) & f.(-a) = (Pcom(o)).(f.a) proof let o9 be Element of ADG, o be Element of AV(ADG); assume that A1: for x being Element of ADG holds f.x = o9+x and A2: o=o9; let a,b be Element of ADG; set a9=f.a,b9=f.b; A3: AV(ADG) = AffinStruct(#the carrier of ADG,CONGRD(ADG)#) by TDGROUP:def 3; then reconsider a99=a9,b99=b9 as Element of AV(ADG); thus f.(a+b) =(Padd(o)).((f.a),(f.b)) proof A4: ((Padd(o)).((f.a),(f.b))) = Padd(o,a99,b99) by Def6; then reconsider c99= (Padd(o)).((f.a),(f.b)) as Element of AV( ADG); reconsider c9=c99 as Element of ADG by A3; o,a99 // b99,c99 by A4,Def5; then [[o9,a9],[b9,c9]] in CONGRD(ADG) by A2,A3,ANALOAF:def 2; then A5: o9+c9 = a9+b9 by TDGROUP:def 2; a9 = o9+a & b9 = o9+b by A1; then o9+c9 = (o9+((a+o9)+b)) by A5,RLVECT_1:def 3 .= o9+(o9+(a+b)) by RLVECT_1:def 3; then c9 = o9+(a+b) by RLVECT_1:8 .= f.(a+b) by A1; hence thesis; end; f.(0.ADG) = o9+(0.ADG) by A1 .= 0.(GroupVect(AV(ADG),o)) by A2,RLVECT_1:4; hence f.(0.ADG) = 0.(GroupVect(AV(ADG),o)); thus f.(-a) = (Pcom(o)).(f.a) proof A6: ((Pcom(o)).(f.a)) = Pcom(o,a99) by Def7; then reconsider c99 = (Pcom(o)).(f.a) as Element of AV(ADG); reconsider c9=c99 as Element of ADG by A3; a99,o // o,c99 by A6,Lm1; then [[a9,o9],[o9,c9]] in CONGRD(ADG) by A2,A3,ANALOAF:def 2; then a9+c9 = o9+o9 by TDGROUP:def 2; then A7: o9+o9 = (o9+a)+c9 by A1 .= o9+(a+c9) by RLVECT_1:def 3; f.(-a) = o9+(-a) by A1 .= (c9+a)+(-a) by A7,RLVECT_1:8 .= c9+(a+(-a)) by RLVECT_1:def 3 .= c9+(0.ADG) by RLVECT_1:5 .= c9 by RLVECT_1:4; hence thesis; end; end; theorem Th53: for o9 being Element of ADG st (for b being Element of ADG holds f.b = o9+b) holds f is one-to-one proof let o9 be Element of ADG such that A1: for b being Element of ADG holds f.b = o9+b; now let x1,x2 be object such that A2: x1 in dom(f) & x2 in dom(f) and A3: f.x1 = f.x2; reconsider x19=x1,x29=x2 as Element of ADG by A2,FUNCT_2:def 1; o9+x29 = f.x19 by A1,A3 .= o9+x19 by A1; hence x1=x2 by RLVECT_1:8; end; hence thesis by FUNCT_1:def 4; end; theorem Th54: for o9 being Element of ADG, o being Element of AV(ADG) st (for b being Element of ADG holds f.b = o9+b) holds rng(f) = the carrier of GroupVect(AV(ADG),o) proof set X = the carrier of ADG; A1: X = dom(f) by FUNCT_2:def 1; let o9 be Element of ADG, o be Element of AV(ADG) such that A2: for b being Element of ADG holds f.b = o9+b; now let y be object; assume y in X; then reconsider y9=y as Element of X; set x9=y9-o9; f.x9 = o9+((-o9)+y9) by A2 .= (o9+(-o9))+y9 by RLVECT_1:def 3 .= y9+(0.ADG) by RLVECT_1:5 .= y by RLVECT_1:4; hence y in rng(f) by A1,FUNCT_1:def 3; end; then A3: X c= rng(f) by TARSKI:def 3; rng(f) c= X & X = the carrier of GroupVect(AV(ADG),o) by RELAT_1:def 19 ,TDGROUP:4; hence thesis by A3,XBOOLE_0:def 10; end; theorem for ADG being Proper_Uniquely_Two_Divisible_Group, o9 being Element of ADG, o being Element of AV(ADG) st o=o9 holds ADG,GroupVect(AV(ADG),o) are_Iso proof let ADG be Proper_Uniquely_Two_Divisible_Group, o9 be Element of ADG, o be Element of AV(ADG) such that A1: o=o9; set AS = AV(ADG); set X = the carrier of ADG,Z=GroupVect(AS,o); set T = the carrier of GroupVect(AS,o); deffunc F(Element of X) = o9+$1; consider g being UnOp of X such that A2: for a being Element of X holds g.a = F(a) from FUNCT_2:sch 4; X = T by TDGROUP:4; then reconsider f = g as Function of X,T; A3: now let a,b be Element of ADG; reconsider fa = f.a as Element of AV(ADG); thus f.(a+b) = (f.a)+(f.b) by A1,A2,Th52; thus f.(0.ADG) = 0.Z by A1,A2,Th52; thus f.(-a) = (Pcom(o)).fa by A1,A2,Th52 .= -(f.a) by Th44; end; f is one-to-one & rng(f) = T by A2,Th53,Th54; then f is_Iso_of ADG,Z by A3; hence thesis; end;