:: Basic Properties and Concept of Selected Subsequence of Zero Based Finite :: Sequences :: http://creativecommons.org/licenses/by-sa/3.0/. environ vocabularies NUMBERS, SUBSET_1, FUNCT_1, NAT_1, TARSKI, MEMBERED, ORDINAL1, FINSET_1, RELAT_1, AFINSQ_1, ARYTM_1, ARYTM_3, FINSEQ_1, XXREAL_0, CARD_1, XBOOLE_0, ORDINAL4, FINSEQ_5, RFINSEQ, JORDAN3, CARD_3, XCMPLX_0, AFINSQ_2, BINOP_1, SETWISEO, FINSOP_1, FUNCOP_1, BINOP_2, VALUED_0, FUNCT_2, INT_1, PRGCOR_2, XREAL_0, SEQ_1, SERIES_1, VALUED_1, RAT_1, SQUARE_1, COMPLEX1, PARTFUN3, PRE_POLY, AMISTD_1, AMISTD_2, REAL_1, ORDINAL2; notations TARSKI, XBOOLE_0, SUBSET_1, XREAL_0, ORDINAL1, CARD_1, NUMBERS, RELAT_1, FUNCT_1, XCMPLX_0, NAT_1, FINSET_1, XXREAL_0, NAT_D, AFINSQ_1, SEQ_1, MEMBERED, VALUED_1, RELSET_1, PARTFUN1, FUNCT_2, FUNCOP_1, INT_1, BINOP_1, BINOP_2, SETWISEO, FINSOP_1, FINSEQ_1, RECDEF_1, VALUED_0, SERIES_1, RAT_1, PARTFUN3, RFINSEQ, ORDINAL2; constructors SERIES_1, PARTFUN3, WELLORD2, SETWISEO, FINSOP_1, NAT_D, RECDEF_1, BINOP_2, RELSET_1, AFINSQ_1, FUNCOP_1, SQUARE_1, BINOP_1, XTUPLE_0, RFINSEQ, ORDINAL2; registrations XBOOLE_0, RELAT_1, FUNCT_1, ORDINAL1, FUNCT_2, FINSET_1, NUMBERS, XXREAL_0, XREAL_0, NAT_1, BINOP_2, CARD_1, FINSEQ_1, AFINSQ_1, ORDINAL2, RELSET_1, ORDINAL3, VALUED_1, VALUED_0, MEMBERED; requirements REAL, NUMERALS, SUBSET, BOOLE, ARITHM; definitions TARSKI, XBOOLE_0, FUNCT_1; equalities VALUED_1, BINOP_1, ORDINAL1; expansions TARSKI, XBOOLE_0, FUNCT_1, BINOP_1, ORDINAL1, FINSEQ_1; theorems TARSKI, FUNCT_1, NAT_1, ZFMISC_1, RELAT_1, CARD_2, XBOOLE_0, XBOOLE_1, FINSET_1, ORDINAL1, CARD_1, XREAL_1, AFINSQ_1, XXREAL_0, NAT_2, FINSEQ_2, WELLORD2, MEMBERED, VALUED_0, VALUED_1, XREAL_0, NAT_D, SERIES_1, PARTFUN3, BINOP_1, BINOP_2, SETWISEO, FUNCOP_1, FINSOP_1, FINSEQ_1, FUNCT_2, XCMPLX_0, GRFUNC_1, RAT_1, INT_1, FINSEQ_3, RFINSEQ, ORDINAL2, FINSEQ_5; schemes NAT_1, AFINSQ_1, FUNCT_2, BINOP_1; begin :: Preparation reserve i,j,k,n,m for Nat, x,y,z,y1,y2 for object, X,Y,D for set, p,q for XFinSequence; Lm1: for X,Y be finite set,F be Function of X,Y st card X=card Y holds F is onto iff F is one-to-one proof let X,Y be finite set,F be Function of X,Y such that A1: card X=card Y; thus F is onto implies F is one-to-one proof assume A2: F is onto; assume F is not one-to-one; then consider x1,x2 be object such that A3: x1 in dom F and A4: x2 in dom F and A5: F.x1=F.x2 and A6: x1<>x2; reconsider Xx=X\{x1} as finite set; Y c= F.:Xx proof let Fy be object; assume Fy in Y; then Fy in rng F by A2,FUNCT_2:def 3; then consider y being object such that A7: y in dom F and A8: F.y=Fy by FUNCT_1:def 3; now per cases; suppose A9: y=x1; x2 in Xx by A4,A6,ZFMISC_1:56; hence thesis by A4,A5,A8,A9,FUNCT_1:def 6; end; suppose y<>x1; then y in Xx by A7,ZFMISC_1:56; hence thesis by A7,A8,FUNCT_1:def 6; end; end; hence thesis; end; then A10: Segm card Y c= Segm card Xx by CARD_1:66; {x1} meets X by A3,ZFMISC_1:48; then A11:Xx <>X by XBOOLE_1:83; Xx c< X by A11; hence thesis by A1,A10,NAT_1:39,CARD_2:48; end; thus F is one-to-one implies F is onto proof assume F is one-to-one; then A12: card dom F=card (F.:dom F) by CARD_1:5,CARD_1:33; assume F is not onto; then not rng F = Y by FUNCT_2:def 3; then not Y c= rng F; then consider y being object such that A13: y in Y and A14: not y in rng F; A15: card rng F <=card (Y\{y}) by A14,NAT_1:43,ZFMISC_1:34; A16: F.:dom F= rng F by RELAT_1:113; {y} meets Y by A13,ZFMISC_1:48; then A17:Y\{y} <>Y by XBOOLE_1:83; Y\{y} c< Y by A17; then card (Y\{y})< card Y by CARD_2:48; hence thesis by A1,A13,A15,A12,A16,FUNCT_2:def 1; end; end; theorem Th1: x in i implies x is Element of NAT proof i c= NAT; hence thesis; end; begin theorem Th2: for X0 being finite natural-membered set holds ex n st X0 c= Segm n proof let X0 be finite natural-membered set; consider p being Function such that A1: rng p = X0 and A2: dom p in NAT by FINSET_1:def 1; reconsider np=dom p as Element of NAT by A2; np=dom p; then reconsider p as XFinSequence by AFINSQ_1:5; X0 c= NAT by MEMBERED:6; then reconsider p as XFinSequence of NAT by A1,RELAT_1:def 19; defpred P[Nat] means ex n st for i st i in Segm $1 & $1-'1 in dom p holds p.i in n; A3: for k st P[k] holds P[k+1] proof let k; assume P[k]; then consider n such that A4: for i st i in k & k-'1 in dom p holds p.i in n; per cases; suppose A5: k+1-1 =k; m=len p; k+1-'1=k by NAT_D:34; then for i st i in (k+1) & (k+1)-'1 in dom p holds p.i in 2 by A12,AFINSQ_1:86; hence thesis; end; end; for i st i in 0 & 0-'1 in dom p holds p.i in 0; then A13: P[0]; for k holds P[k] from NAT_1:sch 2(A13,A3); then consider n such that A14: for i st i in Segm len p & len p -'1 in dom p holds p.i in n; rng p c= Segm n proof let y be object; assume y in rng p; then consider x being object such that A15: x in dom p and A16: y=p.x by FUNCT_1:def 3; A17: len p -1Nat,D()->non empty set,F(set)->Element of D()}: ex p being XFinSequence of D() st len p = i() & for j st j in i() holds p.j = F(j) proof consider z being XFinSequence such that A1: len z = i() and A2: for i st i in i() holds z.i = F(i) from AFINSQ_1:sch 2; for j be Nat st j in i() holds z.j in D() proof let j be Nat; reconsider j0=j as Element of NAT by ORDINAL1:def 12; assume j in i(); then z.j0 = F(j0) by A2; hence thesis; end; then reconsider z as XFinSequence of D() by A1,Th4; take z; thus len z = i() by A1; let j be Nat; thus thesis by A2; end; registration cluster empty natural-valued for XFinSequence; existence proof take the empty XFinSequence of NAT; thus thesis; end; let p be complex-valued Sequence-like Function; cluster -p -> Sequence-like; coherence proof dom p = dom -p & dom p is ordinal by VALUED_1:8; hence thesis; end; cluster p" -> Sequence-like; coherence proof dom p = dom (p") by VALUED_1:def 7; hence thesis; end; cluster p^2 -> Sequence-like; coherence proof dom p = dom (p^2) by VALUED_1:11; hence thesis; end; cluster abs p -> Sequence-like; coherence proof dom p = dom abs p by VALUED_1:def 11; hence thesis; end; let q be complex-valued Sequence-like Function; cluster p+q -> Sequence-like; coherence proof dom (p+q)=dom p /\dom q & dom p is ordinal & dom q is ordinal by VALUED_1:def 1; hence thesis; end; cluster p-q -> Sequence-like; coherence; cluster p(#)q -> Sequence-like; coherence proof dom (p(#)q)=dom p /\dom q & dom p is ordinal & dom q is ordinal by VALUED_1:def 4; hence thesis; end; cluster p/"q -> Sequence-like; coherence; end; registration let p be complex-valued finite Function; cluster -p -> finite; coherence proof dom p = dom -p by VALUED_1:8; hence thesis by FINSET_1:10; end; cluster p" -> finite; coherence proof dom p = dom (p") by VALUED_1:def 7; hence thesis by FINSET_1:10; end; cluster p^2 -> finite; coherence proof dom p = dom (p^2) by VALUED_1:11; hence thesis by FINSET_1:10; end; cluster abs p -> finite; coherence proof dom p = dom abs p by VALUED_1:def 11; hence thesis by FINSET_1:10; end; let q be complex-valued Function; cluster p+q -> finite; coherence proof dom (p+q)=dom p /\dom q by VALUED_1:def 1; hence thesis by FINSET_1:10; end; cluster p-q -> finite; coherence; cluster p(#)q -> finite; coherence proof dom (p(#)q)=dom p /\dom q by VALUED_1:def 4; hence thesis by FINSET_1:10; end; cluster p/"q -> finite; coherence; cluster q/"p -> finite; coherence; end; registration let p be complex-valued Sequence-like Function; let c be Complex; cluster c+p -> Sequence-like; coherence proof dom p = dom (c+p) by VALUED_1:def 2; hence thesis; end; cluster p-c -> Sequence-like; coherence; cluster c(#)p -> Sequence-like; coherence proof dom p = dom (c(#)p) by VALUED_1:def 5; hence thesis; end; end; registration let p be complex-valued finite Function; let c be Complex; cluster c+p -> finite; coherence proof dom p = dom (c+p) by VALUED_1:def 2; hence thesis by FINSET_1:10; end; cluster p-c -> finite; coherence; cluster c(#)p -> finite; coherence proof dom p = dom (c(#)p) by VALUED_1:def 5; hence thesis by FINSET_1:10; end; end; definition let p; func Rev p -> XFinSequence means :Def1: len it = len p & for i st i in dom it holds it.i = p.(len p - (i + 1)); existence proof deffunc F(Nat) = p.(len p - ($1 + 1)); ex q st len q = len p & for k st k in len p holds q.k = F(k) from AFINSQ_1:sch 2; hence thesis; end; uniqueness proof let f1,f2 be XFinSequence such that A1: len f1 = len p and A2: for i st i in dom f1 holds f1.i = p.(len p -(i + 1)) and A3: len f2 = len p and A4: for i st i in dom f2 holds f2.i = p.(len p -(i + 1)); now let i; assume A5: i in dom p; then f1.i = p.(len p - (i + 1)) by A1,A2; hence f1.i = f2.i by A3,A4,A5; end; hence thesis by A1,A3; end; end; theorem Th5: ::from FINSEQ_5:60 dom p = dom Rev p & rng p = rng Rev p proof thus A1: dom p = len p .= len (Rev p) by Def1 .= dom(Rev p); A2: len p = len(Rev p) by Def1; hereby let x be object; assume x in rng p; then consider z being object such that A3: z in dom p and A4: p.z = x by FUNCT_1:def 3; reconsider i=z as Element of NAT by A3; i+1<=len p by NAT_1:13,A3,AFINSQ_1:86; then len p -'(i+1)=len p -(i+1) by XREAL_1:233; then reconsider j = len p - (i + 1) as Element of NAT; A5: j in len (Rev p) by A2,AFINSQ_1:86,XREAL_1:44; then (Rev p).j = p.(len p - (j + 1)) by Def1; hence x in rng(Rev p) by A4,A5,FUNCT_1:def 3; end; let x be object; assume x in rng(Rev p); then consider z being object such that A6: z in dom(Rev p) and A7: (Rev p).z = x by FUNCT_1:def 3; reconsider i=z as Element of NAT by A6; i < len p by A2,A6,AFINSQ_1:86; then i+1<=len p by NAT_1:13; then len p -'(i+1)=len p -(i+1) by XREAL_1:233; then reconsider j = len p - (i + 1) as Element of NAT; len p -(i+1) D -valued; coherence proof rng f=rng (Rev f) by Th5; hence thesis by RELAT_1:def 19; end; end; definition let p,n; func p /^ n -> XFinSequence means :Def2: len it = len p -' n & for m st m in dom it holds it.m = p.(m+n); existence proof thus ex p1 be XFinSequence st len p1 = len p -' n & for m st m in dom p1 holds p1.m = p.(m+n) proof deffunc F(Nat)=p.($1+n); set k = len p -' n; consider q such that A1: len q = k & for m2 be Nat st m2 in k holds q.m2 = F( m2) from AFINSQ_1:sch 2; take q; thus thesis by A1; end; end; uniqueness proof let p1,p2 be XFinSequence; thus (len p1 = len p -' n & for m be Nat st m in dom p1 holds p1.m = p.(m+ n)) & (len p2 = len p -' n & for m be Nat st m in dom p2 holds p2.m = p.(m+n)) implies p1 = p2 proof assume that A2: len p1 = len p -' n and A3: for m st m in dom p1 holds p1.m = p.(m+n) and A4: len p2 = len p -' n and A5: for m st m in dom p2 holds p2.m = p.(m+n); now let m; assume A6: m in dom p1; then p1.m = p.(m+n) by A3; hence p1.m = p2.m by A2,A4,A5,A6; end; hence thesis by A2,A4; end; end; end; theorem Th6: n >= len p implies p/^n={} proof assume n>=len p; then len p-'n=0 by NAT_2:8; then len (p/^n)=0 by Def2; hence thesis; end; theorem Th7: n < len p implies len (p/^n) = len p -n proof assume n < len p; then len p-'n=len p-n by XREAL_0:def 2,XREAL_1:48; hence thesis by Def2; end; theorem Th8: m+n one-to-one; coherence proof let x,y be object; assume that A1: x in dom (f/^n) and A2: y in dom (f/^n) and A3: (f/^n).x=(f/^n).y; reconsider nx=x,ny=y as Nat by A1,A2; A4: nxlen f; then f/^n={} by Th6; hence thesis by A1; end; end; end; theorem Th9: rng (p/^n) c= rng p proof thus rng (p/^n) c= rng p proof let z be object; assume z in rng (p/^n); then consider x being object such that A1: x in dom (p/^n) and A2: z=(p/^n).x by FUNCT_1:def 3; reconsider nx=x as Element of NAT by A1; nx=len p; then (p/^n)={} by Th6; hence thesis by A1; end; end; end; theorem Th10: ::FINSEQ_5:31 p/^0 = p proof per cases; suppose A1: 0 =len p; then p/^0 ={} by Th6; hence thesis by A3; end; end; theorem Th11: ::FINSEQ_5:39 (p^q)/^(len p + i) = q/^i proof A1: len(p^q) = len p + len q by AFINSQ_1:17; per cases; suppose A2: i < len q; then len p + i < len p + len q by XREAL_1:6; then len p +i= len q; hence (p^q)/^(len p+i) = {} by Th6,A1,XREAL_1:6 .= q/^i by A7,Th6; end; end; theorem Th12: ::FINSEQ_5:40 (p^q)/^(len p) = q proof thus (p^q)/^(len p) = (p^q)/^(len p + (0 qua Element of NAT)) .= q/^0 by Th11 .= q by Th10; end; theorem Th13: ::RFINSEQ:21 (p|n)^(p/^n) = p proof set pn = p/^n; now per cases; case A1: len p<=n; p/^n = {} by A1,Th6; hence thesis by A1,AFINSQ_1:52; end; case A2: n empty; coherence; let n be Nat; cluster f/^(dom f + n) -> empty; coherence proof len f <= len f + n + 0 by NAT_1:11; then (len f) - (len f + n) <= 0 by XREAL_1:20; then (len f) -' (len f + n) = 0 by XREAL_0:def 2; then len (f/^(dom f + n)) = 0 by Def2; hence thesis; end; reduce f|(len f + n) to f; reducibility proof len f + n >= len f + 0 by XREAL_1:6; hence thesis by AFINSQ_1:52; end; reduce (f|n)^(f/^n) to f; reducibility by Th13; end; registration let D be set, f be XFinSequence of D, n; cluster f /^ n -> D -valued; coherence proof deffunc F(Element of NAT)=f.($1+n); set p = f /^ n; per cases; suppose A1: nD by Th6; hence thesis; end; end; end; reserve k1,k2 for Nat; definition let p,k1,k2; func mid(p,k1,k2) -> XFinSequence equals (p|k2)/^(k1-'1); coherence; end; theorem Th14: k1>k2 implies mid(p,k1,k2) = {} proof set k21=k2; A1: len (p|k21)<=k21 by AFINSQ_1:55; assume A2: k1>k2; then k1>= (0 qua Nat) +1 by NAT_1:13; then A3: k1-'1=k1-1 by XREAL_1:233; k1>=k2+1 by A2,NAT_1:13; then k1-1>=k2+1-1 by XREAL_1:9; hence thesis by A3,A1,Th6,XXREAL_0:2; end; theorem 1<=k1 & k2<=len p implies mid(p,k1,k2) = (p/^(k1-'1))|(k2+1-'k1) proof assume that A1: 1<=k1 and A2: k2<=len p; set k11=k1,k21=k2; A3: len (p|k21)=k21 by A2,AFINSQ_1:54; k1k2; then k2+1<=k1 by NAT_1:13; then A18: k2+1-'k1=0 by NAT_2:8; mid(p,k1,k2)={} by A17,Th14; hence thesis by A18; end; end; theorem Th16: :: FINSEQ_8:5 mid(p,1,k)=p|k proof 1-'1=0 by XREAL_1:232; hence thesis by Th10; end; theorem :: FINSEQ_8:6 len p<=k implies mid(p,1,k)=p proof assume A1: len p<=k; thus mid(p,1,k)=p|k by Th16 .=p by A1,AFINSQ_1:52; end; theorem :: FINSEQ_8:8 mid(p,0,k)=mid(p,1,k) proof A1: 0-'1=0 by NAT_2:8; mid(p,1,k) = (p|k) by Th16; hence thesis by A1,Th10; end; theorem :: FINSEQ_8:9 mid(p^q,len p+1,len p+len q)=q proof A1: (len p +1)-'1=len p by NAT_D:34; len (p^q)=len p + len q by AFINSQ_1:17; hence thesis by A1,Th12; end; registration let D be set, f be XFinSequence of D, k1,k2; cluster mid(f,k1,k2) -> D-valued; coherence; end; begin :: Selected Subsequences definition let X be finite natural-membered set; func Sgm0 X -> XFinSequence of NAT means :Def4: rng it = X & for l,m,k1,k2 being Nat st l < m & m < len it & k1=it.l & k2=it.m holds k1 < k2; existence proof defpred P[Nat] means for X being set st X c= Segm $1 ex p being XFinSequence of NAT st rng p = X & for l,m,k1,k2 being Nat st ( l < m & m < len p & k1=p.l & k2 =p.m) holds k1 < k2; A1: ex k being Nat st X c= Segm k by Th2; A2: for k being Nat st P[k] holds P[k+1] proof let k be Nat such that A3: for X being set st X c= Segm k ex p being XFinSequence of NAT st rng p = X & for l,m,k1,k2 be Nat st l < m & m < len p & k1=p.l & k2=p.m holds k1 < k2; let X be set; assume A4: X c= Segm(k+1); now set Y=X\{k}; assume not X c= k; then consider x being object such that A5: x in X and A6: not x in Segm k; reconsider n=x as Element of NAT by A4,A5,Th1; nk by TARSKI:def 1; m; A16: for l,m,k1,k2 be Nat st l < m & m < len q & k1=q.l & k2=q.m holds k1 < k2 proof let l,m,k1,k2 be Nat; assume that A17: l < m and A18: m < len q and A19: k1=q.l and A20: k2=q.m; m+1<=len q by A18,NAT_1:13; then A21: m<=len q -1 by XREAL_1:19; then l < len (p^<% k %>) -1 by A15,A17,XXREAL_0:2; then l < len p + len <% k %> -1 by AFINSQ_1:17; then l < len p + 1 -1 by AFINSQ_1:34; then A22: l in dom p by AFINSQ_1:86; A23: m<=len q-'1 by A21,XREAL_0:def 2; A24: now A25: k1 = p.l by A15,A19,A22,AFINSQ_1:def 3; assume m <> len q -'1; then m < len (p^<% k %>) -'1 by A15,A23,XXREAL_0:1; then m < len p + len <% k %> -'1 by AFINSQ_1:17; then m < len p + 1 -'1 by AFINSQ_1:34; then A26: m < len p by NAT_D:34; then m in dom p by AFINSQ_1:86; then k2 = p.m by A15,A20,AFINSQ_1:def 3; hence thesis by A14,A17,A26,A25; end; now assume m=len q -'1; then A27: q.m = (p^<% k %>).((len p + len <% k %>)-'1) by A15,AFINSQ_1:17 .= (p^<% k %>).((len p + 1)-'1) by AFINSQ_1:34 .=(p^<% k %>).(len p) by NAT_D:34 .= k by AFINSQ_1:36; k1 = p.l by A15,A19,A22,AFINSQ_1:def 3; then k1 in Y by A13,A22,FUNCT_1:def 3; hence thesis by A9,A20,A27,NAT_1:44; end; hence thesis by A24; end; A28: {k} c= X by A5,A8,ZFMISC_1:31; rng q = rng p \/ rng <% k %> by A15,AFINSQ_1:26 .= Y \/ {k} by A13,AFINSQ_1:33 .= X \/ {k} by XBOOLE_1:39 .= X by A28,XBOOLE_1:12; hence thesis by A16; end; hence thesis by A3; end; A29: P[0] proof let X be set; assume A30: X c= Segm 0; take <%>(NAT); thus rng <%>(NAT) = X by A30; thus thesis; end; for k2 being Nat holds P[k2] from NAT_1:sch 2(A29,A2); hence thesis by A1; end; uniqueness proof defpred S[XFinSequence] means for X st ex k being Nat st X c= k holds ($1 is XFinSequence of NAT & rng $1 = X & for l,m,k1,k2 being Nat st ( l < m & m < len $1 & k1=$1.l & k2=$1.m) holds k1 < k2) implies for q being XFinSequence of NAT st rng q = X & for l,m,k1,k2 being Nat st ( l < m & m < len q & k1=q.l & k2 =q.m) holds k1 < k2 holds q=$1; let p,q be XFinSequence of NAT such that A31: rng p = X and A32: for l,m,k1,k2 being Nat st l < m & m < len p & k1=p.l & k2=p.m holds k1 < k2 and A33: rng q = X and A34: for l,m,k1,k2 being Nat st l < m & m < len q & k1=q.l & k2=q.m holds k1 < k2; A35: for p being XFinSequence,x be object st S[p] holds S[p^<% x %>] proof let p be XFinSequence,x be object; assume A36: S[p]; let X be set; given k being Nat such that A37: X c= k; assume that A38: p^<% x %> is XFinSequence of NAT and A39: rng (p^<% x %>) = X and A40: for l,m,k1,k2 being Nat st l < m & m < len(p^<%x%>) & k1=(p^<% x %>).l & k2=(p^<% x %>).m holds k1 < k2; let q be XFinSequence of NAT; assume that A41: rng q = X and A42: for l,m,k1,k2 being Nat st l < m & m < len q & k1=q.l & k2=q.m holds k1 < k2; deffunc F(Nat) = q.$1; len q <> 0 proof assume len q = 0; then p^<%x%> = {} by A39,A41,AFINSQ_1:15,RELAT_1:38; then 0 = len (p^<%x%>) .= len p + len <%x%> by AFINSQ_1:17 .= 1 + len p by AFINSQ_1:34; hence contradiction; end; then consider n be Nat such that A43: len q = n+1 by NAT_1:6; A44: ex m being Nat st m=x & for l being Nat st l in X & l <> x holds l < m proof <%x%> is XFinSequence of NAT by A38,AFINSQ_1:31; then rng <%x%> c= NAT by RELAT_1:def 19; then {x} c= NAT by AFINSQ_1:33; then reconsider m=x as Element of NAT by ZFMISC_1:31; take m; thus m=x; thus for l being Nat st l in X & l <> x holds l < m proof len <%x%>=1 by AFINSQ_1:34; then A45: m= (p^<%x%>).(len p + len <%x%> -1) by AFINSQ_1:36 .= (p^<%x%>).(len(p^<%x%>) -1) by AFINSQ_1:17; len(p^<%x %>)) +1 by XREAL_1:29; then A46: len(p^<%x%>)-1 < len(p^<%x %>) by XREAL_1:19; let l be Nat; assume that A47: l in X and A48: l <> x; consider y being object such that A49: y in dom (p^<%x%>) and A50: l=(p^<%x%>).y by A39,A47,FUNCT_1:def 3; reconsider k=y as Element of NAT by A49; k < len (p^<%x%>) by A49,AFINSQ_1:86; then k < len p + len <%x%> by AFINSQ_1:17; then k < len p + 1 by AFINSQ_1:34; then A51: k<=len p by NAT_1:13; k <> len p by A48,A50,AFINSQ_1:36; then k< len p +1-1 by A51,XXREAL_0:1; then k < len p + len <%x%>-1 by AFINSQ_1:34; then A52: k < len(p^<%x%>)-1 by AFINSQ_1:17; then len(p^<%x %>) -'1=len(p^<%x %>)-1 by XREAL_0:def 2; hence thesis by A40,A50,A52,A46,A45; end; end; then reconsider m = x as Nat; A53: not x in rng p proof len p + 1 = len p + len <%x%> by AFINSQ_1:34 .= len (p^<%x%>) by AFINSQ_1:17; then A54: len p < len (p^<%x%>) by XREAL_1:29; A55: m = (p^<%x%>).(len p ) by AFINSQ_1:36; assume x in rng p; then consider y being object such that A56: y in dom p and A57: x=p.y by FUNCT_1:def 3; reconsider y as Element of NAT by A56; A58: y < len p by A56,AFINSQ_1:86; m = (p^<%x%>).y by A56,A57,AFINSQ_1:def 3; hence contradiction by A40,A58,A54,A55; end; A59: for z being object holds z in rng p \/ {x} \ {x} iff z in rng p proof let z be object; thus z in rng p \/ {x} \ {x} implies z in rng p proof assume A60: z in rng p \/ {x} \ {x}; then not z in {x} by XBOOLE_0:def 5; hence thesis by A60,XBOOLE_0:def 3; end; assume A61: z in rng p; then A62: z in rng p \/ {x} by XBOOLE_0:def 3; not z in {x} by A53,A61,TARSKI:def 1; hence thesis by A62,XBOOLE_0:def 5; end; deffunc Q(set) =q.$1; consider q9 being XFinSequence such that A63: len q9 = n and A64: for m be Nat st m in n holds q9.m = Q(m) from AFINSQ_1:sch 2; now let x be object; assume x in rng q9; then consider y being object such that A65: y in dom q9 and A66: x=q9.y by FUNCT_1:def 3; reconsider y as Element of NAT by A65; q.y in NAT; hence x in NAT by A63,A64,A65,A66; end; then rng q9 c= NAT; then reconsider f=q9 as XFinSequence of NAT by RELAT_1:def 19; A67: p is XFinSequence of NAT by A38,AFINSQ_1:31; A68: for m be Nat st m in dom <%x%> holds q.(len q9 + m) = <%x%>.m proof let m be Nat; assume m in dom <%x%>; then m in len <%x%>; then A69: m in 1 by AFINSQ_1:34; Segm(0+1)= Segm 0 \/ {0} by AFINSQ_1:2; then A70: m=0 by A69,TARSKI:def 1; q.(len q9 + m) = x proof x in {x} by TARSKI:def 1; then x in rng <%x%> by AFINSQ_1:33; then x in rng p \/ rng <%x%> by XBOOLE_0:def 3; then x in rng q by A39,A41,AFINSQ_1:26; then consider y being object such that A71: y in dom q and A72: x=q.y by FUNCT_1:def 3; reconsider y as Element of NAT by A71; y+1<=len q by NAT_1:13,A71,AFINSQ_1:86; then A73: y <= len q -1 by XREAL_1:19; len qx holds l x; then k < d by A43,A63,A70,A77,A74; hence contradiction by A42,A43,A76,A72,A75; end; hence thesis by A70; end; A78: dom q = (len q9 + len <%x%>) by A43,A63,AFINSQ_1:34; then A79: q9^<%x%> = q by A63,A64,A68,AFINSQ_1:def 3; A80: not x in rng f proof len f + 1 = len f + len <%x%> by AFINSQ_1:34 .= len (f^<%x%>) by AFINSQ_1:17; then A81: len f < len (f^<%x%>) by XREAL_1:29; A82: m = q.(len f) by A79,AFINSQ_1:36; assume x in rng f; then consider y being object such that A83: y in dom f and A84: x=f.y by FUNCT_1:def 3; reconsider y as Element of NAT by A83; A85: y < len f by A83,AFINSQ_1:86; m = q.y by A63,A64,A83,A84; hence contradiction by A42,A79,A85,A81,A82; end; A86: for z being object holds z in rng f \/ {x} \ {x} iff z in rng f proof let z be object; thus z in rng f \/ {x} \ {x} implies z in rng f proof assume A87: z in rng f \/ {x} \ {x}; then not z in {x} by XBOOLE_0:def 5; hence thesis by A87,XBOOLE_0:def 3; end; assume A88: z in rng f; then A89: z in rng f \/ {x} by XBOOLE_0:def 3; not z in {x} by A80,A88,TARSKI:def 1; hence thesis by A89,XBOOLE_0:def 5; end; X = rng p \/ rng <%x%> by A39,AFINSQ_1:26 .= rng p \/ {x} by AFINSQ_1:33; then A90: rng p = X\{x} by A59,TARSKI:2; A91: for l,m,k1,k2 being Nat st l < m & m < len p & k1=p.l & k2=p.m holds k1 < k2 proof let l,m,k1,k2 be Nat; assume that A92: l < m and A93: m < len p and A94: k1=p.l and A95: k2=p.m; l < len p by A92,A93,XXREAL_0:2; then l in dom p by AFINSQ_1:86; then A96: k1 = (p^<%x%>).l by A94,AFINSQ_1:def 3; len p < len p + 1 by XREAL_1:29; then m < len p + 1 by A93,XXREAL_0:2; then m < len p + len <%x%> by AFINSQ_1:34; then A97: m < len (p^<%x%>) by AFINSQ_1:17; m in dom p by A93,AFINSQ_1:86; then k2 = (p^<%x%>).m by A95,AFINSQ_1:def 3; hence thesis by A40,A92,A96,A97; end; A98: for l,m,k1,k2 being Nat st l < m & m < len f & k1=f.l & k2=f.m holds k1 < k2 proof let l,m,k1,k2 be Nat; assume that A99: l < m and A100: m < len f and A101: k1=f.l and A102: k2=f.m; A103: k2 = q.m by A64,A102,A63,A100,AFINSQ_1:86; l < n by A63,A99,A100,XXREAL_0:2; then l in Segm n by NAT_1:44; then A104: k1 = q.l by A64,A101; m < len q by A43,A63,A100,NAT_1:13; hence thesis by A42,A99,A104,A103; end; X = rng f \/ rng <%x%> by A41,A79,AFINSQ_1:26 .= rng f \/ {x} by AFINSQ_1:33; then A105: rng f = X\{x} by A86,TARSKI:2; ex m being Nat st X\{x} c= m by A37,XBOOLE_1:1; then q9 = p by A36,A91,A67,A90,A98,A105; hence thesis by A63,A64,A78,A68,AFINSQ_1:def 3; end; A106: S[{}]; A107: for p being XFinSequence holds S[p] from AFINSQ_1:sch 3(A106,A35); ex k being Nat st X c= Segm k by Th2; hence thesis by A31,A32,A33,A34,A107; end; end; registration let A be finite natural-membered set; cluster Sgm0 A -> one-to-one; coherence proof for x,y being object st x in dom(Sgm0 A) & y in dom(Sgm0 A) & (Sgm0(A)).x = (Sgm0(A)).y & x<>y holds contradiction proof let x,y be object; assume that A1: x in dom(Sgm0 A) and A2: y in dom(Sgm0 A) and A3: (Sgm0(A)).x = (Sgm0(A)).y and A4: x <> y; reconsider i = x, j = y as Element of NAT by A1,A2; per cases by A4,XXREAL_0:1; suppose A5: i < j; j < len(Sgm0 A) by A2,AFINSQ_1:86; hence contradiction by A3,A5,Def4; end; suppose A6: j < i; i < len(Sgm0 A) by A1,AFINSQ_1:86; hence contradiction by A3,A6,Def4; end; end; hence thesis; end; end; theorem Th20: :: FINSEQ_3:44 for A being finite natural-membered set holds len(Sgm0 A) = card A proof let A be finite natural-membered set; rng(Sgm0 A) = A by Def4; then (len(Sgm0 A)),A are_equipotent by WELLORD2:def 4; then card A = card((len(Sgm0 A))) by CARD_1:5; hence thesis; end; theorem Th21: for X,Y being finite natural-membered set st X c= Y & X <> {} holds (Sgm0 Y).0 <= (Sgm0 X).0 proof let X,Y be finite natural-membered set; assume that A1: X c= Y and A2: X <> {}; reconsider X0=X as finite set; 0 <> card X0 by A2; then 0 < len (Sgm0 X) by Th20; then A3: 0 in dom (Sgm0 X) by AFINSQ_1:86; A4: rng (Sgm0 Y)=Y by Def4; rng (Sgm0 X)=X by Def4; then (Sgm0 X).0 in X by A3,FUNCT_1:def 3; then consider x being object such that A5: x in dom (Sgm0 Y) and A6: (Sgm0 Y).x=(Sgm0 X).0 by A1,A4,FUNCT_1:def 3; reconsider nx=x as Nat by A5; A7: nx nx; hence thesis by A6,A7,Def4; end; case 0=nx; hence thesis by A6; end; end; hence thesis; end; theorem Th22: (Sgm0 {n}).0=n proof len (Sgm0 {n})=card {n} by Th20; then 0 in dom (Sgm0 {n}) by AFINSQ_1:86; then A1: (Sgm0 {n}).0 in rng (Sgm0 {n}) by FUNCT_1:def 3; rng (Sgm0 {n})={n} by Def4; hence thesis by A1,TARSKI:def 1; end; definition let B1,B2 be set; pred B1 {}; then A2: x in B1/\B2 by XBOOLE_0:def 4; then A3: nx in B2 by XBOOLE_0:def 4; nx in B1 by A2,XBOOLE_0:def 4; hence contradiction by A1,A3; end; hence thesis; end; theorem for B1,B2 being finite natural-membered set st B1 {} & (ex x being set st x in X & {x} {} and A2: ex x being set st x in X & {x} card Y by A1; then 0 < len (Sgm0 Y) by Th20; then A5: 0 in dom (Sgm0 Y) by AFINSQ_1:86; rng (Sgm0 Y)=Y by Def4; then A6: (Sgm0 Y).0 in Y by A5,FUNCT_1:def 3; reconsider x0=x as Element of NAT by A3,ORDINAL1:def 12; set nx=x0; nx in {x0} by TARSKI:def 1; then A7: nx<=(Sgm0 Y).0 by A4,A6; {x0} c= X by A3,TARSKI:def 1; then A8: (Sgm0 X).0 <= (Sgm0 {x0}).0 by Th21; (Sgm0 {x0}).0=nx by Th22; hence thesis by A8,A7,XXREAL_0:2; end; theorem Th27: for X0,Y0 being finite natural-membered set st X0 {} by A2,CARD_1:27,XBOOLE_1:15; A18: now assume that A19: not Z c= X0 and A20: not X0 c= Z; consider v1 being object such that A21: v1 in Z and A22: not v1 in X0 by A19; consider v10 being Element of X0 \/Y0 such that A23: v1=v10 and A24: ex k2 being Nat st v10=f.k2 & k2 in card X0 by A21; A25: v10 in Y0 by A17,A22,A23,XBOOLE_0:def 3; reconsider nv10 =v10 as Nat; consider v2 being object such that A26: v2 in X0 and A27: not v2 in Z by A20; X0 c= X0\/Y0 by XBOOLE_1:7; then consider x2 being object such that A28: x2 in dom f0 and A29: v2=f0.x2 by A11,A26,FUNCT_1:def 3; reconsider x20=x2 as Nat by A28; reconsider nv2 =v2 as Nat by A29; A30: x20 {} by A2,CARD_1:27,XBOOLE_1:15; A12: now assume that A13: not Z c= X and A14: not X c= Z; consider v1 being object such that A15: v1 in Z and A16: not v1 in X by A13; consider v10 being Element of X \/Y such that A17: v1=v10 and A18: ex k2 being Nat st v10=f.k2 & k2 in card X by A15; A19: v10 in Y by A11,A16,A17,XBOOLE_0:def 3; reconsider nv10 =v10 as Nat; consider v2 being object such that A20: v2 in X and A21: not v2 in Z by A14; X c= X\/Y by XBOOLE_1:7; then consider x2 being object such that A22: x2 in dom f0 and A23: v2=f0.x2 by A3,A20,FUNCT_1:def 3; reconsider x20=x2 as Nat by A22; now assume x20 < card X; then A24: x20 in Segm card X by NAT_1:44; card X <= card (X \/Y) by NAT_1:43,XBOOLE_1:7; then card X <= len f0 by Th20; then f.x20=f0.x20 by A24,AFINSQ_1:53; hence contradiction by A5,A10,A21,A23,A24,FUNCT_1:def 3; end; then A25: len f <=x20 by A4,AFINSQ_1:54; consider k20 being Nat such that A26: v10=f.k20 and A27: k20 in card X by A18; A28: f.k20=f0.k20 by A4,A27,AFINSQ_1:53; reconsider nv2 =v2 as Nat by A23; k20 {} by A2,CARD_1:27,XBOOLE_1:15; A22: now assume that A23: not Z c= Y0 and A24: not Y0 c= Z; consider v2 being object such that A25: v2 in Y0 and A26: not v2 in Z by A24; Y0 c= X0\/Y0 by XBOOLE_1:7; then consider x2 being object such that A27: x2 in dom f0 and A28: v2=f0.x2 by A6,A25,FUNCT_1:def 3; consider v1 being object such that A29: v1 in Z and A30: not v1 in Y0 by A23; consider v10 being Element of X0 \/Y0 such that A31: v1=v10 and A32: ex k2 being Nat st v10=f.k2 & k2 in Segm card Y0 by A29; A33: v10 in X0 by A21,A30,A31,XBOOLE_0:def 3; reconsider nv10 =v10 as Nat; reconsider nv2 =v2 as Nat by A28; consider k20 being Nat such that A34: v10=f.k20 and A35: k20 in Segm card Y0 by A32; A36: k20+card X0= card X0; then A41: x20-'card X0=x20-card X0 by XREAL_1:233; x20x20 by A39,XXREAL_0:2; then nv10>nv2 by A34,A28,A36,A37,Def4; hence contradiction by A1,A25,A33; end; A44: now per cases by A22; case Z0 c= Y0; hence Z0=Y0 by A19,CARD_2:102; end; case Y0 c=Z0; hence Z0=Y0 by A19,CARD_2:102; end; end; i+card X0 < len f0 by A2,A9,A11,XREAL_1:20; hence thesis by A15,A12,A44,Th8; end; theorem Th31: for X,Y being finite natural-membered set st X {} & X {} and A2: X 0 by A1; then 0 {} & X {} and A2: X 0 by A1; then 0 n; now per cases; suppose A14: k in dom p; set m1 = r.k; set n1 = p.k; now per cases by A13,XXREAL_0:1; suppose A15: m < n; then not m in Y by A1,A10; then m in X by A12,XBOOLE_0:def 3; then m in rng p by Def4; then consider x being object such that A16: x in dom p and A17: p.x = m by FUNCT_1:def 3; reconsider x as Element of NAT by A16; x < len p by A16,AFINSQ_1:86; then A18: x < k + 1 by A15,A17,Th33; A19: k < k + 1 by XREAL_1:29; k + 1 < len r by A9,A11,AFINSQ_1:86; then A20: n1 < m by A8,A14,A19,Def4; k < len p by A14,AFINSQ_1:86; then k < x by A17,A20,Th33; hence contradiction by A18,NAT_1:13; end; suppose A21: n < m; n in X \/ Y by A10,XBOOLE_0:def 3; then n in rng r by Def4; then consider x being object such that A22: x in dom r and A23: r.x = n by FUNCT_1:def 3; reconsider x as Element of NAT by A22; x < len r by A22,AFINSQ_1:86; then A24: x < k + 1 by A21,A23,Th33; A25: k < k + 1 by XREAL_1:29; k + 1 < len p by A9,AFINSQ_1:86; then A26: m1 < n by A8,A14,A25,Def4; k < len r by A11,A14,AFINSQ_1:86; then k < x by A23,A26,Th33; hence contradiction by A24,NAT_1:13; end; end; hence contradiction; end; suppose A27: not k in dom p; A28: k < k + 1 by XREAL_1:29; len p <= k by A27,AFINSQ_1:86; then len p < k + 1 by A28,XXREAL_0:2; hence contradiction by A9,AFINSQ_1:86; end; end; hence contradiction; end; end; 0{} by Th20,CARD_1:27; then A29: P[0] by A1,Th34; A30: for k holds P[k] from NAT_1:sch 2(A29,A7); defpred P[Nat] means $1 in dom q implies r.(len p + $1) = q.$1; A31: now let k; assume A32: P[k]; thus P[k+1] proof set n = q.(k + 1); set a = len p + (k + 1); set m = r.a; assume A33: k + 1 in dom q; then q.(k + 1) in rng q by FUNCT_1:def 3; then A34: n in Y by Def4; k + 1 q.(k + 1); now per cases; suppose A44: k in dom q; set m1 = r.(len p + k); set n1 = q.k; A45: k < len q by A44,AFINSQ_1:86; now per cases by A43,XXREAL_0:1; suppose A46: m < n; m in Y by A37,A38,XBOOLE_0:def 3; then m in rng q by Def4; then consider x being object such that A47: x in dom q and A48: q.x = m by FUNCT_1:def 3; reconsider x as Element of NAT by A47; x < len q by A47,AFINSQ_1:86; then A49: x < k + 1 by A46,A48,Th33; len p + k < len p + k + 1 by XREAL_1:29; then A50: n1 < m by A32,A35,A44,Def4; k < len q by A44,AFINSQ_1:86; then k < x by A48,A50,Th33; hence contradiction by A49,NAT_1:13; end; suppose A51: n < m; n in X \/ Y by A34,XBOOLE_0:def 3; then n in rng r by Def4; then consider x being object such that A52: x in dom r and A53: r.x = n by FUNCT_1:def 3; reconsider x as Element of NAT by A52; x < len r by A52,AFINSQ_1:86; then A54: x < len p + k + 1 by A51,A53,Th33; A55: k < k + 1 by XREAL_1:29; k + 1 < len q by A33,AFINSQ_1:86; then A56: m1 < n by A32,A44,A55,Def4; len p + k < len r by A6,A45,XREAL_1:6; then len p + k < x by A53,A56,Th33; hence contradiction by A54,NAT_1:13; end; end; hence contradiction; end; suppose A57: not k in dom q; A58: k < k + 1 by XREAL_1:29; len q <= k by A57,AFINSQ_1:86; hence contradiction by A33,AFINSQ_1:86,A58,XXREAL_0:2; end; end; hence contradiction; end; end; len q>0 implies Y <>{} by Th20,CARD_1:27; then A59: P[0] by A1,Th32; for k holds P[k] from NAT_1:sch 2(A59,A31); hence thesis by A6,A30,AFINSQ_1:def 3; end; assume A60: Sgm0(X \/ Y) = Sgm0(X) ^ Sgm0(Y); let m,n be Nat; assume that A61: m in X and A62: n in Y; n in rng q by A62,Def4; then consider y being object such that A63: y in dom q and A64: q.y = n by FUNCT_1:def 3; reconsider y as Element of NAT by A63; A65: n = r.(len p + y) by A60,A63,A64,AFINSQ_1:def 3; y < len q by A63,AFINSQ_1:86; then len p + y < len p + len q by XREAL_1:6; then A66: len p + y < len r by A60,AFINSQ_1:17; A67: len p<=len p+y by NAT_1:12; m in rng(Sgm0 X) by A61,Def4; then consider x being object such that A68: x in dom p and A69: p.x = m by FUNCT_1:def 3; reconsider x as Element of NAT by A68; x < len p by A68,AFINSQ_1:86; then A70: x < len p + y by A67,XXREAL_0:2; m = r.x by A60,A68,A69,AFINSQ_1:def 3; hence thesis by A65,A70,A66,Def4; end; definition let f be XFinSequence; let B be set; ::Following is a subsequence selected from f by B. func SubXFinS (f,B) -> XFinSequence equals f*Sgm0(B /\ Segm len f); coherence proof B/\ Segm len f c= dom f by XBOOLE_1:17; then rng Sgm0(B/\ Segm len f) c= dom f by Def4; hence thesis by AFINSQ_1:10; end; end; theorem Th36: for B being set holds len SubXFinS (p,B)= card (B/\ Segm(len p)) & for i st i < len SubXFinS (p,B) holds SubXFinS (p,B).i=p.((Sgm0 (B/\ Segm(len p))).i) proof let B be set; B/\ Segm len p c= dom p by XBOOLE_1:17; then rng Sgm0(B/\ Segm len p) c= dom p by Def4; then dom SubXFinS (p,B) = len Sgm0(B/\ Segm len p) by RELAT_1:27 .= card(B/\ Segm len p) by Th20; hence len SubXFinS (p,B)=card (B/\ Segm len p); let i; assume i < len SubXFinS (p,B); hence thesis by FUNCT_1:12,AFINSQ_1:86; end; registration let D be set; let f be XFinSequence of D, B be set; cluster SubXFinS(f,B) -> D-valued; coherence; end; registration let p; cluster SubXFinS (p,{}) -> empty; coherence proof len (SubXFinS (p,{})) =card {} by Th36; hence thesis; end; end; registration let B be set; cluster SubXFinS ({},B) -> empty; coherence; end; :: AFINSQ_2:48 => AFINSQ_2:83 reserve D for non empty set, F,G for XFinSequence of D, b for BinOp of D, d,d1,d2 for Element of D; scheme Sch5{D()->set, P[set]}: for F be XFinSequence of D() holds P[F] provided A1: P[<%>D()] and A2: for F be XFinSequence of D(),d be Element of D() st P[F] holds P[F^<%d%>] proof defpred R[set] means for F be XFinSequence of D() st len F = $1 holds P[F]; A3: for n st R[n] holds R[n+1] proof let n such that A4: for F be XFinSequence of D() st len F=n holds P[F]; let F be XFinSequence of D(); assume A5: len F = n + 1; then F <>{}; then consider G be XFinSequence, d be object such that A6: F = G^<%d%> by AFINSQ_1:40; reconsider G,dd=<%d%> as XFinSequence of D() by A6,AFINSQ_1:31; A7:rng dd c= D() & rng dd = {d} & d in {d} by AFINSQ_1:33,TARSKI:def 1; len dd = 1 by AFINSQ_1:34; then len F = len G + 1 by A6,AFINSQ_1:17; hence thesis by A2,A4,A5,A6,A7; end; let F be XFinSequence of D(); A8: len F=len F; card X = {} implies X = {}; then A9: R[0] by A1; for n holds R[n] from NAT_1:sch 2(A9,A3); hence thesis by A8; end; definition let D; let F be XFinSequence; assume A1:F is D-valued; let b; assume A2: b is having_a_unity or len F >= 1; func b "**" F -> Element of D means :Def8: :: STIRL2_1:def 3 it = the_unity_wrt b if b is having_a_unity & len F = 0 otherwise ex f be sequence of D st f.0 = F.0 & (for n st n+1 < len F holds f.(n + 1) = b.(f.n,F.(n + 1))) & it = f.(len F-1); existence proof now per cases; suppose len F = 0; hence thesis by A2; end; suppose A3: len F <> 0; defpred P[Nat] means for F st len F = $1 & len F <> 0 ex d be Element of D,f be sequence of D st f.0 = F.0 & (for n st n+1 < len F holds f.(n + 1) = b.(f.n,F.(n + 1))) & d = f.(len F-1); A4: for k st P[k] holds P[k + 1] proof let k such that A5: P[k]; let F such that A6: len F = k + 1 and len F <> 0; set G = F|k; A7: k < k+1 by NAT_1:13; then A8: len G = k by A6,AFINSQ_1:11; now per cases; suppose A9: len G = 0; then 0 in dom F by A6,A8,CARD_1:49,TARSKI:def 1; then A10: F.0 in rng F by FUNCT_1:def 3; reconsider f = NAT --> F.0 as sequence of D by A10, FUNCOP_1:45; take d = f.0,f; thus f.0 = F.0 by FUNCOP_1:7; thus for n st n+1 < len F holds f.(n + 1) = b.(f.n,F.(n + 1)) by A6,A8,A9,NAT_1:14; k 0; k < len F by A6,NAT_1:13; then k in dom F by AFINSQ_1:86; then A12: F.k in rng F by FUNCT_1:def 3; reconsider d1 = F.k as Element of D by A12; A13: 0 in len G by A11,AFINSQ_1:86; consider d be Element of D,f be sequence of D such that A14: f.0 = G.0 and A15: for n st n+1 K holds h.n = F(n) from FUNCT_2:sch 6; take a = h.k, h; h.0=f.0 by A8,A11,A18; hence h.0 =F.0 by A14,A13,FUNCT_1:47; thus for n st n+1 < len F holds h.(n + 1) = b.(h.n,F.(n + 1)) proof let n; assume n+1 < len F; then A19: n+1 <= len G by A6,A8,NAT_1:13; now per cases by A19,XXREAL_0:1; suppose A20: n+1 = len G; then A21: n 0; then 0< len F by A2; then A27: len F-1 is Element of NAT by NAT_1:20; given f1 be sequence of D such that A28: f1.0 = F.0 and A29: for n st n+1 = d proof len<%d%> = 1 by AFINSQ_1:33; then ex f be sequence of D st f.0=<%d%>.0& (for n st n+1 < len <%d%> holds f.(n+1) = b.(f.n,<%d%>.(n+1)))& b "**" <%d%>=f.(1-1) by Def8; hence thesis; end; reconsider zz=0 as Nat; theorem Th38: b "**" <%d1,d2%> = b.(d1,d2) proof len <%d1,d2%>=2 by AFINSQ_1:38; then consider f be sequence of D such that A1: f.0 = <%d1,d2%>.0 and A2: for n st n+1 < 2 holds f.(n + 1) = b.(f.n,<%d1,d2%>.(n + 1)) and A3: b "**" <%d1,d2%> = f.(2-1) by Def8; f.(zz+1)=b.(f.zz,<%d1,d2%>.(zz+1)) by A2; hence thesis by A1,A3; end; theorem Th39: b "**" <%d,d1,d2%> = b.(b.(d,d1),d2) proof set F=<%d,d1,d2%>; len F=3 by AFINSQ_1:39; then consider f be sequence of D such that A1: f.0 = F.0 and A2: for n st n+1 < 3 holds f.(n + 1) = b.(f.n,F.(n + 1)) and A3: b "**" F = f.(3-1) by Def8; A4: f.(1+1)=b.(f.1,F.(1+1)) by A2; f.(zz+1)=b.(f.zz,F.(zz+1)) by A2; hence thesis by A1,A3,A4; end; theorem Th40: :: STIRL2_1:45 b is having_a_unity or len F > 0 implies b "**" (F ^ <% d %>) = b.(b "**" F,d) proof assume A1: b is having_a_unity or len F > 0; now per cases; suppose A2: len F)=d by Th37,A3; len F=0 by A2,NAT_1:13; then b "**" F = the_unity_wrt b by A1,Def8; hence thesis by A1,A2,A4,NAT_1:13,SETWISEO:15; end; suppose A5: len F>=1; set G = F ^ <% d %>; reconsider lenF1=len F-1 as Element of NAT by A5,NAT_1:21; A6: G.(len F)=d by AFINSQ_1:36; A7: len G=len F+len <%d%> by AFINSQ_1:17 .=len F+1 by AFINSQ_1:33; then 1 <= len G by NAT_1:12; then consider f1 be sequence of D such that A8: f1.0 = G.0 and A9: for n st n+1 < len G holds f1.(n+1)=b.(f1.n,G.(n+1)) and A10: b "**" G = f1.(len G-1) by Def8; consider f be sequence of D such that A11: f.0 = F.0 and A12: for n st n+1 < len F holds f.(n+1)=b.(f.n,F.(n+1)) and A13: b "**" F = f.(len F-1) by A5,Def8; defpred P[Nat] means $1+1 < len G implies f.$1 = f1.$1; A14: P[n] implies P[n + 1] proof assume A15: P[n]; set n1=n+1; assume A16: n1+1= 1 & len G >= 1) implies b "**" (F ^ G) = b.(b "**" F,b "**" G) proof defpred P[XFinSequence of D] means for F,b st b is associative & (b is having_a_unity or len F >= 1 & len $1 >= 1) holds b "**" (F^$1)=b.(b "**" F,b "**" $1); A1: for G,d st P[G] holds P[G ^ <%d%>] proof let G,d such that A2: P[G]; let F,b such that A3: b is associative and A4: b is having_a_unity or len F >= 1 & len(G ^ <% d %>) >= 1; now per cases; suppose A5: len G<>0; then b is having_a_unity or len F>=1&len (F^G)=len F+len G & len F+len G >len F+zz by A4,AFINSQ_1:17,XREAL_1:8; then b.(b "**" (F ^ G),d)=b "**" ((F ^ G)^<%d%>) by Th40; then A6: b "**" (F ^ (G ^ <% d %>)) = b.(b "**" (F ^ G),d) by AFINSQ_1:27; len G>=1 by A5,NAT_1:14; then b "**" (F ^ (G ^ <% d %>))=b.(b.(b "**" F,b "**" G),d) by A2,A3,A4 ,A6 .= b.(b "**" F,b.(b "**" G,d)) by A3 .= b.(b "**" F,b "**" (G ^ <% d %>)) by A5,Th40; hence thesis; end; suppose len G=0; then A7: G = {}; hence b "**" (F ^(G ^ <% d %>)) = b "**"(F^({}^<% d %>)) .= b "**"(F^<% d %>) .= b.(b "**" F,d) by A4,Th40 .= b.(b "**" F,b "**" ({}^<%d%>)) by Th37 .= b.(b "**" F,b "**" (G ^ <% d %>)) by A7; end; end; hence thesis; end; A8: P[<%>D] proof let F,b; assume that b is associative and A9: b is having_a_unity or len F >= 1 & len <%>D >= 1; thus b "**" (F ^ <%>D) = b "**" (F^{}) .= b.(b "**" F,the_unity_wrt b) by A9,SETWISEO:15 .= b.(b "**" F,b "**" <%>D) by A9,Def8,CARD_1:27; end; for G holds P[G] from Sch5(A8,A1); hence thesis; end; theorem Th42: :: CARD_FIN:42 n in dom F & (b is having_a_unity or n <> 0 ) implies b.(b "**" F|n, F.n) = b "**" F|(n+1) proof assume that A1: n in dom F and A2: b is having_a_unity or n <> 0; len F>n by A1,AFINSQ_1:86; then A3: len (F|n)=n by AFINSQ_1:54; defpred P[Nat] means $1 in dom F & (b is having_a_unity or len (F |$1) >= 1) implies b.(b "**" F|$1, F.$1) = b "**" F|($1+1); A4: for k st P[k] holds P[k+1] proof let k such that P[k]; set k1=k+1; set Fk1=F|k1; set Fk2=F|(k1+1); assume that A5: k1 in dom F and A6: b is having_a_unity or len Fk1 >= 1; 0 < len F by A5; then A7: 0 in dom F by AFINSQ_1:86; 0 in Segm k1 by NAT_1:44; then 0 in dom F/\k1 by A7,XBOOLE_0:def 4; then 0 in dom Fk1 by RELAT_1:61; then A8: Fk1.0=F.0 by FUNCT_1:47; A9: k= 1 by A6,A13,NAT_1:13; then consider f2 be sequence of D such that A18: f2.0 = Fk2.0 and A19: for n st n+1 < len Fk2 holds f2.(n+1) = b.(f2.n,Fk2.(n+1)) and A20: b "**" Fk2= f2.((k1+1)-1) by A17,Def8; defpred R[Nat] means $1 < k1 implies f1.$1=f2.$1; A21: for m st R[m] holds R[m+1] proof let m such that A22: R[m]; set m1=m+1; assume A23: m1 < k1; k1< len F by A5,AFINSQ_1:86; then m1 < len F by A23,XXREAL_0:2; then A24: m1 in dom F by AFINSQ_1:86; m1 = 1; A32: F.0 in rng F by A30,FUNCT_1:def 3; len F>0 by A30; then A33: len (F|1)=1 by AFINSQ_1:54,NAT_1:14; then A34: (F|1)=<%(F|1).0%> by AFINSQ_1:34; 0 in Segm 1 by NAT_1:44; then A35: F.0=(F|1).0 by A33,FUNCT_1:47; len (F|(0 qua Ordinal))=0; then b "**" F|(0 qua Ordinal)=the_unity_wrt b by A31,Def8; then b.(b "**" F|(0 qua Ordinal), F.0)=F.0 by A31,A32,SETWISEO:15; hence thesis by A32,A34,A35,Th37; end; for k holds P[k] from NAT_1:sch 2(A29,A4); hence thesis by A1,A2,A3,NAT_1:14; end; theorem Th43: :: CARD_FIN:47 b is having_a_unity or len F >= 1 implies b "**" F = b "**" (XFS2FS F) proof assume A1: b is having_a_unity or len F >= 1; per cases by A1; suppose A2: len F >=1; set FS=XFS2FS F; len F=len FS by AFINSQ_1:def 9; then consider f be sequence of D such that A3: f.1 = FS.1 and A4: for n be Nat st 0<>n & n= 1) & G = F * P holds b "**" F = b "**" G proof let P be Permutation of dom F such that A1: b is commutative associative and A2: b is having_a_unity or len F >= 1 and A3: G = F * P; set xF=XFS2FS F; A4: b is having_a_unity or len xF >= 1 by A2,AFINSQ_1:def 9; set xG=XFS2FS G; defpred p[object,object] means for n st $1=n holds $2=P.(n-1)+1; dom F=len F; then reconsider d=dom F as Element of NAT; A6: for x being object st x in Seg d ex y being object st y in Seg d & p[x,y] proof let x be object such that A7: x in Seg d; reconsider x9=x as Element of NAT by A7; 1+zz<=x9 by A7,FINSEQ_1:1; then reconsider x91=x9-1 as Element of NAT by NAT_1:21; A8: x91+1<= d by A7,FINSEQ_1:1; then x91 = 1) & len F=len G & len F=len bFG & (for n st n in dom bFG holds bFG.n=b.(F.n,G.n)) holds b "**" F^G = b "**" bFG proof let bFG be XFinSequence of D such that A1: b is commutative associative and A2: b is having_a_unity or len F >= 1 and A3: len F=len G and A4: len F=len bFG and A5: for n st n in dom bFG holds bFG.n=b.(F.n,G.n); set xG=XFS2FS G; set xF=XFS2FS F; A6: b "**" F=b "**" xF & b "**" G=b "**" xG by A2,A3,Th43; set xb=XFS2FS bFG; A7: len xb=len bFG by AFINSQ_1:def 9; A8: for k be Nat st k in dom xb holds xb.k = b.(xF.k,xG.k) proof let k be Nat such that A9: k in dom xb; k in Seg len xb by A9,FINSEQ_1:def 3; then k>=1 by FINSEQ_1:1; then reconsider k1=k-1 as Element of NAT by NAT_1:21; A10: k in Seg len xb by A9,FINSEQ_1:def 3; then A11: 1<=k by FINSEQ_1:1; then A12: k1=k-'1 by XREAL_1:233; k in Seg len xb by A9,FINSEQ_1:def 3; then k1= 1 & D c= D1 /\ D2 & for x,y st x in D & y in D holds b1.(x,y)=b2.(x,y) & b1.(x,y) in D holds b1 "**" F = b2 "**" F proof let D1,D2 be non empty set; let b1 be BinOp of D1,b2 be BinOp of D2 such that A1: len F >= 1 and A2: D c= D1 /\ D2 and A3: for x,y st x in D & y in D holds b1.(x,y) = b2.(x,y) & b1.(x,y) in D; D1/\D2 c= D1 & D1/\D2 c= D2 by XBOOLE_1:17; then A4:D c= D1 & D c= D2 by A2; rng F c= D1 & rng F c= D2 by A4; then A5:F is D1-valued & F is D2-valued by RELAT_1:def 19; then consider F1 be sequence of D1 such that A6: F1.0 = F.0 and A7: for n st n+1 < len F holds F1.(n + 1) = b1.(F1.n,F.(n + 1)) and A8: b1 "**" F = F1.(len F-1) by A1,Def8; consider F2 be sequence of D2 such that A9: F2.0 = F.0 and A10: for n st n+1 < len F holds F2.(n + 1) = b2.(F2.n,F.(n + 1)) and A11: b2 "**" F = F2.(len F-1) by A1,Def8,A5; defpred P[Nat] means $1 < len F implies F1.$1 = F2.$1 & F1.$1 in D; 0 in dom F by A1,AFINSQ_1:86; then F.0 in rng F by FUNCT_1:def 3; then A12:P[0] by A6,A9; A13: P[n] implies P[n+1] proof assume A14:P[n]; assume A15:n+1 < len F; then n+1 in dom F & n < len F by NAT_1:13,AFINSQ_1:86; then A16:F.(n+1) in rng F & n in dom F by FUNCT_1:def 3,AFINSQ_1:86; A17:F1.(n + 1) = b1.(F1.n,F.(n + 1)) by A7,A15; then F1.(n + 1)= b2.(F2.n,F.(n + 1)) by A3,A16,A14,AFINSQ_1:86 .=F2.(n+1) by A10,A15; hence thesis by A16,A14,A17,A3,AFINSQ_1:86; end; reconsider l1=len F-1 as Element of NAT by A1,NAT_1:21; A18:l1 < l1+1 by NAT_1:13; P[n] from NAT_1:sch 2(A12,A13); hence thesis by A8,A11,A18; end; reserve F for XFinSequence, rF,rF1,rF2 for real-valued XFinSequence, r for Real, cF,cF1,cF2 for complex-valued XFinSequence, c,c1,c2 for Complex; Lm2:cF is COMPLEX -valued proof rng cF c= COMPLEX by VALUED_0:def 1; hence thesis by RELAT_1:def 19; end; Lm3:rF is REAL -valued proof rng rF c= REAL by VALUED_0:def 3; hence thesis by RELAT_1:def 19; end; definition let F; func Sum F ->Element of COMPLEX equals addcomplex "**" F; coherence; end; registration let f be empty complex-valued XFinSequence; cluster Sum f -> zero; coherence proof f is COMPLEX-valued & len f = 0 by Lm2; hence thesis by Def8,BINOP_2:1; end; end; theorem Th47: F is real-valued implies Sum F = addreal "**" F proof assume A1:F is real-valued; then rng F c= REAL by VALUED_0:def 3; then A2:F is REAL-valued by RELAT_1:def 19; rng F c= COMPLEX by A1,MEMBERED:1; then A3:F is COMPLEX-valued by RELAT_1:def 19; per cases by NAT_1:14; suppose A4:len F=0; hence addreal "**" F = 0 by Def8,A2,BINOP_2:2 .= Sum F by Def8,A3,A4,BINOP_2:1; end; suppose A5:len F>=1; A6: REAL = REAL /\ COMPLEX by MEMBERED:1,XBOOLE_1:28; now let x,y;assume x in REAL & y in REAL; then reconsider X=x,Y=y as Element of REAL; addreal.(x,y) = X+Y by BINOP_2:def 9; hence addreal.(x,y) =addcomplex.(x,y) & addreal.(x,y) in REAL by BINOP_2:def 3,XREAL_0:def 1; end; hence thesis by Th46,A5,A6,A2; end; end; theorem Th48: F is RAT-valued implies Sum F = addrat "**" F proof assume A1:F is RAT-valued; rng F c= COMPLEX by A1,MEMBERED:1; then A2:F is COMPLEX-valued by RELAT_1:def 19; per cases by NAT_1:14; suppose A3:len F=0; hence addrat "**" F = 0 by Def8,A1,BINOP_2:3 .= Sum F by Def8,A2,A3,BINOP_2:1; end; suppose A4:len F>=1; A5: RAT = RAT /\ COMPLEX by MEMBERED:1,XBOOLE_1:28; now let x,y;assume x in RAT & y in RAT; then reconsider X=x,Y=y as Element of RAT; addrat.(x,y) = X+Y by BINOP_2:def 15; hence addrat.(x,y) =addcomplex.(x,y) & addrat.(x,y) in RAT by BINOP_2:def 3,RAT_1:def 2; end; hence thesis by Th46,A4,A5,A1; end; end; theorem Th49: F is INT-valued implies Sum F = addint "**" F proof assume A1:F is INT-valued; rng F c= COMPLEX by A1,MEMBERED:1; then A2:F is COMPLEX-valued by RELAT_1:def 19; per cases by NAT_1:14; suppose A3:len F=0; hence addint "**" F = 0 by Def8,A1,BINOP_2:4 .= Sum F by Def8,A2,A3,BINOP_2:1; end; suppose A4:len F>=1; A5: INT = INT /\ COMPLEX by MEMBERED:1,XBOOLE_1:28; now let x,y;assume x in INT & y in INT; then reconsider X=x,Y=y as Element of INT; addint.(x,y) = X+Y by BINOP_2:def 20; hence addint.(x,y) =addcomplex.(x,y) & addint.(x,y) in INT by BINOP_2:def 3, INT_1:def 2; end; hence thesis by Th46,A4,A5,A1; end; end; theorem Th50: F is natural-valued implies Sum F = addnat "**" F proof assume A1:F is natural-valued; then rng F c= NAT by VALUED_0:def 6; then A2:F is NAT-valued by RELAT_1:def 19; rng F c= COMPLEX by A1,MEMBERED:1; then A3:F is COMPLEX-valued by RELAT_1:def 19; per cases by NAT_1:14; suppose A4:len F=0; hence addnat "**" F = 0 by Def8,A2,BINOP_2:5 .= Sum F by Def8,A3,A4,BINOP_2:1; end; suppose A5:len F>=1; A6: NAT = NAT /\ COMPLEX by MEMBERED:1,XBOOLE_1:28; now let x,y;assume x in NAT & y in NAT; then reconsider X=x,Y=y as Element of NAT; addnat.(x,y) = X+Y by BINOP_2:def 23; hence addnat.(x,y) =addcomplex.(x,y) & addnat.(x,y) in NAT by BINOP_2:def 3; end; hence thesis by Th46,A5,A6,A2; end; end; registration let F be real-valued XFinSequence; cluster Sum F -> real; coherence proof Sum F = addreal "**" F by Th47; hence thesis; end; end; registration let F be RAT-valued XFinSequence; cluster Sum F -> rational; coherence proof Sum F = addrat "**" F by Th48; hence thesis; end; end; registration let F be INT-valued XFinSequence; cluster Sum F -> integer; coherence proof Sum F = addint "**" F by Th49; hence thesis; end; end; registration let F be natural-valued XFinSequence; cluster Sum F -> natural; coherence proof Sum F = addnat "**" F by Th50; hence thesis; end; end; registration cluster natural-valued -> nonnegative-yielding for Relation; coherence proof let R be Relation; assume R is natural-valued; then for r be Real st r in rng R holds r >=0; hence thesis by PARTFUN3:def 4; end; end; theorem cF = {} implies Sum cF = 0; theorem Sum <%c%> = c proof c in COMPLEX by XCMPLX_0:def 2; hence thesis by Th37; end; theorem Sum <%c1,c2%> = c1 + c2 proof c1 in COMPLEX & c2 in COMPLEX by XCMPLX_0:def 2; then addcomplex "**" <%c1,c2%> = addcomplex.(c1,c2) by Th38 .= c1+c2 by BINOP_2:def 3; hence thesis; end; theorem Th54: :: RLVECT_1:58 NUMERAL1:1 Sum(cF1^cF2)=Sum(cF1)+Sum(cF2) proof A1: cF1 is COMPLEX -valued & cF2 is COMPLEX -valued by Lm2; thus Sum(cF1^cF2)=addcomplex.(Sum(cF1),Sum(cF2)) by Th41,A1 .= Sum(cF1)+Sum(cF2) by BINOP_2:def 3; end; theorem :: NUMERAL1:2 for S being Real_Sequence st rF=S|(n+1) holds Sum rF = Partial_Sums(S).n proof let S be Real_Sequence; A1:rF is REAL -valued by Lm3; n+1 c= NAT; then A2: n+1 c= dom S by FUNCT_2:def 1; assume A3: rF=S|(n+1); then dom rF = dom S /\ (n+1) by RELAT_1:61; then A4: dom rF = n+1 by A2,XBOOLE_1:28; then consider f be sequence of REAL such that A5: f.0 = rF.0 and A6: for m be Nat st m+1 < len rF holds f.(m + 1) = addreal.(f.m,rF.(m + 1)) and A7: addreal "**" rF = f.(len rF-1) by Def8,A1; defpred P[Nat] means $1 in dom rF implies f.$1=Partial_Sums(S).$1; A8: now let k; assume A9: P[k]; thus P[k+1] proof assume A10: k+1 in dom rF; then A11: k+1 < len rF by AFINSQ_1:86; then A12: k=1; consider f being sequence of REAL such that A5: f.0 = d.0 and A6: for n st n+1 < len d holds f.(n + 1) = addreal. (f.n,d.(n + 1)) and A7: Sum d = f.(len d-1) by A4,Def8,A3; consider g being sequence of REAL such that A8: g.0 = e.0 and A9: for n st n+1 < len e holds g.(n + 1) = addreal. (g.n,e.(n + 1)) and A10: Sum e = g.(len e-1) by A4,A1,Def8,A3; defpred P[Nat] means $1 in dom d implies f.$1 <= g.$1; A11: now let i; assume A12: P[i]; thus P[i+1] proof assume A13: i+1 in dom d; then A14: i+1 < len d by AFINSQ_1:86; then A15: i < len d by NAT_1:13; A16: d.(i+1) <= e.(i+1) by A2,A13; A17: f.(i+1) = addreal.(f.i,d.(i + 1)) by A6,A14 .= f.i + d.(i+1) by BINOP_2:def 9; g.(i+1) = addreal.(g.i,e.(i + 1)) by A1,A9,A14 .= g.i + e.(i+1) by BINOP_2:def 9; hence thesis by A12,A15,A17,A16,AFINSQ_1:86,XREAL_1:7; end; end; reconsider ld=len d-1 as Element of NAT by A4,NAT_1:21; len d-1 < len d - 0 by XREAL_1:10; then A18: ld in len d by AFINSQ_1:86; A19: P[0] by A2,A5,A8; for i holds P[i] from NAT_1:sch 2(A19,A11); hence thesis by A1,A7,A10,A18; end; suppose len d=0; then Sum d = the_unity_wrt addreal & Sum e = the_unity_wrt addreal by Def8,A3,A1; hence thesis; end; end; theorem Th57: Sum (n-->c) = n*c proof set Fn= n-->c; reconsider Fn as XFinSequence of COMPLEX by Lm2; A1:dom Fn = n by FUNCOP_1:13; now per cases; suppose dom Fn=0; hence thesis by A1; end; suppose A2: dom Fn>0; then consider f be sequence of COMPLEX such that A3: f.0 = Fn.0 and A4: for k st k+1 < len Fn holds f.(k + 1) = addcomplex.(f.k,Fn.(k + 1)) and A5: Sum Fn= f.(len Fn-1) by Def8; defpred P[Nat] means $1 < len Fn implies f.$1 =($1+1)*c; A6: for m st P[m] holds P[m+1] proof let m such that A7: P[m]; assume A8: m + 1 < len Fn; then f.(m+1)=addcomplex.(f.m,Fn.(m+1)) by A4; then A9: f.(m + 1) = f.m + Fn.(m+1) by BINOP_2:def 3; Fn.(m+1) = c by A1,FUNCOP_1:7,A8,AFINSQ_1:86; hence thesis by A7,A8,A9,NAT_1:13; end; reconsider lenFn1=len Fn -1 as Element of NAT by A2,NAT_1:20; A10: lenFn1r; assume A1:n in dom rF implies rF.n <= r; A2:len L=len rF by FUNCOP_1:13; now let n;assume n in dom rF; then rF.n <= r & L.n = r by A1,FUNCOP_1:7; hence rF.n <= L.n; end; then Sum rF <= Sum L by Th56,A2; hence thesis by Th57; end; theorem :: STIRL2_1:51 (for n st n in dom rF holds rF.n >= r) implies Sum rF >= len rF *r proof set L=len rF-->r; assume A1:n in dom rF implies rF.n >= r; A2:len L=len rF by FUNCOP_1:13; now let n;assume n in dom rF; then rF.n >= r & L.n = r by A1,FUNCOP_1:7; hence rF.n >= L.n; end; then Sum rF >= Sum L by Th56,A2; hence thesis by Th57; end; theorem Th60: :: STIRL2_1:52 rF is nonnegative-yielding & len rF > 0 & (ex x st x in dom rF & rF.x = r) implies Sum rF >= r proof assume that A1:rF is nonnegative-yielding and A2: len rF > 0 and A3: ex x st x in dom rF & rF.x = r; consider x such that A4: x in dom rF and A5: rF.x = r by A3; reconsider lenrF1=len rF-1 as Element of NAT by A2,NAT_1:20; A6: dom rF=lenrF1+1; reconsider x as Element of NAT by A4; A7: lenrF1 < lenrF1+1 by NAT_1:13; A8: x < len rF by A4,AFINSQ_1:86; then A9: x<=lenrF1 by A6,NAT_1:13; rF is REAL-valued by Lm3;then consider f be sequence of REAL such that A10: f.0 = rF.0 and A11: for n st n+1 < len rF holds f.(n + 1) = addreal.(f.n,rF.(n + 1)) and A12: addreal "**" rF= f.(len rF-1) by Def8,A2; defpred P[Nat] means $1 < x implies f.$1 >= 0; 0 in len rF by A2,AFINSQ_1:86; then rF.0 in rng rF by FUNCT_1:def 3; then A13:P[0] by A1,A10,PARTFUN3:def 4; A14:P[n] implies P[n+1] proof assume A15:P[n]; assume A16:n+1 < x; then n < x & n+1 < len rF by A8,NAT_1:13,XXREAL_0:2; then A17:f.(n + 1) = addreal.(f.n,rF.(n + 1)) & f.n >=0 & n+1 in dom rF by A11,A15,AFINSQ_1:86; then rF.(n+1) in rng rF by FUNCT_1:def 3; then rF.(n+1) >=0 by A1,PARTFUN3:def 4; then f.n+rF.(n + 1) >=zz+zz by A16,A15,NAT_1:13; hence thesis by A17,BINOP_2:def 9; end; A18:P[n] from NAT_1:sch 2(A13,A14); defpred P[Nat] means x <= $1 & $1 < len rF implies f.$1 >= r; now per cases; suppose A19: x=0; assume that x <= x and x < len rF; thus f.x>=r by A5,A10,A19; end; suppose x>0; then reconsider x1=x-1 as Element of NAT by NAT_1:20; assume that x <= x and A20: x < len rF; A21: x1 =0 by A21,A18,BINOP_2:def 9; then f.x>=r+(0 qua Real) by A5,XREAL_1:7; hence f.x>=r; end; end; then A22: P[x]; A23: for m be Nat st m>=x & P[m] holds P[m+1] proof let m be Nat such that A24: m>=x and A25: P[m]; reconsider m1 = m as Element of NAT by ORDINAL1:def 12; assume that x <= m+1 and A26: m+1 < len rF; m+1 in dom rF by A26,AFINSQ_1:86; then A27:rF.(m+1) in rng rF by FUNCT_1:def 3; f.(m1 + 1) = addreal.(f.m1,rF.(m1 + 1)) by A11,A26; then f.(m1+1)=f.m1+rF.(m1+1) & rF.(m1+1) >=0 by A27,A1,BINOP_2:def 9,PARTFUN3:def 4; then f.(m+1) >= r+(0 qua Real) by A24,A25,A26,NAT_1:13,XREAL_1:7; hence thesis; end; for m be Nat st m>=x holds P[m] from NAT_1:sch 8(A22,A23); then addreal "**" rF >= r by A12,A9,A7; hence thesis by Th47; end; theorem Th61: :: STIRL2_1:53 rF is nonnegative-yielding implies (Sum rF=0 iff (len rF=0 or rF = len rF --> 0)) proof assume A1: rF is nonnegative-yielding; hereby assume A2: Sum rF=0; assume A3: len rF <>0; set L=len rF -->0; assume rF <> len rF -->0; then consider k such that A4: k in dom L & L.k <> rF.k by AFINSQ_1:8,FUNCOP_1:13; rF.k in rng rF by A4,FUNCT_1:def 3; then L.k = 0 & rF.k >=0 by A4,A1,FUNCOP_1:7,PARTFUN3:def 4; hence contradiction by A2,Th60,A1,A4,A3; end; A5:rF is COMPLEX-valued by Lm2; assume len rF=0 or rF= len rF -->0 ; then Sum rF = 0 or Sum rF = len rF *0 by A5,Th57,Def8,BINOP_2:1; hence thesis; end; theorem Th62: c(#)cF|n = (c(#)cF)|n proof set ccF=c(#)cF; set cFn = cF|n; A1:len ccF = len cF & len (c(#)cFn) = len cFn by VALUED_1:def 5; per cases; suppose A2:n <= len cF; then A3:len(cFn) = n & len (ccF|n)=n by A1,AFINSQ_1:54; now let i; assume i < len (c(#)cFn); then A4: i in dom (c(#)cFn) by AFINSQ_1:86; thus (c(#)cFn).i = c* (cFn.i) by VALUED_1:6 .= c* (cF.i) by A4,A2,AFINSQ_1:53 .=ccF.i by VALUED_1:6 .=(ccF|n).i by A4,A1,A2,AFINSQ_1:53; end; hence thesis by A1,A3,AFINSQ_1:9; end; suppose n > len cF; then cF|n= cF & ccF|n=ccF by A1,AFINSQ_1:52; hence thesis; end; end; theorem c * Sum cF = Sum (c(#)cF) proof defpred P[Nat] means for cF st len cF=$1 holds c * Sum cF = Sum (c(#)cF); A1: for k st P[k] holds P[k+1] proof let k such that A2: P[k]; A3: kx holds (f|(dom f\{y}))"{x}=f"{x} proof let x,y be object; let f be Function; set d=dom f\{y}; assume A1: f.y<>x; A2: f"{x} c= (f|d)"{x} proof A3: dom (f|d)=dom f/\d by RELAT_1:61; let x1 be object such that A4: x1 in f"{x}; A5: f.x1 in {x} by A4,FUNCT_1:def 7; f.x1 in {x} by A4,FUNCT_1:def 7; then f.x1=x by TARSKI:def 1; then A6: not x1 in {y} by A1,TARSKI:def 1; x1 in dom f by A4,FUNCT_1:def 7; then x1 in d by A6,XBOOLE_0:def 5; then A7: x1 in dom (f|d) by A3,XBOOLE_0:def 4; then f.x1=(f|d).x1 by FUNCT_1:47; hence thesis by A7,A5,FUNCT_1:def 7; end; (f|d)"{x} c= f"{x} proof let x1 be object such that A8: x1 in (f|d)"{x}; A9: (f|d).x1 in {x} by A8,FUNCT_1:def 7; A10: x1 in dom (f|d) by A8,FUNCT_1:def 7; then dom (f|d)=dom f/\d & f.x1=(f|d).x1 by FUNCT_1:47,RELAT_1:61; hence thesis by A10,A9,FUNCT_1:def 7; end; hence thesis by A2; end; theorem :: CATALAN2:45 rng cF c= {0,c} implies Sum cF = c * card (cF"{c}) proof defpred P[Nat] means for cF,c st len cF=$1 & rng cF c= {0,c} holds Sum cF = c* card (cF"{c}); assume A1: rng cF c= {0,c}; A2: for k st P[k] holds P[k+1] proof let k such that A3: P[k]; let F be complex-valued XFinSequence, c be Complex such that A4: len F=k+1 and A5: rng F c= {0,c}; per cases; suppose A6: c <>0; ( not k in k)& Segm k \/ {k}= Segm(k+1) by AFINSQ_1:2; then A7: dom F\{k}=k by A4,ZFMISC_1:117; k 0 by FUNCOP_1:11; then Sum F = len F*0 by Th61; hence thesis by A20; end; end; A21: P[0] proof let F be complex-valued XFinSequence, c be Complex such that A22: len F=0 and rng F c= {0,c}; F"{c} c= 0 & F={} by A22,RELAT_1:132; then card (F"{c})=0 & Sum F =0; hence thesis; end; for k holds P[k] from NAT_1:sch 2(A21,A2); then P[len cF]; hence thesis by A1; end; theorem :: CATALAN2:48 Sum cF = Sum Rev cF proof cF is COMPLEX-valued by Lm2;then reconsider Fr2 = cF,Fr1 = Rev cF as XFinSequence of COMPLEX; A1: len Fr1=len Fr2 by Def1; defpred P[object,object] means for i st i=$1 holds $2=len Fr1-(1+i); A2: card len Fr1 =card len Fr1; A3: for x being object st x in len Fr1 ex y being object st y in len Fr1 & P[x,y] proof let x be object such that A4: x in len Fr1; reconsider k=x as Element of NAT by Th1,A4; k+1 <= len Fr1 by NAT_1:13,A4,AFINSQ_1:86; then A5: len Fr1-'(1+k)=len Fr1-(1+k) by XREAL_1:233; take len Fr1-'(1+k); len Fr1 +zz< len Fr1 +(1+k) by XREAL_1:8; then len Fr1-(1+k) < len Fr1+(1+k)-(1+k) by XREAL_1:9; hence thesis by A5,AFINSQ_1:86; end; consider P be Function of len Fr1,len Fr1 such that A6: for x being object st x in len Fr1 holds P[x,P.x] from FUNCT_2:sch 1(A3); for x1,x2 be object st x1 in len Fr1 & x2 in len Fr1 & P.x1 = P.x2 holds x1 = x2 proof let x1,x2 be object such that A7: x1 in len Fr1 and A8: x2 in len Fr1 and A9: P.x1 = P.x2; reconsider i=x1,j=x2 as Element of NAT by A7,A8,Th1; A10: P.x2=len Fr1-(1+j) by A6,A8; P.x1=len Fr1-(1+i) by A6,A7; hence thesis by A9,A10; end; then A11: P is one-to-one by FUNCT_2:56; then P is onto by A2,Lm1; then reconsider P as Permutation of dom Fr1 by A11; A12: now let x be object such that A13: x in dom Fr1; reconsider k=x as Element of NAT by A13; P.k=len Fr1-(1+k) by A6,A13; hence Fr1.x=Fr2.(P.x) by A1,Def1,A13; end; A14: now let x be object such that A15: x in dom Fr1; x in dom P by A15,FUNCT_2:52; then P.x in rng P by FUNCT_1:3; hence x in dom P & P.x in dom Fr2 by A1,A15,FUNCT_2:52; end; for x being object st x in dom P & P.x in dom Fr2 holds x in dom Fr1; then Fr1 = Fr2 * P by A14,A12,FUNCT_1:10; hence thesis by A1,Th44; end; theorem Th69: for f be Function,p,q,fp,fq be XFinSequence st rng p c= dom f & rng q c= dom f & fp = f*p & fq = f*q holds fp ^ fq = f*(p^q) proof let f be Function,p,q,fp,fq be XFinSequence such that A1: rng p c= dom f & rng q c= dom f & fp = f*p & fq = f*q; set pq=p^q; A2:rng pq = rng p \/rng q by AFINSQ_1:26; then A3:dom (f*pq)=dom pq by A1,RELAT_1:27,XBOOLE_1:8; reconsider fpq = f*pq as XFinSequence by A2,A1,AFINSQ_1:10,XBOOLE_1:8; A4:dom fp=dom p & dom fq = dom q by A1,RELAT_1:27; A5:dom pq=len p+len q & dom (fp^fq) = len fp+len fq by AFINSQ_1:def 3; A6:len fpq = len (fp^fq) by A2,A1,A4,A5,RELAT_1:27,XBOOLE_1:8; k < len fpq implies (fp^fq).k = fpq.k proof assume A7:k< len fpq; then A8:k in dom fpq by AFINSQ_1:86; per cases; suppose k < len p; then k in dom p by AFINSQ_1:86; then pq.k = p.k & fp.k = f.(p.k) & (fp^fq).k =fp.k by A1,A4,AFINSQ_1:def 3,FUNCT_1:13; hence thesis by A8,FUNCT_1:12; end; suppose A9:k >= len p; then reconsider kp=k-len p as Element of NAT by NAT_1:21; len p + kp < len p+len q by A5,A2,A1,A7,RELAT_1:27,XBOOLE_1:8; then kp < len q by XREAL_1:7; then pq.k = q.kp & (fp^fq).k = fq.kp & fq.kp = f.(q.kp) by A7,A1,A3,A4,A5,A9,AFINSQ_1:18,FUNCT_1:13,AFINSQ_1:86; hence thesis by A8,FUNCT_1:12; end; end; hence thesis by A6,AFINSQ_1:9; end; theorem for B1,B2 being finite natural-membered set st B1 D = the_unity_wrt b proof A1: len <%>D = 0; assume b is having_a_unity; hence thesis by A1,Def8; end; definition let D be set, F be XFinSequence of D^omega; func FlattenSeq F -> Element of D^omega means :Def10: ex g being BinOp of D^omega st (for p, q being Element of D^omega holds g.(p,q) = p^q) & it = g "**" F; existence proof deffunc F(Element of D^omega,Element of D^omega) = $1^$2; consider g being BinOp of D^omega such that A1: for a, b being Element of D^omega holds g.(a,b) = F(a,b) from BINOP_1:sch 4; take g "**" F, g; thus thesis by A1; end; uniqueness proof let it1, it2 be Element of D^omega; given g1 being BinOp of D^omega such that A2: for p, q being Element of D^omega holds g1.(p,q) = p^q and A3: it1 = g1 "**" F; given g2 being BinOp of D^omega such that A4: for p, q being Element of D^omega holds g2.(p,q) = p^q and A5: it2 = g2 "**" F; now let a, b be Element of D^omega; thus g1.(a,b) = a^b by A2 .= g2.(a,b) by A4; end; hence thesis by A3,A5,BINOP_1:2; end; end; theorem for D being set, d be Element of D^omega holds FlattenSeq <%d%> = d proof let D be set, d be Element of D^omega; ex g being BinOp of D^omega st (for p, q being Element of D^omega holds g.(p,q) = p^q) & FlattenSeq <%d%> = g "**" <% d %> by Def10; hence thesis by Th37; end; theorem for D being set holds FlattenSeq <%>(D^omega) = <%>D proof let D be set; consider g being BinOp of D^omega such that A1: for d1,d2 being Element of D^omega holds g.(d1,d2) = d1^d2 and A2: FlattenSeq <%>(D^omega) = g "**" <%>(D^omega) by Def10; A3: {} is Element of D^omega by AFINSQ_1:43; reconsider p = {} as Element of D^omega by AFINSQ_1:43; now let a be Element of D^omega; thus g.({},a) = {} ^ a by A1,A3 .= a; thus g.(a,{}) = a ^ {} by A1,A3 .= a; end; then A4: p is_a_unity_wrt g by BINOP_1:3; then g "**" <%>(D^omega) = the_unity_wrt g by Th71,SETWISEO:def 2; hence thesis by A2,A4,BINOP_1:def 8; end; theorem Th74: for D being set, F,G be XFinSequence of D^omega holds FlattenSeq (F ^ G) = FlattenSeq F ^ FlattenSeq G proof let D be set, F,G be XFinSequence of D^omega; consider g being BinOp of D^omega such that A1: for d1,d2 being Element of D^omega holds g.(d1,d2) = d1^d2 and A2: FlattenSeq (F ^ G) = g "**" F ^ G by Def10; now let a,b,c be Element of D^omega; thus g.(a,g.(b,c)) = a ^ g.(b,c) by A1 .= a ^ (b ^ c) by A1 .= a ^ b ^ c by AFINSQ_1:27 .= g.(a,b) ^ c by A1 .= g.(g.(a,b),c) by A1; end; then A3: g is associative; A4: {} is Element of D^omega by AFINSQ_1:43; reconsider p = {} as Element of D^omega by AFINSQ_1:43; now let a be Element of D^omega; thus g.({},a) = {} ^ a by A1,A4 .= a; thus g.(a,{}) = a ^ {} by A1,A4 .= a; end; then p is_a_unity_wrt g by BINOP_1:3; then g is having_a_unity or len F >= 1 & len G >= 1 by SETWISEO:def 2; hence FlattenSeq (F ^ G) = g.(g "**" F,g "**" G) by A2,A3,Th41 .= (g "**" F) ^ (g "**" G) by A1 .= FlattenSeq F ^ (g "**" G) by A1,Def10 .= FlattenSeq F ^ FlattenSeq G by A1,Def10; end; theorem for D being set, p,q be Element of D^omega holds FlattenSeq <% p,q %> = p ^ q proof let D be set, p,q be Element of D^omega; consider g being BinOp of D^omega such that A1: for d1,d2 being Element of D^omega holds g.(d1,d2) = d1^d2 and A2: FlattenSeq <% p,q %> = g "**" <% p,q %> by Def10; thus FlattenSeq <% p,q %> = g.(p,q) by A2,Th38 .= p ^ q by A1; end; theorem for D being set, p,q,r be Element of D^omega holds FlattenSeq <% p,q,r %> = p ^ q ^ r proof let D be set, p,q,r be Element of D^omega; consider g being BinOp of D^omega such that A1: for d1,d2 being Element of D^omega holds g.(d1,d2) = d1^d2 and A2: FlattenSeq <% p,q,r %> = g "**" <% p,q,r %> by Def10; thus FlattenSeq <% p,q,r %> = g.(g.(p,q),r) by A2,Th39 .= g.(p,q) ^ r by A1 .= p ^ q ^ r by A1; end; theorem Th77: p c= q implies p ^ (q /^ len p) = q proof assume A1: p c= q; A2: len p + len (q /^ len p) = len p + (len q -' len p) by Def2 .= len q + len p -' len p by A1,NAT_1:43,NAT_D:38 .= dom q by NAT_D:34; A3: for k st k in dom p holds q.k=p.k by A1,GRFUNC_1:2; for k st k in dom(q /^ len p) holds q.(len p + k) = (q /^ len p).k by Def2; hence p ^ (q /^ len p) = q by A2,A3,AFINSQ_1:def 3; end; reserve r,s for XFinSequence; theorem Th78: p c= q implies ex r st p^r = q proof assume A1: p c= q; take r = q /^ len p; thus p^r = q by A1,Th77; end; theorem Th79: for p,q being XFinSequence of D st p c= q ex r being XFinSequence of D st p^r = q proof let p,q being XFinSequence of D; assume p c= q; then consider r such that A1: p^r = q by Th78; reconsider r as XFinSequence of D by A1,AFINSQ_1:31; take r; thus thesis by A1; end; theorem q c= r implies p^q c= p^r proof assume q c= r; then consider s such that A1: q^s = r by Th78; p^q c= p^q^s by AFINSQ_1:74; hence thesis by A1,AFINSQ_1:27; end; theorem for D being set, F,G be XFinSequence of D^omega holds F c= G implies FlattenSeq F c= FlattenSeq G proof let D be set, F,G be XFinSequence of D^omega; assume F c= G; then consider F9 being XFinSequence of D^omega such that A1: F ^ F9 = G by Th79; FlattenSeq F ^ FlattenSeq F9 = FlattenSeq G by A1,Th74; hence thesis by AFINSQ_1:74; end; registration let p; let q be non empty XFinSequence; cluster p^q -> non empty; coherence by AFINSQ_1:30; cluster q^p -> non empty; coherence by AFINSQ_1:30; end; theorem CutLastLoc(p^<%x%>) = p proof set q = CutLastLoc(p^<%x%>); A1: len(p^<%x%>) -' 1 = len p + 1 -' 1 by AFINSQ_1:75 .= len p by NAT_D:34; A2: dom(p^<%x%>) = len(p^<%x%>) .= Segm(len p + 1) by AFINSQ_1:75 .= Segm len p \/ {len p} by AFINSQ_1:2; A3: not len p in dom p; LastLoc(p^<%x%>) = len(p^<%x%>) -' 1 by AFINSQ_1:70; hence A4: dom q = dom(p^<%x%>) \ {len p} by A1,VALUED_1:36 .= dom p by A2,A3,ZFMISC_1:117; let y be object; assume A5: y in dom q; A6: p c= p^<%x%> by AFINSQ_1:74; thus q.y = (p^<%x%>).y by A5,GRFUNC_1:2 .= p.y by A5,A4,A6,GRFUNC_1:2; end; :: generalizes BALLOT_1:1 to empty D theorem Th17: for D being set, p being XFinSequence of D, n being Nat holds XFS2FS(p|n) = (XFS2FS p)|n & XFS2FS(p/^n) = (XFS2FS p)/^n proof let D be set, p be XFinSequence of D, n be Nat; :: first part thus XFS2FS(p|n) = (XFS2FS p)|n proof A1: now let x be object; hereby assume A2: x in dom XFS2FS(p|n); then reconsider m1 = x as Nat; A3: 1 <= m1 & m1 <= len XFS2FS(p|n) by A2, FINSEQ_3:25; then reconsider m = m1 - 1 as Nat by INT_1:74; m+1 in dom XFS2FS(p|n) by A2; then m in dom(p|n) by AFINSQ_1:95; then A4: m in dom p & m in n by RELAT_1:57; then A5: m+1 in dom XFS2FS p by AFINSQ_1:95; m in Segm n by A4; then m < n by NAT_1:44; then m+1 <= n by NAT_1:13; then x in dom((XFS2FS p)|Seg n) by A3, A5, FINSEQ_1:1, RELAT_1:57; hence x in dom((XFS2FS p)|n) by FINSEQ_1:def 15; end; assume x in dom((XFS2FS p)|n); then x in dom((XFS2FS p)|Seg n) by FINSEQ_1:def 15; then A6: x in dom XFS2FS p & x in Seg n by RELAT_1:57; then reconsider m1 = x as Nat; A7: 1 <= m1 & m1 <= n by A6, FINSEQ_1:1; then reconsider m = m1-1 as Nat by INT_1:74; m+1 in dom XFS2FS p by A6; then A8: m in dom p by AFINSQ_1:95; m+1 <= n by A7; then m < n by NAT_1:13; then m in Segm n by NAT_1:44; then m in dom(p|n) by A8, RELAT_1:57; then m+1 in dom XFS2FS(p|n) by AFINSQ_1:95; hence x in dom XFS2FS(p|n); end; for k being Nat st k in dom XFS2FS(p|n) holds (XFS2FS(p|n)).k = ((XFS2FS p)|n).k proof let k be Nat; assume A9: k in dom XFS2FS(p|n); then A10: 1 <= k & k <= len XFS2FS(p|n) by FINSEQ_3:25; then reconsider m = k-1 as Nat by INT_1:74; m+1 in dom XFS2FS(p|n) by A9; then A11: m in dom(p|n) by AFINSQ_1:95; then m in Segm len(p|n); then m < len(p|n) by NAT_1:44; then A12: m+1 <= len(p|n) by NAT_1:13; Segm len(p|n) c= Segm len p by RELAT_1:60; then len(p|n) <= len p by NAT_1:39; then A13: k <= len p by A12, XXREAL_0:2; m in Segm n by A11; then m < n by NAT_1:44; then m+1 <= n by NAT_1:13; then A14: k in Seg n by A10, FINSEQ_1:1; thus (XFS2FS(p|n)).k = (p|n).(m+1-'1) by A10, A12, AFINSQ_1:def 9 .= (p|n).m by NAT_D:34 .= p.m by A11, FUNCT_1:47 .= p.(m+1-'1) by NAT_D:34 .= (XFS2FS p).k by A10, A13, AFINSQ_1:def 9 .= ((XFS2FS p)|Seg n).k by A14, FUNCT_1:49 .= ((XFS2FS p)|n).k by FINSEQ_1:def 15; end; hence XFS2FS(p|n) = (XFS2FS p)|n by A1, TARSKI:2; end; :: second part per cases; suppose A15: len p <= n; then p/^n = {} by Th6; then A16: XFS2FS(p/^n) = {}; len((XFS2FS p)/^n) = 0 proof per cases by A15, XXREAL_0:1; suppose len p < n; then A17: len p - n < n-n by XREAL_1:14; thus len((XFS2FS p)/^n) = len XFS2FS p -' n by RFINSEQ:29 .= len p -' n by AFINSQ_1:def 9 .= 0 by A17, XREAL_0:def 2; end; suppose A18: len p = n; thus len((XFS2FS p)/^n) = len XFS2FS p -' n by RFINSEQ:29 .= 0 + len p -' n by AFINSQ_1:def 9 .= 0 by A18, NAT_D:34; end; end; hence thesis by A16; end; suppose A19: n < len p; then A20: n <= len XFS2FS p by AFINSQ_1:def 9; A21: len XFS2FS(p/^n) = len(p/^n) by AFINSQ_1:def 9 .= len p -' n by Def2 .= len XFS2FS p -' n by AFINSQ_1:def 9 .= len((XFS2FS p)/^n) by RFINSEQ:29; now let k be Nat; assume A22: 1 <= k & k <= len XFS2FS(p/^n); then A23: 1 <= k & k <= len(p/^n) by AFINSQ_1:def 9; then reconsider m = k-1 as Nat by INT_1:74; m+1 <= len(p/^n) by A23; then m < len(p/^n) by NAT_1:13; then m in Segm len(p/^n) by NAT_1:44; then A24: m in dom(p/^n); A25: k in dom((XFS2FS p)/^n) by A21, A22, FINSEQ_3:25; A26: 1+0 <= k+n by A23, XREAL_1:7; k <= len p - n by A19, A23, Th7; then A27: k+n <= len p - n + n by XREAL_1:6; thus (XFS2FS(p/^n)).k = (p/^n).(m+1-'1) by A23, AFINSQ_1:def 9 .= (p/^n).m by NAT_D:34 .= p.(m+n) by A24, Def2 .= p.(n+m+1-'1) by NAT_D:34 .= (XFS2FS p).(k+n) by A26, A27, AFINSQ_1:def 9 .= ((XFS2FS p)/^n).k by A20, A25, RFINSEQ:def 1; end; hence thesis by A21; end; end; theorem Th5: :: from BALLOT_1:5 for D being set for d be FinSequence of D holds XFS2FS (FS2XFS d) = d proof let D be set; let d be FinSequence of D; set Xd=FS2XFS d; A1: len d = len Xd by AFINSQ_1:def 8; A2: len Xd = len XFS2FS Xd by AFINSQ_1:def 9; now let i such that A3: 1 <= i and A4: i <= len d; reconsider i1=i-1 as Nat by A3,NAT_1:21; A5: i1+1 = i; A6: i-'1 = i1 by XREAL_0:def 2; thus d.i = Xd.i1 by A4,A5,NAT_1:13,AFINSQ_1:def 8 .= (XFS2FS Xd).i by A3,A4,A6,A1,AFINSQ_1:def 9; end; hence thesis by A1,A2; end; registration let D be set, f be FinSequence of D; reduce XFS2FS (FS2XFS f) to f; reducibility by Th5; end; theorem for D being set, p being FinSequence of D, n being Nat holds (FS2XFS p)|n = FS2XFS(p|n) & (FS2XFS p)/^n = FS2XFS(p/^n) proof let D be set, p be FinSequence of D, n be Nat; thus (FS2XFS p)|n = FS2XFS XFS2FS((FS2XFS p)|n) .= FS2XFS((XFS2FS FS2XFS p)|n) by Th17 .= FS2XFS(p|n); thus (FS2XFS p)/^n = FS2XFS XFS2FS((FS2XFS p)/^n) .= FS2XFS((XFS2FS FS2XFS p)/^n) by Th17 .= FS2XFS(p/^n); end; :: analogous theorem of FINSEQ_5:34 theorem for D being set, p being one-to-one XFinSequence of D, n being Nat holds rng(p|n) misses rng(p/^n) proof let D be set, p be one-to-one XFinSequence of D, n be Nat; rng((XFS2FS p)|n) misses rng((XFS2FS p)/^n) by FINSEQ_5:34; then rng((XFS2FS p)|n) misses rng(XFS2FS(p/^n)) by Th17; then rng(XFS2FS(p|n)) misses rng(XFS2FS(p/^n)) by Th17; then rng(XFS2FS(p|n)) misses rng(p/^n) by AFINSQ_1:97; hence rng(p|n) misses rng(p/^n) by AFINSQ_1:97; end; registration cluster finite for Ordinal-Sequence; existence proof reconsider f = 0 --> omega as Ordinal-Sequence; take f; thus thesis; end; end; registration let A be finite Ordinal-Sequence, n be Nat; cluster A /^ n -> Ordinal-yielding; coherence proof consider a being Ordinal such that A1: rng A c= a by ORDINAL2:def 4; rng(A /^ n) c= rng A by Th9; hence thesis by A1, XBOOLE_1:1, ORDINAL2:def 4; end; end;